SKF4560_E Rolling Bearings in Industrial Gearboxes
Short Description
Rolling Bearings in Industrial Gearboxes...
Description
Rolling bearings in industrial gearboxes
© Copyright SKF 1997 The contents of this publication are the copyright of the publisher and may not be reproduced (even extracts) unless permission is granted. Every care has been taken to ensure the accuracy of the information contained in this publication but no liability can be accepted for any loss or damage whether direct, indirect or consequential arising out of the use of the information contained herein. Publication 4560 E Printed in Denmark on environmentally friendly, chlorine-free paper (Multiart Silk) by Scanprint as
Rolling bearings in industrial gearboxes
1 Industrial gearboxes – overview
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2 Bearing types for industrial gearboxes
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3 Design of bearing arrangements
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4 Dimensioning the bearing arrangement
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5 Lubrication and maintenance
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6 Recommended fits
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7 Mounting and dismounting bearings
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8 Application examples
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Rolling bearings in industrial gearboxes Handbook for the gearbox designer
Rolling bearings in industrial gearboxes
Foreword This Handbook is intended to provide the gearbox designer with the knowledge required to select bearings for gearboxes and to correctly design gearbox bearing arrangements. Recommendations are given based on experience gained by SKF during decades of cooperation with gearbox manufacturers the world over. General information regarding the selection, calculation, mounting and maintenance of ball and roller bearings is given in the SKF General Catalogue. The questions arising from the use of rolling bearings in industrial gearboxes are dealt with here. Data from the General Catalogue are only repeated here when it has been thought necessary for the sake of clarity. The application examples described comprise proven gearbox designs from major manufacturers which are worthy of note. Grateful thanks are extended to the companies concerned for the provision of the detailed information about their products and the permission to publish.
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Contents Made by SKF ® stands for excellence. It symbolises our consistent endeavour to achieve total quality in everything we do. For those who use our products, “Made by SKF” implies three main benefits. Reliability – thanks to modern, efficient products, based on our worldwide application know-how, optimised materials, forward-looking designs and the most advanced production techniques.
1 Industrial gearboxes – overview ............................... 9 Types of gearbox ............................................................ 9 Geared transmissions.................................................... 10 Demands made on gearboxes ...................................... 14 Selecting the gears ........................................................ 14 Designing the casing ..................................................... 15
Cost effectiveness – resulting from the favourable ratio between our product quality plus service facilities, and the purchase price of the product.
2 Bearing types for industrial gearboxes .................. 17 Deep groove ball bearings ............................................ 18
Market lead – which you can achieve by taking advantage of our products and services. Increased operating time and reduced down-time, as well as improved output and product quality are the key to a successful partnership.
Angular contact ball bearings ....................................... 20 Cylindrical roller bearings ............................................. 22 CARB™ roller bearings ................................................. 24 Spherical roller bearings ............................................... 26 Taper roller bearings ...................................................... 28 Spherical roller thrust bearings .................................... 30
3 Design of bearing arrangements............................. 33 Shafts and gear wheels in spur gearboxes ................. 33 Shafts in bevel gearboxes ............................................. 44 Shafts in worm gearboxes............................................. 50 Shafts and gear wheels for planetary gearboxes........ 56
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Rolling bearings in industrial gearboxes
4 Calculation of bearing arrangement ....................... 65 Bearing loads ................................................................. 65 Determination of external forces .................................. 66 Calculation of bearing loads ......................................... 74 Dimensioning the bearing arrangement ...................... 76
5 Lubrication and maintenance.................................. 91 Grease lubrication.......................................................... 92 Oil lubrication ................................................................. 95 Maintenance ................................................................... 98
6 Recommended fits..................................................103 7 Mounting and dismounting bearings .................... 109 Adjustment of angular contact bearings.................... 109
8 Application examples ............................................. 115
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The SKF Group – a worldwide corporation SKF is an international industrial Group operating in some 130 countries and is world leader in bearings. The company was founded in 1907 following the invention of the self-aligning ball bearing by Sven Wingquist and, after only a few years, SKF began to expand all over the world. Today, SKF has some 43 000 employees and more than 80 manufacturing facilities spread throughout the world. An international sales network includes a large number of sales companies and some 20 000 distributors and retailers. Worldwide availability of SKF products is supported by a comprehensive technical advisory service. The key to success has been a consistent emphasis on maintaining the
SKF manufactures ball bearings, roller bearings and plain bearings. The smallest are just a few millimetres (a fraction of an inch) in diameter, the largest several metres. In order to protect the bearings effectively against the ingress of contamination and the escape of lubricant, SKF also manufactures oil and bearing seals. SKF's subsidiaries CR and RFT S.p.A. are among the world's largest producers of seals.
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highest quality of its products and services. Continuous investment in research and development has also played a vital role, resulting in many examples of epoch-making innovations. The business of the Group consists of bearings, seals, special steel and a comprehensive range of other hightech industrial components. The experience gained in these various fields provides SKF with the essential knowledge and expertise required in order to provide the customers with the most advanced engineering products and efficient service.
The SKF house colours are blue and red, but the thinking is green. The latest example is the new factory in Malaysia, where the bearing component cleaning process conforms to the strictest ecological standards. Instead of trichloroethylene, a water-based cleaning fluid is used in a closed system. The cleaning fluid is recycled in the factory's own treatment plant.
SKF has developed the Channel concept in factories all over the world. This drastically reduces the lead time from raw material to end product as well as work in progress and finished goods in stock. The concept enables faster and smoother information flow, eliminates bottlenecks and bypasses unnecessary steps in production. The Channel team members have the knowledge and commitment needed to share the responsibility for fulfilling objectives in areas such as quality, delivery time, production flow etc.
The SKF Engineering & Research Centre is situated just outside Utrecht in The Netherlands. In an area of 17 000 square metres (185 000 sq.ft) some 150 scientists, engineers and support staff are engaged in the further improvement of bearing performance. They are developing technologies aimed at achieving better materials, better designs, better lubricants and better seals – together leading to an even better understanding of the operation of a bearing in its application. This is also where the SKF New Life Theory was evolved, enabling the design of bearings which are even more compact and offer even longer operational life.
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1 Industrial gearboxes – overview Types of gearbox . . . . . . . . . . 9 Geared transmission . . . . . . 10 Demands on gearboxes . . . 14 Selecting the gears . . . . . . . 14 Designing the casing . . . . . . 15
1 Industrial gearboxes – overview Types of gearbox
Industrial gearboxes – overview Gearboxes are devices for the transmission or translation of movement. In industry gearboxes are used to transform the speeds and torques produced by the prime mover in order that they are appropriate to the machine which is to be driven. The speeds and torques required by the machine are dictated by its use. Prime movers can generally only meet these requirements when combined with gears.
Types of gearbox Gearboxes are characterised by having at least three members: the power input, power take-off and the casing. The casing transmits the support moment to the base. In contrast, a coupling has only two members: the power input and power Gear Torque < M2 M1 >
Power P1 = P2 + Pv
take-off. The coupling housing has no part in the flow of force. The symbols used for power transmission by gearboxes and couplings are shown in figs 1 and 2 .
Fig 1
Fig 2
PV
Rotational speed ≤ n2 n1 >
M1 n1
Pv (with slip) M1 n1 P1 P2
Power P1 = P2 + Pv
n2
M2
Coupling Torque M1 = M2 Rotational speed n1 ≥ n 2
P1
M2
1
P2
n2
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1 Industrial gearboxes – overview Geared transmissions The main types of power transmission equipment are shown in the following. In addition, there are many combinations, for example bevel/spur gears, spur gears with belt drive input, or variable traction drives combined with a planetary gear.
Types of gearbox Fixed ratio transmissions, shift transmission
Infinitely variable transmissions
Geared transmissions • Spur gears • Planetary gears • Bevel gears • Worm gears • Hypoid gears • Helical gears
Mechanical transmissions • Belt drives • Roller drives • Ratchet gears
Hydraulic transmissions • Hydrostatic transmissions • Hydrodyanmic transmissions
Eccentric drives • Cyclo drives • Harmonic drives
Traction drives • Belt drives • Chain drives
Geared transmissions Geared transmissions are the most commonly used. They transmit power without slip, have high operational reliability and long life, require little maintenance and are characterised by the ability to accept overloading, small size and high efficiency.
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Gear wheels with straight cut teeth (➔ fig 3 a) are simple in design and can be accurately produced. The axial forces generated by inaccuracies and deformations (twisting) are negligible.
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Gear wheels with helical teeth (➔ fig 3 b) run more smoothly and can carry heavier loads than those with straight cut teeth. A more elaborate bearing arrangement is required because of the axial forces.
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The double helix or herringbone (➔ fig 3 c) allows for large tooth widths and can carry particularly heavy loads. The axial forces cancel each other out. Deviations in the helix angle cause axial vibrations.
Spur gears The spur gear is the most well-known and commonly used design of geared transmission. The dimensioning and manufacture of the gear wheels are the easiest to control. Their kinematic behaviour also forms the basis of planetary gears. Spur gears are in rolling contact and, irrespective of tooth type, have parallel axes.
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1 Industrial gearboxes – overview Geared transmissions Fig 3
1 a
b
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c
Internal gearing (➔ fig 3 d) has greater load carrying capacity than external because of the favourable osculation, but is more difficult to produce. The bearing arrangement is more complicated. The most frequent use is in planetary gears.
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Bevel gears
d Spur gear unit a) straight cut teeth b) helical teeth c) double helix d) internal gearing
Bevel gears having spirally cut teeth (➔ fig 4 c) with curved flanks have clear advantages in respect of load carrying capacity. Particularly those with ground teeth are quieter than the types described above. For bevel gears which have to transmit high power, the spiral bevel gears are the most frequently used.
The common characteristic of this type of rolling contact gearing is that the axes of the wheels intersect each other. There are three basic designs categorised by the form of the flank. ●
With straight cut teeth (➔ fig 4 a), the mesh begins and ends across the total tooth width. The noise produced considerably limits the usefulness of straight cut bevel gears.
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Bevel gears with helical teeth (➔ fig 4 b) have straight flanks. The teeth are usually ground and the mesh is gradual. The total overlap is bigger and the noise behaviour better than with straight cut teeth.
Bevel gear unit a) straight cut teeth b) helical teeth c) spirally cut teeth Fig 4
a
b
c
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1 Industrial gearboxes – overview Geared transmissions Hypoid gear unit
Fig 5
Worm gears The worm and wheel axes cross each other at a considerable distance and usually at an angle < 90° (➔ fig 6 ). Worm gears are suitable for large single stage speed reduction. Their operation is quiet and vibration damping. The efficiency is lower than that of competing bevel/spur and planetary gears, because of the higher proportion of sliding motion. To reduce the friction, the use of synthetic lubricants is favoured. The most commonly used design is the cylindrical worm paired with a globoid wheel (➔ fig 6 a). The cylindrical worm can be hardened and ground which improves load carrying capacity; it is also freely adjustable in the axial direction so that bearing arrangement and mounting can be simplified. Two other designs – globoid worm with spur wheel (➔ fig 6 b) and globoid worm with globoid wheel (➔ fig 6 c) – are also used. Depending on the flank form, the worm types are classified as follows:
Hypoid gears The pinion axis is displaced so that the axes of this type of bevel gear do not intersect but are crossed (➔ fig 5 ). The wheels of hypoid gears are usually spirally cut. The advantages of this type of gear derive from the larger pinion and thus the smaller circumferential force for the same torque, as well as from the axis displacement which often allows the pinion to be supported at both sides so that the bearing arrangement is stiffer. The noise behaviour is also improved by the sliding motion in the longitudinal direction of the teeth. However, the additional sliding motion increases the friction, wear and risk of smearing and requires the use of hypoid oils with high additive content.
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Worm gear unit a) cylindrical worm with globoid wheel b) globoid worm with spur wheel c) globoid worm with globoid wheel
ZA worm: trapezoidal worm thread in the axial cross section; ZN worm: trapezoidal worm thread in the normal cross section; ZK worm; trapezoidal tool (in normal cross section); ZI worm; evolvent thread in end face cross section; ZC worm: concave worm flanks
Fig 6
a
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b
c
1 Industrial gearboxes – overview Geared transmissions The ZI and ZC designs are the most popular. The ZI worm can be very accurately ground whilst the favourable osculation conditions of the ZC worm (concave worm, convex wheel) bring load carrying advantages.
Planetary gears From the point of view of the tooth flanks, planetary gears are mostly spur gears. In contrast to the spur gear units so far described, the shafts of which are supported in stationary casings, the planetary gear unit has gear wheels which circulate. They are also referred to as epicyclic gears. In the simplest design (➔ fig 7 ), which is that most commonly used in industry, the sun wheel drives the planetary wheels (when acting as a speed reducer). These are supported in the hollow wheel and drive the planetary carrier from which the power is taken off. Planetary gears have the following important advantages compared with conventional spur gear units: ● ●
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Fig 7 H
P
Simple planetary gear unit (principle) Z sun wheel P planetary wheel H hollow wheel S planetary carrier
S
Z
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the volume, weight and centrifugal mass are smaller; the rolling and sliding velocities in the mesh are lower, so that noise is reduced; some of the power is transmitted as coupling power, so that efficiency is higher.
These advantages have led to a continuous increase in the economic importance of planetary gear units in spite of their disadvantages which include more difficult inspection, maintenance and repairs.
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1 Industrial gearboxes – overview Demands made on gearboxes/Selecting the gears
Demands made on gearboxes The most important demands which must be fulfilled are: ●
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there must be a sufficient safety margin in respect of fatigue and/or requisite life for all components so that the torques and speeds can be reliably transmitted; there must be sufficient cooling even under maximum power transmission conditions; noise emission should not exceed the permitted limits.
In addition to these demands, special requirements in respect of operation and design are dictated by the various applications. Some examples: ●
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radial and/or axial forces on the input and output shafts, e.g. for extruders; external forces on the casing, e.g. in mining; heavy impacts, torque peaks, e.g. when driven by single cylinder combustion engines or when driving bucket excavators; vibrations, e.g. in wire drawing; extreme environmental influences in respect of temperature, dirt, dust, water, e.g. in arctic or tropical open cast mining and in continuous casting plant; seals subjected to pressure, e.g. in submerged gearboxes of dredgers or in mixing equipment in the chemical industry; reversing operation, e.g. for rolling mills; return stop, e.g. for conveyors; operation with little or no clearance and torsional stiffness, e.g. for positioning antennae and for robots; precision, e.g. for printing presses; lubrication with non-flammable lubricants, e.g. in mining; minimum maintenance, e.g. in wind power plant; arrangement, e.g. slip-on gears for converters; accessibility of measuring points to monitor lubrication, temperature, vibrations or torque, e.g. for large plastic extruders.
Selecting the gears To avoid either under or over-dimensioning a gear unit the load and the load carrying capacity of the gear must be able to be determined as accurately and reliably as possible. The size is correctly chosen when a comparison of the load spectrum and the load carrying capacity gives the desired service life. The determination of the load spectrum is a time-consuming and costly exercise calling for considerable measurements. Therefore, dimensioning is usually based on the rated torque of the driven machine, i.e. the operating torque for the most arduous work conditions. For a rolling mill, for example, this is the maximum continuous rolling torque (not the initial entry). The actual loads are higher because of additional external forces, produced by accelerations and vibrations, for example. When calculating the load carrying capacity of the gear wheels, these additional loads are considered by an application factor KA according to DIN 3990. One standard work on the subject lists the following criteria for evaluating the load carrying capacity of gear wheels: ● ● ● ● ● ●
resistance to pitting (tooth flank fatigue), root strength (tooth fracture from fatigue), resistance to scuffing (hot tooth flank welding), wear strength (slow wear of tooth flanks), “grey spot” resistance (fatigue from micro pores on the tooth flanks, and lubricant film formation.
The load carrying capacity which is used as the basis for dimensioning gear wheels is determined in rig tests under standard conditions (partly standardised: FZG test to DIN 51 354).
1 Industrial gearboxes – overview Designing tha casing
Designing the casing The following functions have a decisive influence on the design of the casing: ●
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forces and supporting moments must be taken up and transmiitted at the same time as the position of the gear wheels and the form of the bearing seatings must be accurately maintained; there must be adequate heat removal; noise radiation must be at a minimum; gear wheels and bearings must be protected against contamination by foreign matter; lubricant loss must be prevented.
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The increase in load carrying capacity of gear wheels and rolling bearings resulting from design improvements, improved materials and enhanced quality has enabled gearboxes to be downsized or uprated. The higher specific loads, frictional losses and increased noise resulting from this trend mean that the casings must be more stable so as to keep deformations to a minimum, but also that they should have a sufficiently large surface to prevent inadmissible heating and premature lubricant ageing, and should be properly designed with respect to minimising noise so as not to exceed the noise emission limits.
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2 Bearing types for industrial gearboxes Deep groove ball bearings . 18 Angular contact ball bearings . . . . . . . . . . . . . . . . 20 Cylindrical roller bearings . . 22 CARB™ roller bearings . . . . 24 Spherical roller bearings . . . 26 Taper roller bearings . . . . . . 28 Spherical roller thrust bearings . . . . . . . . . . . . . . . . 30
2 Bearing types for industrial gearboxes
Bearing types for industrial gearboxes For the support of the shafts and gear wheels of industrial gearboxes, rolling bearings are used almost exclusively. The exceptions are in some specialised areas, such as turbo drives, where hydrodynamic plain bearings are used.
There are many good reasons for this dominance of rolling bearings: ●
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good location with minimum radial and axial play enables optimum meshing to be achieved; high specific load carrying capacity with low friction; wide range of internationally standardised products produced in high volumes at reasonable prices and having good availability; can be calculated using reliable load carrying capacity values; little design work for the user; simple arrangement; axially compact so that short and stiff shafts can be used; normal tolerances and surface finishes for shaft and housing seatings; less sensitive to misalignment than plain bearings; ability of radial bearings to accept axial loads; not influenced by direction of load or rotation; low starting torque; no starting problems in intermittent operation; relatively easy to lubricate; favourable behaviour under emergency conditions; economic maintenance.
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Almost all bearing types are used in industrial gearboxes and almost all the available sizes. In the majority of applications, standard “catalogue” bearings can be used; any variants with respect to clearance or cage design are also generally common, so that the comprehensive range of SKF “catalogue” bearings for general engineering applications covers the needs of gearboxes very well and enables the designer to make an optimum selection. The most important bearing types for gearboxes are described in more detail in the following.
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2 Bearing types for industrial gearboxes Deep groove ball bearings
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2 Bearing types for industrial gearboxes Deep groove ball bearings
Deep groove ball bearings Deep groove ball bearings are the most popular of all bearing types and this also applies for gearboxes. The most important characteristics which make them so popular are ●
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they are able to carry radial loads as well as axial loads acting in both directions; they are suitable for high and very high speed operation as their friction is low; they have practically no tendency to smear, i.e. cold welding when the balls are accelerated; they run quietly, particularly if they are lightly preloaded by axial force; they are robust in operation and require little maintenance; they are favourably priced.
These improvements also bring advantages when the bearings are used in gearboxes. In particular the reduced sensitivity to misalignment means that there is no reduction in bearing life under the slight misalignments of up to approximately 3 minutes of arc which are normally encountered. The improved surfaces reduce friction leading to lower running temperatures so that lubrication conditions are improved and bearing life extended.
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The dominant role for deep groove ball bearings is where shafts have to be located axially and loads are relatively light. This is the case in ● ● ● ● ● ●
Benefits offered by SKF
spur gear units (drive shaft and hollow take-off shaft), multi-ratio gear units (switching spur gear wheels), geared motors worm gear units (worm wheels), planetary gears (drive shaft, planetary carrier) and coupling shafts. In recent years SKF has made a number of improvements to deep groove ball bearings which have resulted in further performance enhancements. The more important include ●
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optimised raceway geometry and finish, reducing friction, running noise and sensitivity to misalignment; improved cages which are more stable, thus increasing reliability at high speeds; improved seals, thus enhancing the sealing efficiency of sealed bearings.
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2 Bearing types for industrial gearboxes Angular contact ball bearings
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2 Bearing types for industrial gearboxes Angular contact ball bearings
Angular contact ball bearings The raceways of these bearings are arranged at an angle to the bearing axis (contact angle), so that they are able to carry heavier axial loads than deep groove ball bearings. Sliding movements of the balls are superimposed on their rolling motion, so that the single row bearings require accurate adjustment or a minimum axial load to function properly. Angular contact ball bearings are available in the following designs: ● ●
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single row, single direction angular contact ball bearings, double row, double direction and paired single row angular contact ball bearings and four-point contact ball bearings, i.e. single row, double direction ball bearings.
The improvements made by SKF to single and double row angular contact ball bearings, e.g. reinforcement of the ball set (single row – BE design, double row – A and E designs) to give higher load carrying capacity means that worm gear units can transmit more power and, at the same time, the reduction in friction means that bearing temperature can be lowered. The reduced tolerances for axial clearance and for dimensional and running accuracy which are standard for SKF single row angular contact ball bearings for paired mounting of the CB design, because of the improved location and reduced running noise, are advantageous in low-noise worm gear units such as those required for lifts and escalators.
Benefits offered by SKF
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Single direction implies that axial loads acting in one direction only can be accommodated, whereas double direction bearings (and paired single direction bearings, depending on the arrangement) can take axial loads acting in both directions. The single and double row angular contact ball bearings are preferred as locating bearings for worm shafts. Four-point contact ball bearings are used primarily as thrust bearings in high speed spur gear units, where the outer ring is radially free.
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2 Bearing types for industrial gearboxes Cylindrical roller bearings
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2 Bearing types for industrial gearboxes Cylindrical roller bearings
Cylindrical roller bearings The special properties of cylindrical roller bearings make them a popular choice for gearboxes and include: ● ● ●
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high radial load carrying capacity; low friction – the lowest of any roller bearing under purely radial load; suitable for a wide range of operating speeds, including very high speeds, as the cage has the correct combination of roller guidance, strength and sliding friction properties; ability to accommodate moderate axial loads, when they are simultaneously under radial load, via the slid-ing surfaces of the roller end/flange contact, although the increased friction means that lubrication and cooling must be adapted to the conditions; the ease with which lateral displacement can take place within the bearing makes them ideal as non-locating bearings; proven good performance under external radial accelerations; most designs are separable so that mounting and dismounting are simple.
These characteristics make cylindrical roller bearings ideal for the following applications: ●
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as the non-locating bearings of all high-performance units; the NU design with its flangeless inner ring is perhaps the most used, but also the NJ, NJG and NCF find application; the rings of these bearings need only be axially located at one side, and by mounting the rings with relative axial displacement the bearings can accommodate lateral displacement in both directions. in spur gear units, even where combined radial and axial loads are produced by the helical teeth; the most popular positions are those on the intermediate shaft, as the axial forces from the driven and driving wheels generally act in opposite directions so that the resultant axial load is light.
Practically all improvements made to cylindrical roller bearings by SKF could be considered as tailored to gearbox needs, so that they make an appreciable contribution to increased performance. The main characteristics are ●
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Benefits offered by SKF
the reinforced roller complements and “opened” flanges of the EC design give increased radial and axial load carrying capacity; the logarithmic roller profile ensures an optimum stress distribution over the whole roller length so that edge stresses are avoided even under heavy loads and the permissible misalignments; the refined raceway micro-geometry reduces friction and improves lubricant film formation; newly developed cages ensure proper bearing function over the increased performance range; the standard polyamide cages (designation suffix P) of small bearings have low friction, are elastic and have good sliding properties; the steel window-type cages (designation suffix J) which are standard for medium-sized bearings and can also be fitted to the smaller sizes (to special order) withstand high temperatures and also medium to strong vibrations; the machined brass cages (for gearbox bearings preferably outer ring centred and in two parts, designation suffix MA, or in one piece, suffix MP or ML) are standard for large bearings and can be fitted to other sizes to special order; they can tolerate high speeds and are resistant to vibrations and accelerations.
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The range of cylindrical roller bearings is large compared with other bearing types. The various flange configurations (NU, NJ, NUP, N and NCF designs) make the bearings suitable for a multitude of applications and the different cage designs extend the usefulness of these bearings. 23
2 Bearing types for industrial gearboxes CARB™ roller bearings
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2 Bearing types for industrial gearboxes CARB™ roller bearings
CARB™ roller bearings CARB is a completely new type of bearing: a Compact Aligning Roller Bearing. This single row roller bearing, developed by SKF, is characterised by a combination of properties which make it interesting for a multitude of applications: ●
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the ability to compensate for angular misalignments or initial errors of alignment typical of spherical roller bearings; the ability to take up axial displacements in the bearing itself typical of cylindrical roller bearings; the low cross section typical of needle roller bearings; the high radial load carrying capacity imparted by long sphered rollers; the low friction obtained from optimally matched raceway profiles; the quietness of operation.
Because of its many advantages, the CARB makes an ideal non-locating bearing. The points in favour of its use in industrial gearboxes include, in addition its compact design and high radial load carrying capacity even when misaligned, the potential for downsizing or increasing operational reliability or the power rating. The CARB is particularly suitable for the bearing arrange-ments of ● ● ●
SKF has introduced a completely new roller bearing, the CARB. It is the only bearing available which combines the advantages of three different bearing types without, at the same time, incorporating their disadvantages. For gearbox applications, these advantages translate into the following opportunities for enhanced performance. ●
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Benefits offered by SKF
Up to 30 % higher load carrying capacity at the bearing position combined with small radial space requirements The low cross section allows downsizing or increased performance Compensation for errors of position and also form of bearing seatings in housings thus allowing machining costs to be reduced Both bearing rings can be mounted with an interference fit so that there will be no wear in the bore and no additional axial loads under conditions of axial displacement Quiet running and little vibration
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heavily loaded shafts in spur gearboxes, pinion shafts in bevel gearboxes, and planetary gears.
Two versions of CARB are available: a bearing with cage and a full complement bearing.
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2 Bearing types for industrial gearboxes Spherical roller bearings
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2 Bearing types for industrial gearboxes Spherical roller bearings
Spherical roller bearings The self-aligning capability (also in operation) of spherical roller bearings makes their use advantageous where shaft bending occurs or where there are errors of alignment between shaft and housing (casing). They are therefore used in all cases where misalignment of the bearing rings would produce inadmissible edge stresses if rigid bearings were used. Additional important characteristics make the spherical roller bearing a reliable “all-rounder” for gearbox applications. These include ●
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the high radial load carrying capacity and the ability to accommodate axial loads acting in both directions; the wide range of dimension series and very wide range of sizes even very large sizes.
The many successful development refinements and the improved characteristics resulting from them explain the popularity of spherical roller bearings for gearboxes (particularly in spur, bevel and planetary gear units).
The design and functional characteristics substantiate the leading position of SKF spherical roller bearings: ● ●
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Benefits offered by SKF
long, symmetrical rollers give very high load carrying capacity; the “floating” guide ring between the rows of rollers ensures that the rollers are properly guided (without “wobble”) into the loaded zone and, in cases where axial loads predominate, that the load is correctly carried by the rollers and symmetrically distributed over the roller length; the special form and optimum surface finish of the raceways minimise friction and operating temperature enabling high speed operation; the latest development – the E design – has even higher load carrying capacity as the bearing section is more efficiently exploited; the position of the guide ring above the pitch diameter in the E design favours lubricant film formation between the rollers and guide ring; all SKF spherical roller bearings are fitted with robust metallic cages which perform well even under arduous conditions.
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2 Bearing types for industrial gearboxes Taper roller bearings
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2 Bearing types for industrial gearboxes Taper roller bearings
Taper roller bearings The tapered form of the raceways makes these bearings eminently suitable for combined radial and axial loads. There is a choice of contact angles so that the appropriate bearing for the particular combination of radial and axial loads can be found. The necessity for functional reasons to use two bearings adjusted against each other enables the force distribution on the rollers to be controlled so that maximum life can be obtained at the same time as the stiffness and guidance of gear shafts can be optimised. The main gearbox applications are ● ● ●
spur gear units with helical teeth, bevel and bevel/spur units and worm gear units.
As taper roller bearings can support very heavy loads, they are always used when the load carrying capacity of other bearings for combined load conditions (deep groove and angular contact ball bearings) is inadequate. Because the raceways are at an angle to the bearing axis, an internal axial force is produced when the bearing is radially loaded, which acts on the housing via the outer ring and can deform it. With larger units (from approximately 90 mm shaft diameter) and specifically high performance requirements, the casing walls are often not sufficiently stiff, so that the use of double row or paired single row taper roller bearings (or spherical roller bearings) is recommended, because the internal axial forces cancel out each other and the casing walls will not be deformed. Paired single row taper roller bearings in a face-to-face arrangement (designation suffix DF) are always used when the preset axial play can be exploited and when adjustment during mounting is to be avoided.
SKF taper roller bearings have a number of advantages which make them suitable for industrial gearboxes. These include ●
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Benefits offered by SKF
the ideal form and optimum finish of the roller end/guide flange contact enable hydrodynamic lubrication to be achieved and mixed lubrication conditions avoided, so that the critical running-in process normally required when commissioning a gearbox is not needed; the logarithmic raceway profiles guarantee optimum stress distribution over the whole roller length and prevent edge stresses; the improved surface topography of the raceways enhances lubricant film formation and reduces bearing noise.
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2 Bearing types for industrial gearboxes Spherical roller thrust bearings
Spherical roller thrust bearings The special feature of these bearings is their self-aligning capability. This means that their full load carrying capacity can be utilised, in contrast to the very stiff cylindrical roller thrust bearings, even when the bearing washers are slightly out of alignment with each other. The even distribution of load is still maintained when there are small angular misalignments of the seating surfaces. Such misalignments would considerably shorten the life of cylindrical roller thrust bearings. Spherical roller thrust bearings are used in gearboxes, particularly where axial forces are produced by the driven 30
SKF spherical roller thrust bearings have particularly low friction thanks to the special roller end/flange contact geometry. machine, e.g. in extruder gearing and water turbine gearboxes. The bearings are used successfully as thrust bearings for the pinion and worm shafts of large and very heavily loaded bevel and worm gear units.
Benefits offered by SKF
Marine gearbox with spherical roller bearings, cylindrical roller bearings, fourpoint contact ball bearings and spherical roller thrust bearings
2 Bearing types for industrial gearboxes
2
31
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes . . . . . . . . 33 Shafts in bevel gearboxes . . 44 Shafts in worm gearboxes . 50 Shafts and gear wheels for planetary gearboxes . . . . . . 56
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Design of bearing arrangements
It is quite possible that several different bearing types are used in one gearbox, and where combined gear units are concerned, there are several types of gearing. A stepwise approach is therefore appropriate when selecting bearings, taking each shaft in turn so that the different conditions for the individual shafts and gear wheels can be fully considered. The bearing arrangements described in the following are well proven and the conditions specific to a certain shaft are covered. A presentation of the most commonly used bearing series facilitates the initial selection.
Shafts and gear wheels in spur gearboxes Spur gearboxes are generally used to reduce speed. There are three main types which differ in the way they are mounted: stationary units (mounted on the machine base), cartridge units (mounted on the drive shaft of the driven machine) and flanged units (flanged to the casing of the prime mover and/or driven machine).
3
The drive from the prime mover is via a coupling or a belt. The drive is transmitted to the driven machine via a coupling, a quill shaft connection or via a pinion.
Input shafts The input (drive) shafts have the highest speeds and lightest loads provided no additional external loads have to be considered, e.g. belt tension forces. Vibrations and imbalance forces may be produced by the prime mover. It is also necessary to consider the prob33
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Bearing arrangement for an input shaft with two cross-located deep groove ball bearings
Bearing arrangement for an input shaft with two taper roller bearings arranged face-to-face
34
lems of high angular accelerations when starting without load as well as operation without load at maximum speed in order to prevent bearing damage caused by the rolling elements sliding on the raceways. There is a danger of this occurring when loads are suddenly applied. The temperature differences and the associated thermal expansions in the radial and axial directions are high for input shafts, as the speed related large power loss and relatively small masses as well as the relatively small surface of the pinion shaft mean that there is insufficient heat removal. The distance between bearings is dictated by the casing and the low torque often means that slim shafts are used. This means that shaft
bending and bearing misalignment must be taken into account, particularly if a belt drive is used. Two deep groove ball bearings arranged for cross location (➔ fig 1 ) provide a cost-favourable bearing arrangement for moderate power requirements. Deep groove ball bearings are suitable for high-speed operation. Because of the low friction, small quantities of oil are adequate for lubrication and cooling so that the collected oil splashed by the gear wheels dipping into the oil bath is generally sufficient. In order to prevent axial clamping of the bearings being caused by thermal expansion of the shaft there should be sufficient axial clearance between the outer ring and the cover. For shaft diameters of up to approximately 90 mm, two taper roller bearings arranged face-to-face (➔ fig 2 ) are advantageous both from technical and cost considerations. The taper roller bearings are adjusted against each other via the cover so that they will have zero clearance when at the operating temperature or, for reasons of stiffness, they may have a slight preload. When determining the initial axial clearance it is necessary not only to consider the temperature differential between shaft and casing but also the deformation of the shaft and, above all, the casing. The casings of larger units are often not stiff enough with respect to the axial forces (tooth force + internal axial forces in the bearings). In such cases bearing adjustment is dif-
Bearing arrangement for an input shaft with two cylindrical roller bearings
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Classic locating/nonlocating bearing arrangement with a spherical roller bearing and a cylindrical roller bearing
ficult and shaft guidance is not sufficient-ly accurate. The taper roller bearing arrangement shown is, therefore, not always suitable. Cylindrical roller bearings (➔ fig 3 ) have a high radial stiffness and guide the shaft very accurately without having to be adjusted as taper roller bearings. Axial forces are transmitted via the flanges and roller ends. Because this causes more frictional heat, lubrication and cooling must be particularly good. In order to prevent axial clamping of the bearings when thermal expansion of the shaft takes place, there should be adequate axial play between the flanges. The classical locating/non-locating arrangement (➔ fig 4 ) is more complicated from a design point of view than the cross-located arrangements described above, as the inner and outer rings must be axially located at both sides. However, it has advantages with regard to dimensioning as the axial force is always taken up by a given bearing – in this case the spherical roller bearing – irrespective of the direction of the load. Additionally, displacement of the non-locating bearing is always assured so that there is no risk of axial clamping occurring when the shaft expands. Two NU-design cylindrical roller bearings as radial bearings together with a four-point contact ball bearing as the thrust bearing (➔ fig 5 ) have proved suitable for very high-speed operation (up to n × dm ≈ 1 000 000). For such
high-speed operation the bearings must have ● ●
●
machined brass cages, centred in the outer ring, increased internal clearance: C3 for the cylindrical roller bearings and C4 for the four-point contact ball bearing, and seatings having increased accuracy of form and position (IT4/2).
At high circumferential speeds the bearings will reject normal oil supplies. Therefore, it is necessary to inject oil at high speed (v ≈ 15 m/s) into the gap between cage and inner ring. Oil drainage facilities should be provided at the injection side of the bearings.
3
Bearing arrangement for an input shaft with two cylindrical roller bearings as the radial bearings and a four-point contact ball bearing as the thrust bearing
35
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Intermediate shafts
Bearing arrangement for an intermediate shaft with two taper roller bearings arranged face-to-face
36
Intermediate shafts are the most heavily loaded as they are subjected to the forces from two gear meshes. The speeds are moderate. The axial forces on pinion and wheel oppose each other when the direction of the teeth is the same so that they partially balance each other. There are no additional external forces but vibrations may be transmitted from the input or output shafts. As there is no torque acting at the shaft ends, reasonably small diameters can be used enabling a relatively large bearing section to be utilised for the accommodation of the high radial forces. Design limits for the bearing outside diameter are set by the distance between input and output shafts. When using taper roller bearings (➔ fig 6 ) it should be remembered that axial forces are produced even though the load is purely radial. This may lead to axial deformation of the casing. These deformations occur in the central, less stiff region of the casing because of the position of the intermediate shaft, and are larger than for the input shaft. They lead to a change in position of the shaft and can therefore cause inadmissibly high misalignment of the bearings and the mesh. Experience shows that the casing deformations occurring in smaller units with shaft diameters up to 90 mm are generally within acceptable limits. For larger units it is necessary to resort to
other bearing types or arrangements which are less unfavourable in respect of casing deformation. In comparison with input shafts, the axial loading of cylindrical roller bearings used to support intermediate shafts (➔ fig 7 ) is less critical. The axial forces at the gears act in opposite directions and cancel each other out, at least partially, so that the axial load on the bearings is light. Also the speeds are lower so that frictional losses deriving from the axial load remain small. The high radial load carrying capacity of the cylindrical roller bearings is an advantage as the intermediate shaft bearings are heavily loaded. The choice between caged or full complement cylindrical roller bearings is determined primarily by the factors load, speed, lubrication conditions, friction and cost. Compared with the input shaft, there is only a small temperature gradient between the intermediate shaft and the casing. This makes it possible to use spherical roller bearings in a crosslocated arrangement as shown in fig 8 which is simple in design and therefore cost-favourable. There is a wide range of spherical roller bearings available, particularly for medium and large shaft diameters, and there is also a choice of several cross sections for each diameter. It is thus possible to easily find bearings which can support the heavy loads acting on the intermediate shaft but
Bearing arrangement for an intermediate shaft with two cylindrical roller bearings
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes which have outside diameters within the limits set by the distance between the shafts. A locating/non-locating bearing arrangement as per fig 9 with a spherical roller bearing at the locating side and a CARB as the non-locating bearing offers the possibility of reducing the cross section of the non-locating bearing arrangement, because of the high load carrying capacity of the CARB, so that the available space can be better exploited. In many applications there is a risk that the bearing seating in the housing will be ”hammered out” so that an intermediate sleeve must be incorporated. By using a CARB bearing this is no longer a problem as the outer ring is mounted with an interference fit in the housing, so that a sleeve is not needed.
3
Bearing arrangement for an intermediate shaft with two spherical roller bearings
Bearing arrangement for an intermediate shaft with one spherical roller bearing (locating) and one CARB (nonlocating bearing) Fig 9
37
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes The locating/non-locating arrangement shown in fig 10 can carry very heavy radial as well as axial loads. Two matched single row taper roller bearings (DF execution) are used for the locating arrangement. In contrast to the cross-located bearing arrangements shown in figs 2 and 6, the internal axial forces of the taper roller bearings compensate each other within the bearing pair and do not deform the casing. The intermediate ring supplied with the bearing pair ensures that there is a minimum axial clearance within the bearings. This is adequate for temperature differentials between shaft and casing of up to 20 °C. To avoid deformation of the thin-walled inner ring as the cover screws are tightened, the length of the centring surface (spigot) of the cover should be chosen to give a preload of approximately 0,01 mm.
Drive (output) shafts Locating/nonlocating bearing arrangement for an intermediate shaft with two matched single row taper roller bearings and one cylindrical roller bearing
38
The conditions for the drive shafts are characterised by high torques and low speeds. The torque calls for a large shaft diameter so that the requisite load carrying capacity can be obtained even when using bearings with low cross sections. There are potential problems with lubrication of the rolling contacts if, because of the low speeds, elastohydrodynamic
(EHD) lubrication, i.e. the formation of a separating lubricant film between rolling elements and raceways, cannot be achieved. Operating bearings under conditions of mixed friction or boundary lubrication will result in wear and shorter bearing life. Besides rotational speed, operating temperature and lubricant viscosity are the most important factors determining EHD lubrication. There is a limit to how high the viscosity of the oil can be because consideration must be paid to the high-speed gears and bearings in the unit. Therefore, a cooling of the gearbox in the region where the low-speed bearings of the drive shaft are situated is often the most effective means of increasing bearing life. Suitable additives in the oil can also contribute to a reduction in wear. Other factors influencing drive shaft bearings depend on the gearbox design: ●
In stationary, base-mounted gearboxes, depending on the type of power take-off, it is necessary to consider the forces of the coupling, the propeller shaft, a pinion or of the directly coupled driven machine (e.g. extruders).
Bearing arrangement for an output shaft with two spherical roller bearings
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes ●
●
Bearing arrangement for an output shaft of a cartridge-type unit with full complement cylindrical roller bearings of series NCF 29 V
The bearings in cartridge-type gearboxes are subjected to the reactionary forces of the torque support. Additional forces may also be produced as a result of casing deformation. The casings of flanged gearboxes are bolted to the driven machine. The shafts are generally rigidly coupled so that the double support of the output shaft becomes a multiple support in practice. Centring errors of the coupled components produce additional forces in the bearings so that narrower tolerances for the centring should ensure the accuracy of alignment of the bearing arrangement.
The arrangement with spherical roller bearings (➔ fig 11 ) is especially suitable for applications where rough operation, external additional forces, misalignments and shock loads place heightened demands on the bearings. Axial shock loads are taken up by the less sensitive raceways in the absence of flanges on the rings. For cartidge-type gearboxes, the relatively large diameters of the hollow shaft mean that bearings having low cross section are suitable. Fig 12 shows a well-proven bearing arrangement incorporating full complement
cylindrical roller bearings of series NCF 29 V. For lighter loads but with similar diameters, deep groove ball bearings of series 619 can be used in the same arrangement. For heavier loads as well as larger deformations, but still with the same diameters and arrangement, spherical roller bearings of series 239 are appropriate. Deep groove ball and spherical roller bearings have cages and are thus less susceptible to wear when inadequately lubricated than full complement bearings.
Intermediate gear wheels An internal bearing arrangement is most suitable for intermediate gears as it takes up the least space. Internal bearing arrangements are characterised by rotating outer rings. Therefore, there is rotating outer ring load and stationary inner ring load. This means that the outer rings should have interference fits and the seatings should be very accurately machined in order to keep the rotating inaccuracies – which cause increased friction and additional forces on the bearing cage – to a minimum. With opposing meshes the circumferential forces are added, so that high radial load carrying capacity is required. The axial forces from the
3
Bearing arrangement for an intermediate gear wheel with two cylindrical roller bearings of the NJ design
39
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Bearing arrangement for an intermediate gear wheel with two taper roller bearings arranged back-to-back
40
helical teeth oppose each other and partially cancel each other producing a tilting moment on the bearing which can cause misalignment. Two cylindrical roller bearings of the NJ design provide the requisite high radial load carrying capacity in a restricted space as shown in fig 13 . The design of the associated components of the arrangement is simple. The bearing arrangement of helical intermediate gear wheels must be checked for angular misalignment. An unfavourable combination of wheel diameter, pitch and distance between bearings can produce inadmissible values of misalignment. An extended support width (distance between bearing pressure centres) can be achieved using, for example, angular contact ball bearings. Taper roller bearings in a back-toback arrangement (➔ fig 14 ) also increase the support width as well as reducing the influence of the tilitng moment on the misalignment if they are adjusted to zero clearance, or a light preload. Straight cut gear wheels may be supported by a single spherical roller bearing (➔ fig 15 ). The intermediate gear wheels are thus free to align so that a good mesh is achieved. In order to be able to use standard bearings (without lubrication holes in
the inner ring) oil should be supplied at the side. To prevent the supplied oil from being rejected by the bearing, the seal gap at the supply side should not exceed 1 mm.
Shifting gear wheels For reasons of space these gear wheels are supported internally in a similar manner to the intermediate gears. The torque is transmitted in the engaged condition so that the bearings are subjected to the tooth forces. The inner and outer rings rotate but the relative speed is zero. Both rings have rotating load but the rolling elements do not roll. The continuous changes in load under these stationary conditions cause micro-sliding to take place at the rolling element/raceway contacts. As there is no relative rotation of the rings, a ”washboarding” type of wear will be produced in the raceways. This wear can be reduced by using highly viscous lubricating oil containing anti-wear additives. Where the wheels have helical teeth, the axial force produces a tilting moment and consequently a rotating tilting motion which leads to axial movement in the rolling element/raceway contacts. This increases wear. Ball bearings, adjusted to zero clearance, behave favourably as the balls can
Bearing arrangement for an intermediate gear wheel with a single spherical roller bearing
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes also roll in the axial direction and because the movement is reduced by the clearance-free adjustment. Wear is always load-dependent so that bearings under low specific loads wear less. The washboarding effect is also less prominent as engagement always takes place at new positions so that the wear is evenly spread over the raceway. For the support of shifting wheels, deep groove ball bearings have proved to give good performance (➔ fig 16 ). Bearings with increased radial internal clearance (C3) are used. The clearance-free adjustment via the inner rings produces a contact angle in the bearings of approximately 15°, so that the support width of the bearings is extended. This reduces movement in the relatively stationary bearings under rotating load and thus reduces wear. In addition, the clearance-free back-toback arrangement improves guidance of the wheel. Lubrication of the bearings from the outside is difficult as all components of the arrangement – shaft, bearings and wheel – rotate and because the bearings are partly covered e.g. by the coupling. The most reliable method is to supply oil internally through the shaft.
3
Bearing arrangement for shifting gear wheel with two deep groove ball bearings
41
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Demands on the bearings Modern spur gears generally have hardened gear wheels with ground teeth. It is then possible to obtain high performance with relatively little friction and low noise. A prerequisite for this is the use of high-performance bearings, which should have the properties listed in Table 1 . In addition to these general requirements with respect to ball and roller bearings for high-performance gearboxes, other demands deriving from the specific operating conditions at Demands on rolling bearings for spur gears
each particular bearing position must be considered. To make the situation clearer in Tables 2 to 4 , the text has been kept as short as possible.
Table 1 Demand
Required bearing design feature
High load carrying capacity
Optimised rolling element size and number. Logarithmic roller/raceway contact. Good lubricant film formation through low friction and low raceway surface roughness.
High stiffness
Optimised rolling element size and number. Logarithmic roller/raceway contact.
High dimensional and running accuracy
Particularly the inner ring running accuracy should preferably be to tolerance class P6 or better.
Low friction
Low friction in roller end/flange contact for taper and cylindrical roller bearings. Low friction in roller/raceway contact. Lightweight precision cage. Low raceway surface roughness.
Low running noise
High precision of all bearing components.
Demands on input shaft bearings
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Table 2 Specific operating conditions
Requirements of bearings/steps to guarantee performance
High speed and thus high friction and high operating temperature
Use low-friction bearings. Avoid over-dimensioning. Ensure lubricant supply when starting up cold. Provide good cooling.
Large temperature differential when starting up (slim input shaft heats up more quickly than the better cooled solid casing)
Check required bearing internal clearance; if necessary select bearings with C3 clearance. Ensure axial displacement at non-locating bearing position.
Vibration from drive; imbalance forces
Use bearings with stable cages, e.g. cylindrical roller bearings with steel window-type cages or outer ring centred machined cages, or spherical roller bearings with steel window-type cages.
Idling under light load
Check minimum load. Avoid over-dimensioning. Use bearings with small roller masses where possible. Do not use full complement cylindrical roller bearings. Choose bearing types less susceptible to smearing, e.g. spherical and taper roller bearings.
3 Design of bearing arrangements Shafts and gear wheels in spur gearboxes
Bearing selection
●
The following check list will be found useful when selecting bearings in order not to forget any important factors.
● ●
● ●
● ● ●
Adjusted basic rating life Axial load carrying capacity when the flanges of cylindrical roller bearings are under load Friction Stiffness Misalignment
Sufficient play to prevent inadmissible clamping when temperature differentials are large Minimum load Static safety under peak loads
A preliminary choice can be made from the bearing series shown in Table 5 .
Table 3 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Heavy radial loads
Use bearings with high load carrying capacity.
Low to moderate speeds
Check lubricant film formation. If necessary increase viscosity or improve cooling. Use lubricants with wear-reducing additives.
3
Table 4 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Very low speeds
When lubricant film formation inadequate, i.e. a viscosity ratio (actual to required viscosity) κ < 1, use lubricants with suitable EP additives. When κ < 0,5 bearings with cages (not full complement bearings) must be used. When κ < 0,1 reduce the specific bearing load; aim for s0 > 10.
Shock loads from power take-off;deformations
Use robust, self-aligning, spherical roller bearings.
Table 5 Operating conditions
Bearing series normally used Input shaft Intermediate shaft
Demands on intermediate shaft bearings
Output shaft
Intermediate gears
Shifting gears
Light loads
62 63
63 NJ 2 EC
619 160 60
60 62
618/C3 619/C3
Moderate loads
NJ 2 EC 320 X 222 E(CC)
NJ 22 EC 322 222 E(CC)
NCF 29 V 239 CC
NJ 2 EC 320 X
160/C3 60/C3
Heavy loads
322 232 CC 223 E(CC)
NJ 23 EC NJG 23 VH 223 E(CC) 322/DF
230 CC
NJ 3 EC 303 232 CC 223 E(CC)
62/C3
High speeds
NU 2 ECMA/C3 QJ 2 N2MA/C4
Demands on output shaft bearings
Bearing selection
In addition to the bearing series listed above, a CARB can be used as the non-locating bearing for locating/non-locating bearing arrangements
43
3 Design of bearing arrangements Shafts in bevel gearboxes
Shafts in bevel gearboxes Bevel gears are generally speed reduction gears. The high-speed drive shaft is termed the pinion shaft and the slow-speed driven shaft carries the larger bevel gear wheel. The pinion shaft is driven by the motor via a coupling, a spur gear or a belt drive. The power take-off is either via a coupling or with bevel/spur gears via a pinion.
Pinion shafts The pinion is generally supported in an overhung arrangement. In a few cases the pinion is supported between the bearings but it is difficult to design in a bearing with sufficiently high load carrying capacity at the head. The overhung arrangement offers more space. Two taper roller bearings in a backto-back arrangement as shown in fig 17 offer a cost-favourable and axially as well as radially stiff arrangement for small to medium diameter shafts (d < 90 mm). The bearings are adjusted using a shim between the shaft shoulder and the inner ring of the bearing at the input side. The adjustment is determined to give zero clearance when the bearings are in operation and warm or, if required for stiffness reasons, a slight axial prelod. When determining the initial axial clearance the temperature differential between shaft and casing must be considered as well as the deformations of shaft and casing. Bearing arrangement for a bevel pinion shaft with two taper roller bearings arranged back-to-back
44
Oil should be supplied between the two bearings. A baffle plate ensures that both bearings are reliably supplied with lubricant. The oil drain at the cover side reduces the amount of lubricant reaching the seal.
3 Design of bearing arrangements Shafts in bevel gearboxes
Bearing arrangement for a bevel pinion shaft with two matched single row taper roller bearings arranged face-toface (locating position) and one spherical roller bearing (non-locating position)
For larger shafts, the requisite load carrying capacity can be achieved using a locating/non-locating bearing arrangement as shown in fig 18 . The locating arrangement is at the drive side and consists of two matched single row taper roller bearings (DF execution). The intermediate ring which is supplied with the bearing pair ensures that a minimum axial clearance remains when the bearings are mounted which can cope with temperature differentials between shaft and casing of up to 20 °C. For greater temperature differentials such as may occur, for example, in operation when ambient temperatures are very low, paired bearings with larger axial clearance are required (special execution). In order not to deform the thin-walled intermediate ring when tightening the cover screws, the length of the centring flange (spigot) on the cover should be such that a preload corresponding to approximately 0,01 mm is obtained. The matched taper roller bearings operate as a double row bearing. As the axial load from the pinion dominates, one of the two bearings – depending on the direction of the load – is completely unloaded. Experience shows that this is not a disadvantage when there is little vibration. The non-locating bearing adjacent to the bevel pinion may be either a spherical roller bearing, a cylindrical roller bearing or a CARB.
For one-piece casings, spherical roller bearings offer mounting advantages and they are also relatively insensitive to smearing when loads vary considerably and there are long periods of idling. If cylindrical roller bearings are used, the requisite axial displacement can always take place in the bearing itself so that the outer ring can have an interference fit in the housing, and radial guidance is enhanced. The same is true of CARB (➔ fig 19 ). At this position the bearing will not only enable the axial displacements to be easily accommodated, it will also accept the angular misalignments caused by the off-centre point of action of the tooth forces with no reduction in life. Oil should be supplied to the two taper roller bearings between the outer rings. Experience shows that for small and medium-sized gears (up to approximately d = 150 mm) the non-locating bearing can be adequately lubricated by the oil returning from the locating bearings. For larger gears, however, it is necessary to arrange for a separate oil supply to the non-locating bearing. For spherical roller bearings, the oil should be supplied via the lubrication groove and holes in the outer ring for the best results.
3
Bearing arrangement for a bevel pinion shaft with two single row taper roller bearings arranged back-to-back (locating) and one CARB (nonlocating bearing) Fig 19
45
3 Design of bearing arrangements Shafts in bevel gearboxes
Bearing arrangement for a bevel pinion shaft with one taper roller bearing as a thrust bearing and one taper roller bearing as a radial bearing (locating position) and one cylindrical roller bearing (nonlocating position)
46
Although the bearing arrangement shown in fig 20 is similar to that in fig 18 , there are considerable functional differences. All roller rows are always under load irrespective of the direction of the axial load. If the direction of axial load is from the pinion tip to the drive input, the taper roller bearing at the cover side with its radially free outer ring will be axially loaded, and the opposing bearing will be radially loaded. If the load direction is reversed then the smaller axial load will act on the inboard bearing which is also under radial load. The taper roller bearing at the cover side will then only be subjected to a minimum axial load by the springs. Because all roller rows are always under load, this arrangement is less sensitive to vibrations than that shown in fig 18 . Mounting is more complex because there is no intermediate ring between the taper roller bearings which have to be adjusted on mounting. The radially free outer ring of the taper roller bearing at the cover side is prevented from turning by an O-ring. A variant of this bearing arrangement incorporates a spherical roller thrust bearing which has a higher load carrying capacity. It replaces the taper roller bearing which only carries axial loads. With respect to lubrication, the same recommendations apply as for the arrangement shown in fig 18 .
Output shafts The gear wheels are generally arranged between the bearings for design reasons. This is also true for the bevel/spur gearboxes. For shaft diameters up to approximately 90 mm, two taper roller bearings mounted back-to-back (➔ fig 21 ) provide a technically advantageous and cost-favourable arrangement. With larger dimensions, the casings are often inadequately stiff with regard to the axial forces (tooth force + internal axial force of the bearings). This makes adjustment of the bearings difficult and shaft guidance is generally not sufficiently accurate. The bearing arrangement with cross location is then not altogether suitable. The axial force from the gear wheel always acts in one direction. As the axial force from the pinion dominates, it is possible that the direction of the resultant axial force will change. This must be taken into consideration when adjusting the mesh. When adjusting the taper roller bearings, the shim at the gear wheel side determines the position of the wheel in the gearbox. The shim at the pinion side is used to set the axial clearance of the taper roller bearings. Oil from the collecting pockets above the bearings runs down at the cover side of each bearing. From there the oil must pass through the bearing and thus lubricate it. Oil retaining plates ensure that there is an adequate supply of oil available even when starting up.
Bearing arrangement for a bevel wheel shaft with two taper roller bearings arranged face-to-face
3 Design of bearing arrangements Shafts in bevel gearboxes
Bearing arrangement for a bevel wheel shaft with a double row angular contact ball bearing (locating position) and a cylindrical roller bearing (non-locating position)
The locating/non-locating bearing arrangement shown in fig 22 has the advantage, compared with that shown in fig 21 , that no bearing adjustment is required. The bearings are also insensitive to axial deformation of the casing. This will only be subjected to the tooth forces and not to the internal bearing forces, so that there will be less deformation. A double row angular contact ball bearing is used as the locating bearing. Alternatively, single row angular contact ball bearings in matched sets having the same diameters as the double row bearing and being marginally wider can be used for higher load carrying capacity. To determine the position of the gear wheel in the gearbox and to adjust the mesh, a split washer is inserted between the bearing outer ring and the retaining ring. When doing this the bearing can remain on the shaft. A cylindrical roller bearing of the NU design is used as the non-locating bearing at the other side where the radial load is heavier. The locating/non-locating bearing arrangement shown in fig 23 is similar in design and function to that shown in fig 22 . At the locating side, two single row taper roller bearings are arranged face-to-face. Compared with the double row angular contact ball bearing, the taper roller bearings provide higher load carrying capacity and greater stiffness.
Adjustment of the bevel gear wheel is simplified using a special (hookshaped) sleeve. In order to prevent the thin-walled intermediate ring of the paired taper roller bearings from being deformed as the cover screws are tightened, the length of the spigot in the cover should be chosen to give a preload corresponding to approximately 0,01 mm. Oil should be supplied to the taper roller bearings via the lubrication groove and holes in the intermediate ring. To allow an even distribution over the two bearings, an oil drain should be provided at the cover side.
3
Bearing arrangement for a bevel wheel shaft with two matched single row taper roller bearings (locating position) and one cylindrical roller bearing (non-locating position)
47
3 Design of bearing arrangements Shafts in bevel gearboxes
Demands on the bearings Modern bevel gearboxes usually have hardened gear wheels with ground helical teeth. This enables high power transmission to be achieved with little friction and little noise generation. A prerequisite for this good performance is the use of high-performance ball and roller bearings which should have the properties listed in Table 6 . In addition to these general requirements for bearings for high-performance gearboxes, there are additional requirements which are specific to the actual bearing position.
Demands on rolling bearings for bevel gears
Demands on bevel pinion shaft bearings
48
Bearings for the pinion shaft High radial and axial forces act simultaneously on the pinion shaft. Therefore high radial load carrying capacity is required of the non-locating bearing and high axial load carrying capacity of the locating bearing. Because of the high speed, bearings having low friction should be used. These two requirements are in part contradictory. Experience shows that pinion bearings do not fail from fatigue but are endangered by other influences. From this it is possible to derive the requirements and actions listed in Table 7 .
Table 6 Demand
Required bearing design feature
High load carrying capacity
Optimised rolling element size and number. Logarithmic roller/raceway contact. Good lubricant film formation through low friction and low raceway surface roughness.
High stiffness
Optimised rolling element size and number. Logarithmic roller/raceway contact.
High dimensional and running accuracy
Particularly the inner ring running accuracy should preferably be to tolerance class P6 or better.
Low friction
Low friction in roller end/flange contact for taper roller bearings. Low friction in roller/raceway contact. Low raceway surface roughness.
Low running noise
High precision of all bearing components.
Table 7 Most frequent reason for pinion bearing damage
How to alleviate problem/demands on bearings
Lubrication breakdown
Guarantee lubrication when starting up in the cold state.
Overloading because of too heavy a preload
When selecting bearing size, check the temperature differential between shaft and casing. C3 internal clearance often required.
Inadequate lubricant film generation because of too high operating temperatures
Use low friction bearings. Avoid over-dimensioning. Improve cooling.
Smearing on rollers and raceways caused by roller slip or sliding
Avoid over-dimensioning. Spherical roller bearings are more favourable than cylindrical roller bearings in larger size range (d > 150 mm). When using cylindrical roller bearings aim for small roller diameters; use a full complement bearing.
Wear caused by contaminants
Avoid contaminating the gearbox during production, assembly and in operation.
3 Design of bearing arrangements Shafts in bevel gearboxes To obtain good meshing it is necessary among other things to have a bearing arrangement with high radial and axial stiffness. The locating bearing should therefore have a large contact angle and as small an axial clearance as possible.
Bearing selection When selecting the bearings it is useful to refer to the cheklist given below. ● ● ● ●
Bearings for the output shaft These bearings are predominantly radially loaded so that high radial load carrying capacity is also required of the locating bearing. Because of the slow speeds the risks in respect of thermal behaviour and over-dimensioning compared with the pinion shaft are negligible. The requirements for axial and radial stiffness, for minimum axial clearance and for bearing accuracy correspond to those for the pinion shaft bearings.
●
Adjusted basic rating life Permissible speed Axial and radial stiffness Sufficient bearing clearance in the mounted but cold state to avoid inadmissible preload under conditions of maximum temperature differentials Minimum load
A preliminary selection can be made using the overview of the bearing series commonly used; see Table 8 .
3
Table 8 Bearing arrangement
Bearing selection
Bearing series normally used Bevel pinion shaft Input side Pinion side
Bevel gear wheel/Bevel/spur gear wheel Gear wheel side Opposite side or spur pinion side
Cross location
72 BE 73 BE 313 323 B
72 BE 73 BE 322 332 303 323
Locating bearing(s)
(2×) 72 BECB (2×) 73 BECB 313/DF 322 + 293 E
72 BE 73 BE 323 B 323 B
72 BE 73 BE 322 332 303 323
33 (2×) 72 BECB (2×) 73 BECB 320 X/DF 322/DF
303 + 294 Non-locating bearing
NU 22 EC(/C3) NU 23 EC(/C3) 232 CC(/C3) 223 CC(/C3)
NU 2 EC NU 22 EC NU 3 EC NU 23 EC 223 EC
In addition to the bearing series listed above, a CARB can be used as the non-locating bearing for locating/non-locating bearing arrangements
49
3 Design of bearing arrangements Shafts in worm gearboxes
Shafts in worm gearboxes Generally worm gearboxes are used to reduce speed. There are two main types: one for mounting on the machine base and a cartridge type for mounting on the input (drive) shaft of the machine. The drive from the prime mover is either via a coupling or a belt drive. The power take-off is via a coupling or a quill (hollow) shaft connection. Bearing arrangement for a worm shaft with two angular contact ball bearings in a cross-located arrangement
Worm shafts The heaviest axial loads act on the worm shaft at the same time as speeds are high. Where there is a belt drive, the radial loads will also be heavy.
The temperature differences and the associated thermal expansion in the radial and axial directions are also large in worm gearboxes. Only small masses and surfaces of the worm shafts are available to remove heat. Therefore, there are large temperature gradients from the shaft to the casing and these must be considered when adjusting the bearings. The distance between bearings is dictated by the casing and together with the small torques this often leads to the use of slim shafts. If there is a belt drive, then shaft bending should be calculated so that inadmissible bearing misalignment can be avoided. Two single row angular contact ball bearings in a cross-located arrange50
ment (➔ fig 24 ) offer a cost-favourable, low friction bearing arrangement with low noise for moderate performance and where diameters are small (bearing bore diameter d ≈ 50 mm). The angular contact ball bearings are suitable for high speeds and because of the large contact angle they are also appropriate for predominantly axial loads. The two bearings are adjusted against each other via the cover so that they will have a slight preload when running at the operating temperature. When determining the degree of adjustment it is necessary to consider the temperature differential between shaft and casing, but also casing deformation.
The same type of arrangement but using two steep-angled taper roller bearings (➔ fig 25 ) can carry heavier loads than that with the angular contact ball bearings for the same shaft diameter. Therefore, taper roller bearings are preferred for higher performance gearboxes and for medium to large diameters. When determining the degree of adjustment, it must be remembered that taper roller bearings are axially stiffer than angular contact ball bearings and are therefore more sensitive to excessive preload. It is thus advisable to aim at zero clearance when the bearings are running at the operating temperature. When starting up (worm already warm, casing still cold) a slight preload will be pre-
Bearing arrangement for a worm shaft with two taper roller bearings arranged face-to-face
3 Design of bearing arrangements Shafts in worm gearboxes Bearing arrangement for a worm shaft with two matched angular contact ball bearings (locating position) and one cylindrical roller bearing (nonlocating position)
sent which experience shows can be tolerated when lubrication is good. The locating/non-locating bearing arrangement (➔ fig 26 ) is more costly from a design point of view and because a third bearing is involved but it has the following advantages: ● ●
●
higher load carrying capacity (e.g. for belt tension forces); if paired angular contact ball bearings are used, no individual adjustment is required; axial displacement at the non-locating bearing position is guaranteed.
ed single row taper roller bearings (DF execution) as shown in fig 27 . The intermediate ring which is supplied with the bearing pair ensures that there is a minimum axial clearance in the mounted condition, which is sufficient for temperature differentials between shaft and casing of up to 20 °C. In order not to deform the thin-walled intermediate ring when the cover screws are tightened, the spigot (centring shoulder) in the cover should have a length such that a preload corresponding to approximately 0,01 mm can be obtained.
3
A further performance increase can be obtained by replacing the pair of angular contact ball bearings by two matchBearing arrangement for a worm shaft with two matched taper roller bearings (locating position) and one cylindrical roller bearing (non-locating position)
51
3 Design of bearing arrangements Shafts in worm gearboxes Bearing arrangement for a worm shaft with a taper roller bearing as the radial bearing and a spherical roller thrust bearing as the thrust bearing (locating position) and a cylindrical roller bearing (nonlocating position)
The bearing arrangement shown in fig 28 is particularly suitable when the axial load in one direction predominates, as for example in lifting gear. The spherical roller thrust bearing takes the dominant axial load as well as the axial force produced in the taper roller bearing, which in this case is only subjected to radial load. If the axial load changes direction, then the taper roller bearing takes the radial as well as the axial load, while the spherical roller bearing is spring loaded to give the minimum axial load required for the correct motion of the rollers. Both bearings are adjusted via the cover. When determining the axial clearance it is necessary to consider the temperature differential between shaft and casing. Bearing arrangement for a worm shaft for maximum loads with two radial spherical roller bearings and two spherical roller thrust bearings
52
The advantages of this bearing arrangement are the very high load carrying capacity in the one direction and also that all three bearings are always under load. Bearing noise is then particularly low and the bearings are less sensitive to vibration. Fig 29 shows a bearing arrangement for maximum loads and shocktype operation as encountered, for example, in rolling mills when the rolls are set. The radial forces are taken up by two radial spherical roller bearings mounted as non-locating bearings, whilst the axial forces act on the spherical roller thrust bearings which have radial freedom in the casing. The axial clearance of the spherical roller thrust bearings is obtained by adjusting the
3 Design of bearing arrangements Shafts in worm gearboxes width of the spacer sleeve. The springs ensure that the requisite minimum load is applied to the bearing which is relieved of axial load.
Worm wheel shafts
Fig 30: Bearing arrangement for a worm wheel shaft with two deep groove ball bearings in a crosslocated arrangement
The high torques on the worm wheel shafts require large shaft diameters. As speeds are slow, the load carrying capacity of low cross section bearings (light series) is adequate. Because of the low speeds, lubrication of the worm wheel bearings by oil spray is usually not sufficient and special arrangements must be made for lubricant supply. An oil wiper on the worm wheel or separate grease lubrication of the bearings have been found to give good results.
vide adequate lubrication for the bearings they are greased and a gap-type seal is provided on the inboard side. The arrangement shown in fig 31 with two taper roller bearings is intended for heavier loads than that shown in fig 30 but is otherwise similar. It should be remembered when using taper roller bearings that – in contrast to deep groove ball bearings – the axial adjustment of the bearings will influence the radial guidance of the worm wheel. Therefore, the casing must be sufficiently stiff so that it will not be deformed (beaten out) under load. This would otherwise lead to too large a bearing clearance and inadmissible alterations to the mesh.
Fig 32: Bearing arrangement for a worm wheel shaft with two cylindrical roller bearings
3
Fig 31: Bearing arrangement for a worm wheel shaft with two taper roller bearings arranged faceto-face
In most cases the worm wheel has a globoid form and requires accurate axial guidance, but it must also be possible for the axial position of the mesh to be changed. Two deep groove ball bearings in the cross-located arrangement shown in fig 30 generally have adequate load carrying capacity and are very cost-favourable. The adjustment of the mesh and the bearings is made via the covers. The mesh should preferably be adjusted via the one cover first and then the bearing clearance via the other cover. The temperature of the slowly rotating worm wheel shaft is usually low, so the bearings can be adjusted to almost zero clearance. To keep the oil level down and still pro-
When two cylindrical roller bearings (➔ fig 32 ) of the NJ or NCF (full complement) design are used, the radial guidance of the worm wheel is not influenced by any axial adjustment, so that setting the mesh is simplified. However, axially loaded cylindrical roller bearings are particularly susceptible to wear, so that it is important that they are adequately supplied with lubricant of sufficient viscosity (κ > 0,5) and that the specific bearing load is not too high (s0 > 10).
53
3 Design of bearing arrangements Shafts in worm gearboxes Bearing arrangement for a worm wheel shaft with a double row angular contact ball bearing (locating position) and a cylindrical roller bearing (nonlocating position)
The design of the locating/non-locating bearing arrangement shown in fig 33 is more complex since all bearings rings have to be axially located at both sides. The double row angular contact ball bearing (alternatively two matched single row angular contact ball bearings) guides the worm wheel axially with practically no clearance, so that adjustment is not required. The inner ring without flanges of the cylindrical roller bearing (NU design) allows free axial displacement at the non-locating side.
Bearing selection
Demands on the rolling bearings
The commonly used bearing series are listed in Table 11 to facilitate a preliminary choice.
The demands on the rolling bearings are derived from the specific operating conditions at each bearing position. They are briefly summarised in Tables 9 and 10 .
54
The following checklist may be helpful when selecting the bearings. ● ● ●
● ● ●
Adjusted basic rating life Permissible speed Maximum preload when starting up for the maximum temperature differential Zero clearance or slight preload at the operating temperature Misalignment Static safety under shock loads
3 Design of bearing arrangements Shafts in worm gearboxes Table 9 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Specifically heavy axial loads
Use bearings with large contact angle to take up the axial load.
Need for clearance-free operation and quiet running
Aim for slight preload when running at the operating temperature. When adjusting or selecting initial bearing clearance remember the expected temperature differential.
Large temperature differentials during start-up (slim worm shaft heats up faster than cooled casing)
When adjusting remember the expected temperature differential to avoid inadmissible preloads.
High operating temperatures; the use of lubricants with large proportion of additives which are chemically aggressive to plasticwhen aged
For gearboxes which operate constantly, or mainly (high frequency of use) at high operating temperatures (> 80 °C) and which must also have a long service life (> 20 000 hours) bearings fitted with metal cages should be used.
Table 10 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Accurate axial guidance of worm wheel
Adjust bearings to zero axial clearance.
Very slow speeds
With inadequate lubricant film formation corresponding to a viscosity ratio (actual to required viscosity) of κ < 1 use lubricants with suitable EP additives. When κ < 0,5 only use bearings with cages (not full complement bearings). When κ < 0,1 reduce the specific bearing load; aim for s0 > 10.
Table 11 Operating conditions
Bearing series normally used Worm shaft
Demands on worm shaft bearings
Demands on worm wheel shaft bearings
Bearing selection
Worm wheel shaft
Light loads
72 BEP 73 BEP
618 619 160
Moderate loads
313 (2×) 73 BECBM + NJ 2 ECJ 313/DF + NJ 3 ECJ
60 62 32 + NU 10 (2×) 72 BECBM + NU 2 ECJ
Heavy loads
293 E + 303 + NU 3 ECJ 294 E + 313 + NU 3 ECJ (2×) 293 E + (2×) 230 CC
320 X NCF 29 V NJ 2 ECJ
In addition to the bearing series listed above, a CARB can be used as the non-locating bearing for locating/non-locating bearings arrangements
55
3
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes
Shafts and gear wheels for planetary gearboxes Planetary gearboxes usually come as cartridge-type or flanged units and more seldom for mounting on the base. Power input and also output from the sun wheel is almost exclusively via couplings so that the sun wheel can centre itself in the planetary wheels. Power take-off via the planetary carriers is either via a coupling or, for the cartridge-type units via a hollow shaft connection.
Sun wheels The sun wheel meshes with several planetary wheels, so splitting the power. The arrangement is always symmetrical so that with straight-cut teeth, the reaction forces on the sun wheel bearings should cancel each other out theoretically. In practice, however, this is not the case. The even distribution of load over all the planetary wheels is influenced by many factors. The most important are the design (radial alignment of the sun wheel), the accuracy of manufacture, and the specific load. When the load is heavy the relative deviation in the load distribution will be smaller because of deformation. Because of the ability of the sun wheel to align radially and/or the high manufacturing precision common today, the bearing forces resulting from the uneven load distribution are so small that they can be neglected when selecting the sun wheel bearings. At high Bearing arrangement for an input shaft with two deep groove ball bearings
56
speeds, it is even sensible to subject deep groove ball bearings to a minimum axial load by springs, in order to prevent them from rotating without load, and to achieve smooth running. Fig 34 shows the bearing arrangement of the input shaft which incorporates two deep groove ball bearings in a cross-located bearing arrangement. Transmission of the torque from the input shaft to the sun wheel is via a toothed coupling. This allows the sun wheel to adjust easily and the load distribution will be good as a result. The sun wheel shaft shown in fig 35 is also supported by two deep groove ball bearings, but these are in a locating/non-locating bearing arrangement. The springs acting on the outer ring of the non-locating bearing subject both bearings to axial load. This increases the smooth running of the bearings, particularly at high speeds and under vibrating conditions.
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes
Bearing arrangement for a sun wheel with two deep groove ball bearings
Bearing arrangement for a planetary wheel with a needle roller and cage assembly
Planetary wheels The conditions for the planetary wheels are characterised by heavy radial load from the forces of two meshes as well as by the infuence of radial accelerations and the mass inertia forces resulting from these. Bearings having high radial load carrying capacity are needed, and their cages should be able to endure the mass forces. An internal bearing arrangement is suitable for the planetary wheels as it takes up the least space. This means rotating load for the outer ring and point load on the inner ring. Thus, the outer rings must have interference fits and the seatings must be accurately machined in order to keep the rotating inaccuracy – which leads to increased
friction in the bearings and additional forces on the cages – to be kept as small as possible. The specifically heavy radial loads, the rotating outer rings, and not least, the mass inertia forces cause high friction. Therefore special demands are placed on the lubrication and cooling of the planetary wheel bearings. The least space is taken up by a needle roller and cage assembly as shown in fig 36 . This very cost-favourable bearing arrangement is very suitable for small units (up to approximately 50 mm between shafts) as well as for light loads or short periods of operation as, for example, with small lifting gear. The pins and bores of the planetary wheels serve as bearing raceways. Recommendations regarding raceway hardness and design are given in the section ”Recommended fits” (➔ page 106). The planetary wheel is axially guided by thrust washers. These are secured on the planetary carrier so that they cannot turn. The bearing arrangement shown in fig 37 with two cylindrical roller bearings of the NJ design offers the advantages of very high radial load carrying capacity and very high accuracy as well as high rupture strength in respect of the cage forces if window-type cages are used. The planetary wheel is guided axially by the flanges of the cylindrical roller bearings. To prevent the bearings from being axially clamped, the intermediate ring on the pin should be at least 1 mm wider than the retaining ring in the bore of the wheel. Even though the two cylindrical roller bearings are virtually immediately adjacent to each other, it is not necessary to resort to special bearings for paired mounting (DR execution). Modern manufacturing methods mean that standard bearings differ only slightly in their cross section (bore and outside diameters + internal clearance) from each other. When using two bearings per wheel the deviation will, at the most, cause a slight angular misalignment which is largely compensated for by deformation, so that any effect on the mesh or the load carrying capacity of the bearings is negligible.
3
57
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes Bearing arrangement for a planetary wheel with two cylindrical roller bearings
Bearing arrangement for a planetary wheel with two cylindrical roller bearings without outer ring
To achieve the maximum load carrying capacity in the limited space, the bearing outer rings can be dispensed with, as shown in fig 38 . Cylindrical roller bearings of the RN design are used. The wheel is guided axially by the flange rings and the inner ring flanges. The dimensions of the rings are not standardised and should be agreed with the bearing manufacturer. Recommendations regarding design of the raceways in the wheel bore will be found in the section “Recommended fits” (➔ page 106). Another way to increase load carrying capacity is to use full complement cylindrical roller bearings as shown in fig 39 . In this case, a special double row bearing without outer ring is used. Bearing arrangement for a planetary wheel with a double row full complement cylindrical roller bearing without outer ring
58
The design provides very high load carrying capacity in a small space. However, full complement cylindrical roller bearings cause more friction and are susceptible to wear. They are not suitable for high normal accelerations. Therefore, this bearing arrangement is more appropriate for short-term operation, also with heavy load shocks, rather than for constant operation. A typical application area is that of mobile gear units. The use of a spherical roller bearing to support a planetary wheel, as shown in fig 40 , allows the wheel to adjust to the mesh. When the planetary carriers deform, so that the overhung pins become misaligned, the mesh is improved by the use of a self-aligning Bearing arrangement for a planetary wheel with one spherical roller bearing
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes bearing arrangement, when compared to a rigid bearing arrangement incorporating more than one bearing. The advantage of this self-alignment can also be exploited at high speeds and correspondingly small tooth forces, as there is not much deformation in the tooth contact and the mesh will be good. The easy adjustment of the mesh is also an advantage when the wheels are wide. The smaller theoretical load carrying capacity of the single spherical roller bearing as compared with rigid arrangements where two or more bearings are used is partly compensated for by the even distribution of load over the two rows of rollers. Because of its exceptionally high load carrying capacity compared with other roller bearings and its low cross section, the CARB is eminently suitable for planetary gear bearing arrangements (➔ fig 41 ). Its insensitivity to angular misalignment is particularly important for correct meshing in this case. The planetary wheel can align itself so that even meshing is obtained across the whole tooth width. The favourable distributon of the tooth forces thus obtained has a positive influence on the life of the gearbox.
Fig 41
Planetary wheel bearing arrangement with one CARB
3
59
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes
Planetary carriers To achieve equal power splitting in planetary gear units, it is possible to avoid the need for an additional bearing support for the planetary carrier if the following conditions apply: ●
●
Planetary gearbox of cartridge type with two deep groove ball bearings supporting the planetary carrier
60
the planetary carrier is not subjected to load from the output shaft or the torque support; the weight of the planetary carrier is negligible.
The planetary carrier centres itself under load via the planetary wheel meshes. Fig 42 shows a gearbox where the planetary carrier of the high-speed stage is not supported by bearings. It
centres itself via the planetary wheels in the hollow shaft (housing) and on the supported sun wheel. This multiple centring is only possible if manufacturing precision is adequate.
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes The casing is supported by the planetary carrier of the slow-speed stage. The two deep groove ball bearings in a cross-located arrangement are under load from the restoring force of the torque support and from the weight of the gearbox. The resultant bearing forces are generally small and the rotational speed low so that the load carrying capacity of deep groove ball bearings is usually sufficient. The planetary carrier with take-off shaft shown in fig 43 is supported by two full complement cylindrical roller bearings. This arrangement enables additional forces from the power takeoff to be accommodated.
Bearing arrangement for planetary carrier with two full complement cylindrical roller bearings
3
61
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes
Demands on the rolling bearings The special requirements placed on the bearings for planetary gearboxes are derived from the particular conditions pertaining at the various bearing positions. A brief summary is given in Tables 12 to 14 .
Bearing selection The following list may be found useful to check that the chosen bearings satisfy the demands. ● ● ● ● ●
Adjusted rating life Permissible radial acceleration Permissible speed Friction and cooling Adequate bearing play to prevent inadmissible preload at the maximum operating temperature (sun wheel) or under interference fits (planetary wheel)
Demands on sun wheel bearings
Demands on planetary wheel bearings
62
Table 12 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Light loads; idling
Use of deep groove ball bearings preferred to avoid over-dimensioning.
Requirements for clearance-free operation and quiet running
Adjust deep groove ball bearings axially by springs.
Large temperature differentials when starting up (slim sun wheel shaft heats up more quickly than the casing which is better cooled)
Particularly where casings are solid and/or well cooled use deep groove ball bearings with internal clearance to C3.
Table 13 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Heavy radial loads
Use roller bearings with high load carrying capacity. If lubricant film formation is also inadequate, corresponding to a viscosity ratio (actual to required) of κ < 1 use lubricants with suitable EP additives. When κ < 0,5 only use bearings with cages (not full complement bearings). When κ < 0,1 reduce the specific bearing load; aim for s0 > 10.
Radial accelerations resulting from movement of the planetary wheels around the axis of rotation of the sun wheel
Check cage stresses by calculating mass inertia forces. Pay consideration to mass inertia forces of planetary wheel when calculating bearing life.
Increased friction caused by mass intertia forces and rotating outer rings (rotating inaccuracy)
Ensure adequate lubricant supply and cooling. Use heat-stable lubricants. For gearboxes which continuously, or frequently (high frequency of use) operate at high tempeatures (> 80 °C) and which should also have long service life (> 20 000 hours) bearings with metallic cages should be used.
Deformation of planetary wheel by two meshes on opposite sides
For thin-walled planetary wheels (wall thickness < 3 × modulus) take into account the influence of the tension band load distribution on the loaded zone of the bearing (FEM calculation).
3 Design of bearing arrangements Shafts and gear wheels for planetary gearboxes ●
●
Deformation of planetary wheel when wall thickness small; influence on the load distribution in the bearing Static load safety in respect of load shocks
A preliminary bearing selection can be made by referring to the most frequently used bearing series listed in Table 15 .
Table 14 Specific operating conditions
Requirements of bearings/steps to guarantee performance
Very slow speeds with additional loads from the drive
Use preferably bearings with small cross section. When κ < 1 use lubricants with suitable EP additives. When κ < 0,5 only use bearings with cages (not full complement bearings). When κ < 0,1 reduce the specific bearing load; aim for s0 > 10.
3
Table 15 Operating
Bearing series normally used Planetary wheels Sun wheels
Demands on planetary carrier bearings
Bearing selection
Planetary carriers
Low radial accelerations or short operation periods
NJ 23 ECP NCF 30 V NJG 23 VH 230 CC 232 CC 223 E(CC)
60, 62, 63
618, 619 NCF 18 V, NCF 29 V 239 CC
Moderate radial accelerations and continuous operation
NJ 3 ECMA NJ 23 ECMA 230 CC 232 CC 223 E(CC)
60, 62, 63
618, 619 NCF 18 V, NCF 29 V 239 CC
High radial accelerations
NJ 2 ECML NJ 3 ECML NJ 23 ECML 223 CCJA/VA405
60, 62, 63
618, 619 NCF 18 V, NCF 29 V 239 CC
In addition to the bearing series listed above, a CARB can be used for planetary wheels
63
4 Calculation of bearing arrangements Bearing loads . . . . . . . . . . . . 65 Determination of external forces . . . . . . . . . . . . . . . . . . 66 Calculation of bearing loads . . . . . . . . . . . . . . . . . . . 74 Dimensioning the bearing arrangement . . . . . . . . . . . . . 76 Life calculation . . . . . . . . . 76 Static safety factor . . . . . . . 79 Axial load carrying capacity . . . . . . . . . . . . . . . 79 Minimum load . . . . . . . . . . 80 Normal acceleration and cage load carrying capacity 80 Friction and cooling . . . . . . 81 Permissible speeds . . . . . . 82 Internal clearance and preload . . . . . . . . . . . . 83 Adjustment values for single row angular contact bearings . . . . . . . . 85
4 Calculation of bearing arrangements Bearing loads
Calculation of bearing arrangements Following the preliminary selection of bearing type, it is necessary to determine all the external forces acting on a gear unit and from them to calculate the bearing loads. For the final selection of bearing size (and execution) several criteria must be observed, the most important of which is bearing life. 4
Bearing loads ●
To calculate the bearing loads it is first necessary to determine all the external forces acting on the shaft/bearing system. The following are external forces: ● ● ● ● ●
tooth forces, mass inertia forces from radial accelerations in planetary gears, coupling and propeller shaft forces, belt forces, and weights of shafts and gear wheels.
An analysis of the force distribution over the bearings must then be made. There is a choice of method: ●
fying assumptions and models; advanced methods where bearings, shafts and in part also housings (casing) are considered as a nonrigid system; these methods involve extensive calculations and require the use of sophisticated computer programs available in house at SKF.
Where experience is available from the same or similar designs it is still the custom to use the conventional methods for comparative calculations. Because of the greater information obtained using the sophisticated methods it is recommended that they be applied for new designs and also when conducting damage analysis. Please contact SKF for assistance.
conventional methods based on the beam model, suitable for manual calculations and the corresponding computer programs (included in the SKF CADalogue and ADAM software); these methods rely on simpli-
65
4 Calculation of bearing arrangements Determination of external forces
Determination of external forces Tooth forces The magnitude of the tooth forces is dependent upon the torque which is to be transmitted. As the torque is the fundamental criterium on which all calculations are based, and consequently also the evaluation of the bearing arrangement, it should be determined as accurately as possible, e.g. by measuring or based on experience. Additional forces caused by inaccuracies in the mesh which come from the manufacturing process, or by shocks originating from the input or output drives, are taken into account by selecting an application-related minimum life. When calculating the forces for spur, bevel and planetary gears (➔ fig 1 ), tooth friction is ignored. Friction is only taken into account for hypoid and worm gears where there is a larger proportion of sliding friction. In the following equations the index 1 is used for the driving wheel and the index 2 for the driven wheel. The peripheral force Kp depends on the torque or power and can be obtained from
Kp =
Symbols K tooth force acting at right angles to the tooth flank, N Kp tangential component of K (= peripheral force), N Ka component of K acting parallel to the shaft axis (= axial force), N Kn component of K acting at right angles to the shaft axis (= normal force), N M torque to be transmitted by gear wheel, Nmm W power to be transmitted by gear wheel, kW r pitch radius (mean radius for bevel gear wheels), mm n rotational speed of gear wheel, r/min α angle of engagement, degrees β angle of inclination, degrees δ half cone angle of bevel gear wheels, degrees γ pitch of worm, degrees Z number of teeth µ coefficient of friction of tooth flanks of hypoid and worm gears η degree of efficiency for hypoid and worm gears
M W = 9,5517 × 106 r nr
For spur and bevel gears, the gear ratio is
Tooth forces Fig 1
Kp
n1 r Z = 2 = 2 n2 r1 Z1
r K Ka Kn
66
4 Calculation of bearing arrangements Determination of external forces Spur gear For straight cut spur gear units (➔ fig 2 )
For spiral cut or curved bevel gear units (➔ fig 5 ) the equations shown in Table 1 should be used. As the equations
Ka = 0 Ka2 = Kn1
Kn = Kp tan α
Kn2 = Ka1 and for spiral cut spur gear units (➔ fig 3 )
also apply to bevel gear units where the shafts are at right angles to each other, it is sufficient in this case to calculate the forces acting on the driving wheel, as this will also determine the forces on the driven wheel. Where the teeth are straight cut, the forces Kn and Ka always act in the directions shown in fig 4. For spiral cut or curved teeth, the forces may act in the opposite direction, depending on the angles α, β and δ. In this case, the calculated values for Kn and Ka are negative.
Ka = Kp tan β
Kn = Kp
tan α cos β
Bevel gear units For straight cut bevel gear units (➔ fig 4 ) Ka1 = Kp tan α sin δ1 Kn1 = Kp tan α cos δ1 Ka2 = Kp tan α sin δ2
4
Kn2 = Kp tan α cos δ2 Tooth forces of straight cut
Fig 2
Fig 3
Kp
Kp
Tooth forces of helical cut spur gears
β Ka Kn
Kn
r
Tooth forces of straight cut
r
Fig 4
Fig 5 Kp
Kp
Tooth forces of helical cut bevel gears
β
δ
Ka
Ka Kn
Kn r
r
67
4 Calculation of bearing arrangements Determination of external forces Tooth forces for helical and curve toothed bevel gears
Table 1 Driving wheel
Ka1 =
Kp (− sin β cos δ1 + tan α sin δ1) cos β
Kn1 =
Kp (sin β sin δ1 + tan α cos δ1) cos β
Ka1 =
Kp (sin β cos δ1 + tan α sin δ1) cos β
Kn1 =
Kp (− sin β sin δ1 + tan α cos δ1) cos β
Driven wheel
Ka2 =
Kp (sin β cos δ2 + tan α sin δ2) cos β
Kn2 =
Kp (− sin β sin δ2 + tan α cos δ2) cos β
Ka2 =
Kp (− sin β cos δ2 + tan α sin δ2) cos β
Kn2 =
Kp (sin β sin δ2 + tan α cos δ2) cos β
Tooth forces for hypoid gears
Table 2 Driving wheel
Ka1 = K (− cos α sin β1 cos δ1 + sin α sin δ1 + µ cos β1 cos δ1) Kn1 = K (cos α sin β1 sin δ1 + sin α cos δ1 − µ cos β1 sin δ1)
Ka1 = K (cos α sin β1 cos δ1 + sin α sin δ1 − µ cos β1 cos δ1) Kn1 = K (− cos α sin β1 sin δ1 + sin α cos δ1 + µ cos β1 sin δ1)
Driven wheel
Ka2 = K (cos α sin β2 cos δ2 + sin α sin δ2 − µ cos β2 cos δ2) Kn2 = K (− cos α sin β2 sin δ2 + sin α cos δ2 + µ cos β2 sin δ2)
Ka2 = K (− cos α sin β2 cos δ2 + sin α sin δ2 + µ cos β2 cos δ2) Kn2 = K (cos α sin β2 sin δ2 + sin α cos δ2 − µ cos β2 sin δ2)
68
4 Calculation of bearing arrangements Determination of external forces Hypoid gear units As can be seen from fig 6 , the two shafts of a hypoid gear unit do not lie in the same plane. Therefore, the angle of inclination β1 of the driving wheel is not the same as β2 of the driven wheel. The wheels are so chosen that β1 is larger than β2. The directions of the peripheral forces Kp1 and Kp2 do not coincide, in contrast to spur and bevel gear units. For hypoid gears, the ratio is
As (cos β2/cos β1) > 1, the pitch radius of the pinion is greater for a given ratio and a given size of the wheel which the pinion engages than is the case for a bevel gear unit. The peripheral force Kp1 which acts on the pinion is obtained from M1 r1
The tooth force which acts vertically on the tooth flank is obtained from K =
Kp1 cos α cos β1 + µ sin β1
tan γ =
h 2 π r1
where h in mm is the pass height of the worm on the partial cylinder and r1 in mm the pitch radius of the worm. Generally, the worm drives the worm wheel and the following calculation is for this case. Index 1 refers to the worm and index 2 to the worm wheel (➔ fig 7 ). The tooth forces are obtained from
Kp1 =
4
M1 r1
Ka1 = Kp1
and the peripheral force for the large wheel from Hypoid gears
Worm gear units When calculating worm gears it is common practice to take the angle of pitch γ instead of the angle of inclination β. The following equations can be used γ = 90 − β
n1 Z r cos β2 = 2 = 2 × n2 Z1 r1 cos β1
Kp1 =
The forces Ka and Kn are obtained using the equations shown in Table 2 , taking into account the requirements for the direction of the spiral cut and of rotation.
cos α cos γ − µ sin γ cos α sin γ + µ cos γ
= Kp1 cot γ η Tooth forces of worm gears
Kp2 = K (cos α cos β2 + µ sin β2) Fig 6
Fig 7
Kn1 Kp1
r1
Kp2 Ka1 Ka2 Kn2
r2
69
4 Calculation of bearing arrangements Determination of external forces
Kn1 = Kp1
= Kp1
sin α cos α sin γ + µ cos γ tan α [sin2 γ (1 − η) + η] sin γ
As can be seen from fig 7 the forces acting on the worm wheel are determined by calculating the forces on the worm as follows Kp2 = Ka1; Ka2 = Kp1; Kn2 = Kn1 The reduction ratio for worm gear units is n1 Z = 2 n2 Z1 where Z1 is the number of passes of the worm and Z2 the number of teeth of the worm wheel. Planetary gear units The determination of the forces is shown for the most common type of planetary gear, i.e. with parallel shafts and toothed pinion. Using the following equations it is of no importance for the determintion of the speeds and torques which of the three parts is connected to the drive, the power take-off, or the stationary part (casing), or whether all three parts are in motion and transmit power. The calculation starts with the basic ratio u, which is the ratio of the rolling
Construction of planetary gearbox (schematic)
pitch radius of the hollow wheel R and its planetary wheel to that of the sun wheel and its planetary wheel. The magnitude of the radius s, which for corrected toothing must not be (R + r) /2, does not matter here. The advantage of this method is that the various types with double planetary wheels can be calculated in a simple manner. The same equations can be used for all planetary gear units of types I to III (➔ fig 8 a), which are equivalent to the simple unit (➔ fig 8 b). It should be remembered that the values of R, s and r to be inserted in the equation for u correspond to the lever of the three parts which act on the assumed double lever in the planetary wheel (thus, R is not always the radius of the hollow wheel, s not always the radius of the planetary wheel and r not always the radius of the sun wheel). The basic ratio is obtained from
u =
R (s − r) (R − s) r
For normal toothing (s − r) = (R − s) is valid so that
u =
R r
Fig 8 type I
type II
R
R S
r
type III
R
R S
r
simple unit
S
S r r
a
70
b
4 Calculation of bearing arrangements Determination of external forces If the symbols R, s and r are inserted for the different equivalent planetary units according to fig 8 a, the the upper equation for u is again valid.
Torques: Ms = Mr + MR = (u + 1) Mr
= (
Speeds:
1 + 1) MR u
nr = (u + 1) ns − u nR
nR =
Mr =
(u + 1) ns − nr u
MR = u Mr =
n + u nR ns = r u+1 Speeds of the planetary wheels about their own axes a) for simple planetary gear units
= (ns − nr) = (nR − nr)
R R−s
u M u+1 s
Tooth forces: The peripheral force is obtained from
Kp = npl = (nr − ns)
1 1 M = M u R u+1 s
Mr Mr or Kp = R Zpl r Zpl
where Zpl = number of planetary wheels.
r s−r
4
For straight cut teeth 1
s−r R−s + r R
b) for double planetary units type I:
Ka = 0 Kn = Kp tan α and for spiral cut teeth Ka = Kp tan β
npl = (nR − nr) = (ns − nr)
R R−r s s−r
Kn = Kp
tan α cos β
type II:
npl = (nR − ns) = (ns − nr)
R R−s r s−r
type III: npl = (nR − nr)
r R−r
= (nR − ns)
s R−s 71
4 Calculation of bearing arrangements Determination of external forces Fig 9
Fig 10
FG M
S1
r
ϕ Kr
a S2
FG
Cardan shaft forces
Inertia forces from the radial acceleration The rotation of the planetary carrier about its own axis causes inertia forces on the planetary wheels which must be considered when calculating the bearing load if speeds are high. For the inertia (gyratory) force on a planetary wheel F = m rs ω2 where F = inertia force, N m = mass of planetary wheel, kg rs = radius of centre of gravity of rotating planetary wheel, m ω = angular velocity of the planetary carrier
(= π30n ), s s
−1
ns = rotational speed of the planetary carrier, r/min
Coupling and propeller shaft forces When selecting and designing torquetransmitting couplings, it is desirable that no reactionary forces act on the shaft/bearing system. Even though this is not completely possible, because of inaccuracies governed by manufacture or deviations when aligning the coupled shafts, and not least because of deformations, it may still be assumed that the coupling forces are negligible in comparison to the tooth forces. With propeller shafts, forces are produced when the torque is transmitted. These forces rotate with the rotation of the shaft and change periodically (➔ fig 9 ). For two bearings, the fol-
72
lowing radially acting pair of maximum forces should be used for calculations
FG max =
M tan ϕ a
where FG max = maximum, periodically changing force, N M = torque to be transmitted, Nmm a = distance between bearings, mm ϕ = bending angle of joint, degrees As FG max is the maximum of the periodically changing force, an approximate average force can be obtained from Fm = 0,75 FG max assuming that the bearings are only subjected to load caused by the joint forces. If the bearings are also subjected to other forces then the following approximation applies
Fm =
1 2 Fmin + F 3 3 max
Fmin = forces other than the joint force which act on the bearings, N Fmax = all forces acting on the bearing, including the joint force FG max, N As the bending angle ϕ changes there will be a compensation in length of the propeller shaft which, because of friction, will produce an axial force
Belt forces
4 Calculation of bearing arrangements Determination of external forces Table 3 Type of belt drive
Preload factor f at peripheral speed (m/s) 20
Kr = f Kp = f
Flat belts
3 to 4
2,5 to 3,5
2 to 3
V belts
1,5 to 2,5
1,5 to 2,5
1,5 to 2,5
Toothed belts
1,1 to 1,3
1,1 to 1,3
1,1 to 1,3
Preload factor
where Kr = resultant belt force, N Kp = peripheral force, N M = torque, Nmm f = tensioning factor r = radius of belt pulley, mm
Forces from the torque support
where M = torque, Nmm rm = mean radius of the sliding profile, mm µ = coefficient of friction ϕ = angle of bending, degrees As this axial force only acts during certain periods – namely when the bending angle changes – it should be taken into account for the time it acts when calculating the life, or if the change in angle occurs when the shaft is not rotating, it should be included in the calculation of the static safety factor s0.
Belt forces Torque support forces
M r
Appropriate values of tensioning factor, depending on the peripheral speed, can be obtained from Table 3 .
M µ cos ϕ rm
Fa =
Kr produced by the belt (➔ fig 10 ) can be calculated using
The gear unit may be driven by a belt and power take-off may also be via a belt. The radial force acting on the shaft Fig 11
K1
In cartridge-type gear units, the bearings on the output shaft are subjected not only to the tooth forces, but also to forces from the reaction to the torque and from the weight (➔ fig 11 ). The force K1 acting on the output shaft bearings can be obtained from
4 K1 =
M a +G l l
where K1 = force acting on the bearings, N M = reaction torque (for simplicity it can be taken as being equal to the torque of the output shaft), Nmm G = weight of gear unit including motor and base plate, N l = distance between torque support and output shaft, mm a = distance between torque support and centre of gravity, mm When calculating bearing load it should be remembered that the force K1 is introduced via the bearing outer rings from the casing.
Weights of shafts and gears G K2 a l
The weights of shafts and gears are generally negligible compared with the tooth forces. They should not be ignored, however, when dealing with vertical units as they act axially and may constitute a considerable part of the total bearing load – particularly in large units.
73
4 Calculation of bearing arrangements Calculation of bearing loads
Calculation of bearing loads Once the external forces have been determined it is possible to calculate the bearing loads. It is sensible to divide the forces, as shown in fig 12 , into three vertically acting components. The forces act at the pressure centres of the bearings. For deep groove ball bearings, cylindrical roller bearings and spherical roller bearings, the pressure centre is at the geometric centre of the bearing. For single row angular contact ball bearings and taper roller bearings, the distance between the pressure and geometric centres of the bearing will be found for each bearing in the SKF General Catalogue. If a shaft is supported in a double row angular contact bearing, or in two single row angular contact bearings arranged back-to-back, plus an additional bearing, and if the distance between the bearings is relatively small, under a load consisting of a radial force component Kn and an axial component Ka, the position of the line of action of the radial force Fr acting on the bearing pair or bearings will influence the distribution of the external load over the three rows of rolling elements. The distance ax of the line of action can be determined approximately from the diagram in fig 13 in relation to the contact angle of the bearing and the load ratio Fa/Fr. A more realistic determination of the load distribution over the three rows
Forces acting at the bearing positions when an external force is applied at a point between the pressure centres
can be made by taking into account the resilience of the shaft and bearings. This can be done with the inhouse computer programs developed by SKF.
The external force acts on the shaft between the pressure centres of the bearings The bearings with pressure centres I and II at a distance l corresponding to fig 12 are loaded by a force K acting in any direction. The force is divided into the components Kp, Kn and Ka. For the forces acting vertically at the bearing positions
F1 I =
l−a r Kn − K l l a
F1 II =
a r K + K l n l a
and for the forces acting horizontally
F2 I =
l−a Kp l
F2 II =
a K l p
Position of the force produced by double row and paired single row angular contact bearings
Fig 12
Fig 13
Kp
r
Ka = Fa
F1I FrI
Kn
Kn FrII
F2I
F2II
Fr
0,5
F1II II
0
ax
K
Ka
I
b
Fa
0,4
Ball bearings
0,3
Roller bearings
0,2 0,1
a
0
l
74
0
0,2 0,4 0,6 0,8
1
1,2 1,4 1,6 1,8 2 Fa cotα Fr
4 Calculation of bearing arrangements Calculation of bearing loads The resultant radial load s for the bearings can then be determined using
and for the horizontally acting forces
Fr I = √ F1 I2 + F2 I2
F2 I =
a−l Kp l
F2 II =
a K l p
Fr II = √ F1 II2 + F2 II2 The axial force Fa acts on one of the two bearings – the locating bearing – in addition to the radial forces. When the bearing is not a single row angular contact bearing, Fa = Ka. In single row angular contact bearings under radial load, an axial force will be induced which must be taken into account when calculating the equivalent dynamic bearing load. Details will be found in the SKF General Catalogue.
The external force acts on the shaft away from the pressure centres of the bearings The force K is also divided into three components: Kp, Kn and Ka. According to fig 14 , for the bearing forces acting vertically
F1 I =
a−l r Kn − K l l a
F1 II =
a r Kn − K l l a
Forces acting at the bearing positions when an external force is applied at a point outside the pressure centres Fig 14 Kp F2I I
Ka
FrI
K
F1II
F1I
Kn
FrII II
The resultant radial loads acting on the bearing can then be obtained, as before, from Fr I = √ F1 I2 + F2 I2 Fr II = √ F1 II2 + F2 II2 Once the radial load Fr and the axial load Fa have been determined, the equivalent dynamic bearing load P and then the bearing rating life L10h can be determined following the instructions given in the SKF General Catalogue. The conventional determination of the bearing load described here is based on many simplifying assumptions in order to permit manual calculation. More realistic results are obtained if the deformation of bearings, shafts and possibly also of the casing can be taken into account. This can be done using the sophisticated SKF computer programs available in house. For shaft systems supported at three or more positions it is imperative that deformations are considered, as the conventional methods often lead to rather unrealistic results. Even for statically determinate doubly supported shafts, it is advisable to calculate using the more sophisticated methods when the application limits for a new design are being evaluated, or when additional information is required on bearing and gear displacements and misalignments, or on rolling element loads and stresses in the rolling contact, rather than the approximate life.
4
r
F2II Fa l a
75
4 Calculation of bearing arrangements Dimensioning the bearing arrangement
Dimensioning the bearing arrangement The bearing size and execution required for a given bearing arrangement are determined based on the following criteria: ● ● ● ● ● ● ● ● ●
life static load carrying capacity axial load carrying capacity minimum load normal acceleration and cage load carrying capacity friction and cooling speed capability internal clearance and preload adjustment values for single row angular contact bearings.
A more reliable selection can be made by calculating the adjusted rating life L10ah which also takes into account lubrication. The calculation requires information regarding the viscosity of the lubricant to be used and the bearing operating temperature in addition to the load and speed. By calculating the adjusted rating life it is also possible to determine whether the lubricant is suitable and whether cooling would give better results. A determination of the adjusted rating life is also helpful for the following reasons. ●
In many cases bearing size is simply selected on the basis of the calculated life. The list above and the following comments serve to show that for reliable performance of the bearing, a number of other criteria should be considered in addition to the calculated bearing life. ●
Life calculation The Lundberg and Palmgren theory of bearing fatigue life forms the basis for bearing life calculations. The life equations derived from the theory are to be found in the SKF General Catalogue. Their use for gearbox bearing calculation will be discussed here. Bearing life can be calculated with greater accuracy and reliability, the more accurately the operating conditions are known or can be determined. To calculate the basic rating life L10h according to ISO it is only necessary to know the basic dynamic load rating of the bearing, the equivalent bearing load and the rotational speed. Important influences such as lubricant film formation in the bearing and lubricant cleanliness are not considered in the L10h calculation. In spite of this, if experience of similar bearing arrangements is available and the other parameters which affect bearing life, but which are not considered in the calculation are reasonably constant, a basic rating life calculation may be sufficient to determine the appropriate bearing size.
76
Bearings operating at high speeds but which are lightly loaded are negatively influenced by high temperatures and large inertia forces. Lubricant film formation is promoted at high speeds and an adjusted rating life calculation can show that a smaller bearing can be used than would be suggested by a basic rating life calculation, so that friction as well as inertia forces will be reduced. The reliability of the bearing arrangement will be enhanced. Slowly rotating bearings operating under heavy loads are subject to deformations with correspondingly high proportions of sliding in the rolling contact and are susceptible to wear. The slow speeds mean that lubricant film formation will be poorer, and the adjusted rating life calculation will lead to the choice of bearings having higher load carrying capacity. This will mean that the specific bearing loads will be lighter, deformations and wear will be reduced, and reliability enhanced.
Contamination has a considerable effect on the life of gearbox bearings. The influence of contamination can be calculated using the SKF New Life Theory. The fatigue load limit is also considered when calculating the adjusted rating life L10aah according to the New Life Theory so that it is possible to design an arrangement for infinite life.
4 Calculation of bearing arrangements Dimensioning the bearing arrangement The following parameters are considered when calculating L10aah: ● ● ● ● ● ● ●
dynamic load rating of the bearing, fatigue load limit of the bearing, equivalent dynamic bearing load, rotational speed, lubricant viscosity, operating temperature and cooling, and contamination and sealing.
Calculations according to the New Life Theory are particularly suitable for making parametric studies to determine the influence of the different factors. It should be noted that the various factors have a strong influence on each other, and such calculations are only meaningful when the operating conditions are exactly known. When bearing life calculations for the selection of bearing size are made, only those results obtained using one and the same method should be compared. When determining a suitable life it is necessary to consider how the gearbox is to be used. The requisite basic rating life is dependent on the type
and size of the driven machine, on the length of service and on demands regarding operational reliability. If no experience is available then the guideline values for the requisite basic rating life L10h given in Table 4 can be used. In similar applications, the drives of large machines are generally subjected to more arduous conditions than the drives of smaller machines because of stronger shock loads and larger defomations. This should be taken into consideration when choosing the guide-line value from Table 4. When bearing arrangements are intended for very slow rotational speeds and/or are to have a very short life, the requisite basic dynamic load rating of the bearing is very small. This can lead to an unsuitable bearing being chosen which will give inadequate static safety, or the formation of only an inadequate lubricant film, or to the overloading and consequent deformation of the associated components. If, in addition to the requisite life, a minimum requisite value of the static safety factor s0 is also to be considered, this Table 4
Gearbox application
L10h (operating hours)
Machines and equipment infrequently used: Household appliances Agricultural machinery Medical equipment
300 to 3 000
Machines used for brief periods or intermittently: Cranes Lifts and elevators Construction machinery
3 000 to 10 000
Machines for daily (8 hour) use: Machine tools Woodworking machines Fans Conveyor drives Centrifuges
10 000 to 30 000
Machines for 24-hour use: Rolling mills Compressors Pumps Barges
30 000 to 50 000
Machines for 24-hour operation where high reliability is required: Cement mills Rotary furnaces Power generating plant Large-size open cast mining equipment Wind and water turbines Ocean-going ships
50 000 to 100 000
4
Guideline values for the requisite basic rating life L10h for gearboxes for various applications
77
4 Calculation of bearing arrangements Dimensioning the bearing arrangement should be based on the κ value (ratio of actual to required viscosity). The decision not only depends on the operating speed therefore, but also on the viscosity at the operating temperature and on the mean bearing diameter. Table 5 contains recommendations as whether the bearing selection should be based on the requisite life or on the static safety, taking the value of κ into account. Thus ●
●
●
when κ < 0,1 no life should be given; the material will fatigue under conditions of small κ, but the operational reliability and service life will not depend on fatigue but on other factors which are indirectly accounted for by the static safety factor s0.
when κ > 0,5, the static safety factor s0 should be checked in addition to the requisite life; when κ ≤ 0,5 then the static safety factor s0 must be considered;
Selection criteria
Table 5 Viscosity ratio κ over incl.
Bearing selection based on fatigue life
static safety factor
L10h
L10ah
L10aah
s0
0,1
−
−
−
+
0,1
0,5
−
o
+
+
0,5
1
+
+
+
o
+
+
+
o
1 Symbols + recommended – not appropriate o can also be used
Guideline values for the static safety factor s0
78
Table 6 Bearing type
Type of operation Rotating, Rotating, statically brief shock loaded loads nrel = 0 nrel > 0
κ < 0,1
κ = 0,1 to 0,5
Ball bearings
2
2
10
5
0,5
Roller bearings
3,5
3
10
5
1
Full complement cylindrical roller bearings
–
3
20
10
1
Rotating at very slow speeds under load
Stationary
4 Calculation of bearing arrangements Dimensioning the bearing arrangement
Static safety factor
●
The basic static load rating C0 is used to select bearing size in the following cases: ●
●
● ●
when the bearing rotates at a relative speed of 0 (bearing arrangements of shifting gears) under load (rotating static load); when the bearing rotates and must, in addition to the normal loads, take up heavy shock loads for a fraction of a revolution (e.g. rolling mill drives); when the bearing rotates very slowly under constant load; when the bearing is stationary and is under constant load or is subjected to shock (short duration) loads, e.g. in mobile gearboxes.
●
●
light axial load, when 0,1 < κ ≤ 0,5: Fa max = 0,05 Fap, when 0,5 < κ ≤ 1: Fa max = 0,1 Fap, when 1 < κ ≤ 2: Fa max = 0,2 Fap, where Fap is the maximum permissible axial load at κ ≥ 2 there is an adequate supply of a CLP oil which offers good protection against wear the arrangements for oil supply and drainage are designed so that wear particles will not collect in the bearing
The guideline values of the static safety factor s0 for different bearing types given in Table 6 are valid when there is adequate lubrication using a CLP oil to DIN 51 517 which offers good protection against wear. Bearing selection based on the static safety factor s0 is described in the SKF General Catalogue.
4
Axial load carrying capacity The axial loads acting on rolling bearings are considered when calculating the equivalent dynamic and static bearing loads, see SKF General Catalogue. However, the axial load carrying capacity of cylindrical roller bearings is primarily determined by the load carrying ability of the sliding surfaces of the roller ends and flanges and is very strongly dependent on the lubrication and cooling. When calculating the permissible axial load according to the SKF General Catalogue, a viscosity ratio κ ≥ 2 is presupposed. When κ is smaller friction and wear will increase. Based on experience these effects can be kept at an acceptable level for slowly rotating gearbox bearings if the fol-lowing favourable conditions pertain
79
4 Calculation of bearing arrangements Dimensioning the bearing arrangement
Minimum load In order for bearings to perform correctly they must always be subjected to a given minimum load. This will prevent the rolling elements from sliding on the raceways which would lead to smearing and premature bearing failure. This minimum bearing load can be calculated using the information given in the SKF General Catalogue. When this minimum load is constantly applied, there will be practically no sliding in the bearings. This load can be applied rather easily to thrust bearings, e.g. by springs, even when they are idling, but may be more difficult to arrange for radial bearings. In cases where the weights of shaft and gears are insufficient for the minimum load requirements, the risk of sliding can at least be reduced if the following recommendations are respected. ●
●
●
●
●
● ●
Use ball bearings, taper roller bearings or spherical roller bearings where possible (full complement cylindrical roller bearings are most at risk). Use bearings with small rolling elements – in critical cases at the expense of basic rating life. Keep bearing internal clearance small and – if at all possible – apply a preload. Avoid metallic contact in the rolling element/raceway contacts (ensure adequate supply of lubricant having sufficient viscosity; if necessary use bearings with black oxidised rolling elements). Ensure high accuracy of position and form of the associated components and use bearings of correspondingly high precision. Avoid vibrations wherever possible. Limit periods of idling under insufficient load as far as possible.
Experience shows that idling under insufficient load in gearboxes cannot always be avoided. The bearings which are most susceptible to damage under such conditions are large cylindrical roller bearings (d > 150 mm) as well as full complement cylindrical roller bearings. Often the bearings are damaged during test running without load.
80
The development of smearing – the typical damage caused during idling – and its prevention are being studied. SKF application engineers will gladly provide information on the latest research results.
Normal acceleration and cage load carrying capacity The movement of a planetary gear bearing is made up of a guidance or locating movement, resulting from the rotation of the planetary carrier, and a relative movement resulting from the bearing turning in the planetary carrier. In comparison with bearings mounted in stationary housings, the guidance and coriolis accelerations cause additional inertia forces to act on the planetary gear bearings. The mass of the planetary gear and the associated bearing rings produces a force as a result of the normal guidance acceleration which the bearing arrangement must also accommodate. These accelerations also mean that the masses of the rolling elements and cage will exert additional forces as well as the bearing itself. These additional inertia forces act on the rolling elements, bearing rings and, to a high degree, also the bearing cage. It is thus possible that a bearing will fail not from fatigue but because of cage fracture. The additional forces increase the sliding friction in the contacts which guide the rolling elements and cage. In full complement cylindrical roller bearings, because of the normal acceleration, the rollers are in contact with each other, so that friction increases and lubricant film formation is hindered. As a result the risk of scuffing or seizure is increased. SKF has specially developed computer programs for the calculation of the cage carrying capacity and also for how much the friction will be increased by the additional forces as well as the risk of seizure for full complement cylindrical roller bearings.
4 Calculation of bearing arrangements Dimensioning the bearing arrangement An estimate of the permissible normal acceleration for the bearing and cage designs most frequently used for planetary gears can be made using the following equation and catalogue data
Friction and cooling Bearing friction depends on the following factors: ● ● ●
an ≤ ka
●
dm0,8 g × 103 C0
● ●
where an = permissible normal acceleration ka = a factor (➔Table 7 ) dm = mean bearing diameter = 0,5 (d + D), mm C0 = basic static load rating, N
load, speed, bearing type, bearing size, lubricant properties (viscosity in operation), and lubricant quantity.
The total frictional resistance in a bearing is made up of ● ●
● ● ●
rolling and sliding friction in the rolling element/raceway contacts, sliding friction in the rolling element/ cage contacts (rolling element guidance), sliding friction in the cage/bearing ring contact (cage guidance), friction in the lubricant, and sliding friction of the rubbing seals in sealed bearings.
4
Friction influences heat generation and consequently bearing operating temperature. In gearboxes, the gears produce more friction than the bearings. When making arrangements for cooling, therefore, it is necessary to consider the total friction in the gearbox.
Factor ka
Table 7 Bearing type
Bearing design
Factor ka for circulating oil lubrication with good cooling
for oil bath lubrication without special cooling
Cylindrical roller bearings
ECP ECJ ECM ECMR ECMA ECMP ECML
120 170 150 400 700 1 400 1 800
40 50 50 150 250 500 600
Spherical roller bearings
E CC CC/VA405
250 600 1 400
100 200 500
81
4 Calculation of bearing arrangements Dimensioning the bearing arrangement Operating temperatures in the gearbox (and thus the bearings) should preferably not exceed 100 °C and definitely not be higher than 150 °C for the following reasons: ● ● ●
●
High lubricant viscosity enhances lubricant film formation. The lubricant ages more slowly, the lower the temperature. The dimensional changes in the bearing rings and rolling elements resulting from micro-structural changes in the material are smaller, the lower the temperature. The temperature differential across a bearing is smaller, the lower the temperature, so that preset bearing clearance or preload will not change as much.
The power loss resulting from the bearing friction can be calculated using information given in the SKF General Catalogue. Heat is removed from a bearing by conduction, convection, radiation and by the lubricant. If circulating oil lubrication is to be used, the requisite quantity of oil can be calculated from
Q = 0,039
NR Ta − Te
where Q = requisite quantity of oil (oil flow rate), l/min NR = power loss, W Ta = oil temperature at exit, °C Te = oil temperature at inlet, °C By experience, approximately 1/3 of the power loss is dissipated by the oil and 2/3 through heat conduction, convection and radiation. A value of 10 °C can be assumed for the temperature difference (Ta – Te). The guideline values obtained using the equation below have been found to be good estimates of the oil flow rates.
where Q = oil quantity (oil flow rate), l/min f = factor depending on bearing type and duty = 0,00003 for radial ball bearings, and radial roller bearings for moderate duty = 0,00005 for radial roller bearings in general = 0,00001 for thrust bearings, radial roller bearings with rotating outer ring and planetary gear bearings D = bearing outside diameter, mm B = bearing total width (radial bearings) or height (thrust bearings), mm The guideline values for the oil flow rate are generally on the safe side. For small bearings only very small quantities are required and it is difficult to arrange for a correct supply, particularly when the temperature varies. Often, the oil from pockets which capture oil will be sufficient. As there is a risk with forced oil circulation that the leads and nozzles become blocked it is recommended that either at least 0,25 l/min is supplied to each bearing, or supply pumps should be used which allow larger supply cross sections even where oil quantities are small and pressures high.
Permissible speeds When considering the operating speed, the speed ratings quoted in the SKF General Catalogue should be used as a reference. Bearing speeds which are higher than 70 to 80 % of the catalogue speed ratings are considered high. In such cases the following influences must be specially taken into consideration. ●
●
Q = fDB
82
The heat produced as a result of the friction increases bearing temperature; lubrication (viscosity, type of lubricant, lubricant supply) and cooling must be checked. As the heat loss via the casing is usually good, the temperature differential from inner to outer ring is larger, and a bearing having increased internal clearance (e.g. to C3) is required.
4 Calculation of bearing arrangements Dimensioning the bearing arrangement ●
To ensure proper performance of the bearing (no slip and proper rolling motion of the rolling elements) a correspondingly higher minimum load is required.
The maximum permissible speeds are much higher than the speed ratings (see SKF General Catalogue, factor fn). This also applies to gearbox bearings, so that the maximum permissible speeds for deep groove ball bearings, cylindrical roller bearings (with cage), angular contact ball bearings and fourpoint contact ball bearings are twice the speed ratings. If operating speeds are to exceed the speed ratings by more than 50 %, however, it is not only necessary to consider the points outlined above but also the following points. ●
●
●
●
Use oil jet lubrication with a jet speed of approximately 15 m/s. The oil should be directed at the inner ring raceway or the gap between cage and inner ring. Particularly stable cage designs should be chosen, e.g. one-piece outer ring centred machined brass cages (window-type), designation suffix ML, for cylindrical roller bearings. Minimise the vibrations produced in the complete drive system. This means using bearings with increased accuracy of dimensions and form and associated components with correspondingly high accuracy. Take into account the critical bending and torsional vibrations when designing the gearbox shafts.
In cases where bearings fitted with special cages or with increased accuracy are required, it is advisable to contact the SKF application engin-eering service.
●
●
●
4 When calculating the clearance in operation it must be rememberd that the clearance range quoted in the General Catalogue will be reduced when the bearing is mounted with interference fits and by the temperature differential from inner to outer ring. The Normal bearing clearance is sufficiently large so that if the fits are as normally recommended and operating conditions are normal, a sensible operational clearance will be obtained. In gearboxes, unusual operating conditions (e.g. in the cases below) often require the use of bearings with greater than Normal internal clearance to C3 or C4. In such cases it is advisable to check the operational clearance. ●
Internal clearance and preload The clearance in a bearing in operation is important with regard to proper performance of the bearing and to proper load distribution on the rolling elements. The following conditions should be aimed for when the bearings have reached their operating temperature.
For radial roller bearings in gearboxes (e.g. cylindrical, spherical and double row taper roller bearings) a slight radial internal clearance is favourable as the bearings and associated components (shaft, casing) usually have high radial stiffness. Radial preload combined with the deviations from form normally tolerated in gearboxes, or combined with unexpected differences in temperature would increase the risk of inadmissibly high additional stresses occurring which would overload the bearing. For single row taper roller bearings, although they have high radial stiffness, an axial preload can always be allowed if it can be expected that bearing overloading can be avoided by the casing walls ‘‘giving” in the axial direction. For ball bearings zero clearance is best; a slight preload is less critical for ball bearings than for the much stiffer radial roller bearings.
●
Bearings mounted inside gears for which an interference fit for the outer ring is required. This will further reduce internal clearance. Bearings on high-speed slim shafts which will heat up much more rapidly than the casing. The temperature differential across the bearing will then be particularly large.
83
4 Calculation of bearing arrangements Dimensioning the bearing arrangement ●
Gearboxes where the casing is well cooled. Again there will be a large temperature differential across the bearings. Examples include gearboxes operating out of doors where ambient temperatures are low and gearboxes having thick-walled or fan-cooled casings.
The operational clearance (mounted bearings which have reached the operating temperature) can be calculated by following the scheme shown in Table 8 .
Calculation of operational clearance
Bearing (designation): .......................... Tolerances (shaft/housing bore): ..........................
low
high
Radial clearance (µm) 1 Bearing bore (deviation ∆dmp) 2 Shaft (deviation) 3 Theoretical interference (+) or clearance (−): Zth = Point 2 − Point 1 4 Expected interference Z = Zth − smoothing1) 5 Expansion of inner ring:
.......... .......... .......... ..........
.......... .......... .......... ..........
..........
..........
.......... .......... .......... ..........
.......... .......... .......... ..........
..........
..........
.......... .......... ..........
.......... .......... ..........
..........
..........
15 Radial clearance in operation (Point 13 − Point 14)
..........
..........
Axial clearance (µm) for double row angular contact bearings 11a Total axial clearance reduction (Point 11 × cot α) 12a Axial internal clearance before mounting (min/max) 13a Axial internal clearance after mounting (Point 12a − Point 11a) 14a Thermal expansion:
.......... .......... ..........
.......... .......... ..........
..........
..........
..........
..........
el = 6 7 8 9 10
(solid shaft)
el =
d/F [1 − (di/d)2] 1 − (d/F)2 (di/d)2
E/D [1 − (D/Da)2] 1 − (D/Da)2 (E/D)2
Z
Total radial clearance reduction (Point 5 + Point 10) Radial internal clearance before mounting (min/max) Radial internal clearance after mounting (Point 12 − Point 11) Thermal expansion: et = 1,1 dm
eta = 1,1 dm
∆t 100
(µm, with dm in mm)
∆t cot α 100
(µm, with dm in mm)
15a Axial clearance in operation (Point 13a − Point 14a) 1)
84
Z
(hollow shaft)
Bearing outside diameter (deviation ∆Dmp) Housing bore (deviation) Theoretical interference (+) or clearance (−): Zth = Point 6 − Point 7 Expected interference: Z = Zth – smoothing1) Compression of outer ring: eA =
11 12 13 14
d Z F
For guideline values for smoothing see Table 9.
4 Calculation of bearing arrangements Dimensioning the bearing arrangement Guideline values for smoothing of mating surfaces
Table 9 Nominal diameter over incl
Smoothing
mm
µm
–
50
4
50
100
6
100
–
8
Adjustment values for single row angular contact bearings Single row angular contact bearings (angular contact ball bearings, taper roller bearings) are adjusted axially on mounting. The adjustment values (axial clearance or preload) are based on the operating conditions when the bearing is under load and has reached its operating temperature. Light preload is recommended for gearbox bearings and provides the following advantages compared with clearance: ● ● ● ● ●
accurate shaft guidance, increased stiffness, extended calculated and service lives, quiet running, and compensation for settling movements in operation.
As the bearings have to be adjusted on mounting, i.e. in an unloaded condition at ambient temperature, the changes produced when the bearings are in operation must be considered when determining the adjustment values. The main influences are those of temperature and deformations.
Influence of temperature on the adjustment of angular contact bearings The inner rings of bearings mounted on gearbox shafts are generally hotter than the outer rings. This will reduce the set clearance or increase the set preload. The influence of temperature on the adjustment can be calculated using the following equation provided both shaft and casing are of steel or a material with the same thermal behaviour ∆a = 11 × 10−6 [0,5 (dmA T∆A cot αA + dmB T∆B cot αB) ± T∆m L] where Da
dm L α
T∆A, T∆B T∆m
= reduction in axial internal clearance caused by temperature differential, mm = mean bearing diameter = 0,5 (d + D), mm = mean distance between bearings (➔ fig 15 ), mm = contact angle of bearing, degrees (cot α = 1,5/e; for values of bearingdependent factor e see SKF General Catalogue) = temperature differential from inner to outer ring across bearings A and B, °C = temperature differential from shaft to casing, °C
4
The plus sign is used for bearings arranged face-to-face, the minus sign for bearings arranged back-to-back.
Definition of distance between bearings Fig 15 L
A
L
B
Face-to-face arrangement
A
B
Back-to-back arrangement
85
4 Calculation of bearing arrangements Dimensioning the bearing arrangement If the value of the temperature differential T∆ is not known from experience or measurements, the following guideline values can be used:
Influence of deformations on the adjustment of angular contact bearings When considering deformations it should be remembered that the total resilience is influenced not only by the resilience of the bearings but also by the elasticity of the associated components, the fits and the elastic deformations of all other components through which the forces pass, including the gearbox support. The effects of the different stiffnesses of the associated components can be represented in preload force/preload path diagrams. The three preload force/preload path diagrams shown in Diagrams 1 to 3 show the influence of casing stiffness
T∆ = 5 to 10 °C for slowly rotating gearbox shafts T∆ = 10 to 20 °C for intermediate shafts and moderate speeds T∆ = 20 to 30 °C for slim high-speed shafts T∆ = 30 to 40 °C for high-speed input shafts and well-cooled gearboxes
Preload force/preload “path” diagrams for a bearing arrangement (Design 1)
Diagram 1 Preload force F0 Bearing B
Bearing A Bearing position A total
Bearing position B total
Ka F01
δ a1
Axial displacement δa
δ1
Preload force/preload “path” diagrams for a bearing arrangement (Design 2)
Diagram 2 Preload force F0 Bearing B
Bearing A Bearing position A total
Bearing position B total
Ka F02
δ a2 δ2= δ1
86
Axial displacement δa
4 Calculation of bearing arrangements Dimensioning the bearing arrangement Diagram 3 Preload force F0
Bearing B
Bearing A
Preload force/preload “path” diagrams for a bearing arrangement (Design 3)
Bearing position A total
Bearing position B total
Ka F01 = F03 Axial displacement δa
δ a3 δ3
on the axial displacement δa for the pinion shaft shown in fig 16 as a result of the external force Ka. In all three cases, the bearing stiffness and the external force Ka are the same. The casing in case 1 is very stiff whereas the casings in cases 2 and 3 are less stiff. Cases 2 and 3 differ only in the preload. Whereas in case 2 the preload path d is kept constant with respect to case 1, for case 3, the preload force F0 is the same as for case 1. Irrespectively of whether the preload path or the preload force is kept constant, the axial displacement δa will change depending on the casing stiffness. Thus it is imperative that the total resilience at the bearing positions is taken into account when determining
the preload in order to limit the axial displacement. Using the application example shown in fig 17 (a bevel/spur gear) the choice of adjustment (axial clearance, zero clearance or preload) will be discussed. The locating bearings for the bevel pinion shaft have axial clearance because the temperature differential from shaft to casing is relatively large as the speed is high and the pinion shaft has a small mass. Also the bearings are arranged in the (hook-shaped) sleeve and this arrangement is relatvely stiff in the axial direction. The intermediate shaft bearings and those on the output (power take-off) shaft can be either clearance-free or – Fig 16
B
A
4
Pinion shaft bearing arrangement
Ka δa
87
4 Calculation of bearing arrangements Dimensioning the bearing arrangement
Bevel/spur gearbox bearing arrangements
depending on casing stiffness – even be adjusted to preload. The reason for this is that the speeds are low (less frictional heat), the masses of the shafts are relatively large, and the axial stiffness of the casing is lower. In fact, because of the axial forces generated in the bearings, the casing tends to deform (bulge). Influence of adjustment on bearing life The adjustment has different effects on the life of the two bearings shown in
Influence on bearing life of preload and clearance
Diagram 4 Life
Bearing A
Bearing B
Preload
88
Clearance
fig 16 . Whereas the life of bearing A which is subjected to the external force Ka immediately drops with increasing preload, bearing B will achieve its maximum life when it has a slight preload. Diagram 4 shows qualitatively the dependence of bearing life on preload and clearance. From this it will be seen that the stiffness does not increase very much with increasing preload whereas there is a risk that bearing life will be shortened and there will be increased friction and heat. Thus it is advisable to choose the adjustment so that when under load and at the operating temperature the bearing arrangement will have virtually zero clearance. An adjustment to give a distinct preload should only be chosen if the operating conditions (loads, temperatures, deformations) are accurately known, so that the preload force can be determined using sophisticated computer programs.
4 Calculation of bearing arrangements Dimensioning the bearing arrangement When selecting the bearings therefore, not only must the complete bearing designation (cage design, bearing clearance) be established, but information regarding adjustment values, oil flow rates and minimum load must also be given to production and assembly as well as to the end user, so that proper bearing performance can be guaranteed.
4
89
5 Lubrication and maintenance Grease lubrication . . . . . . . . 92 Oil lubrication . . . . . . . . . . . 95 Maintenance . . . . . . . . . . . . . 98
5 Lubrication and maintenance
Lubrication and maintenance Rolling bearings will only perform reliably when they are adequately lubricated. The lubricant prevents intermetallic contact between rolling elements, raceways and cage and also protects the bearing surfaces against corrosion. The importance of lubrication can be seen from the fact that of all premature bearing failures, some 80 to 90 % are caused by faulty lubrication and/or contamination. Long experience indicates that the same estimate holds true for gearbox bearings.
The task of the gearbox designer to choose the most suitable method of lubrication as well as the most suitable lubricant is made more difficult because of the different and varying demands on lubrication which exist for one and the same gearbox. Generally, the lubrication must not only be appropriate for the bearings but also for the gears. Additionally, the operating conditions for the individual bearings in a gearbox are often very different. One type of lubrication can be the optimum for high-speed, lightly loaded bearings, but unsuitable for heavily loaded bearings which rotate slowly. The operating temperature, which has a significant influence on the quality of the lubrication, is often not only dependent on the
5
load and speed but is also affected by changes in ambient temperature. Since, generally, only one method of lubrication and one lubricant are to be used for a gearbox, the optimum will never be achieved. To find the best compromise all the demands regarding lubrication and lubricant properties must be weighed against each other. The explanations and recommendations given in the following may be helpful.
91
5 Lubrication and maintenance Grease lubrication
Grease lubrication
Greases
The most important advantages of grease lubrication are:
The following properties must be considered when selecting an appropriate grease.
●
● ● ●
●
good protection against corrosion as the grease adheres well to the bearing surfaces; the efficiency of seals against external contaminants is reinforced; there is little risk of leakage; reliable lubricant supply – particularly when operation is intermittent – as the grease is retained at the bearing position; freedom from maintenance for lubricated-for-life bearings.
From this it is possible to define the main areas where grease lubrication can be employed in gearboxes. It is used mostly for small units and particularly for geared motors, and the gears are also grease lubricated. Small gearboxes may often be used in varying positions (horizontal, vertical or inclined at an angle). In such cases lubricant supply is more reliable if grease is used rather than oil bath lubrication. Sealing arrangements can also be simpler if grease is used. The life requirements are often very moderate for small units and if they are only used for short periods at a time, they will require no maintenance, being literally lubricated for life. For oil bath lubricated vertical gearboxes it is sensible to grease the upper bearings as the amount of oil splashed up is generally inadequate. The grease can be retained in position by baffle plates.
Base oil viscosity Generally speaking, the base oil viscosity of a grease can be used to calculate the adjusted rating life Lna, see SKF General Catalogue. This viscosity, ν, should preferably be greater than the required viscosity ν1, both viscosities being at the bearing operating temperature. Consistency Greases of consistency 2 and 3 are generally used for rolling bearing lubrication. Greases with lower consistency are easier to pump; those with higher consistency are easier to retain at the bearing position. At low temperatures soft greases of consistency 0 or 1 may be used, but special grease supply arrangements must then be made (e.g. 100 % grease fill, or a central lubrication unit and short relubrication intervals). For gearboxes subjected to vibrations or which are arranged vertically, a consistency 3 grease with high mechanical stability is preferable. When ‘‘gearbox greases” are used for small gearboxes, lubrication is a type of ‘‘dip” lubrication. The greases have a consistency of 0 or 00. Temperature range The expected operating temperature should lie within the temperature range permitted for the grease. When the temperature is too low, the grease will not have sufficient lubricating properties and when it is too high, ageing will be accelerated. An increase of 15 °C halves the original relubrication interval. Load carrying ability and wear protection For heavily loaded bearings (C/P < 10, e.g. bearings on the intermediate and output shafts) or in cases where a fully separating lubricant film is not present (κ < 1), EP greases are used. As the effect of some EP additives may be detrimental to bearing life, it is advisable to contact the lubricant supplier for recommendations.
92
5 Lubrication and maintenance Grease lubrication Protection against corrosion Usually gearboxes are well protected against the penetration of water. Nevertheless the presence of water or moisture cannot be completely prevented as differences in temperature allow condensation to form. Since any water in the rolling contacts of a bearing will quickly destroy the bearing surfaces, only greases having good rust inhibiting properties should be used.
thickener of the old and new greases are compatible. When a combination of oil and grease lubrication is used (e.g. grease lubricated bearings and oil lubricated gears) the lubricants should also be compatible with each other if negative results are to be avoided. This is particularly important when synthetic gear oils and mineral oil based bearing greases are used.
Oil bleed A grease must bleed oil to allow the formation of a lubricant film in the rolling contact. At low temperatures considerable bleeding is advantageous to ensure lubricant supply. At very slow speeds grease will be pushed away from the raceways and will no longer participate in bearing lubrication. Oil will not bleed to the raceways so that starvation will occur in the rolling contact. Consequently, oil lubrication is to be preferred for very slow speed operation. A much more moderate oil bleed is preferred at higher temperatures (> 80 °C) in order to give long relubrication intervals. Miscibility If, for some reason, it is necessary to change to another grease it should be checked whether the base oil and
5 SKF greases
93
5 Lubrication and maintenance Grease lubrication
SKF greases The SKF range of lubricating greases covers nearly all the requirements for gearbox bearing lubrication. These quality greases were specially developed for bearing lubrication. The most important technical data will be found in the SKF General Catalogue. Table 1 gives recommendations regarding the particular suitability of the various greases for different gearbox applications. Methods of grease lubrication The selection of the lubrication method is basically governed by the relubrication interval which can be determined using the information given in the SKF General Catalogue. ●
●
Suitable SKF lubricating greases for gearbox bearings
94
In cases where the relubrication interval is longer than the expected service life of the bearings a single grease fill will suffice. This presupposes that the grease can be retained in the bearings and that any oil bled from the grease cannot escape through openings below the bearings. Lubrication for life has only been found suitable for small and medium-sized bearings (bearing outside diameter up to 240 mm). Manual relubrication using a grease gun is suitable when relubri-
●
cation intervals are in the range one week to six months and the quantities required are up to 500 g. This means that manual relubrication can be used for bearings with outside diameters up to 420 mm. For larger bearings (D > 420 mm), larger quantities of grease (G > 500 g), or shorter relubrication intervals than one week, a continuous supply of grease is more reliable and also more economic. This is also true where the number of bearings to be grease lubricated is large.
When designing the grease supply, care should be taken to ensure that grease cannot escape at the supply side of the bearing, i.e. that it is compelled to pass through the bearing. At the opposite side of the bearing, the emerging used grease will prevent contaminants from entering the bearing. For double row bearings, the most efficient method is to supply the grease via the lubrication holes in the outer ring or, for paired taper roller bearings, through the lubrication holes in the intermediate ring.
Table 1 SKF grease Designation
Use, properties
LGMT 2
Small bearings (outside diameter D up to approx. 62 mm) Light to moderate loads Moderate temperatures up to 80 °C (max 120 °C) Low friction, quiet, good protection against corrosion
LGMT 3
Medium-sized bearings (outside diameter > 62 mm up to approx. 240 mm) Moderate loads Moderate temperatures up to 100 °C (max 120 °C) Multi-purpose grease, good protection against corrosion
LGEP 2
Heavily loaded roller bearings Moderate temperatures up to 80 °C (max 110 °C) Good protection against corrosion
LGEM 2
Heavily loaded roller bearings at low speeds Moderate temperatures up to 90 °C (max 120 °C) Water repellant
LGLT 2
Small, lightly loaded bearings at high speeds Low temperatures down to −20 °C Low friction, water repellant
LGHQ 3
High temperatures above 80 up to 150 °C Moderate loads Moderate speeds Water repellant
5 Lubrication and maintenance Oil lubrication
Oil lubrication Gearbox bearings are generally oil lubricated when the gears are to be oil lubricated and it is simpler to use a single lubricant. The use of oil lubrication for bearings has the following advantages: ●
●
●
●
●
oil can remove heat when bearings operate at high speeds and high temperatures; at very slow speeds and under heavy loads, oil penetrates to the bearing surfaces more easily than grease; less maintenance is required in respect of supplying oil to the bearing position than for grease lubrication, so that operational reliability is enhanced; the intervals between oil changes are longer than the grease relubrication intervals, particularly for medium and large-sized bearings; changing oil is simpler than changing grease.
Lubricating oils The following lubricant properties should be considered when selecting the oil. Viscosity Preferably the viscosity of the oil ν should be greater than the required oil viscosity ν1, both viscosities being at the bearing operating temperature (see under adjusted rating life in the SKF General Catalogue). When determining the appropriate viscosity for the different bearing requirements (speeds, temperatures etc.) in a gearbox, as well as for gear lubrication, it is advisable, if κ values < 1 are found for some of the positions, to err on the side of higher viscosity for the compromise solution. The intention is to improve the lubrication conditions for the heavily loaded bearings rotating at slow speed at the expense of generating more friction, because of the higher viscosity, in the high speed bearings. The operating viscosity and lubricant film formation can be influenced by selecting an oil of the appropriate viscosity class, but also by cooling.
Load carrying ability, wear protection EP oils (lubricating oils CLP to DIN 51 517) are preferred for the lubrication of spur, bevel and planetary gearboxes. As some EP additives have a detrimental effect on bearing life and EP oils also have varying load carrying ability and wear protection properties, it is advisable to contact the lubricant supplier for recommendations regarding the particular application. Protection against corrosion, behaviour in presence of water The rust inhibiting lubricating oils CLP to DIN 51 517 provide enhanced protection against corrosion as they have good surface wetting properties. Free water in the rolling contact is extremely damaging even when the actual amounts are very small. This is particularly true of bearings where the proportion of sliding is high (e.g. heavily loaded spherical roller bearings and all bearings subjected to centrifugal force). It is thus desirable that the oil will emulsify the small quantities of water which cannot be avoided. Behaviour in presence of air At moderate to high speeds there is a danger of air becoming mixed into the oil (foaming). Gear oils should be capable of expelling dispersed air and should not be able to form a stable foam.
5
Ageing Lubricating oils oxidise as a result of external influences, mainly high temperatures and exposure to air. This oxidation is catalysed (accelerated) in the presence of some metals such as copper or iron (wear particles). Antioxidant additives will slow down the process. Synthetic lubricating oils are more resistant to oxidation than mineral oils, but are not always as good in respect of lubricant film formation. Synthetic oils are used for worm gears because of lower friction, and for gears which are to be used in a wide range of temperatures, e.g. wind turbine gears.
95
5 Lubrication and maintenance Oil lubrication
Oil lubrication methods When selecting the method of lubrication the first aim should be to ensure a reliable supply of lubricant to the bearings. The oil mist inside a gearbox is not sufficient as bearings in modern gearboxes are heavily loaded and under conditions of lubricant starvation will wear and fatigue prematurely. The most used methods are described in the following.
Oil supply and return ducts for oil bath lubrication
96
Oil bath lubrication This method is commonly used for gears operating at peripheral speeds of up to 15 m/s. The oil level should reach the centre of the lowest rolling element. Greater depths mean losses because of churning and higher friction. This is often accepted for small and medium-sized vertical gears (for oscillation and agitation, and submerged units) where the bearings may be fully submerged. Bearings which are arranged above the surface of the oil must be supplied with oil which is captured by oil pockets or grooves where the oil running down
the casing walls is collected. The feed to the bearings should be designed to lead the oil through the bearings before it flows back to the sump. If the feed is on the seal or cover side, then the drainage should be laterally displaced and should be positioned sufficiently high so that the oil must pass through the bearings but at the same time, any surplus oil can run off without impinging on the seals. This also supports oil circulation and exchange at the bearing position on the cover side, thus improving cooling (➔ fig 1 ). If there is a risk that insufficient oil will be caught by the oil pockets, the oil supply can be improved by providing baffle plates or wipers. Bearings with asymmetrical cross section which dip into oil have a pumping action by virtue of their design, and this can contribute to cooling. Appropriate feed and return ducts should be provided.
5 Lubrication and maintenance Oil lubrication
Circulating oil Circulating oil lubrication should be considered above all when ● ● ● ●
●
●
circulating oil is to be used for the gears, the oil is to be used for heat removal, speeds are high to prevent rapid ageing of the oil, oil bath lubrication will not provide enough oil for the bearings, e.g. on vertical or inclined shafts, very large quantities of oil are required for oil bath lubrication because of the size of the gearbox, or the oil is to be continuously ‘‘freshened” by filtration or centrifuging.
●
●
●
When designing for oil circulation the following points should be remembered.
Oil jet lubrication
To guarantee that the bearings are lubricated right at the start, the oil supply leads must be dimensioned to provide oil even when the gearbox is first started up. There is otherwise a risk that oil will only arrive at positions where the feed cross section is larger (e.g. for the gears). To prevent the oil nozzles from becoming blocked they should have an opening diameter of at least 1,5 mm. Where oil pressures are high a suitable throttle length can be used to limit the oil flow. The throttle should be positioned immediately in front of each bearing, so that larger and thus more reliable oil lead diameters can be used with high oil pressures. Bearings operating at high speeds produce turbulence which rejects the oil. Care must be taken to see that the oil can actually enter the bearing at the feed side. Double row bearings are usually best lubricated via the lubrication holes in the outer ring (or paired single row taper roller bearings through the holes in the intermediate ring). For single row bearings the oil should preferably be supplied at the cover side.
5 Oil jet lubrication At very high speeds (n × dm > 106) oil jet lubrication must be used. As shown in fig 2 , the oil should be injected in the gap between inner ring and cage at high speed (v ≈ 15 m/s). Rejected oil must be able to run off between the bearings so that heat can be removed without excessive losses.
97
5 Lubrication and maintenance Maintenance
Maintenance
Monitoring lubrication
Gearbox bearing maintenance consists basically of monitoring the operating conditions in the gearbox and of monitoring the condition of the bearings themselves. This preventive maintenance should enable early identification of any malfunction so that remedial action can be taken. Such action should either prevent premature ending of the bearing service life or, at least, enable bearing replacement to be planned so that downtime costs can be minimised.
Lubricant supply and lubricant quality should be checked. To check the lubricant supply, simple means are available, e.g. a dip stick for oil bath lubrication. For circulating oil lubrication, on the other hand, complex systems are required to check the oil pressure, flow rate and temperature at each lubrication position, and include an alarm system. When choosing the monitoring arrangements lubricant supply relibility should be weighed against the costs which would occur in the event of a
For for analysis of used oil
Table 2 Machine: ............................................................. Type: ................................................................... No.: ...................................................................... Location: ............................................................
Oil:........................................................................ Oil quantity in system: ....................................... Sample taken, date:............................................ Sample taken by: ................................................
Property or guideline value
Test method (Standard)
Unit
Analysis result for used oil
Data for new oil
Colour, appearance
Visual inspection
–
..................
..................
Smell
–
–
..................
..................
Density at 15 °C
DIN 51 757
kg/m3
..................
..................
Kinematic viscosity at 40 °C at 80 °C at 100 °C
DIN 51 562
mm2/s .................. .................. ..................
.................. .................. ..................
Acid number
DIN 51 588, Part 1
mg KOH/g
..................
..................
Water content
ISO 3733
% wt/wt
..................
..................
Solid contaminants > 3 µm (quantity + type)
e.g. IR analysis DIN 51 451
% wt/wt
..................
..................
Four ball test
DIN 51 350, Part 4
N
..................
..................
Special test(s):
...............................................................................................................................................
Remarks:
...............................................................................................................................................
Characteristic
Deviation from new oil As new slight
moderate
large
very large
Ageing Contamination Recommended action:
............................................ Test date
98
.........................................................................................................................
................................................ Test carried out at
.............................................................. Tested by (Signature)
5 Lubrication and maintenance Maintenance blockage. Oil quality can be monitored by measuring the temperature in the oil bath, in the return duct and in the bearings either continuously or at regular intervals. This allows the operating viscosity to be evaluated. Additionally, regular analysis of the used oil is recommended (according to the scheme shown in Table 2 , for example). The results should always be compared to a similar analysis of the fresh oil.
Monitoring load The power consumption of the drive is sometimes used as a measure of the load, but this is not suitable for monitoring bearing loads, as the peak loads are very much smoothed in the recording. Better information is obtained by measuring torque and measuring stress at the root of the gear teeth. A reliable bearing load measurement can only be obtained by using special force measuring bearings equipped with strain gauges. As this method is very expensive, it is generally only used for new developments or during damage analysis.
Monitoring temperature An indication of incipient bearing damage will be given quite late by the temperature, and at low speeds there may be no indication at all. Therefore, measuring bearing temperature is only appropriate for condition monitoring of bearings at high speeds, and then only as an indication of trends. To be of any use, the temperature should preferably be measured directly on the bearing rings. Temperature measurements of bearings, gearbox and oil are very suitable for monitoring the operating viscosity of the oil. This allows important deductions to be made with respect to the operating conditions.
Monitoring wear Under favourable operating conditions (adequate lubricant film thickness and clean lubricant) bearings will operate practically without wear. Where there is a clear indication that particles of bearing steel are among the wear particles the conclusion is that a bearing has already become damaged. It is
then recommended that the gearbox be inspected to determine the source of the wear and to take remedial action to prevent further damage. Wear particle analysis also enables gear wear and seal efficiency to be monitored.
Monitoring vibrations Bearings in operation generate slight noise even when in perfect condition. This running noise could be listened to by holding a wooden stick to the housing and to the ear. In the past this was one of the most reliable monitoring methods in spite of human failings such as limited frequency spectrum, subjective judgements and inability to relate frequencies heard to causes. With the methods and equipment available today diagnoses can be made and condition monitoring is effective. Suitable proven procedures are: ●
●
comparative measurements on similar gearboxes under the same operating conditions, allowing differences to be observed, and/or trend measurements on one gearbox at given intervals, again allowing differences to be noticed.
5 SKF has developed special measuring techniques as well as the requisite equipment allowing a broad spectrum of vibrations to be monitored and making it possible to analyse the type and magnitude of incipient damage in a bearing. The more important items of equipment and associated software are described in the following. SKF VIB Pen This very handy vibration measuring probe (dimensions 150 × 20 × 18 mm; mass 80 g) can measure vibration velocities of 0,1 to 99,9 mm/s in the fre-quency range 10 to1 000 Hz. It is poss-ible to determine whether the machine vibrations are in the range allowed according to ISO 3945. Bearing dam-age can only be identified when it is in an advanced stage using this method. However, as inadmissible vibrations will considerably shorten bearing life, the VIB Pen is a simple and reliable instrument for maintenance personnel to monitor operating conditions. 99
5 Lubrication and maintenance Maintenance
SKF SEE Pen The SEE Pen measures differences in vibration acceleration with time in the frequency range 250 to 350 Hz. The signals in the high frequency band which are measured, evaluated and recorded using the SEE (Spectral Emitted Energy) method are only produced by ‘‘damaged” bearings. The indications may be for lubricant starvation, contamination or actual bearing damage. Thus the SEE Pen is an ideal complement to the VIB Pen (both have the same dimensions) to give simple and reliable bearing condition monitoring. Here too, trend measurements give the optimum evaluation.
e
SKF Picolog This compact, breast-pocket size apparatus combines the measuring capabilities of the VIB and SEE Pens and can also be used for ‘‘enveloping”. The peaks of the enveloped bearing noise are evaluated. The distance between peaks enables the bearing component which is damaged to be identified. Up to 500 recorded measurements and alarm levels can be stored and downloaded on to a PC. Evaluations can be made using PRISM2 Jr. software. The Picolog is an excellent tool for bearing condition monitoring.
-
-
SKF Microlog This portable equipment (mass 2 kg) can be used for frequency analysis and gives optimum evaluation in the low and high-frequency range (SEE). The Microlog is a powerful data log with a display panel. The PRISM2 software permits a variety of evaluation methods to be used, e.g.waterfall diagrams, storage of critical frequencies, determination of alarm levels etc. The Microlog can be used with handheld sensors or with permanently installed sensors. As it records electrical signals, it can be used to measure not only vibration velocities and accelerations but also distances, pressures and temperatures.
100
SKF Multilog This is a system for plant monitoring with permanently installed sensors and is more powerful than the SKF Microlog. It can be used for the continuous monitoring of rolling bearings and machines. In practice, the SEE method indicates incipient bearing damage earlier and more clearly than other methods. This is particularly true when the damage consists of micro cracks and/or cold welding (lubricant starvation) in the rolling contact. Because of the early warning, the user has time to plan bearing replacement.
Photograph (from left to right) SKF Thermo Pen, SKF Picolog, SKF SEE Pen, SKF VIB Pen (upper), SKF Tachometer (lower), SKF Oil Check, SKF Stethoskop, SKF Microlog
5 Lubrication and maintenance Maintenance
5
101
6 Recommended fits
Recommended fits The rings of rolling bearings deform elastically under load and adapt themselves to their seatings. To be able to fully exploit the load carrying capacity and accuracy of the bearings, the bearing rings must be supported with sufficient firmness and accuracy by the associated components. Where the load rotates with respect to the ring, the ring should have an interference fit on or in its seating (shaft, housing or gear). This prevents a loosening of the bearing fit and the ring will not ‘‘wander” under load. Fretting corrosion will also be prevented. It is not possible to provide a sufficiently tight fit for the ring simply by clamping it axially.
The selection of fits is dealt with in detail in the SKF General Catalogue. The following recommendations complement the catalogue information, giving the usual, proven tolerances for high-performance gearboxes for the most common case, i.e. rotating inner ring load and stationary outer ring load (➔ Table 1 ).
6
The recommendations given in Tables 2 and 3 are for special cases which differ from the above, but which are typical of certain types of gear.
103
6 Recommended fits Recommended fits, form and position tolerances for gearbox bearings Table 1 Bearing type
Shaft tolerances (for solid steel shafts and rotating inner ring load) Shaft diameter (mm) ≤18 (18) (40) (100) (140) (200) (280) to to to to to to 40 100 140 200 280 500
Deep groove ball bearings (for light loads P ≤ 0,06 C)
Housing tolerances (for steel, spheroidal graphite or grey cast iron and stationary outer ring load) >500
Housing bore diameter (mm) Bearing ≤300 (300) >500 arrangement to 500
j5
k5
k5
k6
k6
m6
m6
m6
J6 G6
J6 G7
H7 F7
Locating Non-locating
j6
k6
k6
m6
m6
n6
p6
p6
J6
J6
H7
Cross located
j5
k5
k5
m5
m5
m5
–
–
J6
J6
H7
Locating
double row (series 33 D) k5
k5
m5
m5
–
–
–
–
J6
J6
H7
Locating
k5
k5
m5
m5
n6
–
–
–
approx. 1 mm radial clearance (locate to prevent turning)
Thrust bearing
Cylindrical roller bearings (N, NU, NJ designs)
k5
k5
m5
m5
n6
p6
p6
r6
J6
J6
H7
–
Spherical roller bearings
k5
k5
m5
m5
n6
p6
p6
r6
J6 G6
J6 G7
H7 F7
Locating Non-locating
Taper roller bearings single row (adjusted via the outer ring)
k6
k6
m6
m6
n6
p6
p6
–
J6
J6
H7
Cross located
double row, paired single row
k5
k5
m5
m5
n6
p6
p6
r6
J6
J6
H7
Locating
Thrust ball bearings
h6
h6
h6
h6
h6
g6
g6
g6
G7
G7
F7
Thrust bearing
Spherical roller thrust bearings
j6 (for all diameters)
Angular contact ball bearings single row (adjusted via the outer ring) double row, paired single row (series 32, 33, 70 BG, 72 BG, 73 BG)
Four-point contact ball bearings
approx. 1 mm radial clearance
Form and position tolerances, surface roughness Cylindricity
IT5/2 (for all diameters)
Rectangularity
IT5 (for all diameters)
Permissible surface roughness Rz (µm)
4
4
4
6,3
6,3
6,3
6,3
10
8
When shaft tolerances p6 and r6 are used, use of the oil injection method will ease dismounting
104
10
16
Thrust bearing
6 Recommended fits
Housing tolerances for special cases Table 2 Case
Housing tolerance Housing bore diameter (mm) < 300 (300) > 500 to 500
Deep groove ball bearings and spherical roller bearings as non-locating bearings with rotating inner ring load and stationary outer ring load and a temperature differential > 10 °C from outer ring to housing (e.g. when heating via the shaft, high speed operation, very solid housings, low environmental temperatures)
G7
F7
E8
a) axial displacement of outer ring in housing required, e.g. with thermal expansion of shaft and axially stiff housing
G6
G7
F7
b) axial displacement of outer ring not required, e.g. when thermal expansion of shaft is compensated by elastic deformation of housing without overloading bearings
J6
J6
H7
a) locating bearing
G6
G7
F7
b) non-locating bearing
J6
J6
H7
Locating bearings and cylindrical roller bearings under oscillating outer ring load, e.g. when weight and tooth force act in different directions. Special steps have to be taken when mounting in one-piece (non-split) housings (e.g. heating the housing)
JS6
JS6
JS7
Deep groove ball bearings and spherical roller bearings, cross located, with rotating inner ring load and stationary outer ring load
Cylindrical roller bearings of NUP design with rotating inner ring load and stationary outer ring load
Shaft tolerances ➔ Table 1
6
105
6 Recommended fits
Tolerances for bearings mounted in gear hubs Table 3 Bearing type
Bearing arrangement
Shaft tolerance Shaft diameter (mm) < 120 (120) (250) to to 250 315
Housing tolerance Housing bore diameter (mm) < 120 (120) > 250 to 250
Deep groove ball bearings
Shifting gear (inner and outer rings rotate at same speed)
j5
js6
k6
M61)
M61)
N61)
Planetary gear, intermediate gear (outer ring rotates, inner ring stationary)
h5
h6
h6
M61)
M61)
M61)
Spherical roller bearings Cylindrical roller bearings
Planetary gear, intermediate gear (outer ring rotates, inner ring stationary)
h5
h6
h6
N6
P61)
R61)
Cylindrical roller bearings
Planetary gear, intermediate gear (rotating inner and outer ring load)
see Table 1
N61)
P61)
R61)
Cylindrical roller bearings Planetary gear, intermediate gear without outer ring (planetary gear rotates, inner ring stationary)
h5
h6
h6
G62)
F62)
F62)
Cylindrical roller bearings Planetary gear, intermediate gear without inner ring (outer ring rotates)
f62)
e62)
e62)
N6
P6
R6
Needle roller and cage assemblies
g52)
g52)
–
G62)
G62)
–
Planetary gear, intermediate gear
1)
C3 internal clearance required
2)
For raceways on the planetary pins and in gear hubs, the deviation from circularity should be < 25 % of actual diameter tolerance; the deviation from cylindricity should be < 50 % of actual diameter tolerance; the surface roughness should be Ra ≤ 0,2 µm and Rz ≤ 1 µm; hardness should be 58 to 64 HRC and the case depth when finish machined should be Eht = 0,5 √Dw – 0,5 ≥ 0,3 mm, with Dw = rolling element diameter in mm
Measuring a distance for adjustment of taper roller bearings
106
6 Recommended fits
6
107
7 Mounting and dismounting bearings Adjustment of angular contact bearings . . . . . . . . .109
7 Mounting and dismounting bearings Adjustment of angular contact bearings
Mounting and dismounting bearings Rolling bearings are precision products which must be carefully handled when they are being mounted if they are to perform properly. Equal care must be taken when dismounting if the bearings are going to be re-used.
Basically, there are three things to remember when mounting: ●
●
●
cleanliness, to prevent damage to the raceways by contamination and corrosion; accuracy of all associated components, to avoid additional forces arising from deformations and to avoid imprecise running; the force used to mount and dismount should not be applied via the rolling elements and cage; direct blows should be avoided so that indentations and initial damage to the raceways are prevented.
The SKF General Catalogue contains more detailed instructions regarding mounting and dismounting based on the above requirements. A comprehensive selection of SKF tools, equipment and maintenance products are presented in publication 4100 “SKF Bearing Maintenance Handbook”. SKF also offers various training courses and seminars for personnel involved in mounting and dismounting.
Adjustment of angular contact bearings When mounting angular contact bearings (angular contact ball bearings, taper roller bearings) in gearboxes, particular attention should be paid to the adjustment of the bearings as this determines not only the performance of the bearings themselves but also the guidance of the shafts and consequently the load carrying ability of the gears. The calculation of the adjustment value is described in the section ‘‘Dimensioning rolling bearings” (➔ Section 4). The choice of adjustment method depends on whether the bearings are to be adjusted to axial clearance or to preload.
7
109
7 Mounting and dismounting bearings Adjustment of angular contact bearings
Adjustment of taper roller bearings arranged face-to-face to axial clearance First it is necessary to determine the zero clearance condition as accurately as possible. This is rather difficult for taper roller bearings on horizontal shafts, as the weight of the shaft and gears displaces the outer rings axially because of the taper angle, so that the clearance-free roller end/flange contact, which is decisive for the adjustment, is difficult to achieve. The procedure described in the following is well proven and is very much simpler and more reliable. A device is used to swing the gear shaft into the vertical position for the adjustment (➔ fig 1 ). ●
● ●
● ●
Adjustment of taper roller bearings arranged face-to-face with axial clearance
●
Mount the inner rings on the shaft (take care that the rings abut the shoulders correctly). Push the outer rings over the roller and cage assemblies. Place the shaft with bearings in the gearbox which should be horizontally positioned Mount the top of the casing. Screw down the cover at one side of the casing. Tilt the casing so that the shaft is supported via the bearing by the cover.
●
●
●
The weight of the shaft and gears acts as a measuring load on the lower bearing. The upper bearing is free of clearance as soon as all the rollers rotate about their own axes when the shaft is rotated. A limited range of matched single row taper roller bearings (DF execution) is available. The bearing pairs are supplied with an appropriate intermediate ring, so that adjustment is not required. The user can also match single row taper roller bearings himself; the requisite width of the intermediate ring, taking into consideration the fit, is determined as follows. ● ●
Fig 1 ●
a
x
Rotate the shaft by hand (if necessary by turning the input or output shaft) and press the outer ring of the upper bearing downwards in its seating until all the rollers in the bearing turn about their own axes. The bearing arrangement is now free of clearance. The requisite length of the spigot in the cover is determined from a = x – s where s is the required axial clearance. Mount the finish machined cover with shims (if necessary).
●
Mark the bearing components as shown in fig 2 using an electric pen. Place bearing A on three gauge blocks (➔ fig 3 ). Apply the measuring load: 300 N for bearings with outside diameter up to and including 240 mm 500 N for bearings with outside diameter over 240 mm. Turn outer ring 1A by hand so that the rollers abut the flange of the inner ring 1A.
Fig 2
a=x–s s = requisite axial clearance
1B
1B
1
C
1A
110
Marking of bearing components
1A
7 Mounting and dismounting bearings Adjustment of angular contact bearings Fig 3
FB =
Measuring load
F
Gauge block
Measuring the standout F
● ●
Measure the standout FA at three points using the gauge blocks. Calculate the average value of FA from FA =
● ●
FA1 + FA2 + FA3 (mm) 3
Repeat the above procedure for bearing B. Calculate the average value of FB from
●
FB1 + FB2 + FB3 (mm) 3
Determine the width of the intermediate ring from C = FA + FB + ∆a (mm) where ∆a = maximum axial clearance according to Table 1 or for special bearings, the maximum value of the special clearance. The following tolerances apply to the width C of the intermediate ring: 0/–0,04 mm for bearings with outside diameter D ≤ 140 mm and 0/–0,06 mm for berings with outside diameter D > 140 mm
The axial clearance values given take into account the clearance reduction caused by the interference fit when the shaft tolerances (also given in Table 1 ) are applied. These tolerances are required for rotating inner ring loads which are moderate to heavy. The outer ring with its point load should have a seating to tolerance J6 or H7.
Maximum standard axial clearance of matched taper roller bearings Table 1
Maximum standard axial clearance ∆a before mounting
Bearing bore diameter d over incl.
Shaft tolerance
mm
–
mm
Bearings of series 329 320 X
330
331
302,322
332
303,323
313 (X)
– 30 40
30 40 50
k5 k5 m5
– 0,200 0,220
0,120 0,140 0,160
– – 0,220
– 0,160 0,180
0,140 0,160 0,180
0,150 0,170 0,170
0,170 0,180 0,200
0,100 0,110 0,120
50 65 80
65 80 100
m5 m5 m5
0,250 0,270 0,310
0,180 0,200 0,230
0,240 0,290 0,390
0,200 0,240 0,270
0,200 0,220 0,270
0,190 0,220 0,260
0,220 0,260 0,300
0,140 0,170 0,170
100 120 140
120 140 160
m5 m5 n6
0,330 0,370 0,430
0,280 0,300 0,330
0,400 0,400 0,400
0,300 – –
0,280 0,300 0,330
0,300 – –
0,340 0,390 0,430
0,190 0,220 0,240
160 180 190
180 190 200
n6 n6 n6
0,430 0,430 0,450
0,370 0,400 0,400
– – –
– – –
0,370 0,400 0,400
– – –
0,450 0,500 0,500
– – –
200 225 250
225 250 280
p6 p6 p6
0,500 0,500 0,600
0,450 0,500 0,550
– – –
– – –
0,450 0,500 0,550
– – –
0,550 0,600 –
– – –
280 300 340
300 340 360
p6 p6 p6
0,700 0,700 0,750
0,600 0,650 0,750
– – –
– – –
0,600 0,650 –
– – –
– – –
– – –
7
111
7 Mounting and dismounting bearings Adjustment of angular contact bearings
Principle of force/path measurement
There will be virtually no reduction in clearance from any deformation of the outer ring. If looser fits are chosen, then the axial clearance value will be slightly larger when the bearing is mounted. If a tighter fit is used then it is advisable to check that the bearing will not be axially preloaded.
basis or a collective method based on tolerances has not found acceptance in gearbox applications as there is excessive scatter of the preload force when these methods are used. However, the friction torque can be used indirectly for adjustment as will be seen from the following.
Adjustment of taper roller bearings arranged face-to-face to preload
●
When adjusting bearings which are to have a preload it is necessary to achieve a certain preload force. If the preload distance (path) method is to be used, it is first necessary to measure the force and displacement in the mounted condition. This is the only way to be able to take housing resilience into account when determining the appropriate distance. Fig 4 shows the principle of a force/distance measurement. Diagram 1 shows the result of such measurements. The characteristic curve has been extrapolated (broken line) for small loads because the measurements are not sufficiently accurate under such light loads. Using the characteristic curve the desired preload can be set by fitting a shim or spacer ring. The adjustment of taper roller bearings using the friction torque as a
●
The friction torque of the two bearings which are to be adjusted against each other is measured in a rig for a given preload force and at a defined measuring speed and recorded. After mounting the bearings in the gearbox, the preload force is applied by inserting shims until the recorded friction torque is obtained. The speed and lubrication conditions when the torque is measured must be the same as when the original recorded measurements were made.
This method is advantageous particularly when large numbers of bearings are to be adjusted if it is easier to measure torque than force at the assembly position.
Adjustment of taper roller bearings arranged back-to-back To ensure sufficient accuracy, the bearing rings should always be mount-
Fig 4
Recorded force/ path diagram for shaft/bearing/ housing system Diagram 1
Axial force Axial load
S
Axial preload path s
112
7 Mounting and dismounting bearings Adjustment of angular contact bearings Fig 5
●
●
●
Bearing V X B
●
Spacer ring (shim)
X =
● ●
Bearing H
●
Adjustment of taper roller bearings arranged back-to-back on pinion shaft
●
ed against a fixed abutment face which is at right angles to the shaft axis. For taper roller bearings arranged back-toback, therefore, a shim (spacer ring) is inserted between one of the two bearings and a shaft shoulder. The following procedure allows the shim to be fitted without having to mount and dismount bearing V; this would be rather difficult because of the requisite interference fit of the bearing on the shaft. ● ●
Measurement of standout Z
Rest the shaft with bearing H and casing in a vertical position on the face of the pinion (➔ fig 5 ). Turn the casing by hand so that the rollers of bearing H abut the inner ring flange. Measure the standout X at three points (dial gauge). Calculate average standout X.
●
Determine reduction in axial clearance ∆p taking into account the shaft fit from
= ∆r 0,4
1,5 (mm) e
7
where ∆p = reduction in axial clearance, mm ∆r = radial interference, mm e = bearing-related calculation factor, see bearing tables in SKF General Catalogue
Fig 6
Z
Z1 + Z2 + Z3 (mm) 3
∆p = ∆r 0,4 cot α
Mount outer ring of bearing H in the casing. Mount the inner ring with roller and cage assembly of bearing H on the pinion shaft and introduce the shaft into the casing.
Measuring load
Lay bearing V on measuring plate (➔ fig 6 ). Apply measuring load: 300 N for bearings with outside diameter D up to and including 240 mm 500 N for bearings with outside diameter D > 240 mm. Rotate the outer ring of bearing V by hand so that the rollers abut the inner ring flange. Measure the standout Z at three points (dial gauge). Calculate average standout Z.
Z =
●
X1 + X2 + X3 (mm) 3
●
Determine width B of shim for a given adjustment of the pinion bearing arrangement using B = X + Z + ∆p ± ∆a (mm)
Bearing V Measuring plate
where + ∆a is the desired axial clearance and − ∆a is the desired preload.
113
8 Application examples
Application examples In this section various interesting and wellproven gearbox designs from important manufacturers are presented. In order to give a clear presentation, the most important technical data are presented in table form. This has made it possible to avoid long descriptions. The gearbox drawings will certainly inspire designers.
Numerous discussions with manufacturers, which preceded the selection of the gearboxes shown here, confirmed that there is a trend towards specialist gearboxes in order to better satisfy, both technically and economically, the demands of individual applications. However, as often as possible the designs use components from standard series – an advantage not least from a logistics point of view. In the following examples the bearings used are listed starting with those for the input shaft and following the order in which they occur in the power train. The examples show that bearings of standard series are preferred and only a few special bearings are used. The examples also confirm an earlier observation in the section dealing with bearing arrangements for gear shafts, namely that virtually all “catalogue” bearing types are used in gearboxes. SKF, with its comprehensive
range of technically advanced standard bearings, assists the designer in producing technically and economically competitive gearboxes.
8
115
8 Application examples
Bevel/spur
116
Application
Universal (e.g. conveyor drive)
Manufacturer
A. Friedr. Flender AG, Bocholt, Germany
Input drive
Depending on application
Drive rating
P = 53 kW
Drive speed
n = 1 500 r/min
Total ratio
i = 1 : 63
Power take-off
Depending on application: solid, flanged or hollow shaft
Output torque
M2 = 23 800 Nm
Dimensions
960 × 580 × 300 mm
Mass
G = 635 kg
Gears
Case hardened
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 460
Operating temperature
Tmax = 90 °C
Sealing
Radial shaft seals, or largely wear-free labyrinth seals
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
2 × 32309 BJ2 2 × 32310 J2 2 × 32314 J2 2 × 30224 J2
Minimum bearing life
Depending on application
8 Application examples
8
117
8 Application examples
Bevel/spur, two-stage Application
General industrial
Manufacturer
Rossi Motoriduttori, Modena, Italy
Input drive
Electric motor
Drive rating
P = 134 kW
Drive speed
n = 1 400 r/min
Total reduction
i = 10,3 : 1
Output torque
M2 = 9 470 Nm
Dimensions
817 × 450 × 334 mm
Mass
G = 282 kg
Gears
Hardened
Lubrication type
Oil bath
Lubricant
EP oil with viscosity to ISO VG 220
Operating temperature
T = 65 to 80 °C
Sealing
Radial shaft seals
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
2 × 32310 B 2 × 32312 2 × 32026
Remarks
118
Universal attachment possible; stiff, one-piece casing; standard hollow shaft at output side; choice of drive shaft arrangement (position)
8 Application examples
8
119
8 Application examples
Worm, single stage
120
Application
Tilting arrangement
Manufacturer
A. Friedr. Flender, Bocholt, Germany
Input drive
Electric displaceable anchor motor, V-belts
Drive rating
P = 2,3 kW
Drive speed
n = 636 r/min
Total ratio
i = 40 : 1
Output drive
Hollow shaft, cartridge type
Output torque
M2 max = 2 350 Nm
Dimensions
364 × 394 × 221 mm
Mass
G = 65 kg
Gears
Concave flank teeth, worm case hardened and ground, worm wheel of bronze
Lubrication type
Oil bath; worm wheel bearing greased
Lubricants
Polyglycol oil with viscosity to ISO VG 680; worm wheel: rolling bearing grease
Operating temperature
Tmax = 100 °C (oil bath)
Sealing
Radial shaft seals at input and output sides
Bearings Worm shaft Wheel
2 × 31308 J2 2 × 6017 or 2 × 32017 X
Remarks
Cooling by fan wheel on worm shaft
8 Application examples
8
121
8 Application examples
Eccentric drive with cycloid cams
122
Application
General industrial
Manufacturer
SUMITOMO CYCLO EUROPE, Markt Indersdorf, Germany
Input drive
Via coupling
Drive rating
P = 1 kW
Drive speed
n = 1 500 r/min
Total reduction
i = 357 : 1
Output drive
Output shaft with key
Output torque
M2 = 1 810 Nm
Dimensions
300 ∅ × 439 mm
Mass
G = 69 kg
Lubrication type
Grease
Operating temperature
T = 60 °C
Sealing
Radial shaft seals on input and output shafts
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
1 × 6302-Z; 1 × 6302 1 × 6207; 1 × 6307 1 × 6215-Z; 1 × 6213-ZNR
8 Application examples
8
123
8 Application examples
Bevel gear, single stage Application
Kaplan turbine/generator
Input drive
Kaplan turbine
Rating
P = 2 005 kW
Speed
n = 232 r/min
Torque
M1 = 82 500 Nm (turbine)
Total ratio
i = 1 : 3,23
Power take-off
Lamellar coupling (rotationally stiff, can bend elastically, with slipping elements), generator
Dimensions
1 730 × 1 600 × 3 056 mm
Mass
G = 9 000 kg
Gears
Cyclopalloid/HPG, case hardened
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 220
Operating temperature
T = 65 °C
Seals
Radial shaft seals on input and output shafts (on the input shaft with chamber for oil seepage)
Bearings No. 1 shaft
124
No. 2 shaft
1 × NU 1064 MA; 1 × 23060 CC/W33; 1 × 29360 E; 1 × 29248 1 × 22348 CC/C3W33; 1 × 32040 X; 1 × 29340 E
Minimum bearing life
L10h = 100 000 operating hours
Remarks
Turbine shaft = gearbox input shaft. Turbine blade adjustment via input shaft. Each bearing has temperature monitoring. Connections for shock pulse measurements. Very smooth running for environmental reasons.
8 Application examples
8
125
8 Application examples
Spur gear, two-stage
126
Application
Wind power plant
Manufacturer
Renk AG, Rheine, Germany
Input drive
Wind turbine, claw coupling
Rating
P = 168 kW
Speed
n = 63 r/min
Input torque
M1 = 25 480 Nm
Total ratio
i = 1 : 28,97
Power take-off
Elastic coupling, generator
Dimensions
1 215 × 900 × 1 000 mm
Mass
G = 1 350 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Oil bath
Lubricant
Polyglycol oil with viscosity to ISO VG 220
Operating temperature
T ≈ 80 °C
Seals
Felt ring + 2 × V-rings (input) Labyrinth + 2 × V-rings (output)
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
1 × 22315 E; 1 × NU 313 ECJ 2 × 22319 E 1 × NJ 228 ECJ/C3; 1 × 24034 CC/W33
Minimum bearing life
L10h = 100 000 operating hours
Remarks
Monitored by temperature recorder
8 Application examples
8
127
8 Application examples
Planetary spur gear, two-stage
128
Application
Wind power plant
Manufacturer
David Brown, Huddersfield, Great Britain
Input drive
Wind turbine, socket connection with clamping rings
Rating
P = 1 150 kW
Speed
n = 24,5 r/min
Input torque
M1 = 448 000 Nm
Total ratio
i = 1 : 41,63
Power take-off
Elastic coupling, generator
Dimensions
1 730 × 2 748 × 2 100 mm
Mass
G = 9 500 kg
Gears
Planetary wheels straight cut Spur wheels helical cut, case hardened and ground
Lubrication type
Circulating oil
Lubricant
Synthetic oil with viscosity to ISO VG 320 EP
Seals
Flingers with labyrinth seals
Bearings Planetary carrier 3 planetary wheels Spur gear shaft Spur gear pinion Auxiliary drive shaft Hollow shaft
1 × NCF 18/560 V; 1 × NCF 2972 V 3 × 22338 CC/W33 2 × NCF 2952 V 2 × 32328 2 × 32320 J2 1 × NU 213 ECJ
Minimum bearing life
L10h = 50 000 operating hours
8 Application examples
8
129
8 Application examples
Planetary/spur, three-stage Application
Wind power station
Manufacturer
Renk AG, Augsburg, Germany
Input drive
Wind turbine, toothed coupling
Drive rating
P = 1 327 kW
Drive speed
n = 23 r/min
Total ratio
i = 57,7 : 1
Output torque
M2 = 570 000 Nm
Dimensions
1 700 × 2 800 × 3 180 mm
Mass
G = 11 600 kg
Gears
Planetary and spur gears case hardened; spur gears have double helix
Lubrication type
Circulating oil
Lubricant
Synthetic oil with viscosity to ISO VG 220
Operating temperature
T = 46 °C (oil inlet temperature)
Sealing
Special shaft seal at input side, zinc seal at output side
Bearings Planetary carrier 6 planetary gears Planetary carrier Spur gear shaft
130
Pinion (auxiliary drive) Pinion (power take- off)
1 × 608/800 MA; 1 × NJ 18/760 MA6/343016 6 × 24136 CC/C3W33/VE096 1 × 61888 N1MA 2 × 313451 B (cylindrical roller bearing 320 × 440 × 72 mm) 1 × 6222 N1/C3; 1 × NU 2222 ECJ/C3 1 × 32228 J2/DF; 1 × NU 2228 ECMA/C3
Minimum bearing life
L10h = 100 000 operating hours
Remarks
Elastic gearbox suspension; permissible noise level 85 dBA
8 Application examples
8
131
8 Application examples
Planetary/spur, superimposed
132
Application
Ship’s generator drive
Manufacturer
Renk AG, Augsburg, Germany
Input drive
Combustion engine, claw coupling
Drive rating
P = 900 kW
Drive speed
n = 297 to 425 r/min
Total ratio
i = 1 : 4,2 to 1 : 6,1 (variable)
Power take-off
Claw coupling
Output torque
M2 = 4 775 Nm
Dimensions
1 800 × 1 300 × 2 100 mm
Mass
G = 6 300 kg
Gears
Spur, sun and planetary gears case hardened and ground, internally geared ring heat treated
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 100 or SAE 30
Operating temperature
T = 70 °C (oil sump)
Sealing
Zinc rings at input and output sides
Bearings Coupling Planetary carrier Sun wheel Geared ring 3 planetary gears 2 spur gear intermediate shafts 2 spur pinion shafts
4 × NJ 2219 ECMA/C3 4 × NJ 2218 ECMA/C3
Minimum bearing life
L10h = 30 000 operating hours
Remarks
A constant output speed and thus a constant frequency for the generator are aimed at although the input speed varies. The power is split after the lamellar coupling (one part in the planetary gear set, one part in the hydraulic pump and motor); power rejoined via internally geared ring.
2 × 6032 M/C3 1 × 6234 M/C3; 1 × 61938 MA/C3 1 × 6224 MA/C3 2 × 6044 M/C3 6 × NJ 2313 ECMA/C3
8 Application examples
8
133
8 Application examples
Spur gear, two-stage
134
Application
Geared motor for industry
Manufacturer
SEW-Eurodrive, Bruchsal, Germany
Input drive
Electric motor (asynchronous, DC), pulley, turbo coupling
Rating
P = 0,75 to 37 kW
Speed
n = 3 000 to 750 r/min
Total ratio
i = 20,78 : 1 to 201,78 : 1
Power take-off
Coupling, sprocket wheel, gear
Output torque
M2 max = 4 000 Nm
Dimensions
782 × 437 × 400 mm
Mass
G = 173 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 46 to ISO VG 200
Operating temperature
Tmax = 90 °C
Seals
Radial shaft seals
Bearings No. 1 shaft No. 2 shaft
1 × 30307 J2; 1 × NUP 2308 ECJ; 1× 30308 J2 1 × NUP 213 ECJ; 1 × 6315-Z
Minimum bearing life
L10h = 5 000 operating hours (for M2 max)
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Spur gear, three-stage
136
Application
Geared motor for industry
Manufacturer
Flender-Himmelwerk, Tübingen, Germany
Input drive
Electric motor (asynchronous), may be DC; elastic coupling, slip clutch or “Anlaufkupplung”
Rating
P = 3 to 90 kW
Speed
n = 750 to 1 500 r/min
Total ratio
i = 1:18,27 to 1:113,61
Power take-off
e.g. elastic coupling
Output torque
M2 = 9 000 Nm
Dimensions
612 × 702 × 530 mm
Mass
G = approx. 450 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 220
Operating temperature
Tmax = 90 °C
Seals
Radial shaft seals with dust lip
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
1 × NU 212 ECJ; 1 × 6212; 1 × NU 312 ECJ 1 × 22208 E; 1 × 22309 CC 1 × 22312 E; 1 × 21312 E 1 × NJ 2217 ECJ; 1 × 22220 E
Minimum bearing life
L10h = 5 000 operating hours
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Bevel/spur gear, three-stage
138
Application
Geared motor for industry
Manufacturer
SEW-Eurodrive, Bruchsal, Germany
Input drive
Electric motor (asynchronous, DC), coupling, sprocket wheel belt pulley
Rating
P = 1,5 to 45 kW
Speed
n = 3 000 to 750 r/min
Total ratio
i = 11,71 : 1 to 130,16 : 1
Power take-off
Hollow shaft, coupling, sprocket wheel, gear
Output torque
M2 = 6 000 Nm
Dimensions
781 × 557 × 517 mm
Mass
G = 285 kg
Gears
Spur: helical cut, case hardened and ground Bevel: curved teeth and case hardened
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 46 to ISO VG 220
Operating temperature
Tmax = 90 °C
Seals
Radial shaft seals on input and output shafts
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
Electric motor bearings 1 × 30310 J2; 1 × 30311 J2 2 × 32310 J2 2 × 6224
Minimum bearing life
L10h = 5 000 operating hours (for M2 max)
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8 Application examples
Bevel/spur, two-stage Application
Main and auxiliary drive of the travelling gear of a portal crane for container handling
Manufacturer
Bonfiglioli Riduttori, Bologna, Italy
Input drive
Electic motor
Drive rating
P = 25 kW (main drive) P = 4 kW (auxiliary drive)
Drive speed
n = 1 750 r/min (main drive) n = 1 450 r/min (auxiliary drive)
Total reduction
i = 19,5 : 1 (main drive) i = 39,6 : 1 (auxiliary drive)
Output torque
M2 = 12 000 Nm (main drive) M2 = 2 400 Nm (auxiliary drive)
Dimensions
835 × 1 115 × 560 mm
Mass
G = 380 kg (main drive) G = 100 kg (auxiliary drive)
Gears
20 Mn Cr 5, hardened
Lubrication type
Circulating oil (main drive) Oil bath (auxiliary drive)
Lubricant
Oil with viscosity to ISO VG 220
Sealing
Radial shaft seals
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
Remarks
140
2 × 31312 (main drive) 2 × 32014 X (auxiliary drive) 1 × 30313; 1 × 30314 (main drive) 1 × 32208; 1 × 30307 (auxiliary drive) 2 × NNC 4832 V (main drive) 2 × NJ 215 EC (auxiliary drive) Forced circulating oil lubrication is needed for the bearings on the vertical shaft. The auxiliary drive is coupled in by hand as required. Each of the 16 runner wheels is driven by a geared motor. The torques are taken up by the frame via torque supports.
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Spur/planetary gear, three-stage
142
Application
Swivelling drive for floating crane
Manufacturer
Lohmann & Stolterfoht, Witten, Germany
Drive
Electric motor (DC), elastic coupling
Rating
P = 335 kW
Speed
n = 500 r/min
Total ratio
i = 1 : 73,8
Power take-off
Pinion
Output torque
M2 = 472 689 Nm
Dimensions
1 500 ∅ × 4 132 mm
Mass
G = 10 152 kg
Gears
All gears straight-cut; spur, sun and planetary wheels case hardened and ground; hollow wheels heat treated
Lubrication
Oil bath
Operating temperature
Tmax = 70 °C
Seals
Radial shaft seals on input and output shafts; gaptype seal with grease fill for bearing at pinion side of output shaft
Bearings No. 1 shaft No. 2 shaft 3 planetary wheels Planetary carrier 3 planetary wheels Sun wheel Pinion
1 × NJ 226 ECJ; 1 × 22218 CC/W33 2 × NJ 228 ECJ 3 × 22320 CC/W33 1 × NCF 1884 V; 1 × NCF 1892 V 6 × NJ 2320 ECMA 1 × 61836 MA 1 × 24076 CC/W33
Minimum bearing life
L10h = 15 000 operating hours
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Planetary, three-stage, vertical
144
Application
Drive for slewing mechanism, e.g. for floating crane or bucket excavator
Manufacturer
Dorstener Maschinenfabrik AG, Dorsten, Germany
Input drive
Electric motor, elastic coupling
Drive rating
P = 50 kW
Drive speed
n = 1 400 r/min
Total ratio
i = 1 : 103
Power take-off
Pinion for slewing ring
Output torque
M2 = 35 274 Nm
Dimensions
640 ∅ × 1 750 mm
Mass
G = 1 250 kg
Gears
Sun and planetary gears case hardened; internally geared rings hardened; straight cut teeth
Lubrication type
Oil bath; bearings on input and output shafts grease lubricated
Lubricant
Oil with viscosity to ISO VG 220; rolling bearing grease
Operating temperature
T = 78 °C (oil bath)
Sealing
Radial shaft seals on input and output shafts
Bearings No. 1 shaft (input) 3 planetary gears 3 planetary gears 3 planetary gears No. 2 shaft (output)
2 × 6215/C3 1st stage: 3 × 22207 CC 2nd stage: 3 × 22210 E 3rd stage: 3 × NJ 2213 ECJ 1 × NU 1034 MA; 1 × 23038 CC/W33
Minimum bearing life
L10h = 40 000 operating hours
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Bevel/spur, two-stage
146
Application
Conveyor belt drive for tunnelling
Manufacturer
Voith, St. Pölten, Austria
Input drive
Electric motor (asynchronous), turbo coupling
Drive rating
P = 55 kW
Drive speed
n = 1 440 r/min
Total ratio
i = 1 : 18,57
Power take-off
Hollow shaft with shrunk-on washer connection
Output torque
M2 = 6 775 Nm
Dimensions
530 × 475 × 990 mm
Mass
G = 490 kg
Gears
Bevel gears Klingelnberg-Cyclo-Palloid; Spur gears helical cut, case hardened, ground
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 220
Sealing
Radial shaft seals at input and output sides
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
1 × 31316 J1/DF; 1 × NJ 2316 ECM/C3 2 × NJ 2314 ECMA/C3; 1 × QJ 312 N2MA/C3 2 × NCF 2932 V
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Bevel, two-stage
148
Application
Conveyor belt drive
Manufacturer
Brook Hansen, Edegem, Belgium
Input drive
Electric motor
Drive rating
P = 132 kW
Drive speed
n = 1 420 r/min
Total ratio
i = 16 : 1
Output drive
On hollow shaft, shrunk-on washer connection
Output torque
M2 = 16 000 Nm
Dimensions
645 × 450 × 1 130 mm
Mass
G = 500 kg
Gears
Case hardened and ground
Lubrication type
Oil bath
Lubricant
Mineral oil with EP additives
Sealing
Double-action labyrinth seal at input side Radial shaft seals with dust lip at output side
Bearings Shaft No. 1 Shaft No. 2 Shaft No. 3
2 × 31314; 1 × 22315 E 2 × 22315 E; 1 × 81210 2 × NCF 2934 V
Minimum bearing life
L10h = 25 000 hours
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Planetary, two-stage
150
Application
Chain scraper conveyor for underground mine
Manufacturer
Gebr. Eickhoff, Bochum, Germany
Input drive
Electric motor via fluid coupling or elastic coupling with motor where poles can be switched
Drive rating
P = 450 kW
Drive speed
n = 1 450 r/min
Total ratio
i = 1 : 28
Output drive
Toothed coupling or flanged gearbox
Output torque
M2 = 100 000 Nm (briefly 250 000 Nm)
Dimensions
816 × 1 250 × 1 155 mm
Mass
G = 1 870 kg
Gears
Sun and planetary wheels case hardened, hollow wheels of nitrided hardenable steel
Lubrication type
Oil bath
Lubricant
Mineral oil (anti-wear + EP) with viscosity to ISO VG 320
Operating temperature
Tmax = 95 °C (oil bath)
Sealing
Radial shaft seal + dust seal at input side, mechanical seal at output side
Bearings No. 1 shaft 3 planetary gears 3 planetary gears No. 2 shaft
2 × 6222/C3 6 × NJ 2311 ECMA 3 × RN 315 ECP/QR 2 × NJ 2868 ECMA/VE900
Minimum bearing life
L10h = 50 000 operating hours
Remarks
Robust casing ideal for mining applications; power take-off shaft must briefly take up very large forces from the conveyors
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Bevel/spur/planetary, three-stage
152
Application
Chain scraper conveyor for underground mine
Manufacturer
Gebr. Eickhoff, Bochum, Germany
Input drive
Electric motor via fluid coupling, or elastic coupling for switching pole motor
Drive rating
P = 450 kW
Drive speed
n = 1 450 r/min
Total ratio
i = 1 : 28
Power take-off
Toothed coupling, or flanged gearbox
Output torque
M2 = 100 000 Nm (briefly 250 000 Nm)
Dimensions
816 × 1 655 × 990 mm
Mass
G = 2 980 kg
Gears
Bevel, spur, sun and planetary gears case hardened; ring with internal gear hardened and nitrided
Lubrication type
Oil bath
Lubricant
Mineral oil (EP) with viscosity to ISO VG 320
Operating temperature
Tmax = 95 °C (oil bath)
Sealing
Radial shaft seal + dust seal on input shaft; mechanical seal on output shaft
Bearings No. 1 shaft No. 2 shaft No. 3 shaft 3 planetary gears No. 4 shaft
1 × 31322 XJ2/DF; 1 × 22324 CC/W33 1 × 22320 E; 1 × 22326 CC/W33 2 × 32034 X 3 × RN 315 ECP/QR 2 × NJ 2868 ECMA/VE900
Minimum bearing life
L10h = 50 000 operating hours
Remarks
Robust casing for mining conditions; output shaft with bearing arrangement must be able to accommodate very high forces from the conveyor for brief periods
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Bevel/spur/planetary, three-stage
154
Application
Ski lifts (seat and gondola types)
Manufacturer
L. Kissling, Zurich-Seebach, Switzerland
Input drive
Electric motor (asynchronous or DC), elastic coupling
Drive rating
P = 300 kW
Drive speed
n = 1 500 or 1 800 r/min
Total ratio
i = 93,75 : 1 (or from 48,31 : 1 to 132,92 : 1)
Output drive
Flanged-on rope sheave
Output torque
M2 = 170 000 Nm; rope tension: s = 450 000 N
Dimensions
530 × 730 × 1 333 mm + 905 × 1 250 mm ∅
Mass
G = 3 800 kg
Gears
Bevel, spur and planetary wheels case hardened, hollow planetary wheel hardened
Lubrication type
Oil bath and circulating oil
Lubricant
EP oil with viscosity to ISO VG 220 or ISO VG 150
Operating temperature
Tmax = 80 °C (oil bath)
Sealing
Radial shaft seal + Z sealing washer at input side and pairs of radial shaft seals + dust cover at output side
Bearings No. 1 shaft No. 2 shaft No. 3 shaft 1 sun pinion 3 planetary gears Rope sheave
1 × 31315 J2/DF, 1 × 22317 E 2 × 23220 CC/W33 2 × 23122 CC/W33 1 × 89310 6 × NCF 2222 V 1 × 24048 CC/W33; 1 × 23048 CC/W33
Minimum bearing life
L10h = 20 000 operating hours
Remarks
Under-floor drive can be decoupled
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Planetary/bevel plate with adjoining reduction gear
156
Application
Drive for pumps in extraction plant
Manufacturer
Motovario, Modena, Italy
Input drive
Electric motor
Drive rating
P = 9,2 kW
Drive speed
n = 1 750 r/min
Total reduction
i = 3,5 : 1
Output torque
M2 = 500 Nm
Mass
G = 145 kg
Gears
100 Cr 6, hardened and heat treated
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 320
Sealing
Radial shaft seals
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
1 × 6213; 1 × 6309 1 × 6213; 1 × NJ 210 EC 2 × 32206 1 × 30210; 1 × 30213
Minimum bearing life
L10h = 25 000 operating hours
Remarks
Gearbox is designed for maximum reliability under difficult operating conditions
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Spur, split power, three-stage
158
Application
Central drive for tube mill (cement)
Manufacturer
A. Friedr. Flender, Bocholt, Germany
Input drive
Electric motor (asynchronous), elastic coupling
Drive rating
P = 3 600 kW
Drive speed
n = 880 r/min
Total ratio
i = 1 : 62,8
Output drive
Toothed coupling
Output torque
M2 = 2 350 kNm; at start-up 5 885 kNm
Dimensions
3 380 × 4 000 × 3 780 mm
Mass
G = 79 250 kg
Gears
1st stage: helical 2nd stage: straight cut 3rd stage: double helix All gears case hardened
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 460
Operating temperature
Tmax = 65 °C (oil sump)
Sealing
Lamellar rings at input and output sides
Bearings Shaft No. 1 Shaft No. 1 (auxiliary drive) Shaft No. 2 Shaft No. 3 (3×) Shaft No. 4
2 × NU 2248 MA/C3; 1 × QJ 248 N2MA/C3 2 × 6248 M/C3 2 × NCF 2976 V 3 × NU 3068 MA/VE900; 6 × NU 3084 MA 1 × 60/560 MA/C3; 1 × N 28/710 ECMB
Minimum bearing life
L10h = 80 000 operating hours
Remarks
The equal power split is achieved by a radially free pinion and gears adjusted by oil injection method
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Bevel/spur gear, three-stage Application
Drive of a coal grinding mill
Manufacturer
David Brown, Huddersfield, Great Britain
Input drive
Electric motor, elastic coupling
Rating
P = 420 kW
Speed
n = 990 r/min
Total ratio
i = 1 : 24,5
Power take-off
Grinding plate of mill
Output torque
M2 = 99 340 Nm
Dimensions
1 600 × 2 920 × 2 000 mm
Mass
G = 25 600 kg
Gears
Bevel: spiral cut in hard state Spur: helical cut, ground, all case hardened
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 320
Operating temperature
Tmax = 80 °C
Seals
Double radial shaft seals with additional flingers on input shaft; labyrinth with additional special rubbing seal on output shaft
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
160
1 × 32324 J2; 1 × 32220 J2 1 × 32036 X/DF; 1 × 23036 CC/W33 1 × 32036 X/DF; 1 × 23036 CC/W33 1 × 230/560 CA/W33; 1 × 294/630 EM; 1 × 230/500 CA/W33
Minimum bearing life
L10h = 36 000 operating hours
Remarks
Forces from the grinding chamber are taken up by the bearings on the output shaft
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Bevel/planetary, two-stage Application
Raw meal mill (cement industry)
Manufacturer
Renk AG, Augsburg, Germany
Input drive
Electric motor (squirrel cage), elastic coupling
Drive rating
P = 2 600 kW
Drive speed
n = 1 180 r/min
Total ratio
i = 1 : 41,9
Output drive
Grinding receptacle
Output torque
M2 = 882 838 Nm
Dimensions
2 670 × 3 050 × 3 050 mm
Mass
G = 68 600 kg
Gears
Bevel, sun and planetary gears case hardened and ground, internally geared ring pounded and hardened
Lubrication type
Circulating oil
Lubricant
Oil with ciscosity to ISO VG 220
Operating temperature
T = 62 °C
Sealing
Labyrinths at input and output sides
Bearings Bevel pinion shaft
162
Bevel wheel 3 planetary gears
1 × BT2B 332931 (240 × 480 × 220 mm) 1 × NU 2252 MA/C3 1 × 32064 X/DF; 1 × NU 1060 MA/C3 3 × 23164 CC/C3W33
Minimum bearing life
L10h = 75 000 operating hours
Remarks
Temperature, pressure and oil flow rate monitored; shock pulse measurements
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Planetary, three-stage Application
Locomotion drive for construction machines
Manufacturer
Orenstein & Koppel, Hattingen, Germany
Input drive
Flanged-on hydraulic motor, plug-type connection
Drive speed
n = 4 000 r/min (adjustable)
Total reduction
i = 80 : 1 to 200 : 1
Output
Sprocket wheel or flanged-on rim
Output torque
M2 = 44 000 Nm
Dimensions
435 × 435 × 383 mm
Mass
G = 210 kg
Gears
Sun and planetary wheels case hardened and ground; hollow wheels heat treated and nitrided
Lubrication type
Oil bath
Lubricant
Gear oil SAE 90 or engine oil SAE 15W40
Sealing
O-ring (static) at input side, mechanical seal + V-ring at output side
Bearings 1st stage
Sprocket wheel Brake
3 × BC2B 322418 B (22 × 39 × 22 mm; full complement) 3 × BC2B 322421/HB3 (35 × 52 × 26 mm; full complement) 5 × BC2B 326111/HB3 (50 × 70 × 32 mm; full complement) 2 × T4DB 170 1 × 6009
Minimum bearing life
L10h = 500 operating hours at maximum torque
2nd stage 3rd stage
164
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165
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Spur/planetary, three-stage
166
Application
Drive for articulation of excavator
Manufacturer
Dorstener Maschinenfabrik AG, Dorsten, Germany
Input drive
Electric motor, elastic coupling
Drive rating
P = 45 kW
Drive speed
n = 985 r/min
Total reduction
i = 159,4 : 1
Output drive
Hollow shaft with shrunk-on washer, cartridge-type gearbox
Output torque
M2 = 70 000 Nm
Dimensions
800 ∅ × 1 130 mm
Mass
G = 1 800 kg
Gears
Spur and planetary gears case hardened Internally geared rings heat treated
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 320
Operating temperature
T ≈ 90 °C (oil bath)
Sealing
Radial shaft seals on input and output shafts
Bearings No. 1 shaft No. 2 shaft 3 planetary wheels 3 planetary wheels No. 3 shaft
2 × 6215 2 × 6024 3 × 22311 E 3 × 22315 E 1 × NCF 1852 V; 1 × NCF 1856 V
Minimum bearing life
L10h = 50 000 operating hours
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Spur, four-stage, vertical
168
Application
Drive for mixer for chemical industry
Manufacturer
Jahnel Kestermann, Bochum, Germany
Input drive
Electric motor (asynchronous or DC)
Drive rating
P = 75 (or 55) kW
Drive speed
n = 1 500 (or 1 000) r/min
Total ratio
i = 1 : 206,6
Power take-off
Flanged coupling
Output torque
M2 max = 112 500 Nm
Dimensions
1 320 × 1 000 × 1 720 mm
Mass
G = 4 700 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Oil bath and circulating oil
Lubricant
Oil with viscosity to ISO VG 220
Operating temperature
T = 70 °C
Sealing
Radial shaft seal at input side Oil cover and V-ring on output shaft
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft No. 5 shaft Mixer shaft
2 × 33215 2 × 32314 1 × 30218; 1 × 32318 2 × 32322 2 × NCF 1872 V 2 × 32038 X; 1 × 23060 CCK/W33 + OH 3060 H
Minimum bearing life
L10h = 30 000 operating hours
Remarks
Permissible noise level 75 dBA
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Spur, four-stage, vertical
170
Application
Surface ventilator
Manufacturer
Brook Hansen, Edegem, Belgium
Input drive
Electric motor
Drive rating
P = 75 kW
Drive speed
n = 1 475 r/min
Total ratio
i = 1 : 40
Output torque
M2 = 35 000 Nm
Dimensions
760 × 925 × 1 075 mm
Mass
G = 860 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Circulating oil; bearing at output side of output shaft grease lubricated
Lubricant
Mineral oil with EP additives
Sealing
Double action labyrinth at input side; rising pipe + radial shaft seal with dust lip at output side
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
2 × T2ED 050 2 × 32313 2 × 22317 E 1 × 22228 E; 1 × 22328 E
Minimum bearing life
L10h = 50 000 operating hours
Remarks
External radial force 4 500 kN and external axial force 8 900 kN on the output shaft
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Spur, split power
172
Application
Drive for briquetting roll press
Manufacturer
Flender ESAT, Herne, Germany
Input drive
Electric motor (asynchronous), V-belts
Drive rating
P = 630 kW
Drive speed
n = 1 358 r/min
Total ratio
i = 1 : 97,4
Power take-off
Toothed coupling
Output torque
M2 = 432 000 Nm
Dimensions
1 620 × 3 510 × 1 200 mm
Mass
G = 17 000 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Gears: oil bath Bearings: circulating oil
Lubricant
Mineral oil with viscosity to ISO VG 320
Operating temperature
T = 60 °C (oil sump)
Sealing
Radial shaft seals at input and output sides
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft (2×) No. 5 shaft (2×)
1 × 22330 CC/W33; 1 × 22324 CC/W33 2 × 24132 CC/W33 2 × NJG 2330 VH 4 × 23238 CC/W33 2 × 23068 CC/W33; 2 × 23976 CC/W33
Minimum bearing life
L10h = 50 000 operating hours
Remarks
Power split with independent load compensation on the axially freely adjustable double helix pinion shaft of the 3rd stage
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Spur gear, single stage
174
Application
Pinion stand of hot strip finishing mill
Manufacturer
SMS – Schloemann-Siemag AG, Hilchenbach, Germany
Input drive
Electric motor (DC), toothed coupling
Rating
P = 10 000 kW
Speed
n = 0 to 36,4 or 80,24 r/min
Total ratio
i=1:1
Power take-off
Toothed coupling, rolls
Output torque
M2 = 2 × 1 310 000 Nm
Dimensions
2 660 × 5 420 × 2 630 mm
Mass
G = 49 100 kg
Gears
Double helical, case hardened
Lubrication type
Circulating oil with water cooler
Lubricant
Oil with viscosity to ISO VG 460
Seals
Labyrinth seals at input and output sides
Bearings No. 1 shaft No. 2 shaft
1 × 240/600 CA/W33 and 1 × 240/500 CA/W33 1 × 24184 ECA/W33 and 1 × 240/500 CA/W33
Minimum bearing life
L10h = 20 000 operating hours
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Spur, two-stage Application
Drive for vertical edging stand of a blooming mill (hot plate mill)
Manufacturer
SMS – Schloemann-Siemag AG, Hilchenbach, Germany
Input drive
2 electric motors (DC) via toothed coupling
Drive rating
P = 2 × 1 600 kW
Drive speed
n = 0 to ± 140/273 r/min
Total ratio
i = 1 : 7,51
Power take-off
2 cardan shafts
Output torque
M2 = 2 × 1 350 000 Nm
Dimensions
5 600 × 10 430 × 3 700 mm
Mass
G = 258 000 kg
Gears
Helical cut, ground; 1st stage and pinion, 2nd stage: case hardened; gear, 2nd stage: heat treated
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 460
Operating temperature
T = 40 °C (oil supply temperature)
Sealing
Labyrinths at input and output sides
Bearings No.1 shaft (2×)
Weight balancing (2×)
2 × taper roller bearing 331197 A (384,175 × 546,1 × 222,25 mm) 2 × cylindrical roller bearing BC2B 320041 (380 × 540 × 200 mm) 2 × taper roller bearing BT2B 332663/HB1 (519,112 × 736,6 × 258,762 mm) 2 × cylindrical roller bearing 316077 A (440 × 620 × 225 mm) 2 × taper roller bearing BT2B 328310/HA4 (1 562,1 × 1 806,575 × 279,4 mm) 2 × cylindrical roller bearing BC1B 322416/HA1 (1 700 × 2 060 × 160 mm) 4 × 29330 E
Minimum bearing life
L10h = 20 000 operating hours
Remarks
The two rolls are driven via two mechanically separate, electrically synchronised motors
No. 2 shaft (2×)
No. 3 shaft (2×)
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Spur, with shift
178
Application
Drive for a Sendzimir rolling mill
Manufacturer
ERCMD Engrenages et Réducteurs CitroenMessian-Durand, Velizy-Villacoublay, France, for DMS Seclin, France
Input drive
Electric motor (DC), toothed coupling
Drive rating
P = 6 000 kW
Drive speed
n = 0 to 350/850 r/min
Total ratio
i1 = 1 : 1; i2 = 1,595 : 1
Power take-off
4 toothed couplings
Output torque
4 × M2 = 40 925 Nm
Dimensions
2 430 × 4 190 × 4 820 mm
Mass
G = 52 000 kg
Gears
Input stage: helical cut, case hardened, ground Second stage and pinion stand: double helix
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 460
Operating temperature
T = 45 °C (oil inlet temperature)
Seals
Felt seals with labyrinth on input shaft; radial shaft seals on output shafts
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft No. 5 shafts (2×) No. 6 shafts (2×)
1 × 23168 CC/C3W33; 1 × 23080 CAC/C3W33 1 × 23168 CC/C3W33; 1 × 23164 CC/C3W33 2 × NU 19/670 ECMA 2 × 23080 CAC/C3W33 4 × 23244 CC/C3W33; 2 × QJ 1044 N2MA/C4 4 × 23044 CC/C3W33; 2 × QJ 1044 N2MA/C4
Minimum bearing life
L10h = 50 000 operating hours
Remarks
Axial forces on the output shafts 40 000 N per shaft
8 Application examples
8
179
8 Application examples
Spur, with shift
180
Application
Drive for aluminium foil mill (rolling mill)
Manufacturer
David Brown, Huddersfield, Gt. Britain
Input drive
Two electric motors; elastic couplings
Drive rating
P = 2 × 3 000 kW
Drive speed
n = 374 or 935 r/min
Total ratio
i1 = 1 : 1; i2 = 1 : 2,5
Power take-off
Torsionally elastic coupling
Output torque
2 × M2 max = 190 900 Nm
Dimensions
1 810 × 4 530 × 4 135 mm
Mass
G = 45 700 kg
Gears
Double helix, case hardened, ground
Lubrication type
Circulating oil
Lubricant
EP oil with viscosity to ISO VG 220
Operating temperature
T = 70 °C
Sealing
Labyrinth with radial shaft seal on input and output shafts
Bearings No. 1 shafts (4×) No. 2 shafts (4×) No. 3 shaft No. 4 shaft No. 5 shaft No. 6 shaft
8 × 22244 CC/W33 8 × 23248 CC/W33 2 × 230/500 CA/W33 2 × 60/500 MA 2 × 24068 CC/W33 2 × 24064 CC/W33
Minimum bearing life
L10h = 50 000 operating hours
8 Application examples
8
181
8 Application examples
Spur, with shift, one-stage
182
Application
Drive for reeler for hot rolled sheet
Manufacturer
SMS – Schloemann-Siemag AG, Hilchenbach, Germany
Input drive
Electric motor (DC), toothed coupling
Drive rating
P = 1 100 kW
Drive speed
n = 0 to 400 or 1 200 r/min
Total ratio
i1 = 1 : 2,37; i2 = 1 : 5,19
Power take-off
Toothed coupling
Output torque
M2 = 112 000 or 236 000 Nm
Dimensions
2 075 × 2 900 × 1 620 mm
Mass
G = 17 885 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 150
Sealing
Labyrinths at input and output sides
Bearings Shaft No. 1 Shaft No. 2 2 shifting gears
1 × 23240 CC/C3W33; 1 × 24134 CC/C3W33 1 × 23056 CC/C3W33; 1 × NNU 4960 B/SPC3W33 4 × 239/500 CA/C3W33
Minimum bearing life
L10h = 20 000 operating hours
8 Application examples
8
183
8 Application examples
Planetary
184
Application
Drive for rolls of continuous casting plant
Manufacturer
Brevini Riduttori, Reggio Emilia, Italy
Input drive
Electric or hydraulic motor
Drive rating
P = 30 kW
Drive speed
n = 1 200 r/min
Total reduction
i = 555 : 1
Output torque
M2 max = 300 000 Nm
Dimensions
970 × 1 280 mm
Mass
G = 1 850 kg
Gears
Case hardened
Lubricant
EP oil SAE 80
Operating temperature
T = 60 °C
Sealing
Radial shaft seals
Bearings No. 1 shaft 2nd planetary stage 3rd planetary stage 4th planetary stage No. 4 shaft
1 × 16022 6 × AL-NNC 5010 CV 6 × AL-NNC 5016 CV 10 × AL-NNC 5022 CV 2 × NCF 2972 V
Minimum bearing life
L10h = 100 000 hours
Remarks
Gearbox comprises modules from series units
8 Application examples
8
185
8 Application examples
Spur, three-stage Application
Single screw extruder
Manufacturer
Santasalo GmbH, Wuppertal, Germany
Input drive
Electric motor (DC), elastic coupling
Drive rating
P = 600 kW
Drive speed
n = 1 364 r/min
Total reduction
i = 1 : 59,3
Power take-off
Extruder screw
Output torque
M2 = 250 000 Nm
Dimensions
1 580 × 2 680 × 1 665 mm
Mass
G = 12 000 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Circulating oil
Lubricant
Oil with viscosity to ISO VG 320
Operating temperature
T = 70 °C
Sealing
Radial shaft seals on input and output shafts
Bearings No. 1 shaft No. 2 shaft No. 3 shaft No. 4 shaft
186
2 × 22328 CC/W33 2 × NJG 2330 VH 2 × NJG 2338 VH 1 × NCF 3068 V; 1 × NCF 2972 V; 1 × 29480 EM; 1 × 81164
Minimum bearing life
40 000 operating hours
Remarks
Noise damping cover to reduce noise level
8 Application examples
8
187
8 Application examples
Spur switching gear, two-stage
188
Application
Drive for plastic extruder
Manufacturer
Zahnradwerk Köllmann, Wuppertal, Germany
Input drive
Electric motor (DC), elastic coupling
Rating
P = 43 to 49 kW
Speed
n = 1 790 r/min
Total ratio
i1 = 1 : 23,95, i2 = 1 : 17,43
Power take-off
Socket on extruder screw
Output torque
M2 = 5 600 Nm (1st gear) M2 = 4 600 Nm (2nd gear)
Dimensions
430 × 740 × 755 mm
Mass
G = 670 kg
Gears
Helical cut, case hardened, ground
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 320
Operating temperature
Tmax = 70 °C
Seals
Fluoro rubber radial shaft seals
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
1 × 22309 CC; 1 × NJ 309 ECJ 1 × 22311 E; 1 × NJ 311 ECJ; 4 × K 90×98×27 2 × 6221; 1 × 29422 E
Minimum bearing life
L10h = 25 000 operating hours
Remarks
Noise level < 80 dBA
8 Application examples
8
189
8 Application examples
Spur, two-stage
190
Application
Drive for test rig
Manufacturer
Voith, St. Pölten, Austria
Input drive
Hydraulic motor
Drive rating
P = 125 kW
Drive speed
n = 465 to 1 953 r/min
Total ratio
i = 1 : 9,766
Output torque
M2 = 25 000 Nm
Dimensions
740 × 1 219 × 630 mm
Mass
G = 1 135 kg
Lubrication type
Oil bath
Lubricant
Oil with viscosity to ISO VG 220
Sealing
Radial shaft seals at input and output sides
Bearings No. 1 shaft No. 2 shaft No. 3 shaft
2 × NJ 2316 ECM/C3; 1 × QJ 313 N2MA/C3 2 × NJ 2320 ECMA/C3 2 × 23230 CC/C3W33
8 Application examples
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191
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