FR3045837A1 - TEST ASSEMBLY IN FLIGHT OF AN ELECTRONIC POWER CHAIN OF AN AIRCRAFT COMPONENT - Google Patents

Abstract

The present invention relates to a testability assembly (200) in flight of an electronic power train (100) of an aircraft component, said component being activatable by a three-phase AC motor (5) powered by a three-phase AC electrical network. (3) of said aircraft. This set of testability is remarkable in that it comprises: - a power supply unit (201) of the electronic power chain (100), connected on the one hand to a low-voltage continuous network (7) of the aircraft and, on the other hand, to said power electronic chain (100) of the three-phase reciprocating motor (5) of said component; an electronic control unit (203) incorporating an algorithm for testing said electronic power train (100), said housing being connected on the one hand to said power supply box (201) and on the other hand to said electronic power supply chain; power (100).

Description

The present invention relates to an in-flight testability assembly of an electronic power train of an aircraft component. The invention also relates to an "ENU" housing incorporating such an assembly, as well as to a nacelle and to an aircraft comprising the testability assembly of the invention.

An aircraft is driven by several turbojet engines each housed in a nacelle also housing a set of ancillary actuating devices related to its operation and providing various functions when the turbojet engine is in operation or stopped. These auxiliary actuation devices include, in particular, a mechanical thrust reversal system and a variable nozzle system.

The role of a thrust reverser is, during the landing of an aircraft, to improve the braking capacity thereof by redirecting forward at least a portion of the thrust generated by the turbojet engine. In this phase, the inverter makes it possible to return to the front of the nacelle all or part of the gas flows ejected by the turbojet engine, thereby generating a counter-thrust which is added to the braking of the wheels of the aircraft. .

The means implemented to achieve this reorientation of the flow vary according to the type of inverter. However, in all cases, the structure of an inverter comprises movable covers movable between, on the one hand, an extended position in which they open in the nacelle a passage intended for the deflected flow, and on the other hand, a position retraction in which they close this passage. These mobile hoods may furthermore perform a deflection function or simply the activation of other deflection means.

In the grid inverters, for example, the movable hoods slide along rails so that when backing up during the opening phase, they discover deflection vane grids arranged in the thickness of the nacelle . A linkage system connects the movable hood to blocking doors that expand within the ejection channel and block the output in direct flow.

In the door reversers, each movable hood pivots to block the flow and deflect and is therefore active in this reorientation.

Furthermore, an aircraft comprises in known manner two electrical networks: a three-phase alternating electrical network provided by several variable frequency generators coupled to the high pressure stage of each turbojet, delivering an output voltage of 115 volts or 230 volts, and a continuous electrical network delivering a DC voltage of 28 volts.

Various components of the aircraft operate thanks to the three-phase AC mains. These components include for this purpose a three-phase electric motor powered through a power converter by the three-phase AC network of the aircraft. As an example, the components that are powered by the aircraft's three-phase electrical network are the thrust reverser hood electric actuators of a turbojet engine nacelle, the electric reverser hood locks actuators intended for to prevent the opening of the reversing hood when the aircraft is in flight, the movable secondary column variable nozzle electric actuators of a nacelle, the electric landing gear deployment system, etc.

In a converter, the electronic power chain generally used to power a three-phase electric motor of a component of the aircraft is as follows: the 115V reciprocating network of the aircraft feeds an autotransformer-rectifier circuit which delivers a DC voltage constant, which is then sent to an inverter that generates a three-phase signal supplying the three-phase electric motor of the component to be actuated. These circuits are themselves connected to an electronic control unit (incorporating a function "BITE" for "Built In Test Equipment"), set to test the power chain when the aircraft is in the maintenance phase on the ground. In a known manner, the control box incorporating a "BITE" function makes it possible to sequentially search for the most probable failures of the components of the electronic power chain (such as the presence of short circuits, open circuits, blocked switches in open or closed position, etc.).

In order to limit the risks of inadvertent activation in flight of the components of the aircraft powered by the aircraft's 115V reciprocating network, this network is made available by the aircraft manufacturer only when the aircraft touches the ground. Indeed, the inadvertent actuation of certain components of the aircraft in flight, such as that of the movable thrust reverser cowl, could prove catastrophic. The permanent "non-availability" of this alternative three-phase network of the aircraft makes it possible to constitute one of the lines of defense imposed by the aircraft manufacturers.

In the case of a nacelle thrust reverser actuator, the aircraft's 115V reciprocating network which supplies the three-phase electric motor of this actuator is only available when the aircraft touches the ground, thanks to a system called "Weight On Wheel" in English terminology, permitting the issuance of an alternating voltage of 115 Volts electronic power trains driving three-phase motors of all actuators of the thrust reverser as soon as said system detected the aircraft's contact with the ground. When the aircraft has landed and when the pilot controls the deployment of the thrust reversal system, the aircraft's 115V AC mains delivers the desired current to the actuator motors, which actuators actuate and lengthen the actuators. deployment of the inverter cover (s).

In the event of a malfunction of the electronic power train of one of the actuators of the thrust reverser device, the pilot detects this failure when it commands the deployment of the reverser, that is to say the ground, or when the plane has landed. The same applies to all the other components of the aircraft powered by the aircraft's three-phase AC system, which can only be activated when the aircraft lands.

This situation is uncomfortable for the pilot because he can not anticipate a malfunction of the aforementioned components before the plane has landed.

The present invention aims to detect a failure of the electronic power system of a three-phase AC motor of an aircraft component, when the aircraft is in flight and without actuating said component.

To do this, the present invention relates to a set of testability in flight of an electronic power chain of an aircraft component, said component being activatable by a three-phase AC motor powered by a three-phase AC electrical network of said aircraft, said testability assembly being remarkable in that it comprises: a power supply unit of the electronic power unit, connected on the one hand to a low-voltage continuous network of the aircraft and, on the other hand, to said three-phase alternating motor power electronic chain of said component; an electronic control unit incorporating an algorithm for testing said power electronic chain, said box being connected on the one hand to said power supply box and on the other hand to said power electronic chain.

Thus, by providing a power supply unit of the electronic power unit of a component of the aircraft, connected to the DC low voltage source of the aircraft, the housing uses a test voltage which makes it possible to generate stimuli in the electronic engine power chain, which stimuli can test in flight the availability of certain components of the aircraft, without actuating them. The pilot can therefore, in flight, have information on the functionality of certain components of the aircraft. By testing their functionality shortly before landing, the pilot can make a decision in the event that a component is not functional, such as that of landing on an airstrip that would be more suitable for certain types of failures of certain components.

In addition, by providing a housing for generating an isolated test voltage with respect to the operating voltage of the electronic power supply chain supplying the engine of a nacelle component, the electronic power chain, connected to the AC network. three-phase plane, is not changed. This advantageously makes it possible to constitute a very easy solution to implement in the existing control devices.

The low-voltage continuous network of the testability assembly according to the invention is a 28-volt continuous network. Of course, the output voltage of the continuous network can be adapted at will.

According to an advantageous arrangement of the invention, the electronic control unit is connected to a switch of the power supply unit, said switch being intended to be connected to the mass of the aircraft. The power pack of the testability assembly includes a galvanic isolation to not spread fault between the low-voltage and AC three-phase continuous networks of the aircraft. Thus, by providing for connecting the electronic control unit to a switch of the power supply unit, which switch is intended to be connected to the ground of the aircraft, the testability assembly of the invention makes it possible to detect the currents of the leak in the electronic power chain.

Preferably, the testability assembly of the invention comprises means for connection to an in-flight testability control unit.

The present invention also relates to a housing comprising an electronic power chain of a three-phase AC motor of an aircraft component, characterized in that it further comprises a testability assembly according to the invention supplying said electronic power chain. in continuous low voltage.

Advantageously, the housing of the invention comprises at least one high voltage diode at the output of the power supply unit of the testability unit.

The present invention also relates to a nacelle for an aircraft turbojet engine comprising a thrust reverser device, said thrust reverser device comprising: a cover, movable between an extended position in which said hood opens a passage in said thrust reverser device; nacelle and a retracted position in which said cover closes said passage; at least one actuator able to move said cover alternately between said retracted and deployed positions, said actuator being controlled by a three-phase AC electric motor driven by an electronic power chain capable of being powered by a three-phase AC electrical network, said basket; being remarkable in that it further comprises a testability assembly according to the invention, supplying said electronic low-voltage power chain, and being connected to said electronic power chain via the control box.

Finally, the present invention relates to an aircraft comprising a component controlled by a three-phase AC electric motor driven by an electronic power chain capable of being powered by a three-phase alternating electrical network, remarkable in that it further comprises a testability assembly according to the invention. invention, supplying said electronic power chain with low continuous voltage, and being connected to said electronic power chain via the control box. Other features, objects and advantages of the present invention will appear on reading the following description and on examining the appended figures in which: FIG. 1 represents a housing incorporating a testability assembly according to FIG. invention; - Figure 2 illustrates an alternative embodiment of the housing of Figure 1; FIG. 3 is a diagram illustrating an in-flight test control of an actuator of a turbojet nacelle thrust reverser.

Throughout the figures, identical or similar references represent identical or similar organs or sets of members.

Referring to Figure 1 which shows a housing 1 or housing "ENU", acronym for "Electrical Nacelle Unit" designating the control device and control of one or more motor (s) alternative ( s) three-phase (s) driving one or more components integrated into a turbojet nacelle. These components can in particular designate, by way of example, electric thrust reverser cowl actuators, variable section nozzle section electrical actuators, door thrust reverser door electric actuators, electric actuators of the primary, secondary or tertiary reversing hood locks to prevent the opening of the reversing hood when the airplane is in flight.

In known manner, the housing 1 comprises an electronic power chain 100 powered by the three-phase AC electrical network 3 of the aircraft, 115 Volts. The electronic power chain 100 can, however, be powered by the three-phase AC mains network of the aircraft, which can also deliver 230 volts. The electronic power chain 100 powers an electric machine such as a motor 5 of a nacelle component, for example a turbojet nacelle thrust reverser hood actuator.

The electronic power chain 100 comprises an autotransformer-rectifier circuit 101, often designated by the acronym "ATRU" for "Auto-Transformer-Rectifier Unit", defining a filter stage harmonic currents and a circuit 103 inverter mounted in series with the autotransformer 101.

The autotransformer-rectifier circuit 101 typically comprises an autotransformer 1011, comprising a primary winding and two secondary windings, and a rectifier circuit 1013 comprising two rectifier bridges comprising six diodes each. Of course, the autotransformer-rectifier circuit is not limited to the circuit diagram proposed here by way of example only, but it should be understood that it can be used any autotransformer-rectifier circuit for delivering a constant DC voltage to the circuit inverter 103.

The inverter circuit 103 comprises a capacitor 1030, a resistor 1031 connected in parallel with the capacitor, a switch 1032 connected in series with the resistor, and three switch arms 1033, 1034, 1035 connected in parallel with the resistor. The inverter circuit further comprises a plurality of current and / or voltage sensors of the power electronics chain. Five sensors 1036, 1037, 1038, 1039 and 1040 are shown in FIG. 1. Of course, the inverter circuit is not limited to the electric circuit proposed here given solely by way of example. It can include a distinct number of sensors, depending on the data that you want to acquire. In fact, any inverter circuit capable of generating a three-phase electrical signal supplying the motor 5 of a component of the nacelle, the motor 5 being connected in series at the output of the inverter circuit 103, may be envisaged.

According to the invention, the housing 1 "ENU" includes a testability assembly 200. The assembly 200 comprises a power supply unit 201 of the power electronic chain 100, and a control unit 203.

The power supply unit 201 of the electronic power chain 100 is connected to a low-voltage continuous network 7 of the aircraft. This low voltage continuous network 7 typically delivers a DC voltage of 28 volts. The power supply unit 201 comprises a transformer 2010, typically a single-phase transformer, this transformer may, alternatively, have one or more outputs depending on the technology of the power supply. The power supply unit 201 thus constitutes an insulated power supply with respect to the AC power supply delivering a voltage of 115 volts. The power supply unit 201 of the electronic power chain is furthermore connected to the electronic power chain 100 of the three-phase AC motor 5 of the nacelle component, via a link 9. More precisely, the electrical power chain 100 is powered by low voltage isolated through one or more high voltage diodes 10.

The electronic control unit 203, or "BITE" box (English acronym for "Built In Test Equipment") is set, via a test algorithm, to test the electronic power chain 100. The electronic control unit is this effect is connected to the inverter circuit 103 of the electronic power chain 100 via a link 11. In a known manner, the "BITE" control box makes it possible to sequentially search for the most probable failures of the components of the electronic power chain (as for example the presence of short circuits, open circuits, switches blocked in open or closed position, etc.). According to the invention, the electronic control unit 203 is connected to the power supply unit 201 supplying the electronic power chain 100 via a link 13. The control box 203 is also connected to the continuous electrical network 7 of the aircraft, via a link 14.

The electronic control unit 203 is furthermore connected to a testability control box 2 in flight, or "EEC" box, acronym for "Electronic Engine Control", via a link 16.

The power supply unit 201 further includes galvanic isolation so as not to propagate a fault between the low-voltage and AC three-phase continuous networks of the aircraft.

In order to be able to detect the leakage currents, a controlled switch 2011 connects the secondary of the transformer 2010 of the power supply unit 201, to the ground 15 of the aircraft. The switch 2011 of the power supply unit 201 is connected to the control box 203 by a link 17.

Referring now to Figure 2, illustrating an alternative embodiment of the housing 1 "ENU" of the invention. According to this variant, the housing 1 "ENU" is identical to that described with reference to Figure 1 except that the electronic power chain 100 feeds two electrical machines, such as for example the motors 5a, 5b. For this purpose two inverter circuits 103a, 103b are connected in parallel at the output of the autotransformer-rectifier circuit 101. The embodiment of FIG. 2 illustrates two motors 5a, 5b respectively at the output of two inverter circuits 103a, 103b, but of advantages. Inverter circuits each driving an electric motor are contemplated in the context of the present invention.

In the above examples, the housing 1 "ENU" contains a testability assembly 200 according to the invention and an electronic power chain. The testability assembly 200 of the invention can be an integral part of the housing 1 "ENU", as is the case in the example illustrated in FIGS. 1 and 2, but it must be understood that this set of testability can also be external to the housing 1 "ENU". In this case, the testability assembly 200 is connected to the electronic power chain 100 of the electric motor (s) of the component (s) to be tested. Similarly, the electronic circuits of the electronic power chain can belong to the same housing or, conversely, to several separate boxes connected to each other.

The operation of the testability assembly will now be described with reference to FIGS. 1 to 3, FIG. 3 diagrammatically representing a flight test command of a turbojet nacelle thrust reverser actuator.

During the flight, the control box 203 is permanently powered by the 28-volt aircraft network, via the link 14. Before landing and before or after landing gear output, the pilot sends a testability order to the box 1 "ENU", via the box 2 "EEC" (step A of Figure 3). The housing 2 "EEC" sends to the control unit 203 via the link 16 (step B of Figure 3) a testability order of the electronic power chain 100, for example the inverter system.

The control unit 203 activates the insulated power supply unit 201 via the "Start" command, via the link 13. The electronic power chain 100 is then supplied with DC low voltage by the power supply unit 201, delivering an isolated voltage 28 Volts, for example, through the high voltage diodes 10. The algorithm installed in the control box 203 defines the sequence of tests to be performed on the components of the electronic power chain 100, in order to sequentially search the failures of the components of the electronic power chain 100. These tests may include, for example, the search for short circuits, open circuits, switches blocked in open or closed position, etc.. The detection of possible faults on the power electronic chain 100 is provided by the voltage and / or current sensors 1036, 1037, 1038, 1039 and 1040. However, to test an insulation fault of the electronic power supply chain. the airplane mass, the control unit 203 activates the switch 2011 of the power supply unit 201 so as to establish a connection with the mass 15 of the aircraft. The detection of an insulation fault of the electronic power chain is done by measuring current or voltage across an impedance in series with the switch 2011.

When the test sequence is complete, the control box 203 returns to the box 2 "EEC" the collected information relating to the functionality of the tested component (step C of Figure 3). The box 2 "EEC" then returns this information to the pilot (step D). Alternatively, the box 2 "EEC" sends this information to an external device for collecting data, or stored in a memory internal to the housing 2 "EEC" this information.

By knowing the functionality status of the tested component the driver can make a decision. In the case where a component is not functional, the pilot can then make the decision to land on an airstrip that would be more suitable for certain cases of failure of certain components.

Thanks to the present invention, the testability assembly makes it possible to drive the electronic power string of a component by a low DC voltage. This makes it possible to create low voltage stimuli, which makes it possible to test the availability of the electronic power train of the engine or engines of a component, without controlling their deployment. Thus, the electronic power chain of the engine (s) is not degraded.

This makes it possible to perform a flight test command on components that can not be opened in flight, as this may lead to dangerous behavior of the aircraft, and this enables the pilot to take a decision in the event of a failure of a flight. component of the aircraft.

It goes without saying that the present invention is not limited to the only embodiments of this testability set, described above only as illustrative examples, but on the contrary embraces all the variants involving the technical equivalents of means described and their combinations if they fall within the scope of the invention. For this purpose, in the example of the above description, the power electronic chain to be tested is an electronic power chain of one or more engine (s) of electric actuator (s) nacelle components. The testability assembly of the present invention is in no way limited to the testability of actuators of nacelle components that can be activated by a three-phase AC motor, but on the contrary it encompasses any component of the aircraft that can be activated by a three-phase AC motor, such as for example the electric actuators of the landing gear.

Claims (8)

1. Testability set (200) in flight of an electronic power train (100) of an aircraft component, said component being activatable by a three-phase alternating motor (5, 5a, 5b) powered by an alternating electric network three-phase (3) of said aircraft, said testability assembly being characterized in that it comprises: - a power supply box (201) of the electronic power chain (100), connected on the one hand to a low-voltage continuous network (7) of the aircraft and, secondly, to said power electronic chain (100) of the three-phase AC motor (5, 5a, 5b) of said component; an electronic control unit (203) incorporating an algorithm for testing said electronic power train (100), said housing being connected on the one hand to said power supply box (201) and on the other hand to said electronic power supply chain; power (100). 2. testability assembly (200) according to claim 1, characterized in that the low voltage continuous network (7) is a 28 Volts continuous network. 3. testability assembly (200) according to one of claims 1 or 2, characterized in that the electronic control unit (203) is connected to a switch (2011) of the power supply unit (201), said switch being intended to be connected to the mass (15) of the aircraft. 4. testability assembly (200) according to any one of claims 1 to 3, characterized in that it comprises a connecting means (16) to a casing (2) control testability in flight. 5. Housing (1) comprising an electronic power chain (100) of a three-phase AC motor of an aircraft component, characterized in that it further comprises a testability unit (200) according to any one of claims 1 to 4 supplying said electronic power chain (100) with low DC voltage. 6. Housing according to claim 5, characterized in that it comprises at least one high voltage diode (10) at the output of the power supply unit (201) of the testability assembly (200). 7. Nacelle for an aircraft turbojet engine comprising a thrust reverser device, said thrust reverser device comprising: a cover, movable between an extended position in which said cover opens a passage in said basket and a position of retraction in which said cover closes said passage; at least one actuator able to move said cover alternately between said retracted and deployed positions, said actuator being controlled by a three-phase AC electric motor (5, 5a, 5b) controlled by an electronic power chain (100) capable of being powered by a three-phase AC mains; said nacelle being characterized in that it further comprises a testability unit (200) according to any one of claims 1 to 4 supplying said low-voltage DC electronic power chain (100), and being connected to said electronic chain of power through the control box (203). 8. Aircraft comprising a component controlled by a three-phase alternating electric motor (5, 5a, 5b) controlled by an electronic power chain (100) capable of being powered by a three-phase alternating electrical network, characterized in that it further comprises a testability assembly (200) according to any one of claims 1 to 4 supplying said low voltage electronic power supply chain (100) and being connected to said electronic power chain via the control box (203) .