Design Consideration of Hot Oil System

September 19, 2017 | Author: Omar Ezzat | Category: Hvac, Heat Exchanger, Pump, Furnace, Valve
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Design considerations of hot oil system Subhasish Mitra

Introduction: Widely used in process industries especially in oil and gas plants as a heating medium, hot oil is a heat transfer fluid (HTF) capable of transporting heat energy within a specified temperature range. Use of HTF is attractive since it exchanges heat purely in liquid phase by sensible heat transfer mode rather than by latent heat transfer mode in condensing vapour phase which enhances system efficiency. Additionally, unlike steam, HTFs do not require high system pressure to carry out high temperature operation owing to their low vapour pressure and high boiling point which simplifies the system design. Some typical hot oil grades used in the industries are Therminol, Dowtherm (A, G, J, Q, HT), Syltherm, Shell thermia, B.P. Transcal etc. To achieve optimum fluid life, they need to be used only within the recommended bulk and film temperature limits specified by the manufacturer. When not subjected to contamination, i.e., moisture, air, process materials, etc., and thermal stress beyond the specified limits, HTFs can give years of service without significant physical or chemical change. A closed loop system design is often chosen to cater heat duty to the process consumers through a fired heater or waste heat recovery system. A minor make up although is required to the system as some quantity of hot oil needs to be discarded from the system due to gradual thermal degradation. Efficient design of this hot utility system is crucial for satisfactory performance of the respective process. This article aims at elaborating the major design aspects of hot oil system such as sizing basis of the equipment in the loop with illustrating calculations, general design considerations, PSV selection criteria, control philosophy and system protection philosophy.

General description of the HTF system: A hot oil system in general is a closed loop heating arrangement with a heat source typically a fired heater or some kind of waste heat recovery units (WHRU) and heat sinks i.e. process heat exchangers. Fig.1 illustrates such a system as per Shell design engineering practice (DEP) [1]. Hot the oil is filled up in the system by a make-up pump through a normally no flow (NNF) line 1

Split range To flare PC N2

Expansion vessel

WHRU

-

Trim cooler TC

Full flow bypass

Spill over bypass

FC Process stream

Trim cooler

UY

+

Split range

-

TC Process consumers

>

X

PDC

> Filter

TC Circulation pump

Pump out cooler To flare

N2

Normally no flow

HTF storage tank

Make up pump

Fig. 1: Closed loop process flow diagram of hot oil system as per Shell DEP 2

from the storage tank. To avoid contact with oxygen which eventually deteriorates hot oil quality; the tank is kept under nitrogen blanket. The expansion vessel is usually kept at the highest point of the system to vent any trapped gas. Stable level in the expansion vessel confirms complete filling of the loop. Hot oil is circulated by the circulation pump through WHRU/heater coils and heat is supplied to all process consumers. After heat exchange, hot oil is returned to the suction of circulation pump. Supply temperature of the hot oil is controlled by a temperature controller at the outlet of trim air cooler which operates on the both main line and bypass line control valve through a split range control mechanism. Temperatures of the process streams are maintained by controlling the hot oil flow rates. Process consumers can be completely bypassed through the full flow bypass line during start up and partially bypassed by sensing the pressure differential through the spill over bypass line when plant runs under turned down condition. Under these circumstances, WHRU/heater load is dissipated in the trim cooler on the full bypass line. Volume expansion or contraction of hot oil system is accommodated in the expansion vessel. During maintenance of the system or any connected equipment in the loop, hot oil is drained into the storage tank through the pump out cooler. Fig.2 describes similar process flow diagram of hot oil system commonly employed in oil and gas plants. This scheme primarily differs from previous one by introducing a fuel gas fired heater as the heat source and a separate hot oil draining system. The BMS is an elaborate fuel gas flow control system to effectively utilize the individual burner of the fired heater and usually supplied by the heater manufacturer. During maintenance, hot oil is collected from the low point drains of the closed loop piping and collected to an underground draining vessel through the dedicated draining network system. The same vessel can be used for system filling purpose using the drain pump. Hot oil drums can be emptied into this vessel through a filling connection. For complete cleaning of this drain vessel, a vacuum truck connection is provided. A basic process control scheme is presented in Fig.2. Outlet temperature of the fired heater is controlled by a temperature controller which controls the fuel gas flow and hot oil flow to the heater. In case plant runs under turndown condition, pressure of the system increases due to reduced demand of hot oil. The pressure controller senses reduction of flow rate through pressure rise and bypasses the unused hot oil flow through the hot oil trim cooler. Temperature at the downstream of trim cooler is controlled by manipulating the motor speed. 3

FC

N2

To flare PCV

PCV

Full flow bypass Expansion vessel Fired heater Start-up line

TC

PC

BMS Process stream

FG FC Trim cooler

TC Process consumers

M FC Filter

TC Normally no flow

From hot oil drain header

To flare

N2 To flare

N2

HTF drain drum pump

HTF storage tank

HTF drain drum

Fig. 2: A general process flow diagram of hot oil system commonly employed in oil and gas plants

4

Sizing of equipment: The major equipment used in a standard hot oil system are listed below, •

Hot oil expansion vessel



Hot oil circulation pump



Hot oil filter



Hot oil start-up pump



Fired heater and waste heat recovery units from gas turbine generator (GTG)



Hot oil run down cooler



Heat exchangers (Consumers)



Hot oil storage tank



Hot oil make up pump



Hot oil drain drum and drain system



Hot oil sump pump

Below various design considerations and sizing basis of the individual equipment are discussed.

Hot oil expansion vessel: The expansion vessel allows for thermal expansion of the hot oil. Additionally this vessel is used for venting low boiling point components generated in the system during normal operation and purging out inert gas and water vapour during hot oil drying in start-up phase. The expansion vessel minimizes the consequences of any upsets in the hot oil system operation. Following are some significant aspects that need to be taken care of while designing this vessel, • accommodating thermal expansion of the hot oil heated from minimum to maximum operating temperature. • maintaining the NPSHr for the hot oil circulating pumps under all operational circumstances. • venting of possible residual water present in the circuit during start-up. • allowing filling of equipment and during re-commissioning after shut down for maintenance. The largest volume of the individual equipment that can be maintained while the hot oil system remains in operation usually determines this inventory. The expansion vessel is connected to the system return line on the pump suction side. The vessel is elevated so that the normal operating level of the hot oil in the vessel is higher than the highest possible hot oil level in the system (generally it is the fired heater or WHRU coils and typically 15 – 20 m from datum level). This 5

will facilitate proper venting and provide sufficient NPSH for the loop circulation pump.

If this requirement is difficult to meet, a lower elevation may be selected but additional design measures are then required to prevent vapour locking in the high points of the circuit. Hot oil system pressure needs to be positive at the highest point to avoid any boiling and overflow into the flare system. The expansion vessel is connected to the flare and equipped with an inert gas (nitrogen or fuel gas) blanket to serve as a barrier between the hot fluid (usually operating at a temperature above the flash and fire point of the hot oil) and the flare. The vessel’s vapour space is prevented from contacting the atmosphere as it expedites aging of the hot oil and allow moisture to enter the system during shutdown periods (these might create corrosive acid compounds and a safety hazard). Only for operation at high temperatures, particularly approaching or exceeding the boiling point of the hot oil, a positive pressure of at least 1 to 2 bar above the vapour pressure of the hot oil (at this temperature) should be maintained otherwise a blanketing gas pressure in the range of 200 to 300 mm wC (water column) needs to be maintained. The nitrogen blanketing supply can be equipped with a split-range controller or selfactuating PCVs and a non-return valve, which will regulate the nitrogen supply and its vent to flare. A dead pressure zone is required between the inert gas supply pressure and the vent-toflare set pressure. In this dead zone, the pressure is not controlled and is allowed to float freely while the nitrogen supply and vent-to-flare valves are both closed. This dead zone will reduce nitrogen consumption and lower the starting point of venting low boiling point components. The non-return valve prevents hot oil vapour and nitrogen back-flow into the nitrogen system in the event of a pressure increase in the vessel.

A start up line between return line header and expansion vessel top is provided which can be used to vent out air pockets in the loop during start-up by continuous pump circulation. During operation, low boiling degradation products are vented on pressure control and routed to the flare. The expansion vessel is equipped with a pair of safety relief valve capable of protecting the system against over-pressure caused by events such as fluid degradation, contamination, maloperation, and overheating or tube failure in the process heat exchangers. The outlet of safety relief valve is routed to flare.

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If the ambient temperature falls below the freezing point of the HTF or its degradation products with the possibility of congealing, blanketing gas lines and safety relief lines along with associated valves are required to be heat traced in order to prevent line plugging.

The expansion vessel serves the combined function of an expansion vessel and a knock-out drum. It should have sufficient capacity to cater for various operating upsets in the system. The expansion vessel allows for degassing of the hot oil and therefore should be fitted with a half open pipe type inlet device. This vessel is designed based on volume expansion (loop hold up consisting of pipe volume, fired heater/WHRU coil volume and all heat exchanger hold up) of hot oil system of between maximum and minimum possible operating temperature. Volume expansion (typically ~ 20%) is considered as difference between specific volume (m3/kg) i.e. inverse of specific gravity of hot oil at maximum and minimum operating temperature of the system which is required to be accommodated between Low liquid level and High liquid level of the expansion drum. An additional 20% is added to cater for various operating upsets in the systems such as vaporization of residual water in the system and a tube burst.

The inventory between LL and LLLL should be 25% of the vessel volume or 150 mm whichever is more while HHLL is fixed at 150 mm above HLL. Vessel diameter can be found out by setting HHLL at 80 – 85% of vessel ID assuring that 75% vessel volume gets accommodated within HLL. The remaining volume of the vessel volume allows for gas-liquid separation and is filled with inert gas.

A sizing calculation for expansion vessel is illustrated below.

Hot oil expansion drum calculation: Piping volume = π(Dp/2)2 Lp where Dp = pipe ID, Lp = piping length according to plot plan. As per P&ID and plot plan, total piping hold up volume: 65.5 m3 Total piping volume with 10% margin = (65.5 x 1.1) = 72 m3 (Margin can be increased up to 30% if major uncertainty persists in the plot plan) Equipment hold up volume = 15.1 m3 (this comprises of volume of heater coil and heat exchangers. Heat exchanger volumes are calculated as follows considering HTF flows in the tube 7

side. Shell volumes need to be considered otherwise for hold up calculation if HTF flows in shell side), nπ (D/2) 2 L where Dt = tube ID, Lt = tube length n = number of tubes. So, Total system volume = (72 + 15.1) = 87.1 m3

Consider following physical properties for commercial grade HTF (Table 1) Expansion volume from cold start up to normal operation is considered as design case for the vessel. A check case is performed to ensure adequate design margin in case of process upset.

Table 1: Density variation with temperature of a commercial grade HTF Design case

Check case

Temperature

Temp oC

Density kg/m3

Temp oC

Density kg/m3

Min operating temp.

60

973

210

868

Max operating temp.

210

868

230

854

Mass of total hold up (density at min op temp) = (87.1 x 973) = 84748.3 kg 84766.7 kg Volume of oil required based on density at max op temp = (84748.3/868) = 97.6 m3 Expansion volume: (vol at max op temp – vol at min op temp) = (97.6 – 87.1) = 10.5 m3 With 20% margin on expansion volume = (10.5 x 1.2) = 12.6 m3.

The check case is considered to see adequacy of the given margin. Volume of oil required based on density at min op temp = (84748.3/868) = 97.6 m3 Volume of oil required based on density at max op temp = (84748.3/854) = 99.2 m3 Expansion volume: (vol at max op temp – vol at min op temp) = (99.2 - 97.6) = 1.6 m3 Max expansion of volume including the process upset = (10.5+1.6) = 12.1 m3 can be accommodated within the 20% margin. So design is adequate.

Let’s select an expansion vessel of configuration 2.2 m (ID) x 7.6 m (L) for this service. An L/D ratio of more than 3 is considered in the selection. 8

We need to ensure that the design expansion volume should be accommodated within the operating liquid levels i.e. HLL and LL. Levels are adjusted within the controllable range to accommodate the desired liquid volume.

Volumes within the levels are calculated by adding part volume of cylinder and head. Part area of cylinder between BTL and LLLL = D2/8(2α-sin 2α) where α = cos-1((D/2-LLLL)/ (D/2)) Part volume of cylinder = D2/8 (2α-sin 2α) L where L = length of cylinder Part volume of the head (2: 1 SE) = π/2(DH2/2 – H3/3) Similarly volume occupied between all the levels are calculated

and tabulated below,

Table 2: Liquid levels to check design volume within the selected dimensions Total volume

Levels

Height (m)

Diameter

2.2

30.28

HHLL

1.76

26.03

HLL

1.55

22.85

NLL

0.82

10.25

LLL

0.66

7.59

LLLL

0.15

0.87

m3

The above calculation shows that between HLL and LLL a volume of 15.26 m3 is provided which is sufficient for the calculated expansion volume with margin (12.6 m3). Thus the selected diameter and length of expansion vessel are suitable to meet the design requirement. Normal level is based on expansion volume for design case since vessel will be operating at 2100C max however it can lie anywhere between HLL and LL preferably at 50% of the range depending on the operating conditions.

Hot oil circulating pumps: Hot oil circulating pumps are centrifugal pumps 1 X 100% typically arranged as 1 working + 1 stand-by unless there is a clear justification for 3 X 50 % capacity to maintain the closed loop 9

circulation through fired heater or WHRU or in combination of both as per project requirement. Flow rate of this pump is designed based on heat duty of all the consumers typically all the reboilers. 10% margin is applied on total calculated flow rate. For line sizing refer Table 8. If continuous filtration is applied via a bypass across the pump (10% of total flow max), the capacity of the pumps should include this additional flow. In the event of low hot oil pressure, the spare pump should take over automatically. The stand-by pump should be maintained in a pre-heated state in order to avoid thermal shock when starting by providing the bypass across the discharge check valve. Due to prolonged operation, hot oil may degrade generating some lower boiling point components which lead to higher vapour pressure of the hot oil in the system than the pure hot oil as specified by the manufacturer. The rise in vapour pressure lowers the NPSHa. To determine the NPSHa to the pump, it is assumed that the vapour pressure of the hot oil is equal to the pressure in the expansion vessel at normal operating temperature. If necessary, the height of the drum is raised to ensure that there is sufficient NPSHa. While calculating NPSHa, it is wise to keep 1 meter margin to account for any unforeseen pressure loss. NPSHr is specified by the pump manufacturer and should be less than NPSHa by at least 1-2 ft margin. Discharge pressure of the pump is obtained by summing up expansion vessel pressure and all the pressure drops incurred in the discharge line including line, fittings, equipment and valves. A general condition applies to all pumps to be capable of cold filling of the system.

Hot oil filters: Organic HTFs degrade over time due to thermal cracking, oxidation and contamination. The byproducts of degradation are sludge and coke. Contaminates can also include dirt, sand, dust, mill scale, and slag from piping that accumulate during down-time maintenance or from installation. Often a Y type or basket type strainer is installed at the pump suction. Typically the strainer contains 100 mesh size stainless steel woven wires. These are designed to protect the pump and flow meter. Installing filter in the loop has following benefits •

Removal of particulates that can degrade the oil



Maintains viscosity of fluid longer by reducing sludge build-up



Maintains thermal efficiency of system longer and reduces energy cost



Extends HTF life 10



Reduced maintenance costs by protecting pumps and valves from contaminates

The strainer should be cleaned regularly to prevent pump cavitation which can cause mechanical seal failure. For continuous filtration purpose, hot oil loop generally is provided with 1 X 100% filter in 1 working + 1 stand by arrangement at a side stream bypass line around circulation pump discharge. A partial flow rate up to 10% max is routed through the filter to screen thermal degradation product. A differential pressure indicator across the filters in the bypass line is fitted to monitor fouling in the system. Filters need to be equipped with 75 µm to 100 µm elements during commissioning and initial operation, and subsequently these are replaced with 10 µm to 20 µm elements unless the hot oil manufacturer of makes more stringent recommendations or project has a different requirement.

Hot oil start up pump: 1 X 100 centrifugal pump without any stand by is provided in case WHRUs are used as heat source in the closed loop hot oil system. This pump is supplied power from emergency diesel generator as it is required to maintain a small circulation flow through WHRU coils before the GTGs start. This is an essential requirement as WHRU coils are not advisable to run dry while GTGs are running because of thermal damage possibility. This pump is sized to cater to 5% (max) of total system flow rate in order to maintain a velocity of about 1 m/sec and should have same discharge pressure to that of circulation pump.

Fired heater and WHRU: Generally natural draft or mechanical draft (induced or forced) fuel gas fired heater is used as heat source in the hot oil system. If fired heater is the only heat source in the loop then its duty is calculated summing up all the consumers’ duty with a design margin of 10-15%. A heater efficiency of 80 - 85% is considered to figure out design heat duty. In some cases, fired heater may be required as only as stand by when most of the heat input into the system is recovered from heat recovery coils in flue gas stack of GTG. Flue gas leaves GTG stack at a very high temperature (500 – 600°C) and by controlling flue gas damper opening, this heat can be utilized in the hot oil loop. When WHRU coils are the prime source of heat, heat recovery coils are sized based on operation philosophy of the GTGs. Following calculation illustrates estimation of fired heater heat load. 11

Heat load of fired heater The following hot oil consumers are identified in a typical onshore oil and gas plant. The heat loads are calculated in HYSYS and listed below. All the designed figures include 10% margin unless otherwise specified.

Table 3: Heat load of hot oil consumers Equipment

Thermal Load, kW Normal Design

Stabilizer reboiler

1066

1173

Deethanizer reboiler

2821

3103

Debutanizer reboiler

1569

1726

550

605

6006

6607

Molecular sieve regeneration gas heater and regeneration gas super heater Total

So, total heat duty of the fired heater is 6607 kW. The heat duty will proportionately increase if there are parallel production trains. Consequently separate fired heater may be required if the total heat requirement cannot be met by a single heater. Fuel gas requirement to fired heaters can be estimated as follows. Consider, low pressure fuel gas is available at 5 barg pressure and 450 having LHV of 44380 kJ/kg. The LHV depends upon the fuel gas compositions and various simulation cases need to be analysed to find out the lowest LHV to be considered for the design case. Assuring 85% thermal efficiency of the heater, fuel gas flow requirement is (6607 x 3600)/(44380 x 0.85) = 630.5 kg/hr

Hot oil trim cooler: In order to improve operation and increase the flexibility of the hot oil system, a trim cooler is installed in the loop. This cooler serves the purpose of rejecting heat during heater start-up or when consumer duties in the loop suddenly reduce because of decrease in plant throughput or some inadvertently caused mal-operations. Typically, an air-cooled heat exchanger is selected. The cooler should be capable of rejecting the minimum heater duty at stable operation (heater 12

turn-down is ~ 25%, usually specified by the manufacturer) or highest process consumer duty in the system, whichever is more. Flow rate through cooler can be estimated by the oil temperature at cooler outlet which is normally fixed at 600C. In addition to 10% margin on flow rate, 10% margin on thermal duty should also be provided by means of surface area.

Heat Exchangers (Process consumers): In systems with heat users operating at pressures above that of the hot oil system, the piping design should take into account of all hazards caused by a tube rupture inside this equipment. Hot oil distribution headers and piping to consumers are sized for 110 % of the maximum flow. The spill over lines and control valves are sized for the flow of the largest consumer to allow for a sudden block-off of the heat user. Manual bypass lines are sized for 100 % flow. The following usually apply except for double-pipe heat exchangers: If the process pressure exceeds the hot oil system pressure, the preferred arrangement is to ensure a free flow (no valves) from the consumer (heat exchanger) to the expansion vessel. If valves are installed, the following alternatives may be applied: •

The hot oil system is designed for the higher pressure (2/3rd rule)



Overpressure protection devices (safety relief valves or rupture disks) are installed at the outlets of the affected heat exchangers with relief to flare via a liquid separator.

If designed and operated properly, hot oil systems can be considered to be non-fouling, so Utube type heat exchangers may be applied if the hot oil flows inside the tubes. This is cheaper than floating head type heat exchangers and significantly reduces the risk of leakage and, consequently, contamination of the hot oil or process fluid. For the design specification of hot oil systems a fouling resistance of 0.00017 m2/kW is taken. Effects of leakage of hot oil into the process or vice-versa are reviewed and double welded tube-to-tube sheet connections are specified, if required. All heat exchangers are equipped with hard piped drains and vents to allow the hot oil to be drained into the drain drum. To speed up the evacuation, a nitrogen purge point is installed to allow a hose connection from a nearby utility station.

Hot oil storage tank: The hot oil storage tank is sized to have a working volume equal to the full inventory of the system (pipe volume as per plant lay out, fired heater/WHRU coil volume and heat exchanger 13

hold up), plus an additional 10 % volume to accommodate make-up of losses caused by venting and mechanical leaks. On plants with multiple parallel trains it may be justified to reduce the storage tank capacity to hold the inventory of a single train only unless it is feasible that these trains must be drained at the same time.

The minimum fluid level in the tank is set to ensure sufficient NPSH for the make-up pump. If the ambient temperature falls below the hot oil minimum pumpability temperature, it may congeal and plug the pipelines. Special design considerations need to be applied for such congealing service. In this circumstance, the tank is heated, preferably electrically, and the suction line to the pump is heat-traced. The storage tank is equipped with inert (nitrogen/fuel gas) gas blanketing with self-actuating PCVs connected to flare or vent to atmosphere at safe location to serve as a barrier between the fluid and the atmosphere to limit aging (oxidation) and moisture ingress.

During shipment, air bubbles can be entrained in the fluid. If the cold fluid is immediately pumped into the system, the air bubbles can cause pump cavitation. It is advisable that the fluid should be near room temperature prior to charging the system. The drums may be stored in a warm room to bring the fluid up to room temperature. The warmer the fluid, the more easily it can be pumped into the system. A complete spare hot oil inventory should be made available to replace a total loss of hot oil from the system due to leakage or contamination by a process fluid.

Hot oil make-up pump: 1 X 100% centrifugal pump without any stand by is provided for hot oil make up service. This pump should fill up the entire hot oil system from hot oil storage tank. The pump is sized for complete fill up of the system within 8 hours to 24 hours (max). In case, hot oil storage tank is not in the scope of the project then hot oil sump pump should act as make up pump. Discharge head of the pump is estimated based on the elevation of the expansion vessel.

Hot oil drain drum and drain system: A hard piped dedicated closed drain system for maintenance purposes is provided. The purpose of a hot oil drain system is to collect hot oil inventory in a controlled manner from piping and 14

equipment prior to maintenance so that it can be returned later to the system for re-use or controlled disposal, as required. Since drainage of hot oil in hot condition to the drain drum is not envisaged, it is cooled prior to entering the storage drum by the run down cooler or via the process. The hot oil inventory can be cooled by alternative means such as with a column reboiler on hot oil with the column operating on total reflux and thus using the overhead condenser as indirect means of cooling the hot oil in the system. In systems with a fired heater, the combustion air fans can be used to cool down the furnace while hot oil is circulated through the heater tubes.

A drain system is intended to reduce spillage of hot oil, which could lead to HSE incidents. The drain piping should be installed underground and be free flowing to a closed collection vessel. Because the installation of drain piping is underground, the drain system is solely for the collection and draining of cooled down hot oil. The drain header is routed as close as possible to the drain points to reduce the length of small bore drain piping. Where a free flow of drained hot oil is not feasible, then an above ground nitrogen purge assisted drain line may be considered. A suitably sized vent is made on the collecting drum to vent the nitrogen to safe location at atmosphere or to flare. The collection drum is normally inert gas (nitrogen/fuel gas) purged to avoid ingress of air and/or moisture from the flare, and be located in a (dry) pit for secondary containment. The collection drum is sized to receive the hot oil volume from the largest consumer or group of consumers in the loop that can be taken out of service at the same time with margin (25% max). The collection vessel is provided with a pump for returning the hot oil to the hot oil storage tank or into main system itself in case hot oil storage tank is not in project’s scope. A connection is provided for vacuum truck to empty out the drum for hot oil disposal. If the collection vessel is also used for make-up of fresh hot oil into the system from storage drums, a filling connection is made available for connecting a portable drum unloading barrel pump. This connection may be combined with vacuum truck connection.

Hot oil sump pump: Hot oil sump pump is a vertical submersible 1 X 100% centrifugal pump placed inside the hot oil drain drum. In case, hot oil storage tank is not in the scope of the project, the sump pump can be utilized as the make-up pump and will follow the same sizing basis.

15

Line sizing: To design the circulation loop hydraulics, total hot oil flow rate needs to be estimated. Consider the following physical characteristics of the commercial Shell Thermia B HTF (Table 4). Supply temperature of the hot oil is fixed at 2600C (Tsupply), little above fire point ensuring that maximum heat transfer is possible without degrading the quality subject to maximum permitted bulk temperature. Table 4: Physical characteristics of Shell Thermia B HTF Density at 15 deg C Flash point PMCC Flash point COC Fire point COC Pour point Kinematic viscosity at 0 deg C at 40 eg C at 100 deg C at 200 deg C Initial boiling point Autoignition temperature neutralization value Ash (Oxid) Carbon residue (Conradson) Copper corrosion (3h/100 deg C) Coefficient of thermal expansion

Unit kg/cu.m deg C deg C deg C deg C

Standard ISO12185 ISO2719 ISO2592 ISO2592 ISO3016

property values 868 210 220 255 -12

sq.mm/s

ISO3104

230 25 4.7 1.2

deg C deg C mgKOH/g %m/m %m/m

ASTM D86 DIN 51794 ASTM D974 ISO 6245 ISO 10370 ISO 2160

1/deg C

>355 360
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