METHOD AND DEVICE FOR DIAGNOSING STATIC CURRENT SENSOR FAULTS OF A DRIVING SYSTEM OF A SYNCHRONOUS M

专利摘要:
The method according to the invention allows the diagnosis (15, 16) of phase current sensor faults of a control system in a synchronous rotating electric machine of a motor vehicle. According to the invention, the method takes into account differences between measurements provided (14) by the sensors and nominal values of the phase currents (ia, ib, ic) in order to diagnose faults. These differences are calculated (18) in a rotating reference and are independent of an electromechanical model of the machine. According to a particular embodiment of the method according to the invention, the marker used is a Park marker (17). The method detects sensor faults if the differences are substantially non-zero (19) and a sensor offset fault if a residual pulse (ωres) of the differences is substantially equal to a measured speed (ω) of the control system.
公开号:FR3025890A1
申请号:FR1458792
申请日:2014-09-17
公开日:2016-03-18
发明作者:Sidath Diao；Zaatar Makni；Demba Diallo
申请人:Valeo Equipements Electriques Moteur SAS；
IPC主号:

专利说明:

[0001] FIELD OF THE INVENTION 1. METHOD AND DEVICE FOR DIAGNOSING FLOW OF PHASE CURRENT SENSORS OF A DRIVING SYSTEM OF A SYNCHRONOUS MOTOR VEHICLE ROTARY ELECTRIC MACHINE TECHNICAL FIELD OF THE INVENTION The present invention relates to a method and a device for fault diagnosis of phase current sensors of a control system of a synchronous rotating electric machine of a motor vehicle.
[0002] The invention also relates to a synchronous rotary electrical machine comprising such a device, in particular a machine such as a permanent magnet synchronous electric motor for applications in electric and hybrid motor vehicles, electrical power steering, air conditioning compressors and electric motors. fans.
[0003] BACKGROUND ART OF THE INVENTION. The number of electronic equipment and electrical functions in embedded systems in vehicles is steadily increasing. This is due to their great flexibility of use, their compactness and their low maintenance constraint. However, their availability and reliability are an issue because they can be prone to breakdowns. As a result, mechanisms are provided very early in the design phase, so as to facilitate the detection of defects, the diagnosis and the appropriate reconfiguration of the controls. Many works have been carried out in the field of fault detection of electrical control systems and their characterizations. The cases of the current sensors, the angular position sensor, and the DC voltage sensor of a control of a permanent magnet synchronous motor are known from the state of the art, and good experimental results have been obtained. , but few details are given on the issue of fault isolation in the case of current sensors. For the skilled person, the most used method for the detection and characterization of the defect (FDI in English terminology, acronym for "Fault 3025890 - 2 - Detection and Isolation") is based on the observation of the behavior of the real system compared to a theoretical model. The differences that appear allow you to decide whether the system has a default or not. However, this method has many disadvantages. It requires in particular to build a model taking into account all the variables of state of the system, and it is difficult to model the disturbances, due to the resisting torque or the variation of speed for example, which are not defects. To overcome these drawbacks, it has been proposed in the article "Current Sensor Fault Diagnosis in Stationary Frame for PMSM Drive in Automotive Systems", S. Diao et al., 2014 Ninth International Conference on Ecological Vehicles and Renewable Energies (EVER) , IEEE, an alternative based on an estimate from a system of differential equations of a dynamics of a difference between measured phase currents and nominal phase currents. However, the estimators used involve electrical parameters which are not independent of the machine and are calculated in a stationary reference which does not make possible all possible simplifications in the case of a control system.
[0004] GENERAL DESCRIPTION OF THE INVENTION The object of the present invention is therefore to take into account the properties of a control system to simplify the calculations of these differences. It relates specifically to a method for fault diagnosis of phase current sensors of a control system of a synchronous rotating electrical machine of a motor vehicle. According to the invention, the method takes into account differences between measurements provided by the sensors and nominal values of the phase currents in order to diagnose faults, these differences being calculated in a rotating reference and being independent of one another. electromechanical model of the machine. According to another characteristic of the invention, this marker is a Park marker. In the method according to the invention, sensor faults are detected if these differences are substantially non-zero. According to the invention, an offset defect of at least one of the sensors is detected if a residual pulse of the differences is substantially equal to a measured speed of the control system. According to the invention, alternatively, a gain defect of at least one of the sensors is detected alternately if a residual pulse of the differences is substantially equal to twice a measured speed of the control system. In the method according to the invention, a faulty sensor is identified among the phase current sensors of the control system by comparing at a measured electrical angle a residual electric angle defined by the relation: 10 ares = arctan (- Tql id) where id and Tg are the differences defined above. The invention also relates to a fault diagnostic device for phase current sensors of a control system of a synchronous rotating motor machine of a motor vehicle capable of carrying out the method described above. The device in question is of the type comprising: means for acquiring measurements provided by the sensors and an electrical angle of the control system; digital processing means for these measurements; Flag generation means signaling sensor faults. According to the invention, these processing means perform a Park transformation. According to the invention, these processing means comprise means for analyzing waveforms of the phase currents in a Park reference frame, these waveform analysis means including means for calculating a current. slippery average over time. In the device according to the invention, the acquisition means also acquire a speed of the control system and the processing means furthermore comprise means for detecting an offset defect and / or a loss of gain. At least one of the sensors as a function of this speed. According to the invention, the processing means further comprise means for identifying a faulty sensor among the phase current sensors as a function of the electric angle. The invention also relates to a synchronous rotary electrical machine 35 comprising at least one control system. This machine comprises, according to the invention, a device for diagnosing phase current sensor defects of the control system having the characteristics described above. A semiconductor computer memory, intended to be integrated into a device for diagnosing phase current sensor faults of a control system of a synchronous rotary electric machine of a motor vehicle according to the invention, remarkable in that that it contains a computer code representative of the method according to the invention, is also covered by the invention.
[0005] These few essential specifications will have made obvious to the person skilled in the art the advantages provided by the method and the device for diagnosing phase current sensor faults of a control system of a synchronous rotary electric machine of a motor vehicle according to the invention, as well as the synchronous rotating electrical machine and the associated computer memory 15, compared to the state of the prior art. The detailed specifications of the invention are given in the following description in conjunction with the accompanying drawings. It should be noted that these drawings have no other purpose than to illustrate the text of the description and do not constitute in any way a limitation of the scope of the invention.
[0006] BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a general block diagram of a control system of a synchronous rotating electrical machine. Figure 2 is a block diagram of a control unit of the control system of a synchronous rotating electrical machine shown in Figure 1 incorporating a device for diagnosing phase current sensor defects according to the invention. Figure 3 is a flowchart illustrating the method according to the invention for diagnosing phase current sensor faults of a control system 30 of a synchronous rotating electrical machine. DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION A control system 1 of a synchronous rotary electrical machine 2, such as that shown in FIG. 1, generally comprises a control unit 3025890 -5- 3 controlling an inverter 4 supplying the synchronous electric machine 2 with current from a source of DC voltage 5. Measurements of the voltage Vbat of the DC voltage source 5, phase currents ia, ib, ic corresponding to the three phases A, B, C, of the electrical angle e and the speed w associated with the torque set Fre and speed Wref are the usual inputs of the control unit 3. This control unit 3 generates the control signals U, V, W of the inverter 4 so that the electric machine synchronous 2 provides the required torque Fre at the specified speed curef, parameters most often transmitted on a fieldbus 6. Figure 2 shows the main elements of the control unit 3. The electric angle e of the control system 1 is provided to the control unit 3 by a position sensor 7 of a rotor 8 of the synchronous rotating electrical machine 2.
[0007] The speed w is provided by a speed sensor 9, or by a calculation from the electric angle e. The measurements of the phase currents ia, ib, ic are provided by phase current sensors 10. It is precisely these phase current sensors 10 which can have defects, either an offset defect or a defect. of gain. These defects are obviously detrimental to the proper functioning of the control system 1 of the synchronous rotating electrical machine 2, and it is necessary to detect them and to characterize the faulty sensor. The purpose of the control unit 3 is to allow efficient operation of the control system 1 over a wide range of torques and speeds. To do this, a closed control loop is required. 11. The closed control loop 11 is a corrector which ensures a good control of the phase currents measured from a reference current [cf. A reference current calculation block 12 gives this reference current leef from the reference frequencies Fref or cure speed, and the electrical parameters of the rotating electrical machine 2. This reference current calculation block 12 transforms a reference current. mechanical reference in an electrical reference. After the reference voltages Vref have been calculated by the closed control loop 11, the pulse width modulation control block 30 generates the control signals U, V, W modulated in width. pulse (or PWM, acronym for "Pulse Width Modulation" in English terminology) of the inverter 4. With regard to the closed control loop 11, since it is a control system 1, the control can be achieved in different benchmarks. The well-known Clarke transformation is a projection of phase magnitudes on two fixed axes (11,6). Then the transformation of Clarke can be followed by a rotation which converts the alternative components of the reference (11,6) .in continuous components 10 on direct and quadrature axes (the mark (d, q)). The combination of a Clarke transformation and a rotation of the marker (ct, p) to the mark (d, q) is usually called a Park transformation. The main advantage of these transformations is a reduction in the order of the system (from 3 to 2) and a decoupling of the control variables.
[0008] Effective control of an electrical driving system 1 requires that the instantaneous currents ia, ib, ib are well known. For reliable operation of the electrical control system 1, the control strategy must be tolerant to a sensor fault 10. Then, the continuity of operation is ensured and the security constraints are met.
[0009] Currently, in the most demanding applications, hardware redundancy is used to overcome a sensor failure 10. This solution makes the design of the electric control system 1 more complex and increases the cost thereof. On the other hand, software redundancy is much more interesting because of its scalability in addition to its low cost. For this purpose, a diagnostic method based on an analysis of the waveforms of the currents in a rotating reference mark (d, q) is developed. This method, illustrated in FIG. 3, only needs the phase currents ia, ib, ib provided at the input 14, the electrical angle θ and the speed w to detect and identify the faulty sensor among the 10 is the assumption of a single sensor failure 10, but this assumption is realistic because the probability of the simultaneous failure of two sensors is very low. The analysis of the waveform of the currents in the rotating reference is detailed below. The equations of the currents are first given in the natural reference (a, b, c) and in the Park reference (d, q) in the usual operating mode, or nominal, in the absence of a sensor fault. (the index h indicates variables in this mode). In the natural coordinate system (a, b, c), we have the following nominal values: 'a, h = Icos (0) ibm 27c = I cos (0 -) / cm 27c = Icos (0 +) In the reference of Park (d, q), one computes 17: 1 1 1 Vi Vi = ii32 case 0 COS (0 - -an) cos (0 + -an) 3 3 -sine -sin (0-72t 3 3) -sin (e + 72t) The consequence of a faulty sensor is then modeled in a first case of an offset defect and in a second case of a gain defect.
[0010] In the first case, the measurements provided by the phase current sensors 10 are written for each of the three phases A, B, C: iam = ia, h + AIa ibm = ib, h + Aib 'cm = ic , h + Aic Olj: Dia, Dib and Dib are offsets on phases A, B and C respectively. m, ibm and icm are the measurements provided by the phase current sensors 10 of phases A, B and C respectively. Differences id, Tg between the measurements and the nominal values are obtained in the Park coordinate system by means of the equalities: 7. . lq = d '' dm - id, h / dm 10 15 1o, h the ib ic. When the nominal values / ah and are not known, they can be approximated by applying a sliding average over time to the values of the currents. For each of the phases A, B and C, we have: PhaseA Phase B PhaseC lid = 3 cos (0-273c), 27c Icc, = -2 cos (0 + -27c). 9, = - 3 sin (e - 3) /, 2 27c i = - isin (e +) i. <T 10 id = -2cos (eya 3 i = -2 sin (e) / aa In the reference in rotation, the currents id, h, id, t, are continuous in nominal mode When an offset fault occurs on one of the three phase current sensors 10, a sinusoidal component id, d is added to the currents continuous id, h, the, at the electrical frequency.
[0011] If the differences id, id are substantially zero 19 (with the noise), in the method according to the invention Flag Flags A, B, C 20 are generated representative of the absence of defect of the sensors 10 (Flag A, B , C = 0). On the other hand, if the differences id, id are substantially non-zero, in the method according to the invention, an analysis of the waveform 21 of the phase currents in the Park reference is carried out by defining a residual electric angle by the relation ares = arctan (- Iq / id), and by calculating a residual Wres pulsation by the expression Wres = deres / cit. In the first case of an offset defect, this residual Wres pulse is equal (to calculation and measurement errors) to the speed w, and in the second case to a gain defect, this residual pulsation Wres is twice the speed w, as will be shown below. This analysis of the waveform 21 of the phase currents in the Park coordinate system makes it possible in the method according to the invention to decide on the absence of a sensor fault (Flag A, B, C = 0) 23 if no alternating component at the frequencies co / 27 or cutrr is detected. If an alternating component is detected, in the method according to the invention, the fault is confirmed and a comparison 16 of the residual electrical angle θ with the electrical angle θ makes it possible to determine the phase A, B, C corresponding to the defective sensor. of the three phase current sensors 10: 3025890 9 - PhaseA PhaseB PhaseC cigs - am27c 93s - 93s = OEt-2n 3 3 According to the method of the invention, the flags Flag A, B, C 5 are then generated. the presence of a fault on one of the phase current sensors 10 (Flag A, B, C = 1). In the second case of sensor fault (gain defect), the measurements iam, ibm, icm provided by the phase current sensors 10 are written for each of the three phases A, B, C: 10 i am = G where Ga, Gb, Gc are the gains of the current sensors 10 of the phases A, B, C respectively (in nominal mode, Ga = Gb = Gc = 1), and I is the current flowing in the stator windings of the synchronous rotating electrical machine 2. Differences id, Tg between the measurements and the nominal values are obtained 18 in the Park reference frame by means of equalities: 'd = id, h -' dm .-. . When the nominal values id, and I are not known, they can be approximated by applying a sliding average over time to the values of the currents. We have for each of the phases A, B and C: PhaseA here = 1 (1-G,) I (1+ cos 20) 25 - -1 6 (1-Ga) / sin20 q - PhaseB id = -1 ( 1-Gb) I (1 + cos (20 -Ln)) I ig -1 (1-Gb) I sin (20 -47t) 3 3 Phase C id = -1 (1 -Gc) / (1 + cos (20 + -47c)) 1. 47c 3 i - (- 1 - Gc) / sin (20 + -) I q - 6 3 302 5 890 - 10 - These relationships clearly show that when a gain defect appears on one of the three current sensors of phase 10, a sinusoidal component id, q, is added to the continuous currents id, h, igh at twice the electrical frequency. The device for diagnosing phase current sensor faults 5 of a control system 1 of a synchronous rotary electric machine 2 of a motor vehicle, also referred to by the invention, is a specific module 25 implementing the method described above and integrated in the control unit 3 shown in FIG. 2. This specific module 25, according to an architecture known in the art, comprises: means of acquisition of the measurements of the phase currents ia, ib, ic provided by the sensors 10 and an electrical angle 6 of the control system 1; digital processing means for these measurements; flag generation means Flag A, B, C 20, 23, 24 signaling the absence or the presence of a fault on one of the sensors 10.
[0012] Since the control unit 3 already comprises a microprocessor, a microcontroller or a similar digital circuit, in particular implementing the closed control loop 11, these acquisition means, these digital processing means and these generation means are those of the control unit 3. A computer code, representative of the method according to the invention, stored in a memory 26, makes it possible to use this common architecture to: - execute the required Park transformation; - analyzing waveforms of phase currents in the Park coordinate system; detect the offset and / or gain defects of the sensors 10; - identify the faulty sensor.
[0013] The flags Flag A, B, C 20, 23, 24 are taken into account by the closed control loop 11 to reconfigure the processing algorithms so as to ensure continuity of operation of the control system 1, even in case of failure of one of the phase current sensors 10. The method and the device according to the invention are robust thanks to the use of a nonparametric approach independent of an electromechanical model of the machine 2. As it goes of itself, the invention is not limited to the single preferred embodiment described above. Other embodiments are not outside the scope of the present invention insofar as they result from the following claims.

权利要求:
Claims (12)
[0001]
CLAIMS1) A method for diagnosing (15, 16) phase current sensor faults (10) of a control system (1) of a synchronous rotating electrical machine (2) of a motor vehicle, characterized in that said method takes into account differences (id, Tg) between measurements provided (14) by said sensors (10) and nominal values of said phase currents (ie, ib, ic) in order to diagnose faults, said differences (id, 7q ) being calculated (18) in a rotation mark and being independent of an electromechanical model of said machine (2).
[0002]
2) A method for diagnosing (15, 16) phase current sensor faults (10) of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to claim 1, characterized in that what said landmark is a Park landmark (17).
[0003]
3) A method for diagnosing (15, 16) phase current sensor faults (10) of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to claim 2, characterized in that detecting said sensor faults if said differences (id, 7q) are substantially non-zero (19).
[0004]
4) A method for diagnosing (15, 16) phase current sensor failures (10) of a control system (1) of a synchronous rotating motor machine (2) of a motor vehicle according to claim 3, characterized in that detecting (21, 22) an offset defect of at least one of said sensors (10) if a residual pulse ((Aires) of said differences (id, 7q) is substantially equal to a measured speed (w ) of said steering system (1).
[0005]
5) Method for the diagnosis (15, 16) of phase current sensor faults (10) of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to Claim 3, characterized in that detecting (21, 22) a gain defect of at least one of said sensors (10) if a residual pulse of said differences (id, 7q) is substantially equal to twice a measured speed (w) of said steering system (1). 3025890 - 12 -
[0006]
6) Method for the diagnosis (15, 16) of phase current sensor faults (10) of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to any one of the claims 4 or 5 5, characterized in that it identifies (16) a defective sensor among said sensors (10) by comparing a year, g_leesiectrical measured (6) of said system (n pilot (1) a residual electric angle 1 defined by the relation: ares = arctan (- Tql id where id and Tg are the said differences.
[0007]
7) Device for diagnosing (25) phase current sensor defects (10) of a control system (1) of a synchronous rotating electric machine (2) of a motor vehicle suitable for carrying out the method according to any one of the preceding claims 1 to 6, of the type comprising: measurement acquisition means (1a, 1b, 0 provided by said sensors (10) and an electrical angle (6) of said system control means (1); - digital processing means of said measurements (la, ib, 0; - flag generating means signaling said sensor faults (10); characterized in that said processing means perform a transformation of Park.
[0008]
8) Device for diagnosing (25) phase current sensor faults (10) of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to Claim 7, characterized in that said processing means comprises waveform analysis means of said phase currents (ia, ib, ic) in a Park mark (17), said waveform analysis means including means for calculating a moving average over time. 30
[0009]
9) Device for diagnosing (25) phase current sensor failures (10) of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to claim 8, characterized in that said acquisition means also acquire a speed (w) of said control system (1) and in that said processing means further comprise means for detecting an offset defect and / or a gain defect of at least one of said sensors (10) as a function of said speed (w).
[0010]
10) Device for diagnosing (25) phase current sensor failures (10) 5 of a control system (1) of a synchronous rotary electric machine (2) of a motor vehicle according to claim 9, characterized in that said processing means further comprise means for identifying a faulty sensor among said sensors (10) as a function of said electric angle (e). 10
[0011]
11) Synchronous rotating electrical machine (2) comprising at least one integrated control system (1), characterized in that it comprises a diagnostic device (25) for phase current sensor defects of said control system (1) according to any one of the preceding claims 7 to 10. 15
[0012]
12) Computer memory (26) for semiconductor purposes for integration in a diagnostic device (25) for phase current sensor faults (10) of a control system (1) of a synchronous rotary electrical machine (2) Motor vehicle according to any one of claims 7 to 10 above, characterized in that it contains a computer code representative of the method 20 according to any one of claims 1 to 6 above.

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法律状态:
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2016-03-18| PLSC| Publication of the preliminary search report|Effective date: 20160318 |

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2017-09-29| PLFP| Fee payment|Year of fee payment: 4 |

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2019-09-30| PLFP| Fee payment|Year of fee payment: 6 |

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2020-09-30| PLFP| Fee payment|Year of fee payment: 7 |

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2021-09-30| PLFP| Fee payment|Year of fee payment: 8 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1458792|2014-09-17|

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FR1458792A|FR3025890B1|2014-09-17|2014-09-17|METHOD AND DEVICE FOR DIAGNOSING STATIC CURRENT SENSOR FAULTS OF A DRIVING SYSTEM OF A SYNCHRONOUS MOTOR VEHICLE ROTARY ELECTRIC MACHINE|FR1458792A| FR3025890B1|2014-09-17|2014-09-17|METHOD AND DEVICE FOR DIAGNOSING STATIC CURRENT SENSOR FAULTS OF A DRIVING SYSTEM OF A SYNCHRONOUS MOTOR VEHICLE ROTARY ELECTRIC MACHINE|

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EP15771683.8A| EP3195467A1|2014-09-17|2015-09-10|Method and device for diagnosing phase current sensor defects in a system for controlling a synchronous rotary electrical machine of a motor vehicle|

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US15/512,312| US10718845B2|2014-09-17|2015-09-10|Method and device for diagnosing phase current sensor defects in control system of synchronous rotary electric machine of motor vehicle|

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PCT/FR2015/052424| WO2016042238A1|2014-09-17|2015-09-10|Method and device for diagnosing phase current sensor defects in a system for controlling a synchronous rotary electrical machine of a motor vehicle|

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CN201580060959.7A| CN107112943B|2014-09-17|2015-09-10|Method and device for diagnosing a phase current sensor defect in a system for controlling a synchronous rotating electrical machine of a motor vehicle|

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JP2017514850A| JP2017533688A|2014-09-17|2015-09-10|Method and apparatus for diagnosing phase current sensor faults in a system for controlling a synchronous rotating electrical machine of a motor vehicle|