• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
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    • 专利摘要:
    The starter system comprises a storage battery (110), a DC starter (120), an electronic control computer (142), a transmission relay (162), starter accessories (168), a generator gas generator (160) comprising itself a compressor (164), a combustion chamber (165) and a high pressure turbine (166), and a free turbine (167). First and second circuits are connected in parallel and interposed between the accumulator battery (110) and the DC starter (120). The first circuit includes a DC-DC converter (130) connected in series with a first switch (132) and the second circuit includes a second switch (133). In addition, the system includes at least one compressor speed sensor (163), a free turbine inlet temperature sensor (151), and a generator circuit (141). controlling the first and second switches (132, 133) according to the information provided by the compressor speed sensor (163) (163) and the free turbine inlet temperature sensor (151) (167).
    公开号:FR3015571A1
    申请号:FR1363458
    申请日:2013-12-23
    公开日:2015-06-26
    发明作者:Vincent Poumarede;Pierre Harriet
    申请人:Turbomeca SA;
    IPC主号:
    专利说明:

    [0001] TECHNICAL FIELD AND STATE OF THE PRIOR ART The invention relates to a method and a system for reliable startup of a turbomachine. The field of application of the invention is more particularly that of the control of the start-up of aeronautical gas turbine propulsion engines, such as helicopter turboshaft engines or fixed-wing aircraft turboprop engines, or the control of the engine. start-up for auxiliary power units or APU ("Auxiliary Power Unit") gas turbine mounted on aircraft. The invention is however applicable to other types of turbomachines, for example industrial turbines. An aircraft turbine engine comprises, in known manner, a combustion chamber, a compressor shaft on which a compressor wheel is mounted for supplying compressed air to said combustion chamber and at least one starter or starter-generator connected to said shaft to provide him with sufficient starting torque to drive him in rotation. To start the turbine engine, the starter first accelerates the compressor shaft in a first startup phase during which the fuel circuit upstream of the starter injectors is pressurized and purged. Then, in a second start-up phase, a fuel injection is initiated before ignition of said fuel is made in the combustion chamber of the turbine engine. Finally, in a third startup phase, at a predetermined rotational speed, the action of the starter is stopped and the turbine engine can continue to accelerate through the combustion of said fuel. 301 5 5 7 1 2 To enable ignition of the fuel, the air supplied by the compressor wheel to the combustion chamber must comply with certain pressure and speed conditions at the fuel injectors, so as to guarantee a ratio fuel / air accurate and not to blow the flame. However, since the volume of air supplied by the compressor wheel to the combustion chamber is proportional to the speed of rotation of the compressor shaft, the rotational speed of the shaft of the gas generator must therefore be included in a speed interval, called the ignition window, and for a time long enough for the ignition to be performed correctly. Traditionally, the turboshaft engines of almost all light or medium helicopters, and even those of some heavy helicopters as well as many turboprop aircraft with fixed wing, are started using a starter or a starter DC generator supplied with a DC voltage of 28V. The main advantages of DC starters lie in the fact that they are robust, relatively simple and controlled, shelf-mounted electrical machines and can be used to start a turbine engine directly from a power source. voltage of 28V, for example the battery of the helicopter, without the need for a static converter or a complex driving strategy. However, their practical implementation comes up against difficulties, which will be explained with reference to FIG. 7 and that the base equations recalled below make it possible to better understand. If one defines various parameters as follows: Uo: voltage of the battery 10 empty, Rbat: value of the internal resistance 11 of the battery 10, Rcab: value of the resistance of the wiring 31, 301 5 5 7 1 3 Rind : value of the resistor 21 of the armature winding of the starter 20, E = E (N): counter-electromotive force (fcém) of the starter 20, Idem: starting armature current, 5 Ubat: terminal voltage of the battery 10, Udem: voltage across the starter 20, We have: Idem = (Ubat - Udem) / Rcab = (Uo - E (N)) / (Rbat + Rcab + Rind) With: E (N) = kx N, N being the rotational speed of the starter 20 and k an electrical constant of the starter 20 (which depends in particular on the winding). On the other hand, the electromagnetic torque of the starter 20 is expressed by: Cern = kx Idem x Iex, Iex being the excitation current (Iex = Idem for a series excitation starter, Tex can also be regulated independently by a generator control unit or GCU ("Generator Control Unit") for machines with separate excitation). We deduce that, at N = 0, E = 0 and therefore: Idem = Uo / (Rbat + Rcab + Rind) 20 We see that the armature current Idem, during the first moments of startup, that is to say say when the fcém of the starter 20 is still very low, is directly proportional to the no-load voltage Uo of the battery 10 and only limited by the total resistance (Rbat + Rcab + Rind) of the supply line. However, the supply voltage (expected for example to be 28V in rated conditions) can vary significantly depending on whether it is a start from the battery or a park group. On the other hand, the internal resistance of the battery Rbat increases at low temperature. The resistance values of the electrical conductors Rcab, Rind, meanwhile, increase when the temperature increases. It will therefore be understood that the current and consequently the start-up torque can vary considerably depending on the type of power supply supplying a voltage of, for example, 28V (battery, starter-generator of the other turbine, auxiliary power unit of the aircraft or fleet group used for ground starting), ambient conditions (temperature) and circumstances (hot or cold starter). In practice, the aircraft manufacturer limits the starting current by using a suitable cable section (offering a minimum value of resistance), or even by adding in series a starting resistor which is shunted after a few moments as will be explained later. . On the other hand, the resistive torque of the gas generator and the associated transmission relay is also very variable, particularly as a function of the pressure and temperature parameters of the atmosphere P0, TO (related to the density of the air) and the oil temperature (linked to friction in the transmission relay which essentially comprises a gearbox, on which accessory equipment such as pumps, alternator, starter, etc.) are mounted. The minimum starting torque specified is all the higher as the temperature is low, as can be seen in FIG. 8, which represents curves 1 to 4 giving the evolution of the torque as a function of the speed of rotation expressed in FIG. percentage of the nominal value NG of the rotation speed of the gas generator, for a maximum torque Cmax, a minimum torque Cmin1 at -40 ° C, a minimum torque Cmin2 at -30 ° C and a minimum torque Cmin3 to + 55 ° C. This often leads the aircraft manufacturer to oversize its starting power circuit to minimize the impedance of the Rcab wiring and provide sufficient torque at very low temperature, ground and battery (s). Consequently, when starting on a park group 30 (which is rarely standardized, with a voltage that is often high), at altitude (with a low compressor resistance torque) or with an already hot turbine engine (with low friction), one can end up with a very high starting torque - higher than the maximum value specified Cmax - and a low resistance torque, causing a significant acceleration of the gas generator which then passes too quickly the ignition window. It is also known that certain turbomachines are characterized by a low and relatively narrow ignition window, between 8% NG and 15% NG approximately, where NG is the nominal speed of the gas generator, 100% NG approximately corresponding to the speed Rotating the compressor shaft when the turbine engine is operating at a speed to provide the Maximum Takeoff Power (PMD): outside of these limits, the chamber can not be turned on. On the other hand, the breakdown frequency of the spark plugs of the combustion chamber is generally very low, of the order of a few Hertz: the number of sparks and therefore the ignition probabilities are all the more low that the gas generator stays in the ignition window for a short time. Another factor that is difficult to take into account is the variable duration of fuel filling of the injection ramps associated with the combustion chamber, which can be at the origin of a delay between the moment of opening of the valves and the actual arrival of fuel in the room. Finally, once the starter injectors have been switched on, the duration of propagation of the flame to the adjacent injectors is also a complex phenomenon currently poorly controlled, which requires a not too high air speed. For all these reasons, it is therefore important not to cross the ignition window too quickly and stay there for a minimum of 301 5 5 7 1 6 in order to be sure to light the room in good conditions and to stabilize the flame. It can therefore be seen that a start-up torque that is poorly controlled and too high can lead to passing through the ignition window too quickly and to missing starts. However, we have seen that current starters-generators and starters 28V, unmanned, can only with difficulty meet the contradictory specifications of minimum torque / maximum torque in all possible situations. A system for making the ignition and starting of the turboshaft engines more robust is therefore desirable. For this it has already been proposed to incorporate a starting resistor, as shown in FIG. 9: to limit the starting current, a series resistor 32 of value Rdem is introduced in series with the battery 10 in series with a switch 33 (this which creates a voltage drop and therefore limits the current when the fcém of the starter 20 is low). The resistor 32 is short-circuited above a certain speed threshold by the closing of a switch 34. However, the starting resistance only makes it possible to reduce the acceleration of the gas generator in the circumstances where the torque of the starter would be too high (high battery voltage, low resistors, hot engine, etc ...). In other cases, especially when the resistive torque is high or the low supply voltage (cold battery), the limitation of the starting current is not necessary, and may even be potentially disabling. On the other hand, the starting resistance dissipates a very high power (1 to 3 kW); it is therefore complex to manufacture and it must be installed in a place where Joule losses can be easily removed and will not overheat the surrounding material. 301 5 5 7 1 7 Finally, the energy lost in the resistor leads to oversize the battery. It has also been proposed to perform a series / parallel start, as illustrated in FIGS. 10 and 11. This solution is used on some turboprop engines started on a 28V battery. It requires two batteries 13 and 14. At the start of the start and below a threshold speed (or current), the batteries 13 and 14 are connected in parallel, as shown in Figure 10, where two switches 15 and 16 are closed while a switch 17 is open. The starter 20 is therefore powered at a voltage U equal to 28V, and the batteries 13, 14 share the high starting current, a current 1/2 flowing in each of the batteries 13 and 14. Above a threshold When the speed of the starter 20 has increased sufficiently to limit the current, the batteries 13 and 14 are reconnected in series, as shown in FIG. 11, where the two switches 15 and 16 are open, while the switch 17 is closed. A current I therefore flows in each of the batteries 13 and 14. The starter 20 is then supplied with a double voltage equal to 56V in the example in question, which makes it possible to increase the maximum speed of assistance without debonding the starter 20. Serial / parallel starting requires two 28V batteries, while helicopters usually only have one (except "cold weather kit"), and a DC starter rated for a nominal voltage of 56V. Not all 28V 25 starter-generators and starters available on the shelf are rated for this voltage in repeated use. On the other hand, the problem of too fast acceleration in the ignition window is not treated, the purpose of this assembly being rather to continue to assist the acceleration of the gas generator at high speed (so with a high speed) without debonding the starter.
    [0002] It has also been proposed to optimize the computer-controlled start sequence (and phase). This involves driving and stabilizing the rotational speed of the gas generator shaft in the preferred ignition window and then, once ignition is detected (for example by detecting an increase in T45, c that is, the temperature of the gases at the inlet of the free turbine), to control the acceleration optimally. The diagram of FIG. 12 illustrates this process and shows an increasing speed of rotation as a function of time (section 5), then a constant rotation speed NG ignition which can vary in a range between 8% NG and 15% NG (section 6) , where NG represents a nominal rotation speed of the gas generator, then after an ignition detection performed for example with the detection of an increase in the temperature of the gases at the inlet of the free turbine (T45), a speed of rotation again increasing as a function of time (section 7). The section 6 thus corresponds to a maintenance of the rotation speed at a roughly constant value in the ignition window, while the section 7 corresponds to an approximately constant acceleration. Documents WO2011 / 0563960 and CA 2,685,514 also disclose turbine engine driven start laws. Document US 20100283242 describes, as illustrated in FIG. 13, the electrical architecture of a device for starting a turboprop 40 using an alternating starter 20 powered by a DC / AC controlled converter 23, which therefore allows to control the acceleration of the gas generator. The DC / AC controlled converter 23 is itself supplied from a 28V battery 10 via a DC-DC converter 21 and a DC bus 22. A fairly similar architecture, based on cascading DC-DC and DC-AC converters sized for full starting power, is described in US5493201. It may be noted that the so-called "optimized" start-up mentioned above, as well as according to the variants identified in the various patent documents mentioned above, when it is applied in its entirety, that is to say with the control of the acceleration of the gas generator after ignition, can be implemented only with particular starter technologies (coiled excitation synchronous machine for example), the starter must also have a power electronics and control unit (inverter) allowing speed and torque control for the maximum power of the starter, which can reach very high levels (from 10kW to 20kW). This power electronics is therefore particularly heavy and expensive. Power architectures using high voltage AC starters require not only a specific rotating machine and a DC / AC converter sized for full power, but in addition a DC-DC chopper (DC / AC). DC) to raise the voltage of the 28V network to the level of the DC bus voltage (a few hundred volts). It is therefore in all cases a particularly heavy, complex and expensive solution. DEFINITION AND OBJECT OF THE INVENTION The object of the invention is to remedy the aforementioned drawbacks and in particular to make it possible to avoid over-dimensioning the power supply batteries, while improving the reliability of the starting and by making the ignition more robust. and starting turboshaft engines. To solve the above-mentioned problems, there is provided a reliable starting system for a turbomachine comprising a storage battery, a DC starter, an electronic control unit, a transmission relay (including the mechanical drive of the gas generator and fuel pumps by the starter), starting accessories (such as spark plugs, starter electromagnets and / or stop) to manage a distribution fuel to injectors and ignition of the fuel during a start-up phase, a gas generator comprising itself a compressor, a combustion chamber and a high-pressure turbine, a free turbine (intended to drive for example a rotor of helicopter or a turboprop propeller via a mechanical gearbox), characterized in that the system further comprises first and second second circuits connected in parallel and interposed between said accumulator battery and said DC starter, in that the first circuit comprises a DC-DC converter connected in series with a first switch and the second circuit comprises a second switch, in that it further comprises at least one sensor of the rotational speed of the compressor, a temperature sensor at the inlet of the free turbine and a control circuit of said first and second switches according to the information provided by said sensor. the speed of rotation of the compressor and by said temperature sensor at the inlet of the free turbine. Preferably, the system further comprises a diode mounted in the first circuit in series with the DC-DC converter and the first switch. According to a particular embodiment, the DC starter is of the starter-generator type, which allows, above a speed threshold of the gas generator, to switch this starter-generator into generator mode so as to supply for example an aircraft onboard network in which the turbomachine is installed.
    [0003] According to a particular embodiment, the starting system further comprises a sensor for the rotation speed of the DC starter and the DC-DC converter is controlled by said DC revolution speed sensor when said first switch is closed. In this case, the electronic control computer may comprise a unit for generating a speed reference Nref corresponding to a preferential ignition window of the turbomachine and a link for transmitting this speed reference Nref to the DC / DC converter. . According to another particular embodiment, the DC-DC converter is slaved by said sensor of the speed of rotation of the compressor when said first switch is closed. In this case, the electronic control computer may comprise a unit for generating a speed reference Nref corresponding to a preferential ignition window of the turbomachine, and a unit for generating a starter torque setpoint. Cref and a transmission link of this torque setpoint Cref to the DC-DC converter. By way of example, the DC-DC converter may comprise an electromagnetic compatibility filter, a precharge circuit, and a buck-type chopper chopper. More particularly, the electronic control computer comprises a logical signal generation unit SL1, SL2 applied to an onboard network management unit of a helicopter for controlling the actuation respectively of the first and second switches. The electronic control computer comprises a unit for detecting the exceeding of a predetermined threshold of the rotation speed NG of the compressor and for controlling the deactivation of the first and second switches as well as the deactivation of said starter accessories. According to one aspect of the invention, the control circuit of the DC-DC converter comprises both a speed control loop and a current control loop. The speed control loop and the current control loop can be incorporated in an independent control circuit of the DC-DC converter. According to an alternative embodiment, the speed control loop is incorporated in the electronic control computer and the current control loop is incorporated in an independent control circuit of the DC-DC converter. The invention also relates to a process for the reliable start-up of a turbomachine comprising a storage battery, a DC starter, an electronic control computer, a transmission relay, starter accessories responsible for managing a fuel distribution. injectors and ignition of this fuel during a start-up phase, a gas generator comprising itself a compressor, a combustion chamber and a high-pressure turbine, and a free turbine, characterized in that the process comprises the following steps: - paralleling and interposing between said accumulator battery and said DC starter of the first and second circuits, wherein the first circuit comprises a DC-DC converter connected in series with a first switch and the second circuit includes a second switch, - measure the speed of rotation of the compressor, - mesu Rer the temperature at the inlet of the free turbine and - control said first and second switches according to the information of measuring the speed of rotation of the compressor and measuring the temperature at the inlet of the free turbine. More particularly, during initialization of the start-up, activation of the starter accessories is commanded, at the same time a Nref speed reference corresponding to a preferential ignition window of the turbomachine is transmitted to said DC-DC converter. closes said first switch while activating the DC-DC converter to accelerate the compressor, then regulating the electrical voltage delivered to the starter, in order to regulate the speed acquisition of said compressor to the speed reference Nref, when said speed reference Nref is reached, it ignites the combustion chamber of the turbomachine, the temperature is measured at the inlet of the free turbine and after detection of a rise in temperature confirming the ignition of the combustion chamber, we close the second switch, we open the first switch and we disable the DC-DC converter, then ap Upon detection of the exceeding of a start-up threshold by the rotational speed of the compressor, the starting accessories are deactivated and the second switch is opened so as to deactivate the starter. The invention is particularly applicable to turbine engine starting systems for aircraft and especially helicopters. The present invention takes into account the fact that the critical moment during a turbomachine start is the ignition of the combustion chamber. Stabilizing the speed of the gas generator in the preferred ignition window for a sufficient period of time, until the ignition is detected, thus makes it possible to avoid most of the causes of ignition failure: starter torque is poorly controlled, passage too much speed in the ignition window, filling time of the fuel lines, 301 5 5 7 1 14 delay of propagation and stabilization of the flame from the ignition nozzles to the main injectors at very low temperatures, etc. This constraint, which only applies to low speeds of rotation of the gas generator (less than 15% NG, where NG is the nominal speed of the generator), imposes on the aircraft manufacturer to limit the starting torque on the entire speed range, which can be disabling in very low temperature impregnated start-up situations where the resisting torque of the gas generator is high, the starter voltage of the starter is low. the and difficult ignition.
    [0004] On the other hand, once the chamber is on, the maximum and minimum torque requirements relating to the acceleration of the gas generator are much less restrictive: it is sufficient that the torque is high enough to assist the gas generator to the speed where the power recovered on the high pressure turbine will allow the turbine engine gas generator to accelerate on its own, and not too high not to blow the flame. In this second phase, a precise control of the starter in dNG / dt is not imperative, which is all the more interesting that the requested power is then much larger.
    [0005] The invention therefore consists of a device, controlled by the engine of the turbine engine, making it possible to speed up the engine gas generator and to maintain it at a constant speed in the ignition window of the engine, as long as the ignition of the engine the combustion chamber of the engine is not effective. The main advantage is that the power required to maintain the rotating gas generator in the ignition window is very small. For example, the mechanical power needed to keep rotating in its ignition window the gas generator of a helicopter turbine engine is of the order of 1 to 3 kW, while the maximum power developed by the starter during the start sequence can reach 5 to 20 kW, or 5 to 7 301 5 5 7 1 15 times more. This box based power electronics is therefore a size and a very low cost compared to a similar system sized to control the starter over the entire speed range of startup. 5 Once ignition is detected, the device is shunted and the starter is directly powered from the aircraft's onboard network, typically 28V, without control, the starter fcém already rotating at the time of switching to reduce the starting current and largely erase the peak current found when the gas generator is initially off. BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the invention will emerge from the following description of particular embodiments, given by way of example, with reference to the appended drawings, in which: FIG. 1 is a diagrammatic view of assembly of an exemplary embodiment of a turbomachine starting device according to the invention; FIG. 2 is a more detailed view of an example of a DC-DC converter which may be included in the device according to the invention illustrated in FIG. 1; FIG. 3 is a schematic overall view of a first exemplary embodiment of a turbomachine starting device 25 according to the invention, with the control circuits; Figure 4 is a schematic view of a servo loop corresponding to the first embodiment of Figure 3; FIG. 5 is a schematic overall view of a second exemplary embodiment of a turbomachine starting device 30 according to the invention, with the control circuits; Figure 6 is a schematic view of a servo loop corresponding to the second embodiment of Figure 5; Figure 7 is an electrical diagram corresponding to a starting device according to the prior art; FIG. 8 is a diagram showing various curves giving the shape of the maximum and minimum values of the starter torque as a function of the speed of rotation for different operating conditions, making it possible to ensure ignition of the combustion chamber in the field of flight ; Fig. 9 is an electrical diagram showing the insertion of a starting resistor according to the prior art; FIGS. 10 and 11 are electrical diagrams of a known two-battery starting device connected respectively in parallel and in series as a function of a speed threshold; Fig. 12 is a diagram showing a known computer-controlled starting sequence; and Fig. 13 is a diagram of a known device for starting a turboprop engine using an AC starter powered by a DC-AC controlled converter. DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS FIG. 1 diagrammatically shows the general configuration of a device according to the invention. The reliable starting system of a turbomachine comprises a storage battery 110, which may be a single battery or a group of batteries and may be constituted by the power supply of an aircraft on-board network, for example at a voltage of 28V, but the invention is not limited to such a value. 301 5 5 7 1 17 A DC starter 120 may be constituted by a simple DC starter or by a starter-generator (GD) capable of operating not only in motor mode, but also in generator mode when the start-up phase is completed, for example to power an onboard network. In the rest of the description, the term "starter" denotes a simple starter and a starter-generator, unless otherwise indicated. The turbomachine starting system comprises a transmission relay 162, in particular with a gearbox for ensuring the transmission of motion between the starter 120 and the main shaft of the turbomachine, as well as ancillary equipment, such as pumps associated with the injectors. fuel in the combustion chamber. FIG. 1 shows still the main elements of the turbomachine with a gas generator 160 itself comprising a compressor 164, a combustion chamber 165 and a high-pressure turbine 166, as well as a free turbine 167 and accessories. 168. Also shown in FIG. 1 is a sensor 161 of the speed of rotation of the starter 120 and a sensor 163 of the speed 20 of rotation of the compressor shaft 164 of the turbomachine. The starter system according to the invention comprises first and second circuits connected in parallel and interposed between the storage battery 110 and the DC starter 120. The first circuit comprises a DC-DC converter 130 connected in series with a battery. first switch 132 and optionally a diode 131. The second circuit comprises a second switch 133. As will be described below with reference to FIGS. 3 and 5, the system also comprises other sensors for measuring the operation of the turbomachine, such as a temperature sensor 151 at the inlet of the free turbine 167. The temperature T45 at the inlet of the free turbine 167 makes it possible to provide information reflecting the ignition conditions in the combustion chamber 165. It is therefore possible to use in place of the sensor 151 any other type of sensor for noting the ignition conditions in the combustion chamber 165. The first and second switches 132, 133 are controlled from a control circuit 141 (FIGS. 3 and 5) as a function of the information provided by the sensor 163 of the speed of rotation of the compressor 164 and by the sensor 151 of FIG. the temperature at the inlet of the free turbine 167. An electronic control computer 142, 142 ', which can be constituted by the traditional electronic computer of the turbomachine, also called EECU (Figures 3 and 5), provides the management of the measures provided by the sensors 151 and 163 and the control of the DC-DC converter 130 in cooperation with the control circuit 141, which may be a pre-existing electrical core, such as an aircraft network management module. The starting device according to the invention thus consists essentially of a DC-DC converter 130 supplying, when the contactor 132 is closed, the starter 120 at the start of the start-up phase and supplying the necessary power to maintain the gas generator 160 in the ignition window. When the ignition is confirmed, the switch 133 is closed and the switch 132 is open, so as to continuously supply the starter 120 directly from the battery 110 which can be integrated into an onboard network, for example at 28V, for the continue starting in a non-controlled manner. Switches 132 and 133 may be part of the "electric core" of the helicopter. Diode 131 is not required but may be useful to protect the output of the DC-DC converter 130 when the control of the contactors 132 and 133 is covered. The DC-DC converter 130 may include, for example, a simple buck buckener 136 (see FIG. 2) which, from the supply voltage of the network U (for example 28V), supplies the starter armature 120 with the necessary ID current. to regulate the torque of the starter 120 and thus slaving the rotational speed NG of the compressor shaft 164 of the gas generator 160 to the setpoint, regardless of the operating conditions (voltage of the on-board network, value of the impedances of the power supply 110 and starter 120, compressor 164's resistant torque, etc.). Since the electrical power required is small, the DC-DC converter acts as a progressive starting system which limits the current draw on the on-board network during the first start-up times, when the starter motor 120 is almost zero. This aspect makes it possible to reduce the thermal stresses on the starter motor 120, the mechanical stresses on the splines and the section to be broken of the starter motor drive 120 and, when starting on the battery 110 of the helicopter, to reduce the fall of voltage found 20 on the onboard network when powering the starter 120 speed and fcém null. The speed regulation of the electric machine requires a speed sensor 161, which can either be part of the starter 120 itself (some starters-generators are equipped with it, in particular to manage the defluxing), or be integral with the drive. the starter 120 (sound wheel, Hall effect sensor or other). The preferential ignition window being capable of varying according to the flight range (atmospheric pressure P0, atmospheric temperature TO), it is desirable to be able to vary the speed reference 30 Nref of the DC-DC converter 130, the latter being 301. 5, which is produced by the turbine engine computer 142 and is transmitted to the device via a digital or analog link 145 (eg variable duty cycle), as illustrated in FIG. for example, as shown in FIG. 2, an electromagnetic compatibility filter 134, with coupled iron inductances 101 and capacitors 102, 103, followed by a precharging circuit 135, with a resistor 104 that can be shunted by a switch 105, and a buck type chopper 136, with a capacitor 106, a controlled switch 107 constituted by semiconductor components power supply, a diode 108 and an inductor 109, for outputting a DC current ID. The operation of the starter system according to the invention will now be described in more detail in various embodiments with reference to FIGS. 3 to 6. When selecting the start, the control computer of the turbomachine (EECU) 142 sends a logic signal SL1 to the management system of the helicopter electrical network (electrical core) 141, activates a starter electro-valve and the spark plugs, and controls a fuel flow law adapted to start, by a line 149 of control of the starting accessories symbolically assembled in Figures 1, 3 and 5 under the reference 168. Simultaneously, the EECU 142 develops according to different parameters which it ensures the acquisition (atmospheric pressure P0, atmospheric temperature TO, residual temperature T45, that is to say the temperature of the gases at the inlet of the free turbine, etc ...) the speed reference Nref corresponding to the window preferably of the turbine engine, and transmits this instruction to the DC-DC converter 130.
    [0006] On activation of the logic signal SL1, the electric core 141 closes the contactor 132 (activation via line 147) and transmits the activation instruction of the DC-DC converter 130 (activation of the "ON / OFF" signal via line 144).
    [0007] The DC-DC converter 130 powered by the on-board network 110 starts, accelerates the rotation of the compressor shaft 164 of the gas generator 160, and then regulates the current ID delivered to the starter 120 so as to regulate the acquisition. speed of the rotating machine ND at the set speed Nref.
    [0008] Once the ECU 142 finds that the rotational speed NG of the compressor shaft 164 of the gas generator 160, measured by the sensor 163 and supplied to the ECU by the line 148, has reached and stabilized at the nominal speed Nref, the regulation electronic computer 142 starts the ignition of the turbomachine by sending the required control information on the control line 149 of the starter accessories. When the ECU 142 detects and confirms the ignition of the combustion chamber, for example by measuring the elevation of the T45 via the line 151, it sends a logic signal SL2 to the management system of the helicopter edge network 141, then deactivates the logic signal SL1. Upon activation of the logic signal SL2, the electric core 141 closes the contactor 133 (activation via line 143): the starter 120, supplied directly from the on-board network 110, continues to accelerate and start the turbomachine in a conventional manner.
    [0009] Simultaneously, the diode 131 is blocked in reverse, which makes it possible to avoid the short circuit of the output of the DC-DC converter 130. It should be noted that the recovery of the control of the contactors 132 and 133, made possible by the diode 131, ensures the absence of any discontinuity in the power supply of the starter 120.
    [0010] On deactivation of the logic signal SL1, the electric core 141 opens the contactor 132 (deactivation of the signal transmitted by the line 147), which isolates the output of the DC-DC converter 130 from the starter 120, and transmits the deactivation instruction of the DC converter. Continuous 130 (deactivation of the signal "ON / OFF" on line 144). When the EECU 142 detects that the speed NG of the compressor shaft 164 of the gas generator 160 exceeds the end of start threshold (threshold at which the turbine engine becomes autonomous), it deactivates the starting accessories 168 by the line 149, as well as the logic signal SL2. On deactivation of the logic signal SL2, the electric core 141 opens the contactor 133 (deactivation of the control signal via the line 143), which cuts off the power supply of the starter 120. Above a threshold speed, the starter Generator 120 may be switched to generator mode to power the onboard network 110, but this function can not be accomplished if it is a simple starter. From the point of view of the control of the DC-DC converter 130, there are conventionally two nested control loops 20: speed control then torque control or current (see Figures 4 and 6). The speed setpoint corresponding to the ideal ignition window of the turbomachine, Nref, delivered by line 172, is developed by the EECU 170 of the turbomachine in block 171 according to parameters of which the EECU 170 provides the acquisition (for example and in a non-exhaustive manner: atmospheric pressure P 0, compressor inlet air temperature TO ...), then transmitted to the control system 180 of the DC-DC converter 130 in a digital or analog manner. The speed measurement of the rotating machine ND effected by the sensor 161 and transmitted by the line 146 (FIG. 3) or 181 (FIG. 4) is compared with the set point Nref in the comparator 182 to give a AN speed error, which is processed by the corrector 183 to give a torque set Cref. This torque setpoint is processed by block 184 which transforms it into a current setpoint Iref. The measurement of the current ID at the output of the DC-DC converter 130, is compared with the reference Iref in the comparator 186 to give an error AI, which is processed by the corrector 187 to give a setpoint 188 of the conduction duty cycle T which serves to control the power semiconductor (s) 189 (FIG. 4) or 107 (FIG. 2) of the chopper 10 of the DC-DC converter 130. In another slightly different embodiment, illustrated in FIGS. 6, the speed control loop is this time calculated by the EECU 270. The speed reference Nref supplied at the input 272 of a comparator 274 is developed by the EECU 270 in the same manner as previously, in a block 271 which is similar to block 171 of FIG. 4, but is compared with the speed measurement NG of rotation of the compressor shaft 164 of the gas generator 160 (which is proportional to the rotational speed ND of the starter 120 ), provided at the input 273 of the comparator 274 so as to develop the torque setpoint Cref, which is transmitted by the EECU 270 to the control circuit 280 of the DC-DC converter 130. This torque setpoint Cref is processed by the control circuit 280 of the DC-DC converter 130 in the same manner as in the previous embodiment of Figure 4, the elements 281 to 286 of Figure 6 corresponding to the elements 184 to 189 of Figure 4 respectively and not being described in again, to result in the control of the chopper semiconductor 286. It can be seen that one of the advantages of this embodiment is that it makes it possible to dispense with the speed sensor 161 on the starter 120, the speed loop being processed directly at the computer 301 5 5 7 1 24 turbine engine by virtue of the speed acquisition of the NG gas generator produced by the sensor 163. In general, the invention concerns both a system and a process for the reliable start-up of a turbomachine.
    [0011] The reliable start-up method of a turbomachine comprising a storage battery 110, a DC starter 120, an electronic control computer 142, 142 ', a transmission relay 162, starting accessories 168, a generator gas 160, itself comprising a compressor 164, a combustion chamber 165 and a high-pressure turbine 166, as well as a free turbine 167, comprises the following steps: - to be connected in parallel and interposed between the storage battery 110 and the DC starter 120 of the first and second circuits, wherein the first circuit comprises a DC-DC converter 130 connected in series with a first switch 132 and the second circuit comprises a second switch 133, - measuring the speed of rotation of the compressor 164, - measuring the temperature at the inlet of the free turbine 167 and - controlling said first and second switches 132, 133 as a function of s information for measuring the speed of rotation of the compressor 164 and for measuring the temperature at the inlet of the free turbine 167. More particularly, during the initialization of the startup, the activation of the starter accessories is controlled 168, simultaneously 25 is transmitted to the DC-DC converter a speed reference Nref corresponding to a preferred ignition window of the turbomachine and the first switch 132 is closed, while activating the 301 5 5 7 1 25 DC-DC converter 130 to accelerate the compressor 164, then regulate the electrical voltage delivered to the starter 120, in order to regulate the speed acquisition of the compressor 164 to the speed reference Nref. When the speed setpoint Nref is reached, the combustion chamber 165 of the turbomachine is ignited, the temperature at the inlet of the free turbine 167 is measured and after detection of a temperature rise confirming the ignition of the combustion chamber 165, the second switch 133 is closed, the first switch 132 is opened and the DC-DC converter 130 is deactivated, then after detection of the exceeding of an end-of-start threshold by the speed of rotation of the compressor, disabling the starter accessories 168 and opening the second switch 133. The method and the reliable boot system according to the invention have many advantages.
    [0012] They make it possible to reduce the number of aborted starts by failure of ignition or blowing of the flame in the combustion chamber of the gas generator of the turbomachine. They make the boot more robust with respect to the starting conditions (flight range, oil temperature, starter supply voltage, etc ...). They make it possible to minimize dispersions over the duration of starts. They therefore make it possible to avoid breakdowns between an aborted start and a new attempt, and consequently allow the size and mass of the on-board battery to be reduced.
    [0013] 301 5 5 7 1 26 They simplify the aircraft manufacturer's work to design the starter's power supply, in order to comply with the imposed maximum starting torque mask. They allow a limitation of the inrush current during starting at zero speed, which makes it possible to minimize the wear of the brushes of the starter-generator, to minimize the constraints on the coupling (splines, section to be broken), to reduce the voltage drop of the onboard network and optimize the sizing of the battery. This results in better availability of helicopters, given the decreased aborted start-up rate. By reducing the power of the device, the mass and the cost are also reduced with respect to a static converter sized for full starting power (about 15% of the maximum starting power).
    [0014] The system according to the invention is compatible with most current starters-generators and 28V starters used on helicopters. The invention is not limited to the embodiments described, but extends to all the variants within the scope of the claims.
    [0015] Thus, for example, the device comprising the driven DC-DC converter 130 may be implanted by an aircraft manufacturer directly into the electric core 141, provided that the engine specifications are known on the one hand, the requirements in terms performance (torque, speed), on the other hand, the interfaces (transmission format of the speed reference to the device).
    权利要求:
    Claims (15)
    [0001]
    CLAIMS1.Reliable startup system for a turbomachine comprising a storage battery (110), a DC starter (120), an electronic control computer (142, 142 '), a transmission relay (162), starter accessories (168) for managing fuel delivery to and ignition of fuel during a start-up phase, a gas generator (160) including a compressor (164), a combustion chamber ( 165) and a high pressure turbine (166), as well as a free turbine (167), characterized in that the system further comprises first and second circuits connected in parallel and interposed between said accumulator battery (110) and said DC starter (120), in that the first circuit comprises a DC-DC converter (130) connected in series with a first switch (132) and the second circuit comprises a second switch (133). ), further comprising at least one compressor speed sensor (163), a temperature sensor (151) of the free turbine inlet temperature (167) and a circuit (141) controlling said first and second switches (132, 133) based on the information provided by said compressor speed sensor (163) (164) and said input temperature sensor (151) of the free turbine (167).
    [0002]
    The starter system of claim 1, characterized in that it further comprises a diode (131) mounted in the first circuit in series with the DC-DC converter (130) and the first switch (132).
    [0003]
    3. Starting system according to claim 1 or claim 2, characterized in that the DC starter (120) is of the starter-generator type.
    [0004]
    4. Starting system according to any one of claims 1 to 3, characterized in that it further comprises a sensor (161) of the speed of rotation of the DC starter (120) and in that the continuous converter Continuous (130) is configured to be slaved by said sensor (161) of the rotation speed of the DC starter (120) when said first switch (132) is closed.
    [0005]
    Starting system according to any one of claims 1 to 3, characterized in that the DC-DC converter (130) is configured to be slaved by said sensor (163) of the rotational speed of the compressor when said first switch (132) is closed.
    [0006]
    The starter system according to any one of claims 1 to 5, characterized in that the DC-DC converter (130) comprises an electromagnetic compatibility filter (134), a precharging circuit (135) and a step-down chopper (136) Buck type.
    [0007]
    7. Starting system according to claim 4, characterized in that the electronic control computer (142) comprises a development unit of a speed reference Nref corresponding to a window 20 of preferential ignition of the turbomachine and a link (145) for transmitting this speed reference Nref to the DC-DC converter (130).
    [0008]
    8. Starting system according to claim 5, characterized in that the electronic control computer (142 ') comprises a unit for generating a speed reference Nref corresponding to a preferred ignition window of the turbomachine, and a unit for generating a torque setpoint Cref and a link (152) for transmitting this torque setpoint Cref to the DC-DC converter (130).
    [0009]
    9. Starting system according to any one of claims 1 to 8, characterized in that the electronic control unit (142, 142 ') includes a logic signal generating unit SL1, SL2 applied to a unit (141) of helicopter onboard network management for controlling the actuation of the first and second switches (132, 133) respectively.
    [0010]
    10. Starting system according to any one of claims 1 to 9, characterized in that the electronic control computer (142, 142 ') comprises a unit for detecting the exceeding of a predetermined threshold of the speed of rotation NG of compressor and control of deactivation of the first and second switches (132, 133) and deactivation of the starter accessories (168).
    [0011]
    11. Starting system according to any one of claims 1 to 10, characterized in that it comprises a control circuit of the DC-DC converter (130) which comprises both a speed control loop and a loop current control.
    [0012]
    12. The starter system according to claims 4 and 11, characterized in that said speed control loop and said current control loop are incorporated in an independent control circuit of the DC-DC converter (130).
    [0013]
    13. Starting system according to claims 5 and 11, characterized in that said speed control loop is incorporated in said electronic control computer (142 ') and said current control loop is incorporated in a circuit independent of control of the DC-DC converter (130).
    [0014]
    14. A method for reliably starting a turbomachine comprising a storage battery (110), a DC starter (120), an electronic control computer (142, 1421 a transmission relay (162), starter accessories (168) responsible for managing a fuel delivery to injectors and igniting the fuel during a start-up phase, a gas generator (160) including itself a compressor (164), a combustion chamber (165) and a high-pressure turbine (166) and a free turbine (167), characterized in that the method comprises the following steps: - mounting in parallel and interposing between said accumulator battery (110) and said DC starter (120) first and second circuits, wherein the first circuit comprises a DC-DC converter (130) connected in series with a first switch (132) and the second circuit comprises a second switch (133); measuring the rotation speed of the compressor (164), - measuring the temperature at the inlet of the free turbine (167) and - controlling said first and second switches (132, 133) according to the measurement information of the rotational speed compressor (164) and measuring the temperature at the inlet of the free turbine (167).
    [0015]
    15. Starting method according to claim 14, characterized in that during the initialization of the start, the activation of the starter accessories (168) is commanded, and at the same time the said DC-DC converter (130) is transmitted with an instruction of Nref speed corresponding to a preferred ignition window of the turbomachine and said first switch (132) is closed while activating the DC-DC converter (130) to accelerate the compressor (164) and then regulate the electric voltage delivered to the starter (120). ) in order to regulate the speed acquisition of said compressor (164) at the speed setpoint Nref, when said speed setpoint Nref is reached, the combustion chamber (165) of the turbomachine is ignited, measuring the temperature at the inlet of the free turbine (167) and after detecting a rise in temperature confirming the ignition of the combustion chamber (165), closing the second 301 5 5 7 1 31 switch (133), opens the first switch (132) and disables the DC-DC converter (130), then after detecting the exceeding of a start-up threshold by the rotation speed of the compressor, the starting accessories (168) are deactivated and the second switch (133) is opened.
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    同族专利:
    公开号 | 公开日
    EP3092389B1|2020-07-01|
    FR3015571B1|2018-11-23|
    US20170002744A1|2017-01-05|
    RU2016130041A|2018-01-30|
    KR20160102202A|2016-08-29|
    WO2015097361A1|2015-07-02|
    CN105849390B|2019-06-07|
    RU2016130041A3|2018-07-02|
    CA2933774A1|2015-07-02|
    CA2933774C|2021-07-06|
    KR102265943B1|2021-06-16|
    RU2666029C2|2018-09-05|
    EP3092389A1|2016-11-16|
    CN105849390A|2016-08-10|
    PL3092389T3|2020-11-02|
    JP2017503954A|2017-02-02|
    JP6509874B2|2019-05-08|
    US10450962B2|2019-10-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    GB740090A|1952-12-12|1955-11-09|Rolls Royce|Improvements relating to starting and ignition systems for gas turbine engines|
    US2938338A|1956-01-20|1960-05-31|Gen Motors Corp|Gas turbine starting system|
    US3600887A|1969-09-08|1971-08-24|Ford Motor Co|Electrical starting and operating system for gas turbine engine|
    US6147414A|1997-12-19|2000-11-14|Alliedsignal Inc.|Dual-purpose converter/startup circuit for a microturbine power generating system|
    US20060061336A1|2004-09-21|2006-03-23|Honeywell International|Method and apparatus for controlling an engine start system|
    EP2264297A1|2009-06-17|2010-12-22|Eurocopter|Device and method for starting of a helicopter turbine, using an electrical energy source comprising supplementary discharging means|
    FR2964515A1|2010-09-07|2012-03-09|Peugeot Citroen Automobiles Sa|Circuit for controlling e.g. MOSFET of multiphase booster chopper of switching power supply of car, has master clock generating master clock signal, where circuit is analog electronic circuit realized from electronic components|
    US2983338A|1958-08-25|1961-05-09|Ford Motor Co|Spot disc brake|
    CN2066638U|1989-12-09|1990-11-28|北京市西城新开通用试验厂|Starter for generators of vapor marine|
    RU2050455C1|1993-11-22|1995-12-20|Анатолий Михайлович Рахмаилов|Gas-turbine engine and its starting method|
    US5493201A|1994-11-15|1996-02-20|Sundstrand Corporation|Starter/generator system and method utilizing a low voltage source|
    JPH08277723A|1995-04-06|1996-10-22|Nissan Motor Co Ltd|Gas turbin generator|
    RU2224352C2|1996-12-03|2004-02-20|Эллиотт Энерджи Системс, Инк.|Power system for ac turbine/generator unit mounted on common shaft|
    US6093975A|1998-10-27|2000-07-25|Capstone Turbine Corporation|Turbogenerator/motor control with synchronous condenser|
    US6414866B2|1999-11-15|2002-07-02|Alliedsignal Inc.|Active filter for a converter having a DC line|
    US6281595B1|2000-09-25|2001-08-28|General Electric Company|Microturbine based power generation system and method|
    EP1289118A1|2001-08-24|2003-03-05|Siemens Aktiengesellschaft|Method and arrangement for starting a turbo set|
    US20040080165A1|2001-12-31|2004-04-29|Capstone Turbine Corporation|Turbogenerator/motor controller with ancillary energy storage/discharge|
    US6703719B1|2002-08-28|2004-03-09|General Electric Company|Systems and methods for managing a battery source associated with a microturbine power generating system|
    US20040160061A1|2003-01-31|2004-08-19|Capstone Turbine Corporation|Gas-turbine engine with catalytic reactor|
    US6931856B2|2003-09-12|2005-08-23|Mes International, Inc.|Multi-spool turbogenerator system and control method|
    US7355300B2|2004-06-15|2008-04-08|Woodward Governor Company|Solid state turbine engine ignition exciter having elevated temperature operational capability|
    US7204090B2|2004-06-17|2007-04-17|Pratt & Whitney Canada Corp.|Modulated current gas turbine engine starting system|
    CN201025131Y|2007-01-31|2008-02-20|沈阳黎明航空发动机有限责任公司|Frequency conversion startup device of steamship engine|
    US7861534B2|2007-05-03|2011-01-04|Pratt & Whitney Canada Corp.|Method of starting turbine engine from low engine speed|
    US7952220B2|2007-09-21|2011-05-31|Hamilton Sundstrand Corporation|Generator for gas turbine engine having main DC bus accessory AC bus|
    JP2009150362A|2007-12-21|2009-07-09|Ihi Corp|Starter control device and gas turbine power generating device having the starter control device|
    US20100283242A1|2007-12-26|2010-11-11|Dooley Kevin A|High Voltage Start of an Engine from a Low Voltage Battery|
    US8030788B2|2008-12-31|2011-10-04|General Electric Company|Method and systems for an engine starter/generator|
    DE102009027407A1|2009-07-01|2011-01-05|Robert Bosch Gmbh|Method for operating a starter control, computer program product and starter control|
    US8925328B2|2009-10-26|2015-01-06|Siemens Energy, Inc.|Gas turbine starting process|
    US9086018B2|2010-04-23|2015-07-21|Hamilton Sundstrand Corporation|Starting a gas turbine engine to maintain a dwelling speed after light-off|
    FR2967847B1|2010-11-23|2015-06-26|Hispano Suiza Sa|METHOD AND ARCHITECTURE FOR PROCESSING REGENERATED ELECTRIC ENERGY OF AN AIRCRAFT|
    DE102011101531B4|2011-05-14|2015-09-24|Volkswagen Aktiengesellschaft|Motor vehicle electrical system and method for operating a motor vehicle electrical system|
    FR2990573B1|2012-05-11|2015-11-20|Hispano Suiza Sa|SYSTEM FOR CONTROLLING AND POWERING TURBOMACHINES OF A HELICOPTER|
    EP2875982B1|2012-07-19|2019-08-21|Mitsubishi Electric Corporation|Device and method for controlling propulsion of electric vehicle|
    CA2922466A1|2013-09-06|2015-03-12|Ge Aviation Systems Llc|Method for starting aircraft engines|TWI625919B|2016-12-23|2018-06-01|財團法人工業技術研究院|Power holding circuit device|
    US10352189B2|2017-05-10|2019-07-16|Pratt & Whitney Canada Corp.|Method and system for setting an acceleration schedule for engine start|
    US10676199B2|2017-06-12|2020-06-09|General Electric Company|Propulsion system for an aircraft|
    US10953995B2|2017-06-30|2021-03-23|General Electric Company|Propulsion system for an aircraft|
    US10738706B2|2017-06-30|2020-08-11|General Electric Company|Propulsion system for an aircraft|
    US10696416B2|2017-06-30|2020-06-30|General Electric Company|Propulsion system for an aircraft|
    US10569759B2|2017-06-30|2020-02-25|General Electric Company|Propulsion system for an aircraft|
    US10432130B2|2017-11-28|2019-10-01|GM Global Technology Operations LLC|Electric powertrain and a method of operating the same|
    US10369896B2|2017-11-28|2019-08-06|GM Global Technology Operations LLC|Apparatus and method for flexible DC fast charging of an electrified vehicle|
    CN110939529B|2019-11-25|2020-11-06|西安航天动力研究所|Integrated gas supply device|
    US20210207542A1|2020-01-06|2021-07-08|Hamilton Sundstrand Corporation|Starter/generator arrangements for gas turbine engines|
    法律状态:
    2015-12-14| PLFP| Fee payment|Year of fee payment: 3 |
    2016-12-07| PLFP| Fee payment|Year of fee payment: 4 |
    2017-09-01| CD| Change of name or company name|Owner name: SAFRAN HELICOPTER ENGINES, FR Effective date: 20170727 |
    2017-11-21| PLFP| Fee payment|Year of fee payment: 5 |
    2019-11-20| PLFP| Fee payment|Year of fee payment: 7 |
    2020-11-20| PLFP| Fee payment|Year of fee payment: 8 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1363458A|FR3015571B1|2013-12-23|2013-12-23|METHOD AND SYSTEM FOR RELIABLY STARTING TURBOMACHINE|
    FR1363458|2013-12-23|FR1363458A| FR3015571B1|2013-12-23|2013-12-23|METHOD AND SYSTEM FOR RELIABLY STARTING TURBOMACHINE|
    EP14827838.5A| EP3092389B1|2013-12-23|2014-12-15|Method and system for more reliable starting of a turbo machine|
    PCT/FR2014/053334| WO2015097361A1|2013-12-23|2014-12-15|Method and system for more reliable starting of a turbo machine|
    RU2016130041A| RU2666029C2|2013-12-23|2014-12-15|Method and system for reliable starting turbine engine|
    CN201480070367.9A| CN105849390B|2013-12-23|2014-12-15|Method and system for reliably starting turbine engine|
    CA2933774A| CA2933774C|2013-12-23|2014-12-15|Method and system for more reliable starting of a turbo machine|
    US15/104,339| US10450962B2|2013-12-23|2014-12-15|Method and a system for reliably starting a turbine engine|
    JP2016542180A| JP6509874B2|2013-12-23|2014-12-15|Method and system for reliably starting a turbine engine|
    KR1020167017171A| KR102265943B1|2013-12-23|2014-12-15|Method and system for more reliable starting of a turbo machine|
    PL14827838T| PL3092389T3|2013-12-23|2014-12-15|Method and system for more reliable starting of a turbo machine|
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