Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
  • F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
  • F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
  • F02C7/22—Fuel supply systems
  • F02C7/236—Fuel delivery systems comprising two or more pumps
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
  • F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
  • F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
  • F02C7/32—Arrangement, mounting, or driving, of auxiliaries

Definitions

• the invention relates to the fuel circuits of aircraft engines. It relates in particular to the fuel supply of helicopter turbine engines. STATE OF THE ART
• HP high pressure
• LP low pressure centrifugal pump
• the presence of air can be observed during the first following restart.
• an air leak when the engine is off can occur at the seals. dynamic or semi-dynamic or valves.
• the presence of air is observed when the engine is first started in the morning.
• the presence of vapor it can result from the vaporization of the fuel during the restarting of a hot engine in the presence of a volatile fuel.
• the presence of air or a vapor phase in the fuel circuit prevents, delays or can interrupt the supply of fuel during the start, compromising the success of the start.
• aircraft manufacturers may wish to dispense with providing a pumping member at the level of the tank even if the column of fuel going from the tank to the engine risks being initially empty. This request is made in particular for small and medium-sized motors. In other words, the motors must be self-priming. Aircraft manufacturers may also wish to dispense with a return line to the tank. An object of the invention is therefore to dispense with a pumping device in the fuel tank, or even a return line to the tank.
• a liquid fuel supply system for an aircraft engine comprising: - a fuel tank, - a suction pipe connected to the tank and located higher than the tank,
• a supply pump configured to be mechanically driven by an accessory relay box and to be connected at the output to a fuel supply circuit of the engine
• the electric pump being in communication with the suction duct independently of the supply pump, and with the drain, the supply pump being in communication with the suction duct independently of the electric pump.
• the electric pump is able to evacuate the gas found in the fuel circuit if necessary, upstream of the supply pump.
• This electric pump is driven by an electric motor independent of the rotation of the gears of the accessory relay box driven by the rotation of the high pressure (HP) shaft of the turbomachine. It can therefore in particular be actuated before starting the turbine engine, so that the fuel pumped by the supply pump at the time of starting is free of gas bubbles. Under these conditions, it is no longer necessary to provide a pump in the tank itself to evacuate the gas before starting the turbomachine. It can be noted that the device, once the air has been evacuated, does not reject liquid towards the drain.
• the invention allows a saving in weight in the aircraft. It reduces the risk of false starting or related to maintenance operations. It requires a hydraulic connection at two points of the fuel circuit but without causing stress on the latter and in particular its pumps. This solution also eliminates design constraints that usually apply to the low pressure pump, if present, and to certain hydromechanical regulators (hydromechanical unit or HMU in English).
• the invention can easily be adapted to existing engines. This purge device does not necessarily require power electronics. The drain stays dry. It is also observed that, thanks to the arrangement of the invention, the electric pump is segregated from the main fuel circuit and therefore cannot disturb the latter.
• the invention eliminates the need to perform engine ventilation after a maintenance operation to recondition the fuel system.
• the supply circuit in the case of a helicopter, comprises, from upstream to downstream with reference to the flow of fuel, a tank, a low pressure pump, a filter and a high pressure pump, the tank being located higher than the filter.
• the electric pump can then be attached to the main filter to form a single block.
• a low-pressure pump is thus provided upstream of the filter, it will preferably (even necessarily) be a centrifugal pump: this pump, even when stopped, must be permeable to the liquid to allow the electric pump to suck up the fuel of the reservoir.
• a volumetric pump for example with gears stopped is almost not permeable to the liquid.
• the invention may also have at least one of the following characteristics: - the suction pipe is connected to the tank by means of a pipe which extends continuously upwards from the tank;
• the system comprises an air/liquid separation chamber arranged fluidically in series between an outlet of the electric pump and the drain; - a valve with a hydraulic fuse function is arranged fluidically in series between an outlet of the air/liquid separation chamber and the drain, the valve being configured to close when liquid fuel enters the valve;
• the valve is configured to close when a pressure difference between an upstream end of the valve, with reference to a direction of a flow of fuel in the system, and a downstream end of the valve is greater than a predetermined threshold ;
• the system comprises a valve extending in a conduit forming a bypass with respect to the electric pump, the valve being configured to allow communication when the electric pump is subjected to a pressure difference which exceeds a predetermined threshold;
• the system comprises a non-return device configured so that no gas or liquid can enter the electric pump from a pipe located downstream of the electric pump, with reference to a direction of a flow of fuel in the system, when the electric pump is stopped, the device being for example separated from the valve or integrated into the valve;
• the electric pump is located at a highest point of a part of the fuel circuit extending upstream of the supply pump with reference to a direction of a flow of fuel in the system; and - the supply pump forming a first supply pump, the system comprises a second supply pump extending upstream of the electric pump with reference to a direction of a flow of fuel in the system.
• an aircraft comprising an engine, such as a turbomachine, configured to be supplied with fuel by a system according to the invention, the engine comprising a high-pressure shaft configured to be driven in rotation by the combustion of the fuel and to drive the feed pump.
• an engine such as a turbomachine
• the engine comprising a high-pressure shaft configured to be driven in rotation by the combustion of the fuel and to drive the feed pump.
• an electric engine pump pumps fuel from a tank located on board the aircraft and evacuates gas through a drain, and - independently of the electric pump, the pump supply pumps fuel from the tank and powers the engine.
• FIG. 1 is an axial sectional view of an aircraft turbojet engine according to a mode of realization of the invention
• FIG. 2 is a perspective view of the box of accessories of the turbojet of Figure 1;
• FIG. 7A to 7C illustrate three stages of the operation of a valve in another embodiment
• - Figure 8 is an axial sectional view of a detailed embodiment of such a valve.
• an aircraft turbojet engine 2 according to one embodiment of the invention, here double body. It extends around a main longitudinal axis X-X. It comprises a high pressure shaft 4 and a low pressure shaft 6. It comprises from left to right, that is to say from upstream to downstream with reference to the flow of gas which flows in the main vein in operation in the turbomachine: a fan 8, a high pressure compressor 10, a combustion chamber 12, a high pressure turbine 14 and a low pressure turbine 16.
• the high pressure shaft 4 is configured to be driven in rotation by the combustion of a fuel.
• the turbojet engine comprises a radial shaft 20 engaged with the high-pressure shaft 4 in a manner known per se in order to be driven in rotation by the latter. It also includes an accessory relay box 18 shown in Figure 2 with some equipment in place.
• the housing comprises a transfer shaft 22, parallel to the main axis XX, remote from the latter, and driven in rotation by the radial shaft 20. From the power take-off at the heart of the engine and via the radial shaft 20 and the transfer shaft 22, the accessory relay box 18 drives and supports in a manner known per se equipment such as fuel pumps, electric generators, a lubrication unit, a starter , an oil separator and other components that make up all of the aircraft's auxiliary engine and power generation equipment.
• the turbojet fuel supply circuit and in particular the components of this circuit, some of which are carried by the accessory relay box 18.
• the circuit comprises a suction duct 24 (FIG. A), a drain 26 (FIG. 5) and a downstream supply duct forming an outlet 28 (FIG. 4) each opening outside the casing.
• It also comprises in this case a low-pressure feed pump 30 and a high-pressure feed pump 32. These two pumps are driven in rotation by the axial secondary rotor 22 in a manner known per se and which will not be detailed here.
• the circuit also comprises a priming device 34 comprising in particular an electric pump 36 serving to initiate the pumping of the fuel.
• the aircraft is also equipped with at least one fuel tank 40 located outside the turbine engine and illustrated in FIG. 4.
• the main arrangement of the fuel circuit is illustrated in FIGS. 3 and 4.
• the low pressure pump 30 is in communication with reservoir 40 by conduit 42 through conduit 24. Conduit 42 extends continuously upward from the reservoir.
• the regulator 48 which constitutes a fuel metering unit, then through a flow distribution member 50 for the injectors, and finally to the injectors 52 of the turbojet engine.
• the following components are therefore arranged in series in this circuit in this order from upstream to downstream by reference to the direction of fuel flow in the circuit: the low pressure pump 30, the heater 44, the filter 46, the high pressure pump 32, the regulator 48, the distribution device 50 and the injectors 52.
• the regulator 48 is also connected by a return line to the fuel circuit upstream of the heater 44 in order to return the excess fuel pumped into the circuit. As a variant, the return can also take place downstream of the heater.
• the ignition device 34 is connected to the heater 44, downstream of the latter, by a branch pipe 54 thus forming a branch with the pipe leading from the heater 44 to the filter 46. It is above all a question of connecting the device of priming 34 at a high point upstream of the high pressure pump 32; in Figure 5 the device is connected to a high point in the filter block upstream of the filter medium.
• the ignition device 34 is therefore located downstream of the heater 44.
• the same is true for the filter 46.
• the device and the filter are not downstream of each other.
• the low pressure pump 30 is located upstream of the electric pump 36. It is in communication with the pipe 24 independently of the electric pump 36. The same applies to the high pressure pump 32.
• the low pressure pumps and high pressure are configured to be rotated by the accessory relay box 18.
• Initiator 34 is in communication with an upstream input of filter 46.
• the electric pump 36 is here a small volumetric pump, also called a micropump.
• the electric pump is located at a highest point of a part of the fuel circuit extending upstream of the high pressure pump 32.
• the device comprises an air/fuel separation chamber 56 downstream of the electric pump 36. It may be a chamber operating by gravity and/or by cyclonic effect.
• the electric pump 36 is in communication with the conduit 24 and with the drain 26, each time independently of the low pressure and high pressure pumps.
• the pump 36 is preferably located in a local low point making it possible to keep it "wet” even in the event of an air intake, whatever its origin. Indeed, a wet pump generally performs better in air than a dry pump.
• the function of the air/fuel separation chamber 56 is to separate the air and the fuel so as to:
• the air/fuel separation chamber allows the liquid to be brought back by gravity to the pump.
• the separation chamber thus makes it possible to meet certain recommendations:
• the total volume of the pipe downstream of the pump 36 and of the separation chamber 56 must be greater than or equal to the volume necessary to drown the pumping device.
• the priming device 34 comprises a valve 58 with hydraulic fuse function arranged fluidically in series between an outlet of the air/liquid separation chamber 56 and the drain 26.
• the valve is configured to close when a pressure difference between an upstream end and a downstream end of the valve is greater than a predetermined threshold.
• Such a valve is known per se and can be arranged in different ways. Its principle of operation is illustrated for example with the support of the structure of FIG. 6.
• This valve here comprises a body 60 and an annular member 62 mounted to slide in the body and which comprises a central passage for the fluid.
• This passage 62 thus forms a movable orifice of the valve at a first opening of the latter.
• the valve also comprises a finger 64, one rear end of which is rigidly fixed to one end of the body and the other end, free, is oriented in the direction of the member 62.
• a spring 66 bears on the rear end of the finger on the one hand and on the sliding member 62 on the other hand so as to tend to move the latter away from the finger.
• the valve includes a side opening 67 extending opposite the spring and the finger. This opening is in communication downstream with the drain 26.
• the pass-through configuration of the valve is illustrated in the first view of Figure 6.
• the slider 62 is held away from the end of the finger 64 by the spring 66 so that fluid can enter the valve through the organ sliding and out through the side opening 67.
• the fluid therefore passes from upstream to downstream through the valve.
• the passing fluid is a gas, for example a mixture of air and fuel vapors expelled by the electric pump 36
• its passage through the sliding member 62 generates almost no pressure drop between the upstream and the downstream of the sliding member 62, so that the valve remains in its passing configuration.
• valve 58 When a significant quantity of essentially liquid fuel reaches the valve 58, which means that the liquid fuel has risen from the tank to the outlet of the electric pump 36 by expelling the air through the valve, the pressure drops of the liquid passing between the upstream and the downstream of the valve are such that a force is created on the sliding member 62. This force tends to move the sliding member 62 against the action of the spring 66 until it comes into abutment on the finger 64. The end of the finger then obstructs the orifice of the central passage of the member 62 and thus blocks the flow of liquid.
• the valve is found in non-passing configuration as shown in the second view of figure 6.
• the valve therefore has a hydraulic fuse function reacting to the passage of a liquid. It closes when a significant flow of liquid fuel appears in the valve.
• the threshold of the valve determined in particular by the diameter of the orifice of the central passage of the member 62 and by the calibration of the spring 66, is chosen so that the electric pump 36 is capable of expelling the air through the check valve (see below) without locking the valve.
• the electric pump 36 is capable of expelling the air through the check valve (see below) without locking the valve.
• the priming device 34 also comprises a valve 57, for example with ball and spring, ensuring a non-return function. Thus, it is configured so that no gas or liquid can enter the electric pump 36 from a conduit located downstream of the latter when it is stopped.
• the valve 58 and the valve 57 form a dispensing member.
• the valve can be integrated into the valve depending on the architecture chosen for the latter.
• valve inlet pressure is generally lower than PO, PO being the manometric height linked to the difference in height with the helicopter tank.
• the device 34 may also include a pressure relief valve 69 extending in a conduit 70 forming a bypass with respect to the electric pump 36.
• the bypass conduit therefore extends from the separation chamber 56 to the upstream inlet of the filter 46, in fluid parallel to the conduit comprising the electric pump 36.
• the valve 69 is configured to allow communication when the electric pump 36 is subjected to a pressure difference which exceeds a predetermined threshold. It therefore allows if necessary to limit the pressure once the valve is locked. It is optional.
• the electric pump 36 is started. This does not require the turbojet to be started.
• the electric pump 36 first pumps gas located in the pipe 42 connecting it to the tank, because if gas is there it is located at least at the top of the pipe 42 up to the junction between the pipe and the tank. suction pipe 24.
• the gas thus pumped passes through the low pressure pump 30, the heater 44, then the electric pump 36, the separation chamber 56 and finally the valve 58 and the valve 57 to be evacuated by the drain 26.
• the gas is pumped first. When there is no more gas, it is liquid fuel which is pumped until it reaches valve 58 where it generates an increase in pressure at the inlet of the latter which causes it to close.
• the electric pump 36 is then stopped, since the fuel supply circuit is then primed due to its filling almost up to the filter 46. It can therefore be seen that, independently of the low pressure and high pressure pumps, the electric pump pumps the fuel from the tank.
• the turbojet (or turbine engine) is then started to put the high pressure shaft 4 into rotation.
• the low-pressure and high-pressure pumps pump fuel from the tank to supply the turbomachine injectors, independently of the electric pump.
• FIGS. 7A-C and 8. Another embodiment of the valve 58' is illustrated in FIGS. 7A-C and 8. It can be used for example when the aircraft is a helicopter. This time, the non-return function is integrated into the valve.
• the valve 58 ' comprises a cylinder 80 having a front opening 82 and a rear opening 84.
• the fuel supply pipe 86 connected to the separation chamber 56 comprises a branch so that it communicates on the one hand with the front opening 82 and on the other hand with the rear opening 84.
• a restriction 88 or nozzle is interposed between the branch and the front opening 82.
• a piston 90 is slidably mounted in the cylinder 80 in which it defines a front chamber 92 capable of communicating with the front opening 82 when the valve 98 is open and a rear chamber 94 communicating with the rear opening 84.
• the drain 26 also opens laterally into the front chamber 92.
• the piston 90 is returned by a spring 96 at high pressure towards the rear opening 84, the spring resting on the one hand against the front end of the cylinder 80 and on the other hand against a shoulder of the piston.
• the spring 96 is for example chosen so that the piston 90 moves towards the front of the cylinder when it is subjected to a pressure difference of at least 100 kPa. It is the abutment of the valve 98 which stops the movement of the assembly forward.
• the piston 90 carries at its front end a valve 98 mounted to slide in the piston and biased towards the front end of the cylinder by a spring 100 with low calibration. The calibration of the first spring 96 is stronger than that of the second.
• the low-rate spring 100 is, for example, chosen so that the valve 98 opens when it is subjected to a pressure difference of at least 15 kPa.
• FIG. 7A illustrates the first position and corresponds to a stationary situation where the priming micropump 36 is not activated. The pressure of the fluid at the arrival of the micropump then being substantially equal to that (atmospheric) in the drain 26, the pressure difference exerted on the valve 58' is practically zero. The valve therefore remains closed.
• the piston 90 bears against the shoulder of the cylinder, without blocking the rear opening 84.
• the valve 98 for its part bears against the front end of the cylinder, so that the front opening 82 is closed and the drain 26 therefore does not communicate with pipe 86.
• the engine is stopped and the pressure at the inlet of the valve is generally lower than the PO, namely the manometric height linked to the difference in height with the tank of the helicopter.
• the second position corresponds to a situation where the micropump 36 is activated and the inlet fluid is essentially gaseous.
• the pressure of the gas delivered by the pump is sufficient to open the front opening 82 of the valve despite the presence of the restriction 88: the valve 98 moves to the right against the action of its spring 100.
• the gas pressure is insufficient for the gas present in the chamber 94 on the right to push the piston 90 to the left, the force of the spring 96 of the piston being preponderant.
• the front opening 82 of the valve therefore remains open and the gas can be evacuated into the drain 26.
• the third position corresponds to a situation where the micropump 36 is activated and the inlet fluid is essentially liquid.
• This 58' valve is therefore automatically locked by fuel and automatically unlocked by air.
• a detailed embodiment of this valve is shown in Figure 8.
• the valve 98 bears to the left against an O-ring 102 in the closed position.
• the passage of air to the drain, when the valve is open, takes place through an external longitudinal groove 104 made in the cylindrical body of the valve.
• the cylinder 80 is here formed in two parts 81, 83, namely a part 81 on the right in Figure 8 surrounding the piston 90 and a part 83 on the left which surrounds the front of the valve 98.
• the invention is also applicable to other types of aircraft engines, for example the internal combustion piston engines of small helicopters.
• the low pressure pump 30 and the heater 44 are not essential. Either or both could be deleted. If both are removed, the conduit 24 of the supply system is located just upstream of the junction between the main filter and the ignition device 34.

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• Engineering & Computer Science (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Details Of Reciprocating Pumps (AREA)
• Cooling, Air Intake And Gas Exhaust, And Fuel Tank Arrangements In Propulsion Units (AREA)
• Structures Of Non-Positive Displacement Pumps (AREA)

Applications Claiming Priority (2)

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• 2021
  • 2021-04-21 FR FR2104169A patent/FR3122220B1/fr active Active
• 2022
  • 2022-04-13 CN CN202280034338.1A patent/CN117295883A/zh active Pending
  • 2022-04-13 EP EP22722308.8A patent/EP4326976A1/de active Pending
  • 2022-04-13 WO PCT/FR2022/050698 patent/WO2022223907A1/fr active Application Filing

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