FR2935023A1 - FUEL FLOW DOSER - Google Patents

Abstract

The present invention relates to a metering device (22) for fuel flow. The invention is characterized in that it comprises a plurality of orifices (24a ... 24h) and a plurality of control pins (26a ... 26h) capable of closing said orifices, each of the control pins being movable separately from the other control pins between an open position in which the associated port is open and a closed position in which the associated port is closed.

Description

The present invention relates to the field of fuel supply of engines and in particular turbomachines. Traditionally, in an aircraft engine, such as a helicopter, fuel flow is regulated to maintain the engine in a predetermined operating range. For example, when the engine is a helicopter turbine engine, the main requirement is to obtain a single rotation speed, which is kept constant regardless of the torque applied to the rotor. To do this, the fuel flow must be metered. The present invention more particularly relates to a fuel flow metering device, preferably but not exclusively for a turbomachine, such as a helicopter gas turbine for example. Such a metering device is already known elsewhere. To regulate the flow of fuel flowing through a metering orifice, a control needle, associated with the orifice, is moved by a stepping motor so as to gradually decrease or increase the flow section through the orifice. In use, this type of metering has some disadvantages. First of all, it should be noted that the stepper motors are not very reliable and it happens that the engine pitch, although initially precalibrated, changes during severe operating conditions, for example when it is mounted in a turbomachine producing significant vibrations during its operation. This phenomenon distorts the regulation of the fuel because the control element of the control valve does not know a priori the new value of the pitch. It is conceivable that the occurrence of an offset between the setpoint and the flow rate obtained does not make it possible to correctly pilot the aircraft, which can be harmful. To overcome this drawback, a control member is generally provided for monitoring the operation of the stepper motor. This member is fixed to the motor to verify that the displacement of the control pin corresponds to the setpoint provided by the electronic control member. If this is not the case, the control member 35 corrects the setpoint signals as a function of the offset measured by the control member.

However, the management of the control and control elements generates an undesirable rise in temperature of the computers on board the aircraft. An object of the invention is to provide a simpler fuel flow metering dispenser overcoming the disadvantages mentioned above. The invention achieves its object by the fact that the dispenser according to the invention comprises a plurality of orifices and a plurality of control points capable of closing said orifices, each of the control needles being movable independently of the other control pins between an open position in which the associated orifice is open and a closed position in which the associated orifice is closed. Preferably, each of the control pins is movable only between said open position in which the associated port is open and said closed position in which the associated port is closed. In other words, the associated orifice can take only two states: open or closed. According to the invention, the regulation of the flow takes place by opening a more or less large number of orifices while closing off the others, depending on the flow rate that it is desired to obtain. It is clear that the more ports open, the greater the total passage area offered to the fuel flow is large so that the fuel flow increases accordingly. Advantageously, the surfaces of the orifices follow a law 25 of increasing variation. It follows that the flow rates of the orifices also follow a law of increasing variation. An interest is to be able to adapt the range of flow rates that the metering can offer to the operating characteristics of the engine. Indeed, by combining orifices with different flow rates, it is possible to obtain a wide range of possible flow rates with a reduced number of orifices. Preferably, but not exclusively, the orifices are dimensioned such that the flow of fuel to flow through each of the orifices is proportional to a power of 2.

In other words, each orifice (except the first) has a flow rate twice as large as the previous one. Preferably, each orifice (except the first) has an opening area twice as large as the previous one.

Thus, it will be possible advantageously to size the orifices so that the first orifice has a flow rate of one liter per hour, the second orifice a flow rate of two liters per hour, the third orifice a flow rate of four liters per hour, etc. Thanks to the present invention, it is therefore possible to obtain a very wide flow rate range with a reduced number of control needles, while avoiding step motors. For example, with eight orifices dimensioned as specified above, it is advantageously possible to obtain a flow rate range of between 0 liters per hour and 255 liters per hour with an increment of 1 liter per hour. Moreover, with nine orifices, it is possible to obtain a flow range ranging from 0 liters per hour to 511 liters per hour with a step of 1 liter per hour. According to an advantageous variant, each of the control valves is moved by an electromagnet of said metering device. They can also be moved by a piezoelectric actuator. Preferably, the fuel flow metering device according to the invention further comprises a plurality of springs associated with the control pins so that each of said control needles tends to be brought by the associated spring in the closed position when the electromagnet associated with the control point is not enabled. Moreover, the dispenser further advantageously has at least one position sensor for detecting the position of one of the control needles. This sensor therefore advantageously makes it possible to control whether the orifice 30 is open or closed, that from the position of the control needle. To do this, it is possible to use a Hall effect cell, a GMR or any other device allowing such a position determination. To reduce the volume of the dispenser, the latter may for example be arranged in such a way that the orifices are formed in the form of barrel. That is to say that the orifices are formed substantially in the same plane while being arranged along a circular line.

According to an advantageous variant of the invention, the dispenser according to the invention further comprises an emergency port associated with an emergency needle such that the emergency orifice is closed by the emergency needle during normal operation of the dispenser. while the emergency port is open in case of total failure. It is therefore understandable that thanks to the emergency opening, the engine continues to be supplied with fuel although the other orifices are closed by the control valves. This keeps the engine running.

To do this, the emergency needle is preferably actuated by an emergency electromagnet, and the dispenser further comprises an emergency spring cooperating with the emergency needle to bring it to the open position when the emergency electromagnet is not not activated.

The invention also relates to a system for regulating the fuel supply comprising a metering device according to the invention, an electronic control member of the metering device and an input for supplying the metering device with fuel. According to an advantageous aspect of the invention, the electronic control member is arranged to be cooled by the flow of fuel flowing through said inlet. For this purpose the control member may advantageously be arranged around the feed inlet so as to be cooled by the flow of fuel entering the dispenser. The invention further relates to a fuel supply circuit of a turbomachine comprising a regulation system according to the invention. Finally, the invention relates to a turbomachine comprising a fuel supply circuit according to the invention. The invention will be better understood and its advantages will appear better on reading the description which follows, of an embodiment indicated by way of non-limiting example. The description refers to the accompanying drawings in which: - Figure 1 is a schematic view of a fuel supply circuit of a turbomachine according to the invention; FIG. 2 shows a flow metering device according to the present invention comprising eight control points, three of which are in the closed position and five in the open position; - Figure 3 is a detailed view of a control valve of the dispenser according to the invention, the needle being shown with its electromagnet and the associated spring; FIG. 4 is a schematic view of a control pin of FIG. 2, in the open position and in the closed position; - Figure 5 is a sectional view of the dispenser according to the invention, where only one of the control pins has been shown, the latter not obturating the associated orifice; - Figure 6 is a sectional view of a variant of the dispenser according to the invention, the latter further comprising a relief needle, which is here shown in the open position while the control needle is in the closed position; and - Figure 7 is a variant of the feeder of Figure 5 in which the electronic control member is traversed by the fuel supply inlet. Traditionally, turbomachines, such as for example helicopter gas turbines, comprise a fuel supply circuit 10 such as that shown in FIG. 1. This schematic circuit 10 comprises a fuel tank 12 connected to one or more ) pump 14 for sending the fuel to an injection wheel 16 which comprises a plurality of injectors. As seen in this figure, the circuit 10 comprises a first ignition conduit 10a opening on igniters 18 for ignition of the fuel / air mixture in the combustion chamber. The supply circuit 10 further comprises a main injection conduit 1Ob opening into the injection wheel 16 and wherein the fuel flow Q is controlled by a fuel flow control system 20 according to the present invention.

This control system 20 comprises a fuel flow metering device 22 according to the present invention.

In the example represented here, it can be seen with reference to FIG. 2 that the metering device 22 comprises eight orifices 24a, 24h, and eight control pins 26a, 26b movable and able to close off said orifices. According to the invention, each of the control pins is movable independently of the others between an open position in which the associated orifice is open and a closed position in which the associated orifice is closed by said control needle. As seen in Figure 2, the orifices 24a..24h are formed on a thick disc 28 so as to have the shape of a barrel. This particular form has the advantage of being compact. In Figure 3, there is shown in more detail one of the control pins 26 and its associated orifice 24, the other pins being substantially similar.

The control needle 26 is in the form of a needle whose one end forms a conical tip intended to close off the orifice 24. The end opposite the tip carries a stop 32 against which a spring 33 comes in order to exert an axial force on the control pin 26, said force being directed towards the associated orifice 24. It follows that the spring 33 exerts a force tending to move the needle in its closed position in which the associated orifice 24 is closed. Each control pin 26 is further actuated by an electromagnet 34 which encloses it. This electromagnet, powered by an electronic control member 37, has a state of rest in which it exerts no force on the needle 26, as a result of which the needle is brought into its closed position by the spring 33. In contrast, when actuated, the electromagnet 34 exerts on the control pin 26 an axial force, opposite to that of the spring, which tends to bring it into its open position. The electromagnet 34 is chosen so as to be able to generate a force of intensity greater than that generated by the spring 33. It follows that when the electromagnet is activated, it counteracts the force of the spring 33 so that the control valve 26 moves to the open position.

It is therefore clear that the position of each control pin 26a..26h preferably corresponds to a binary state: open or closed. In the example shown in FIG. 2, the control valves 24a to 24e are in the open position, while the 24f control valves at 24 hours are in the closed position. This is also illustrated in FIG. 4 which shows the control needle 26 in its closed position (closed orifice) and in its open position (open orifice). In this example, the openings 14a..14h are dimensioned so that their surfaces follow a law of increasing variation so that their corresponding flows are proportional to a power of two, the coefficient of proportionality being in this case equal to one. . Thus, in this example: the flow rate Q1 of the orifice 24a is 1 liter per hour, the flow rate Q2 of the orifice 24b is 2 liters per hour, the flowrate Q3 of the orifice 24c is 4. liters per hour, the flow rate Q4 of the orifice 24d is 8 liters per hour, the flow rate Q5 of the orifice 24e is 16 liters per hour, the flow rate Q6 of the orifice 24f is 32 liters per hour, hour, the flow rate Q7 of the orifice 24g is 64 liters per hour, and the flow rate Q8 of the orifice 24 is 128 liters per hour. It is therefore understood that if only the orifice 24g is open, the others being closed, then the metering station sets the flow rate at 64 liters per hour. Similarly, if the orifices 24g and 24c are open, then the dispenser sets the flow rate to 68 liters per hour, and so on. It follows that, in this example, the range of flow rates dosable by the dispenser ranges between 0 liter per hour (all orifices are closed) and 255 liters per hour (all orifices are open), with an increment of 1 liter per hour. It will therefore be understood that each of the flow rates in this range is selected by actuating the appropriate control needles. With the help of Figures 5 to 7, will now be described in more detail the control system 20 and the metering device 22 according to the invention. In these figures, for the sake of simplicity, only one of the control pins 26a..26h is shown. It is called in the following: control valve 20 26.

As seen in these figures, each control pin 26 is also associated with a position sensor 36, in this case a Hall effect cell for detecting the position of the control pin 26.

Referring to Figure 5, it is found that the metering device 22 is housed in a first chamber 38 of the control system 20, which first chamber 38 is intended to be filled with fuel. The first chamber 38 is supplied with fuel via an inlet pipe 40 connected to the outlet of the pump 14.

In addition, the disk 28 comprising the orifices 24 separates the first chamber 38 from a second chamber 42 opening on a fuel supply line 44 of the regulation system, it being specified that said outlet pipe 44 is connected to the wheel of injection 16. In FIG. 5, the control valve 26 is shown in the open position, in which position the fuel can flow from the first chamber 38 to the second chamber 42 before exiting through the outlet 44 at a controlled flow rate. Q. The electromagnet therefore moves the control needle 26 in a direction opposite to the orifice 24 against the force exerted by the spring 33. In this example, it can be seen that the position sensor 36 is fixed on a wall 46 of the control system 20 in the axial extension of the end of the control pin 26 opposite the tip 30. Moreover, the spring 32 is mounted coaxially with respect to the control pin 26 in the right direction. while being supported on said wall 46 of the regulation system 20. The spring 32 therefore extends orthogonally from the wall 46. In this example, it can be seen that the sensor 36, the spring 33 and the stop 32 are also housed in the first chamber 38 so are also bathing in the fuel.

Furthermore, both the electromagnet 34 and the position sensor 36 are connected to the electronic control member 37 whose function is to control the control valves according to a flow instruction C. Referring to FIG. 6, an advantageous variant of the invention will now be described. In this variant, the flow meter 20 further comprises an emergency port 50 associated with an emergency needle 52 having an open position in which the orifice 50 is open and a closed position in which the emergency orifice is closed by the emergency needle. The emergency needle 52 carries at one of its ends a point 54 of conical shape adapted to close the orifice 50. However, unlike the tip 30 of the control pins 26, that the emergency needle 52 is disposed on a the side of the disc 28 opposite that against which the tips 30 of the control pins 26 are intended to bear.

Moreover, the end of the emergency needle 52 opposite the tip 54 also carries a stop 56 fixed to a backup spring 58. This emergency spring 58 bears on the wall 46 so that it tends to move the needle control 52 axially to the second chamber 42. Thus the emergency spring 58 tends, by its own action, to bring the emergency needle in its open position. The emergency needle 52 is in this case actuated by an emergency electromagnet 60 similar to the electromagnets 34 which are intended to actuate the control pins 26.

Thus, when activated, the emergency electromagnet 60 tends to axially move the emergency needle 52 to the wall 46. In other words, the emergency electromagnet, by its own action, tends to bring the emergency needle 52 in its closed position. The electromagnet 60 is chosen so as to be able to generate a force of intensity greater than that generated by the spring 58 as a result of which, when activated, the emergency electromagnet counteracts the force generated by the spring 58 and brings the emergency needle 52 to the closed position. Conversely, when it is not activated, the emergency spring brings the emergency needle 52 to the open position.

Advantageously, the emergency electromagnet 60 is activated during normal operation of the control valves 24a..24h, so that in normal operation of the dispenser, the emergency port 50 is closed. Conversely, in the case of a breakdown of the dispenser, for example in the event of a power failure, the electromagnets 34 of the control pins 26 and the electromagnet of the emergency needle 52 are deactivated, so that all the needles 26a..26h are brought into the closed position by the action of their associated springs and, conversely, the emergency needle 52 is brought into the open position by the action of the emergency spring 58.

Therefore, it is understood that in case of failure, a fuel flow Q 'is advantageously ensured even though the metering device 22 is out of service. This allows in particular to keep the engine on, admittedly in a degraded mode, despite a power failure occurring on board the aircraft. With the help of Figure 7 will now be described an advantageous variant of the control system. In this variant, the electronic control member 37 is disposed against the wall 46 while being traversed by the inlet duct 40 for supplying fuel to the first chamber 38. Thanks to this arrangement, the fresh fuel flow advantageously cools the electronic control member 37 which, like any electronic device, tends to heat up during use.

Claims (13)

REVENDICATIONS1. Fuel flow metering device (22) characterized in that it comprises a plurality of orifices (24, 24a ... 24h) and a plurality of control valves (26, 26a ... 26h) capable of closing off said orifices , and in that each of the control pins is movable independently of the other control valves between an open position in which the associated orifice is open and a closed position in which the associated orifice is closed. 2. fuel flow meter according to claim 1, characterized in that the surfaces of the orifices (24, 24a ... 24h) follow a law of increasing variation. 3. fuel flow meter according to claim 1 or 2, characterized in that the orifices (24, 24a ... 24h) are dimensioned so that the flow of fuel to flow through each of the orifices is proportional to a power of 2. 4. fuel flow meter according to any one of claims 1 to 3, characterized in that each of the control needle (26, 26a ... 26h) is moved by an electromagnet (34) of said metering device (22). 5. fuel flow meter according to claim 4, characterized in that it further comprises a plurality of springs (33) cooperating with the control pins (26) so that each of said control needles tends to be brought in the closed position when the electromagnet (34) associated with said control valve is not activated. 6. Fuel flow meter according to any one of claims 1 to 5, characterized in that it further comprises at least one position sensor (36) for detecting the position of one of the control pins (26a). ... 26h). 7. fuel flow meter according to any one of claims 1 to 6, characterized in that the orifices (24a ... 24h) are formed in the form of barrel. 8. fuel flow meter according to any one of claims 1 to 7, characterized in that it further comprises an emergency port (50) associated with an emergency needle (52) so that the orifice is blocked by the emergency needle during normal operation of the dispenser (22) while the emergency port is open in case of total failure. Fuel flow meter according to claim 8, characterized in that the emergency needle (52) is actuated by an emergency electromagnet (60), and in that the dispenser further comprises an emergency spring (58). attached to the emergency needle to bring it into the open position when the emergency electromagnet is not activated. A fuel supply regulating system (20) comprising a metering device (22) according to any one of claims 1 to 9, an electronic control member (37) of the metering device (22), and a metering duct (22). inlet (40) for feeding the fuel metering device. A fuel supply regulating system according to claim 10, characterized in that the electronic control member (37) is arranged to be cooled by the flow of fuel flowing through said fuel line. entrance (40). Fuel supply circuit (10) for a turbomachine comprising a regulation system (20) according to claim 10 or 11. 13. A turbomachine comprising a fuel supply circuit (10) according to claim 12.