06 NFC Pump Control System
January 28, 2017 | Author: piteng1945 | Category: N/A
Short Description
Download 06 NFC Pump Control System...
Description
SERV1852-02 08/08
-5-
Text Reference Main Pumps
MAIN HYDRAULIC PUMPS AND PUMP CONTROL VALVE GROUPS Stick Cylinder Bucket Cylinder Swing Motor
Main Control Valve Group
Pilot Control Valves
Priority Valves
Pilot Manifold
Pilot Pump Fan Motor
Boom Cylinders
Travel Motors
Main Hydraulic Pumps
M Fan Pump
Tank
The Fan Motor and Pump are only used on the 330D and 336D
1
INTRODUCTION This section of the presentation will cover the main hydraulic pumps and pump controls for the 300D Hydraulic Excavators. The main pump group consists of a variable displacement piston drive pump and a variable displacement piston idler pump. The drive pump and the idler pump are part of an integral housing. The drive pump and the idler pump are identical in construction and operation. The pumps are sometimes referred to as S.B.S. (side by side) pumps. The main difference between all of the pumps is the maximum pump flow for each model. Both the drive pump and the idler pump have individual pump control valve groups to control the pump flow. The 320D through the 329D use the same type of pump control valve group. The 330D/336D pump control valve group is the same as the pump control valve group used on the 345C pump.
SERV1852-02 08/08
-6-
Text Reference Main Pumps
POWER SHIFT PRESSURE SYSTEM Idler Pump
Pump Control Valve Power Shift PRV Solenoid
Engine Speed Sensor
Drive Pump
Output Pressure Sensor
Engine ECM
Machine ECM
Pilot Pump
Engine Speed Dial
Monitor
OK
2
Power shift pressure is controlled by the Machine ECM, and assists in pump regulation. Power shift pressure is one of three pressures to control the pump. The pilot pump supplies the power shift PRV solenoid with pilot oil. The Machine ECM monitors the selected engine speed (from the engine speed dial), the actual engine speed (from the engine speed sensor and Engine ECM), and the pump output pressures (from the output pressure sensors). The power shift PRV solenoid valve regulates the pressure of the power shift oil depending upon the signal from the Machine ECM to the pump control valve groups. When the engine speed dial is in position 10, the Machine ECM varies the power shift pressure in relation to the actual speed of the engine. The power shift pressure is set to specific fixed values dependent upon the position of the engine speed dial. The fixed power shift pressures assist cross sensing pressure (not shown) with constant horsepower control.
SERV1852-02 08/08
-7-
Text Reference Main Pumps
When the engine speed dial is on position 10 and a hydraulic load is placed on the engine, this condition causes the engine speed to decrease below the engine's target rpm. When this decrease occurs, the Machine ECM signals the power shift PRV solenoid valve to send increased power shift pressure to the pump control valve groups. The increased power shift signal causes the pumps to destroke, and reduce the horsepower demand placed on the engine. With a decreased load from the hydraulic pumps the engine speed increases. This function is referred to as engine underspeed control. Engine underspeed control prevents the engine from going into a "stall" condition where engine horsepower cannot meet the demands of the hydraulic pumps. The power shift signal to the pump control valve groups enables the machine to maintain a desired or target engine speed for maximum productivity. Power shift pressure has the following effect on the main hydraulic pumps: - As power shift pressure decreases, pump output increases. - As power shift pressure increases, pump output decreases. Power shift pressure ensures that the pumps can use all of the available engine horsepower for the hydraulic system at all times without exceeding the output of the engine. NOTE: The target rpm is the full load speed for a specific engine "no load" rpm. Engine target rpm is determined by the opening of one of the implement, swing, and/or travel pressure switches at the end of an operation. The Machine ECM then waits 2.5 seconds and records the engine speed. This specific rpm is the "new" no load rpm. The Machine ECM then controls the power shift pressure to regulate pump flow to maintain the full load (target) rpm for the recorded no load rpm. Target rpm can change each time the pressure switches open for more than 2.5 seconds.
SERV1852-02 08/08
-8-
Text Reference Main Pumps
PROPORTIONAL REDUCING SOLENOID VALVE PWM SIGNAL INCREASE
Solenoid
Plunger Spring
Tank Power Shift Pressure Pilot Pressure
3
The proportional reducing solenoid valve (PRV) for the power shift pressure is located on the drive pump control valve group. The proportional reducing solenoid valve receives supply oil from the pilot pump. The solenoid receives a pulse width modulated signal (PWM signal) from the Machine ECM. The PWM signal sent from the Machine ECM causes the proportional reducing solenoid valve to regulate the pilot pressure to the pump control valve groups to a reduced pressure. This reduced pressure is called power shift pressure (PS). The output flow of the drive pump and the idler pump is controlled in accordance with the power shift pressure. The power shift pressure is used to control the maximum hydraulic pump output in relation to the engine rpm. A decrease in engine speed causes an increase in power shift pressure and a decrease in pump flow.
SERV1852-02 08/08
-9-
Text Reference Main Pumps
When the speed dial is at dial position 10, if the Machine ECM senses a decrease in engine speed below target rpm, the Machine ECM increases the PWM signal sent to the solenoid. The magnetic force of the solenoid increases. As the magnetic force of the solenoid becomes greater than the force of the spring, the spool moves down against the force of the spring. The downward movement of the spool blocks the flow of oil to the tank. More power shift pressure oil is now directed to the pump control valve group. The increased power shift pressure acts on the drive pump control valve group and the idler pump control valve group. If both pumps are upstroked, then both pumps will destroke as a result of the increase in power shift pressure. If only one pump is upstroked, only the upstroked pump will destroke.
SERV1852-02 08/08
- 10 -
Text Reference Main Pumps
PROPORTIONAL REDUCING SOLENOID VALVE PWM SIGNAL DECREASE
Solenoid
Plunger Spring
Tank Power Shift Pressure Pilot Pressure
4
If engine speed is above the target rpm, the Machine ECM decreases the power shift pressure to increase the pump flow. When the Machine ECM senses an increase in engine speed above the target speed the Machine ECM decreases the PWM signal sent to the proportional reducing solenoid valve. As the magnetic force of the proportional reducing solenoid valve becomes less than the force of the spring, the spool moves up. The upward movement of the spool restricts the pilot oil flow to the power shift passage and opens the power shift passage to the drain. The power shift pressure is reduced. The reduced power shift pressure acts on the drive pump control valve group and the idler pump control valve group. Depending on which circuits are activated, the drive pump and/or the idler pump will upstroke as a result of a decrease in power shift pressure.
SERV1852-02 08/08
- 11 -
Text Reference Main Pumps
3 5 4
1 6
2
5
320D - 329D MAIN HYDRAULIC PUMP GROUP This illustration shows the main hydraulic pumps groups. The drive pump (1) is driven by the engine and the idler pump (2) is driven by the drive pump. The pilot pump (3) is mounted on the drive pump. The medium pressure pump (4) is driven by the idler pump. The drive pump supplies oil to the right half of the main control valve group and the following valves: - stick 2 control valve - boom 1 control valve - bucket control valve - attachment control valve - right travel control valve
SERV1852-02 08/08
- 12 -
Text Reference Main Pumps
The idler pump supplies oil to the left half of the main control valve group and the following valves: - left travel control valve - swing control valve - stick 1 control valve - boom 2 control valve - auxiliary valve for tool control (if equipped) The output of the variable-displacement piston pumps is controlled by the pump control valve groups (5 and 6) mounted on the main hydraulic pumps.
SERV1852-02 08/08
- 13 -
Text Reference Main Pumps
5
1
6
3
4
2
6 This illustration shows the pump control valve group for the drive pump. Except for the power shift solenoid, the components for the idler pump are identical. The power shift PRV solenoid valve (1) provides a common power shift pressure for both pumps. The power shift PRV solenoid valve is controlled by the Machine ECM. The pump output pressure sensors (2) signals the Machine ECM of each pump's output pressure. The Machine ECM uses the pump output pressure, actual engine speed, and desired engine speed to determine the power shift pressure. The pressure sensors also signal the Machine ECM to cancel the AEC settings if the pump pressure increases above approximately 7370 kPa (1100 psi) and the engine rpm is still at an AEC setting. The horsepower adjusting screws (3) adjust the hydraulic horsepower output of each pump. The maximum angle screw (4) limits the maximum flow of each pump. The pressure tap (5) above the power shift PRV solenoid valve can be used to check the PRV signal pressure. The pressure tap (6) just above the pressure sensor can be used to check the drive pump supply pressure. Another pressure tap (not shown) can be used to check the idler pump supply pressure. Cat ET can also be used to check these two pressures.
SERV1852-02 08/08
- 14 -
MAIN PUMP GROUP U
STANDBY
Text Reference Main Pumps Medium Pressure Circuit
M2
Pump Control Valve
Main Control Valve Group (Left Side)
Left NFC Control Orifice PS2 Idler Pump
Cross Sensing Orifice
Med Press Pump Pilot Pump
M Drive Pump
Case Drain
Actuator
Power Shift PRV Solenoid Valve Main Control Valve Group (Right Side) M1 Output Pressure Sensor U
Pilot Filter and Manifold
Right NFC Control Orifice
Pilot Pump
7 This illustration shows the pumps in STANDBY condition. The pump control valve groups will upstroke, destroke, or maintain the displacement of the pump depending on the conditions the pump control valve group senses. The pump control valve group controls oil pressure (stroking pressure) to the right side of the actuator, which controls the angle of the pump swashplate. Each pump has a pump control valve group which senses the three following control signals: - a pump specific Negative Flow Control (NFC) signal from the main control valve group - a common power shift signal pressure generated by the power shift PRV - a common cross sensing signal pressure from the output of the two main pumps NFC: NFC pressure is the most significant controlling signal in a negative flow controlled hydraulic system. Each pump control valve group receives a specific NFC signal that is based upon the hydraulic demand for that specific pump.
SERV1852-02 08/08
- 15 -
Text Reference Main Pumps
Flow from the drive pump supplies the right half of the main control valve group and has a corresponding NFC signal for the drive pump. Flow from the idler pump supplies the left half of the main control valve group and has a corresponding NFC signal for the idler pump. The open-center valves in the main control valve group allow pump output to flow through unrestricted. An orifice in the NFC valve creates a restriction to the pump output which increase the NFC pressure. The NFC pressure then signals the corresponding pump control valve group. Each pump will remain at STANDBY as long as a full NFC signal pressure is present. When a hydraulic control valve is shifted from the NEUTRAL position, the NFC signal pressure to the corresponding pump is reduced, which causes the pump to UPSTROKE. Any change in the movement of a valve in the main control valve group will effect the NFC signal because the valves send a variable NFC signal to the pump depending on the needed pump output. Output of each pump is unaffected by a change in the NFC signal to the other pump. NFC pressure has the following effect on the main hydraulic pumps: - As NFC pressure decreases, pump output increases, - As NFC pressure increases, pump output decreases. NFC signal pressure overrides all other control of the main hydraulic pumps. Cross Sensing: Cross sensing pressure is essentially an average pressure from the output of the drive pump and the idler pump. The output of each pump flows respectively to the left and right halves of the main control valve group. The output of each pump also flows to the cross sensing orifices. The cross sensing pressure compensates for the horsepower demand of each pump individually and for the two pumps together. With cross sensing assistance, the pumps constantly regulate the flow to effectively use all of the available engine horsepower at any given time. This regulation is referred to as constant horsepower control. Cross sensing pressure has the following effect on the main hydraulic pumps: - As cross sensing pressure decreases, pump output increases, - As cross sensing pressure increases, pump output decreases. Given a fixed NFC signal, cross sensing signal pressure regulates the output of the main hydraulic pumps. NOTE: Hydraulic horsepower is a function of pump output flow and pressure. As pump flow or pressure increases, the horsepower demand increases. As pump flow or pressure decreases, the horsepower demand decreases.
SERV1852-02 08/08
- 16 -
Text Reference Main Pumps
MAIN PUMP CONTROL VALVE GROUP STANDBY
D
Pin A
Actuator
D Actuator Pivot
Cross Sensing Signal
Control Linkage
Power Shift Signal NFC
Pin A
Control Signal Pivot
Pin B
Guide Horsepower Control Spool
Sleeve
Pin B
Shoulder
Pilot Control
Control Piston
Swashplate SECTION D-D
8 Pump Control Valve Group The above illustration shows a cross sectional view of one of the main hydraulic pump control valve groups in STANDBY. The main pumps will be in STANDBY condition when the engine is running and all control valves are in NEUTRAL. Under these conditions the NFC pressure signal to the pump control valve groups is high. The pump can not upstroke until NFC signal pressure is reduced. The high NFC signal pressure causes the NFC control piston to move left against the force of the NFC spring on the right. When the NFC control piston moves left the piston contacts the shoulder on the pilot piston, which causes the pilot piston to move the horsepower control spool against the spring force on the left end of the valve. The passage between horsepower control spool and the sleeve is now open to tank, causing the right end of the actuator to be open to the tank. The actuator moves to the right, moving the swashplate to a minimum angle, which causes pump output flow to be minimum. NOTE: With S.B.S. pumps, system pressure at STANDBY (maximum NFC signal) destrokes the pumps to minimum. When the pump is upstroked all three signals work together to control the angle of the pump swashplate to regulate the pump flow.
SERV1852-02 08/08
- 17 -
Text Reference Main Pumps
MAIN PUMP CONTROL VALVE GROUP UPSTROKED - NFC SIGNAL REDUCED
D
Pin A
Actuator
D Actuator Pivot
Cross Sensing Signal
Control Linkage
Power Shift Signal NFC
Pin A
Control Signal Pivot
Pin B
Guide Horsepower Control Spool
Sleeve
Pin B
Shoulder
Pilot Control
Control Piston
Swashplate SECTION D-D
9 The pumps must have a reduction in NFC pressure to upstroke from STANDBY. The illustration shows the pump control valve groups upstroking the pump due to a decrease in NFC signal pressure. As shown, there is no NFC signal pressure, indicating that at least one control valve has been fully shifted. When one of the joysticks or travel levers is moved from the NEUTRAL position, NFC signal pressure decreases proportionally to the amount the joystick or travel lever is moved. When the NFC signal pressure decreases, the spring on the control piston forces the control piston to the right. The horsepower control springs on the left overcome the cross sensing signal pressure and the power shift signal pressure to move the horsepower control spool to the right. With the horsepower control spool shifted to the right, the passages between the sleeve and the horsepower control spool are closed off to tank and pump output pressure is allowed to flow to the right side of the actuator. Because the right side of the actuator is larger than the left side, the greater force generated by the pressure on the right side causes the actuator to move left to upstroke the pump. The pump can also be upstroked by a decrease in either power shift or cross sensing pressure, but only after a reduction in NFC pressure has caused the pump to move from the minimum angle.
SERV1852-02 08/08
- 18 -
Text Reference Main Pumps
MAIN PUMP CONTROL VALVE GROUP CONSTANT FLOW
D
Pin A
Actuator
D Actuator Pivot
Cross Sensing Signal
Control Linkage
Power Shift Signal NFC
Pin A
Control Signal Pivot
Pin B
Guide Horsepower Control Spool
Sleeve
Pin B
Shoulder
Pilot Control
Control Piston
Swashplate SECTION D-D
10
As the pump upstrokes, the movement of the actuator causes the control linkage to move the sleeve around the horsepower control spool. The sleeve moves to the right as the actuator moves to the left. Because of the geometry of the control linkage, a large movement of the actuator moves the sleeve a small amount (see Section D-D). The small movement of the sleeve causes the passages between the sleeve and the horsepower control spool to open partially to the tank and partially to the pump output. The pressure signal sent to the right side of the actuator is now metered, which causes the actuator to reach a balance point where the pump does not upstroke or destroke. With the actuator at a fixed position the swashplate angle of the pump is fixed. Constant flow is now achieved. Due to varying loading and operating conditions, this fixed output is rarely maintained for very long. When operating conditions change, the pump will UPSTROKE or DESTROKE.
SERV1852-02 08/08
- 19 -
Text Reference Main Pumps
MAIN PUMP CONTROL VALVE GROUP DESTROKE
D
Pin A
Actuator
D Actuator Pivot
Cross Sensing Signal
Control Linkage
Power Shift Signal NFC
Pin A
Control Signal Pivot
Pin B
Guide Horsepower Control Spool
Sleeve Pin B
Shoulder
Pilot Control
Control Piston
Swashplate SECTION D-D
11
The three things which can cause the pumps to DESTROKE are: - an increase in NFC pressure - an increase in cross sensing pressure - in increase in power shift pressure This illustration shows the system under a heavy hydraulic load. As the supply pressure increases due to the heavy load, the cross sensing signal pressure rises as an average of the left and right pump delivery pressures. The cross sensing signal acts on the difference of the two areas on the pilot piston. As the cross sensing signal increases, the pilot piston moves to the left, which pushes the horsepower control spool left against the force of the horsepower control springs on the left. As the spool moves left, the large end of the actuator is opened to tank by a passage between the horsepower control spool and the sleeve. The pressure decreases on the right end of the actuator and the actuator moves to the right, which causes the pump to DESTROKE.
SERV1852-02 08/08
- 20 -
Text Reference Main Pumps
An increase in power shift signal pressure has a similar effect as an increase in cross sensing signal pressure. If the hydraulic pump lugs the engine below full load speed, the Machine ECM increases the current to the power shift PRV solenoid valve. The increased signal causes a higher power shift signal to be sent to the pump control valve groups. The power shift pressure acts on the right side of the pilot piston. The force generated from the power shift pressure assists cross sensing pressure to destroke the pump. As the pump destrokes the engine speed will increase due to the reduction in load. An increase in NFC signal pressure will cause the pump to destroke. If all control valves were returned to NEUTRAL, the NFC signal causes the pump to fully destroke and return to STANDBY.
SERV1852-02 08/08
- 21 -
6
Text Reference Main Pumps
8 5
4
7 1 9
10
2
3
12
330D /336D MAIN HYDRAULIC PUMP GROUP The 330D and the 336D uses a new Kawasaki designed main hydraulic pump group (1) rated at 2 x 280 L/Min (2 x 74 gpm). The pump group is different from the pump group used on the 330C, however it continues to use an NFC control system. This pump group is similar to the pump group used on the 345C. The drive pump (2) is driven by the engine via a flexible coupling. The idler pump (3) is driven directly off the drive pump. Each pump rotating group has its own pump control valve group. The pump control valve groups are used to adjust the output flow of the pumps. Each pump rotating group also has its own pressure tap and pressure sensor. A power shift PRV solenoid valve (4) is mounted on the top, center of the pump group case. The power shift PRV solenoid valve uses pilot system oil and sends some of the pilot oil to the main hydraulic pump control valve groups as a control signal pressure. The power shift pressure is checked at pressure tap (5). Additional pump components shown in this photo are: the drive pump control valve group (6), the idler pump swashplate minimum angle adjustment (7) and the idler pump control valve group (8). The pilot pump (9) is driven off the idler pump and the demand fan pump (10) is driven off of the drive pump.
SERV1852-02 08/08
- 22 -
Text Reference Main Pumps
2
1
13
This is a view of the drive pump pump control valve group. The pump control valve group is located above and behind the power shift PRV solenoid valve. This illustration shows: - the drive pump negative flow control adjustment (1) - the drive pump horsepower control adjustment (2) The idler pump control valve group has similar adjustment screws.
SERV1852-02 08/08
- 23 -
Text Reference Main Pumps
330D / 336D PUMP COMPONENTS AND INPUTS Right NFC Control Orifice
Horsepower Control Spool
Drive Pump Cross Sensing Signal
Torque Control Spool
Idler Pump Cross Sensing Signal
NFC Spool
Drive Pump Output Pressure Sensor Actuator
P
Destroke Main Control Valve (Right Side)
Drive Pump
M
Pilot Pump
Pilot Pump
Power Shift (PRV) Solenoid Valve
Idler Pump
14
Each pump receives four different signals to control the output flow of the pumps: - power shift pressure - system pressure from that pump - cross sensing pressure (from the other pump) - Negative Flow Control (NFC) pressure Power Shift Pressure: The power shift PRV receives a control signal from the ECM. The ECM sends an electrical signal to the power shift PRV to regulate power shift pressure in relation to the engine speed. The power shift signal to the pump control valve groups enables the machine to maintain the target engine speed for maximum productivity.
SERV1852-02 08/08
- 24 -
Text Reference Main Pumps
If the Machine ECM senses that the engine is below the target speed due to a high hydraulic load from the main pumps, the Machine ECM will increase the power shift pressure. The target speed is the full load for the no load engine speed. (The new no load speed is taken 2.5 seconds after the implement/swing and the travel pressure switches open when the joysticks and the travel control pilot controls are returned to NEUTRAL). As power shift pressure increases, the pump control valve groups destroke the main pumps accordingly. This reduces the load on the engine, and consequently enables the engine to maintain the target engine speed. If the engine speed is above the target speed, the Machine ECM will decrease power shift pressure, causing the pumps to upstroke and produce more flow. Cross sensing Control Pressure: Each pump control valve group gets a cross sensing control pressure from the other pump system pressure. Cross sensing pressure is essentially an average pressure from the output of the drive pump and the idler pump. Negative Flow Control (NFC): NFC is the primary controlling signal for the main pump output. The NFC signal to the main pump control valve group is generated in the main control valve group. The NFC signal is delivered to the left and right pump control valve groups from the left and right halves of the main control valve group, respectively. When the joysticks or travel levers are in the NEUTRAL position, the oil flows from the main pumps through the open center bypass passages of the control valves. The oil flows to the valves and returns to the tank by way of the NFC control orifices. The restriction of the NFC orifices causes a pressure signal to be sent to the right and left pump control valve groups, respectively, as an NFC signal. When the main pump control valve groups receive a high NFC signal from the main control valves, the pumps remain at a standby output flow at or near minimum pump displacement. When a joystick or travel lever is moved from a NEUTRAL position, the open-center passage of the corresponding implement/travel function is closed in proportion to spool movement. This reduces the NFC signal to the main pump control valve and the pump output flow is increased proportionally. When the control valve is fully shifted, the NFC pressure is reduced to slow return check valve pressure. The use of an NFC hydraulic system maximizes efficiency of the machine by only producing flow from the pumps when the flow is needed. NOTE: A high NFC signal will always overcomes the horsepower control and decrease pump flow to minimum.
SERV1852-02 08/08
- 25 -
Text Reference Main Pumps
Right NFC Control Orifice
Torque Control Spool
330D / 336D HYDRAULIC PUMPS STANDBY
Horsepower Control Spool
NFC Spool Actuator
Main Control Valve (Right Side)
Drive Pump
Pilot Pump
Drive Pump Output Pressure Sensor
P
M
Power Shift PRV
Idler Pump
Actuator Pilot System
Destroke
P
Pilot Pump
Main Control Valve (Left Side) Idler Pump Output Pressure Sensor
Left NFC Control Orifice
15
This illustration shows the pumps in STANDBY condition. Each pump control valve group senses the Negative Flow Control (NFC) signal, the power shift pressure, the cross sensing pressure, and the system pressure for that pump. When one of more circuits are activated, the pump control valve groups will upstroke or destroke the pumps to maintain the pump flow depending on the four signal pressures to the pump control valve groups. The pump control valve group controls oil pressure to the left side of the actuator. This controls the angle of the pump swashplate. The 330D/336D hydraulic pumps are always trying to upstroke to increase flow. The pump control valve groups vary the oil pressure used to destroke the hydraulic pumps.
SERV1852-02 08/08
- 26 -
The idler pump supplies oil to the following valves: - left travel control valve - swing control valve - stick I control valve - boom II control valve - idler (left) pump negative flow control valve - auxiliary valve (if equipped) The drive pump supplies oil to the following valves: - right travel control valve - standard attachment control valve - bucket control valve - boom I control valve - stick II control valve - drive pump negative flow control valve
Text Reference Main Pumps
SERV1852-02 08/08
- 27 -
Torque Control Lever
PUMP CONTROL GROUP Horsepower Control Sleeve
Text Reference Main Pumps
Negative Flow Control Lever
Pivot Pin
Pivot Pin
Horsepower Control Spool Horsepower Control Section Feedback Lever Pin
Torque Control Section
Negative Flow Control Spool Maximum
Torque Control Piston
Feedback Lever Small End Of Actuator Piston
Minimum
Large End Of Actuator Piston
Torque Control Spool
16
Pump Control Valve Group This illustration shows the three separate control sections of the pump control group. The three control sections are connected with a series of pins and linkages. The separate control sections work together to regulate pump flow by changing the angle of the pump swashplate, according to demand and hydraulic horsepower requirements. Pump supply pressure is directed to the small end of the actuator piston to upstroke the pump toward maximum angle. A regulated pressure signal is directed to the large end of the actuator piston to destroke the pump toward the minimum angle. The horsepower control section directs some of the system pressure oil to and from the large end of the large actuator piston. The lower end of the feedback lever is connected to the actuator piston. The feedback lever works as a follow-up linkage to move the horsepower control spool when the large actuator piston moves. The negative flow control (NFC) section works in conjunction with the horsepower control section to destroke the swashplate when all hydraulic controls are in NEUTRAL or during implement or travel MODULATION. The torque control section works in conjunction with the horsepower control section to regulate pump flow when the hydraulic circuits are actuated.
SERV1852-02 08/08
- 28 -
Torque Control Lever
Large Hole
Text Reference Main Pumps
Horsepower Control Spool
Pivot Pin
Pivot Pin
Torque Control Spool
Feedback Lever Pin NFC Lever NFC Spool
Actuator Piston
Feedback Lever
Swashplate
PUMP CONTROLS END VIEW
17
This illustration shows an end sectional view of the pump controls. The NFC spool is connected to the lower end of the NFC lever with a pin. The upper end of the NFC lever pivots on a fixed pin in the housing. The torque control spool is connected to the lower end of the torque control lever with a pin. The upper end of the torque control lever also pivots on a fixed pin in the housing. The upper end of the feedback lever is connected to the horsepower control spool with a pin. The lower end of the feedback lever is connected to the actuator piston. The feedback lever pin fits tightly into the feedback lever. The feedback lever pin extends into large holes in the torque control lever and the NFC lever. The large holes permit individual control from the torque control lever and the NFC lever. Movement of the actuator piston causes the feedback lever to pivot on the feedback lever pin and move the horsepower control spool.
SERV1852-02 08/08
- 29 -
Text Reference Main Pumps
330D / 336D PUMP CONTROL GROUP STANDBY - FULL DESTROKE
Horsepower Control Spool
Pivot Pin Feedback Lever Pin
NFC Spool
NFC Lever NFC Lever Pin
NFC Pressure
NFC Adjustment Screw Feedback Lever
Minimum Angle Stop
Swashplate
Maximum Angle End of Actuator Piston
Minimum Angle End of Actuator Piston
18
This illustration shows the NFC portion of the pump control group. When all hydraulic control valves are in NEUTRAL, a high NFC pressure (system pressure) from the NFC orifice is directed to the left end of the NFC spool. The NFC pressure pushes the NFC spool to the right against the spring force. In the STANDBY condition, the horsepower control spool directs a signal pressure, which is part of system pressure, to the minimum angle end of the actuator piston. The increase in pressure moves the actuator piston to the right against the minimum angle stop screw. The pump flow will remain constant until the NFC pressure from the control valve decreases. The NFC adjusting screw changes the effect of the NFC pressure on the NFC spool. Turning the screw in (clockwise) causes the NFC pressure to increase higher before the NFC spool moves. This condition causes the pump to upstroke sooner (less modulation) when the hydraulic control valve is ACTIVATED. Turning the screw out (counterclockwise) causes the NFC spool to move at a lower NFC pressure. This condition causes the pump to upstroke later (more modulation) when the hydraulic control valve is ACTIVATED.
SERV1852-02 08/08
- 30 -
Text Reference Main Pumps
330D / 336D PUMP CONTROL GROUP FLOW INCREASE - START OF UPSTROKE Horsepower Control Sleeve
Orifice
Horsepower Control Spool
Pivot Pin
Feedback Lever Pin NFC Lever
NFC Piston
NFC Lever Pin
NFC Pressure
Feedback Lever
Maximum Angle Stop
Swashplate
Minimum Angle End of Actuator Piston
Maximum Angle End of Actuator Piston
19
This illustration shows the pump control group at the beginning of an upstroke caused by a decrease in NFC pressure. The pivot pin is fixed to the pump control housing. The NFC lever pivots around this point. When a hydraulic control valve in the main control valve is shifted, the NFC pressure is decreased. Due to reduced NFC pressure, spring force moves the NFC piston to the left. The NFC piston moves the lower end of the NFC lever to the left. As the lower end of the NFC lever moves to the left, the large hole through the lever also moves to the left. As the large hole moves to the left, spring force pulls the horsepower control spool and the upper end of the feedback lever to the left because the feedback lever pin is allowed to move to the left. The minimum angle actuator piston is opened to case drain through the right orifice in the horsepower control sleeve and the right end of the horsepower control spool. System supply pressure pushes the maximum angle actuator piston to the left to upstroke the pump.
SERV1852-02 08/08
- 31 -
Text Reference Main Pumps
330D / 336D PUMP CONTROL GROUP CONSTANT FLOW
Horsepower Control Sleeve
Orifices
Pivot Pin Feedback Lever Pin
Horsepower Control Spool NFC Piston
NFC Lever
NFC Lever Pin
NFC Pressure
Feedback Lever
Maximum Angle Stop
Swashplate
Minimum Angle End of Actuator Piston
Maximum Angle End of Actuator Piston
20
As the actuator piston moves, the lower end of the feedback lever moves to the left. The feedback lever rotates clockwise with the feedback lever pin as the pivot point. The upper end of the feedback lever pulls the horsepower control spool to the right until the right land on the horsepower control spool reaches a balance point between the orifices through the horsepower control sleeve. Flow to and from the minimum angle end of the actuator piston is metered by the horsepower control spool and the horsepower control sleeve. The swashplate angle remains constant until the NFC pressure is again changed.
SERV1778 08/08
- 32 -
Text Reference Main Pumps
330D / 336D PUMP CONTROL GROUP FLOW INCREASE - FULL UPSTROKE
Horsepower Control Sleeve
Orifice
Pivot Pin Feedback Lever Pin
Horsepower Control Spool
NFC Lever
NFC Piston
NFC Lever Pin
NFC Pressure
Feedback Lever Maximum Angle Stop
Swashplate
Minimum Angle End of Actuator Piston
Maximum Angle End of Actuator Piston
21
The amount of reduction in NFC signal pressure determines the amount of pump upstroke. If NFC pressure is reduced to minimum, the pump will upstroke until the actuator piston contacts the maximum angle stop screw. NOTE: A decrease in power shift pressure will cause an increase in flow from the pump in the same manner as described for a decrease in system pressure, since both power shift pressure and system pressures act on the torque control piston.
SERV1852-02 08/08
- 33 -
Text Reference Main Pumps
330D / 336D PUMP CONTROL GROUP FLOW DECREASE - START OF DESTROKE
Horsepower Control Spool
Orifice
Torque Control Lever Pin
Torque Control Piston
Pivot Pin
Feedback Lever Pin Torque Control Lever Horsepower Adjustment Screw
Power Shift Pressure
Horsepower Control Springs
Cross Sensing Signal
Torque Control Spool
Maximum Angle End of Actuator Piston
Minimum Angle End of Actuator Piston
22
This illustration shows the torque control piston and horsepower control spool sections of the pump control valve group with the pump in the upstroked position at the beginning of DESTROKE due to an increase in the load on the system. For the purpose of this presentation, assume that power shift pressure from the power shift PRV solenoid valve remains constant. The pivot pin is fixed to the pump control housing. The torque control lever pivots around this point. The large horsepower adjustment screw regulates the pressure or point that the pump starts to destroke (large spring adjustment). The small adjustment screw regulates the rate that the pump destrokes (small spring adjustment). Power shift pressure from the power shift PRV solenoid valve enters the pump control group and pushes on the plug at the left end of the torque control piston. System supply pressure from this pump enters the pump control valve group and goes to the right shoulder area on the torque control piston.
SERV1852-02 08/08
- 34 -
Text Reference Main Pumps
The cross sensing signal pressure from the other pump goes to the left shoulder area on the torque control piston. The combination of power shift pressure and the two system supply pressures push the torque control piston to the right against the force of the horsepower control adjustment springs. The horsepower control spool directs the signal pressure to the minimum angle end of the actuator piston to destroke the hydraulic pump. When the system supply pressures and power shift pressure push the torque control piston to the right: The torque control spool moves to the right to compress the horsepower control springs. The torque control spool moves the lower end of the torque control lever to the right with the fixed pin on the upper end of the torque control lever as the pivot point. The torque control lever pulls the feedback lever pin and the upper end of the feed back lever to the right. The feedback lever pulls the horsepower control spool to the right against the spring force. System supply pressure is directed around the horsepower control spool through the center orifice of the horsepower control sleeve and to the minimum angle end of the actuator piston. The increase in pressure in the minimum angle piston moves the actuator piston to destroke the pump.
SERV1852-02 08/08
- 35 -
Text Reference Main Pumps
330D / 336D PUMP CONTROL GROUP FLOW DECREASE - END OF DESTROKE
Horsepower Control Spool
Orifices
Pivot Pin
Feedback Lever Pin Torque Control Lever
Torque Control Piston
Torque Control Lever Pin
Power Shift Pressure Cross Sensing Signal
Feedback Lever
Swashplate
Minimum Angle End of Actuator Piston
Maximum Angle End of Actuator Piston
23
This illustration shows the pump control group at the end of a DESTROKE due to an increase in load on the system. When the actuator piston moves toward minimum angle, the lower end of the feedback lever moves to the right, turning the lever counterclockwise with the feedback lever pin as the pivot point. The feedback lever movement shifts the horsepower control spool to the left so system supply pressure is metered through the two orifices to and from the minimum angle end of the actuator piston. Pump flow is held constant until one of the signal pressures changes. An increase in power shift pressure will cause a decrease in flow from the pump in the same manner as described for an increase in system pressure since both the power shift pressure and system pressure act on the torque control piston.
View more...
Comments