METHOD FOR DETECTING A SHORT CIRCUIT IN A SYNCHRONOUS MACHINE EQUIPPED WITH AN ANGULAR POSITION SENS

专利摘要:
The invention relates to a method for detecting a short-circuit between phases in a polyphase synchronous machine (1) comprising a stator (2) and a rotor (3), said machine being equipped with at least one angular position sensor. (la) of the rotor (3), the rotor (3) comprising means for generating a magnetic induction being provided to move around the stator (2), the angular position sensor (1a) comprising at least two measuring sensors of the magnetic induction (6), the measurement sensors of the induction (6), extending at an axial end (3a) of the rotor (3) facing and in the immediate vicinity of the axial edges (4a) means for generating a magnetic induction, characterized in that it consists in: i1) using the values measured and delivered by the inductive measurement sensors, i2) calculating the slope of the curve of the measured values as a function of time , i3) comparing the calculated slope with a threshold value Vs, and i4) if the computed slope is greater than or equal to the threshold value Vs, generating an alert signal S via the electronic unit and, if not, restarting step il).
公开号:FR3017959A1
申请号:FR1451456
申请日:2014-02-24
公开日:2015-08-28
发明作者:Pierre Dumas
申请人:Lohr Electromecanique SAS；
IPC主号:

专利说明:

[0001] TECHNICAL FIELD The present invention relates to the general technical field of angular position sensors as well as to the general technical field of synchronous machines comprising means for detecting a short-circuit in a synchronous machine equipped with an angular position sensor. to generate a magnetic induction and such a position sensor.
[0002] The present invention more particularly relates to a synchronous machine with sinusoidal electromotive force, comprising a position sensor for controlling the power supply of said machine. The invention finds its application mainly in synchronous machines powered by a polyphase alternating voltage.
[0003] The invention will be described hereinafter more particularly, but not exclusively, with means for generating a magnetic induction constituted by way of example embodiment of permanent magnets. A synchronous machine with permanent magnets consists of a wound stator and a rotor carrying the permanent magnets. Such a machine is powered and driven via a power electronics. A synchronous machine with permanent magnets and sinusoidal electromotive force can be controlled with a vector control system. This type of control, known as such, provides high performance, namely high accuracy and high torque dynamics. These performances are necessary, especially for traction motors. A control system for obtaining high performance, however, requires a precise knowledge of the angular position of the rotor and this in real time. The angular position of the rotor is generally given by a position sensor which consists in particular of a rotating part mechanically linked to the rotor. There are thus known different technologies for determining the angular position of the rotor. For example, the position sensor called "resolver", the incremental digital encoder or the absolute encoder.
[0004] These known technologies, however, have disadvantages. Indeed, these known position sensors all include a rotating part mechanically linked to the rotor. This constitutes an important constraint when designing the machine in which the position sensor must be integrated. The rotating portion of the angular position sensor is generally rotated through a drive tube. Such a drive tube generally passes through the stator and very often has significant inertia that can lead to a slower measurement of the angular position. The lack of precision associated with such a measurement leads to an impairment of the machine's performance. In addition, having to traverse the machine to retrieve angular position information substantially increases the complexity of the assembly. It is then necessary to use a larger number of mechanical parts, which increases the risk of failures. Moreover, during the first commissioning of a known synchronous machine, a so-called calibration operation must be performed by a converter. During this operation, the machine is rotating and the converter measures the angle corresponding to the zero crossing of the electromotive force. This calibration operation must be carried out again during a maintenance operation of the sensor change type, change of an electromagnetic part of the rotor or the stator, or change of the complete machine. Such a rigging operation is often very difficult to achieve, in particular for long vehicles of the railway vehicle type, since it is necessary to lift the said vehicles to allow free orientation of the wheels during stalling. The wedging operation is however very important because an angular offset between the measured angular position and the actual position of the rotor leads to a significant drop in the torque. For example, a shift of one mechanical degree leads to a torque drop of about 5% and an offset of two mechanical degrees leads to a torque drop of 20%. Known synchronous machines may also have failures related to a short circuit between two phases. Such a failure interrupts or greatly degrades the operation of the synchronous machine and repair can not be avoided. DISCLOSURE OF THE INVENTION The object of the present invention is therefore to provide a novel process for the detection of short-circuit between phases of a synchronous machine. Another object of the present invention is to implement such a detection method with simple, reliable, few and economical means. The objects assigned to the invention are achieved by means of a method of detecting a phase-to-phase short circuit in a polyphase synchronous machine comprising a stator and a rotor, said machine being equipped with at least one angular position of the rotor, the stator comprising a coil intended to be supplied with current, the rotor comprising means for generating a magnetic induction being provided to move around the stator, the angular position sensor comprising at least two measurement sensors of the rotor; magnetic induction and at least one electronic unit, the induction measurement sensors, fixed, extending at an axial end of the rotor facing and in the immediate vicinity of the axial edges of the means for generating a magnetic induction, characterized in that it consists in: il) using the values measured and delivered by the inductive measurement sensors, i2) calculating the slope that the curvature presents e measured values as a function of time, i3) comparing the calculated slope with a threshold value, i4) if the calculated slope is greater than or equal to the threshold value, generating an alert signal via the electronic unit and if not, go back to step 11). According to an exemplary implementation, the method according to the invention consists in repeating steps i1) to i4) with a frequency of between 0 and 1000 Hz. According to an exemplary implementation, the method according to the invention is to use the alert signal to interrupt the power supply of the synchronous machine. According to an exemplary implementation, the method according to the invention consists in using the alert signal to reconfigure the polyphase power supply of the synchronous machine.
[0005] According to another exemplary implementation, the method according to the invention consists in using the warning signal to interrupt the power supply of the synchronous machine. According to an exemplary implementation, the method according to the invention, the means for generating a magnetic induction used in the rotor are permanent magnets or electric windings. According to an exemplary implementation, the method according to the invention is implemented on a wheel motor of a vehicle.
[0006] The synchronous machine in which the process according to the invention is implemented advantageously constitutes a wheel motor of a rail or road vehicle. The method according to the invention has the remarkable advantage that it can detect via the rotor angular position sensor, a possible short-circuit between two phases of the synchronous machine. No additional detection system specific to the determination of a short-circuit between phases is therefore necessary in a synchronous machine in which the method according to the invention is implemented.
[0007] BRIEF DESCRIPTION OF THE FIGURES Other features and advantages of the invention will also emerge from the drawings given by way of nonlimiting illustration in which: FIG. 1 illustrates an exemplary embodiment of a synchronous machine in which the method is implemented; according to the invention; - Figure 2 shows a detail, in section, of Figure 1; FIG. 3 is an illustration of an exemplary embodiment of a removable support for the angular position sensor in front view, intended to be inserted into a synchronous machine in which the method according to the invention is implemented. ; - Figure 4 illustrates a block diagram of the electronic means necessary for the operation of the angular position sensor of a synchronous machine and therefore used to implement the method according to the invention; and FIG. 5 illustrates, using a block diagram, an example of a vector control system of a synchronous machine with permanent magnets and a sinusoidal electromotive force, in which the method according to the invention is implemented. .
[0008] FIG. 1 illustrates an exemplary embodiment of a synchronous machine 1 comprising an angular position sensor mounted on a stator 2 schematically illustrated in FIG. flange form mechanically secured to the stator 2.
[0009] The synchronous machine 1 also comprises a rotor 3 provided with permanent magnets 4. The end portion 2a covers at least partially and without contact an axial end 3a of the rotor 3. An example of an arrangement between the axial end 3a and the end portion 2a is illustrated in greater detail in FIG. 2. The stator 2 comprises a winding, not shown, intended to be supplied with polyphase current via a power electronics device also called a converter or inverter. The latter is advantageously supplied with voltage and current. The rotor 3 advantageously has a substantially cylindrical shape 3b whose inner face is covered with permanent magnets 4. The rotor 3 is intended to rotate around the portion of the stator 2 extending in the free space delimited internally to said rotor 3. The permanent magnets 4 are for example stacked in an axial direction in axial grooves formed in the inner face of the cylinder 3b. The mounting and fixing of the permanent magnets 4 on the inner face of the rotor 3 is carried out in a known manner. By way of example, the permanent magnets 4 are slidably introduced into axial grooves and held radially due to a complementarity of shapes of said grooves and said permanent magnets 4. The permanent magnets 4 are axially locked in each groove via a holding part 5 made of non-magnetic material, illustrated in more detail in FIG. 2. The holding piece 5 constitutes a stop 5a preventing axial movements of the permanent magnets 4 engaged in the corresponding groove. The dimensions and shapes of the holding part 5 are chosen so as not to hinder access to a localized area facing at least part of the axial edge 4a of the last permanent magnet 4 engaged in each groove. The axial end 3a of the cylinder 3b, which does not have permanent magnets 4, advantageously has a slightly flared shape in a radial direction. Such a conformation thus makes it possible to limit the space requirement resulting from the fixing of the holding part 5. A holding part 5 is advantageously fixed on the cylinder 3b at the end of each groove by means of a screw 51), thus axially blocking all rows of permanent magnets 4.
[0010] The synchronous machine 1 according to the invention also comprises an angular position sensor of the rotor 3. The angular position sensor comprises, in particular, sensors for measuring the magnetic induction 6. These are designed to detect the variation of the axial magnetic field. generated by the permanent magnets 4. This variation of the axial magnetic field is detected and transformed into a voltage delivered by the magnetic induction measurement sensors 6.
[0011] The angular position sensor also comprises at least one electronic unit designed to receive the induction voltages of the measuring sensors of the magnetic induction 6 and to deduce the angular position of the rotor 3. This determination is made absolutely. The electronic unit also makes it possible to transmit in real time relative information on the angular position of the rotor 3 to the power electronics device. The sensors for measuring the magnetic induction 6 are mechanically secured to the end portion 2a and extend at an axial end of the rotor 3, facing and in the immediate vicinity of the axial edges 4a of the last permanent magnets 4 engaged in the grooves. During the rotation of the rotor 3, each axial edge 4a therefore passes in front of the measuring sensors of the magnetic induction 6. The magnetic measurement sensors 6 are advantageously fixed on a removable support 7. The removable support 7 has for this purpose a axial support portion 7a and a support end portion 7b. The support end portion 7b extends substantially transversely to the axial support portion 7a. The sensors for measuring the magnetic induction 6 are arranged on an outer face 7c of the free end of the axial support portion 7a. The removable support 7 preferably has a curvature substantially conforming to the curvature of the rotor 3. The sensors for measuring the magnetic induction 6 are advantageously fixed and distributed on an external face 7c along a line whose curvature substantially matches the curvature of the the succession of axial edges 4a permanent magnets 4. The removable support 7 is for example introduced into a slot 8 formed in the end portion 2a. Of course the slot 8 has a curvature identical or similar to that presented by the axial support portion 7a. The removable support 7, once equipped with the magnetic induction measurement sensors 6, is introduced axially into the slot 8 until the stop of the portion of the support end 7b on the outside face of the part end 2a. The dimensions of the removable support 7, and in particular the axial length of the axial support portion 7a, are chosen so that the sensors for measuring the magnetic induction 6 extend at a distance e from the axial edges 4a. The distance e is for example between 1.5 and 2.5 millimeters and preferably equal to 2 millimeters. All types of fastening means, not shown, can also be used to secure the support end 7b with the end portion 2a. The synchronous machine 1 according to the invention comprises, according to an exemplary embodiment, at least three magnetic induction measurement sensors 6 arranged on a removable support 7. According to another exemplary embodiment, the synchronous machine 1 conforms to the The invention, illustrated in FIG. 1, comprises two removable supports 7 each of which is provided for example with at least two magnetic induction measurement sensors 6. FIG. 3 is a front view illustration of an exemplary embodiment of FIG. a removable support 7 comprising five magnetic induction measurement sensors 6. The synchronous machine 1 according to the invention thus comprises, according to an exemplary embodiment of FIG. 3, two removable supports 7 each comprising five induction measurement sensors. 6. Advantageously, the outer face 7c of the axial support portion 7a is provided with a temperature sensor 9. The latter makes it possible to use the ambient temperature of the synchronous machine 1 for adjust its control, because the induction depends on the temperature. According to a preferred embodiment, the removable support 7 comprises at least one electronic circuit of the electronic unit or part of an electronic circuit of said electronic unit. For example, the power electronics device is a converter controlling the synchronous machine 1 by a modulation of pulse widths. The sensors for measuring the magnetic induction 6 are preferably Hall effect sensors. According to another example of the embodiment of the synchronous machine 1 according to the invention, the magnetic induction measurement sensors 6 consist of AMR / GMR sensors, called magnetoresistance sensors. While Hall effect sensors measure the DC component of the magnetic field, magnetoresistance sensors exhibit operation based on the variation in the electrical resistance of a material as a function of the direction of the magnetic field applied thereto. These sensors are known as such and are therefore not described further. By using Hall effect sensors or magnetoresistance sensors, the wedging operation of the angular position sensor is no longer necessary. Indeed, these sensors measure the spatial distribution of the magnetic field generated by the permanent magnets 4 and even when the synchronous machine 1 is stopped. This makes it possible to dispense with any calibration operation at the commissioning of the synchronous machine 1 or following a maintenance operation of said synchronous machine 1. This therefore results in a remarkable advantage for the synchronous machine 1 according to to the invention. FIG. 4 is a synoptic illustration of the electronic means necessary for the operation of the angular position sensor 1a of the synchronous machine 1 according to the invention. The latter therefore comprises the wound stator 2 and the rotor 3 comprising the permanent magnets 4.
[0012] The angular position sensor thus comprises functional means, which include induction measurement sensors 6, associated with the electronic unit for acquiring a signal and for calculating the positioning angle of the rotor. 3. The functional means consist, for example, of two magnetic induction measurement sensors 6 mounted fixed, without contact and facing the permanent magnets 4. The information from these induction measurement sensors 6 is then amplified and filtered respectively by amplification means 10 and filtration means 11 before a computer 12 acquires said information. This calculator 12 of the electronic unit thus determines the rotor angle (angular position of the rotor) from the information from the induction measurement sensors 6 and communicates in real time the rotor angle to a vector control system 13, which controls a converter 14. The communication of the rotor angle to the vector control system 13 is performed via a field bus type protocol like SSI, PROFIBUS or others. In addition, the sign of the rotor angle determined by the computer 12, defines the direction of rotation of the synchronous machine 1 according to the invention. FIG. 5 illustrates, using a block diagram, the vector control system 13 of a synchronous machine 1 with permanent magnets 4 and a sinusoidal electromotive force. In this vector control example, the synchronous machine 1 comprises the converter 14 powered by a voltage. The vector control system 13 makes it possible to control the converter 14 by means of PWM pulse width modulation to generate an average supply voltage on each of the phases P1, P2, P3 of the synchronous machine 1 and by consequently, a determined current in each of said phases P1, P2, P3. The converter 14 thus transforms a voltage delivered by a DC voltage source U into a three-phase supply voltage of the synchronous machine 1. The latter thus operates in traction mode and alternately in a three-phase voltage generator, for example when a vehicle is in operation. a braking phase. The vector control system 13 comprises a control unit of the converter 14, current sensors 15, a voltage sensor 16 and the angular position sensor 1a of the synchronous machine 1. The vector control system 13 receives for example the instruction of torque C. From the information from the current sensors 15 and the angular position sensor 1a and from the setpoint C, the control unit of the converter 14 calculates the voltage vector to be applied to said converter 14 so that the synchronous machine 1 reaches the torque setpoint C. The vector control system 13, in particular a synchronous machine 1 with permanent magnets 4 and sinusoidal electromotive force, is known as such and will therefore not be described further in FIG. the current. The synchronous machine 1 according to the invention has the remarkable advantage that it comprises an angular position sensor 1a making it possible to carry out a direct measurement of the magnetic field produced by the permanent magnets 4 and consequently to know the evolution of said magnetic field as a function of time. This makes it possible to detect a deterioration of the performance of the permanent magnets 4 and consequently the performance of the synchronous machine 1.
[0013] Moreover, the angular position sensor 1a of the synchronous machine 1 makes it possible to detect a sudden increase in the induced magnetic field, resulting from a short-circuit between phases. The synchronous machine 1 thus makes it possible to implement a short-circuit detection method between two phases in accordance with the invention and this by means of a succession of steps explained hereinafter. According to a first step II), the values B (t) measured and delivered by the induction measurement sensors 6 are used. In a second step i2), the slope dB (t) / dt ( time derivative) of the curve of measured values B (t) as a function of time. According to a third step i3), the calculated slope dB (t) / dt is compared to a threshold value Vs. Then according to a fourth step i4), if the calculated slope dB (t) / dt is greater than or equal to the threshold value Vs, an alert signal S is generated by means of the electronic unit and, in the opposite case, step i 1) is resumed.
[0014] Advantageously, the process according to the invention consists in repeating steps 11) to 14) continuously. According to an exemplary implementation of the detection method, the alert signal S allows the power supply of the synchronous machine 1 to be interrupted.
[0015] According to another example of implementation of the detection method, the alert signal S reconfigures the polyphase power supply of the synchronous machine 1. With the computer 12, it is possible to determine simultaneously the absolute angular position of the rotor 3 and a short circuit according to the method described above. The computer 12 can thus identify the phases to be isolated from the synchronous machine 1 and control accordingly the power supply of said synchronous machine 1. The synchronous machine 1 with permanent magnets 4 and sinusoidal electromotive force advantageously constitutes a motor-wheel .
[0016] The synchronous machine 1 can also be used as a winch motor or as an elevator motor. It is obvious that the present description is not limited to the examples explicitly described, but also includes other embodiments and / or implementation. Thus, a described technical feature can be replaced by an equivalent technical characteristic, without departing from the scope of the present invention.

权利要求:
Claims (7)
[0001]
REVENDICATIONS1. A method for detecting a phase-to-phase short circuit in a polyphase synchronous machine (1) comprising a stator (2) and a rotor (3), said machine (1) being equipped with at least one angular position sensor (the ) of the rotor (3), the stator (2) comprising a coil adapted to be supplied with current, the rotor (3) comprising means for generating a magnetic induction being arranged to move around the stator (2), the sensor of angular position (la) comprising at least two magnetic induction measuring sensors (6) and at least one electronic unit, the fixed induction measuring sensors (6) extending at one end axial axis (3a) of the rotor (3) facing and in the immediate vicinity of the axial edges (4a) means for generating a magnetic induction, characterized in that it consists in: it) using the values measured and delivered by the sensors of induction measure (6), i2) calculate the slope dB (t) / dt that the curve of measured values as a function of time, i3) comparing the calculated slope dB (t) / dt with a threshold value, i4) if the calculated slope is greater than or equal to the threshold value Vs, generating an alert signal S via the electronic unit and if not resume step II).
[0002]
2. Method according to claim 1, characterized in that it consists in repeating the steps il) to i4) continuously.
[0003]
3. Method according to claim 1 or 2, characterized in that it consists in using the alert signal S to interrupt the power supply of the synchronous machine (1).
[0004]
4. Method according to claim 1 or 2, characterized in that it consists in using the alert signal S to reconfigure the polyphase power supply of the synchronous machine (1).
[0005]
5. Method according to any one of claims 1 to 4, characterized in that the means for generating a magnetic induction used in the rotor (3) are permanent magnets (4).
[0006]
6. Method according to any one of claims 1 to 4, characterized in that the means for generating a magnetic induction used in the rotor (3) consist of electric windings.
[0007]
7. Method according to any one of claims 1 to 6, characterized in that it is implemented on a wheel motor of a vehicle.

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同族专利:

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公开号 | 公开日

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AU2015220637A1|2016-09-15|

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US20170070177A1|2017-03-09|

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KR20160124855A|2016-10-28|

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WO2015124855A1|2015-08-27|

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FR3017959B1|2017-08-25|

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EP3111243A1|2017-01-04|

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CN106258001A|2016-12-28|

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CA2938723A1|2015-08-27|

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US9906185B2|2018-02-27|

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CN106258001B|2019-06-14|

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AU2015220637B2|2018-12-13|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

DE3405225A1|1983-02-24|1984-08-30|Elin-Union Aktiengesellschaft für elektrische Industrie, Wien|Device for detecting shorted turns|

---

FR2680920A1|1991-08-28|1993-03-05|Bosch Gmbh Robert|Electric motor with a device for detecting the position of the rotor, the speed of rotation and/or the direction of rotation|

---

EP0552991A2|1992-01-23|1993-07-28|Ontario Hydro|Method and apparatus for detecting stator faults in rotary dynamoelectric machines|

---

US20130033215A1|2011-08-01|2013-02-07|Illinois Institute Of Technology|Apparatus and method for permanent magnet electric machine condition monitoring|

---

FR2461857B1|1979-07-24|1984-05-25|Renault|

---

US4837519A|1985-09-06|1989-06-06|Southern California Edison Company|Fault detection|

---

US5030917A|1990-04-20|1991-07-09|General Electric Company|Transient rotor fault detection in induction and synchronous motors|

---

DE59913902D1|1998-03-21|2006-11-23|Ebm Papst St Georgen Gmbh & Co|Electronically commutated motor|

---

US6774664B2|1998-09-17|2004-08-10|Danfoss Drives A/S|Method for automated measurement of the ohmic rotor resistance of an asynchronous machine|

---

US6573745B2|2001-05-04|2003-06-03|Ford Global Technologies, Inc.|Permanent magnet degradation monitoring for hybrid and electric vehicles|

---

US7064513B2|2003-10-01|2006-06-20|J. L. Behmer Corporation|Phase angle control for synchronous machine control|

---

JP3799362B1|2005-08-25|2006-07-19|山洋電気株式会社|Rotating electric machine with magnetic sensor|

---

CN105871143B|2006-07-24|2018-07-20|株式会社东芝|Variable magnetic flux motor drive system|

---

DE102008059005A1|2008-11-25|2010-05-27|Schaeffler Kg|Adjusting device for adjusting a relative angular position of two shafts and method for operating an actuator, in particular such an adjusting device|

---

JP5194083B2|2010-09-22|2013-05-08|山洋電気株式会社|Method and apparatus for determining deterioration of permanent magnet of electrical equipment|

---

US8654487B2|2011-03-11|2014-02-18|Siemens Industry, Inc.|Methods, systems, and apparatus and for detecting parallel electrical arc faults|

---

AT511807B1|2011-08-01|2013-03-15|Univ Wien Tech|METHOD AND DEVICE FOR ONLINE RECOGNITION OF STATE-OF-CHARGE INSULATION IN AN ELECTRICAL MACHINE|

---

GB2483177B|2011-10-19|2013-10-02|Protean Electric Ltd|An electric motor or generator|

---

DE102011056252A1|2011-12-09|2013-06-13|E-Motiontech GmbH|Permanent-magnet synchronous motor for automobile engine, has magnetic sensors to measure magnetic field of permanent magnets, and evaluation unit to evaluate measurement signals from sensors so as to determine motor status parameters|

---

FR2987439B1|2012-02-28|2014-11-21|Vishay S A|ROTARY POSITION SENSOR DEVICE AND APPARATUS INCLUDING SUCH A DEVICE|

---

US9625512B2|2014-01-08|2017-04-18|Caterpillar Inc.|Detecting ground fault location|US10284055B2|2015-09-01|2019-05-07|Mitsubishi Electric Corporation|Actuator and method of adjusting actuator|

---

FR3058790B1|2016-11-14|2018-11-02|Safran Electronics & Defense|CONTACTLESS ANGULAR SENSOR|

---

US10371736B2|2017-02-28|2019-08-06|Delphi Technologies Ip Limited|Short-circuit pinpointing device|

---

DE102018000473A1|2018-01-23|2019-07-25|Alexandre Imas|Magnetic sensor for measuring the components of the stator field vector in three-phase machines|

法律状态:
2016-02-25| PLFP| Fee payment|Year of fee payment: 3 |

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2017-02-27| PLFP| Fee payment|Year of fee payment: 4 |

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2018-02-26| PLFP| Fee payment|Year of fee payment: 5 |

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2020-02-26| PLFP| Fee payment|Year of fee payment: 7 |

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2021-11-12| ST| Notification of lapse|Effective date: 20211005 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1451456A|FR3017959B1|2014-02-24|2014-02-24|METHOD FOR DETECTING A SHORT CIRCUIT IN A SYNCHRONOUS MACHINE EQUIPPED WITH AN ANGULAR POSITION SENSOR|FR1451456A| FR3017959B1|2014-02-24|2014-02-24|METHOD FOR DETECTING A SHORT CIRCUIT IN A SYNCHRONOUS MACHINE EQUIPPED WITH AN ANGULAR POSITION SENSOR|

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PCT/FR2015/050367| WO2015124855A1|2014-02-24|2015-02-16|Method for detecting a short circuit in a synchronous machine fitted with an angular position sensor|

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CN201580010090.5A| CN106258001B|2014-02-24|2015-02-16|Method for detecting the short circuit in the synchronous machine equipped with angular position pick up|

---

KR1020167025878A| KR20160124855A|2014-02-24|2015-02-16|Method for detecting a short circuit in a synchronous machine fitted with an angular position sensor|

---

CA2938723A| CA2938723A1|2014-02-24|2015-02-16|Method for detecting a short circuit in a synchronous machine fitted with an angular position sensor|

---

AU2015220637A| AU2015220637B2|2014-02-24|2015-02-16|Method for detecting a short circuit in a synchronous machine fitted with an angular position sensor|

---

US15/119,972| US9906185B2|2014-02-24|2015-02-16|Method for detecting a short circuit in a synchronous machine fitted with an angular position sensor|

---

EP15709255.2A| EP3111243A1|2014-02-24|2015-02-16|Method for detecting a short circuit in a synchronous machine fitted with an angular position sensor|