Apparatus for measuring excitation parameters of induction motor and method thereof
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01R-031/30
G01R-031/34
출원번호
US-0540077
(2012-07-02)
등록번호
US-9435864
(2016-09-06)
우선권정보
CN-2011 1 0317304 (2011-10-18)
발명자
/ 주소
Gao, Zhiguang
Lu, Cheng
Ying, Jianping
출원인 / 주소
Delta Electronics (Shanghai) CO., LTD
대리인 / 주소
Ren, Yunling
인용정보
피인용 횟수 :
0인용 특허 :
3
초록▼
The present invention relates to the technical field of motor control, and discloses an apparatus for measuring excitation parameters of an induction motor and a method thereof. The method comprises: maintaining the induction motor static, and inputting a test current to a test phase of the inductio
The present invention relates to the technical field of motor control, and discloses an apparatus for measuring excitation parameters of an induction motor and a method thereof. The method comprises: maintaining the induction motor static, and inputting a test current to a test phase of the induction motor; and calculating, based on a voltage of the test phase of the induction motor, a stator flux linkage of the test phase of the induction motor corresponding to a magnitude of the test current. The disclosure can conveniently and accurately measure excitation parameters of the induction motor.
대표청구항▼
1. An apparatus for measuring excitation parameters of an induction motor, comprising: a control unit, a power converter, and an excitation parameter calculating unit, wherein: the power converter is for providing a test current to a test phase of the induction motor, and an output of the power conv
1. An apparatus for measuring excitation parameters of an induction motor, comprising: a control unit, a power converter, and an excitation parameter calculating unit, wherein: the power converter is for providing a test current to a test phase of the induction motor, and an output of the power converter maintains the induction motor static;the control unit is equipped with a current instruction for indicating the test current, and the control unit is for regulating the test current provided by the power converter to be equivalent to the current instruction, meanwhile controlling the output of the power converter to maintain the induction motor static; andthe excitation parameter calculating unit is for receiving a voltage signal of a test phase of the induction motor and a current signal of the test phase of the induction motor to calculate the excitation parameters. 2. The apparatus according to claim 1, wherein the control unit comprises: a comparator, equipped with the current instruction, and for receiving a sample signal of the test current and comparing the sample signal with the current instruction to output an error of the current signal; anda regulator, for receiving the error of the current signal, regulating the test current provided by the power converter to be equivalent to the current instruction, and controlling the output of the power converter to maintain the induction motor static. 3. The apparatus according to claim 2, wherein the regulator comprises: a test phase regulator and a signal converter, wherein: the test phase regulator is for receiving the error of the current signal, and outputting a test phase voltage instruction for indicating a test phase voltage output by the power converter; andthe signal converter is for receiving the test phase voltage instruction, controlling the test phase voltage provided by the power converter to be equivalent to the test phase voltage instruction, and meanwhile controlling the output of the power converter to maintain the induction motor static. 4. The apparatus according to claim 3, wherein the voltage signal of the test phase received by the excitation parameter calculating unit is the test phase voltage instruction. 5. The apparatus according to claim 1, wherein the current signal of the test phase received by the excitation parameter calculating unit is a sample signal of the test current. 6. The apparatus according to claim 1, wherein the current signal of the test phase received by the excitation parameter calculating unit is the current instruction. 7. The apparatus according to claim 1, wherein the voltage signal of the test phase received by the excitation parameter calculating unit is a sample signal of a test phase voltage of the induction motor. 8. The apparatus according to claim 1, wherein the output of the power converter maintains the induction motor static by the following settings: the test current or the test phase voltage provided by the power converter to the test phase of the induction motor equals a sum of magnitudes of currents or voltages provided to another two non-test phases of the induction motor, and a direction of the test current or the test phase voltage is opposite to a direction of the currents or the voltages provided to the two non-test phases; orthe test current or the test phase voltage provided by the power converter to the test phase of the induction motor equals a magnitude of a current or a voltage provided to one non-test phase of the induction motor, and a direction of the test current or the test phase voltage is opposite to a direction of the current or the voltage provided to said one non-test phase, and another non-test phase of the induction motor is electrically disconnected from the power converter or none of current or voltage is provided by the power converter to said another non-test phase of the induction motor. 9. The apparatus according to claim 1, wherein the current instruction is a single periodic current instruction or a periodic current instruction with different current magnitude for each period. 10. The apparatus according to claim 9, wherein a periodic waveform of the current instruction comprises a point-symmetric waveform with respect to a point in corresponding periodic time zone, and the point-symmetric waveform comprises three waveform segments: a negative direct-current waveform segment, a positive-negative alternating waveform segment, and a positive direct-current waveform segment. 11. The apparatus according to claim 10, wherein the periodic waveform of the current instruction is a point-symmetric trapezoidal waveform with respect to a midpoint in corresponding periodic time zone. 12. The apparatus according to claim 10, wherein the periodic waveform of the current instruction comprises two half waveform segments axis-symmetric to each other, and each half waveform segment is a point-symmetric waveform with respect to a midpoint in the periodic time zone corresponding to the half waveform segment. 13. The apparatus according to claim 12, wherein the periodic waveform of the current instruction consists of two half-periodic waveform segments which are axis-symmetric to each other, and each half-periodic waveform segment is a point-symmetric trapezoidal waveform with respect to the midpoint in the periodic time zone corresponding to the half-periodic waveform segment. 14. The apparatus according to claim 9, wherein the excitation parameter calculating unit calculates one or multiple groups of excitation parameters of the test phase of the induction motor corresponding to a magnitude or magnitudes of the current instruction. 15. A method for measuring excitation parameters of an induction motor, comprising: maintaining the induction motor static, and inputting a test current to a test phase of the induction motor; andcalculating, performed by an excitation parameter calculating unit, based on a voltage of the test phase of the induction motor, a stator flux linkage of the test phase of the induction motor corresponding to a magnitude of the test current;wherein maintaining the induction motor static comprises controlling a magnitude and a direction of volts voltage or current provided to the test phase and non-test phases of the induction motor, in which:the test current or the voltage provided by a power converter to the test phase of the induction motor respectively equals a sum of the magnitudes of currents or the magnitudes of voltages provided to another two non-test phases of the induction motor, and the direction of the test current or the voltage is opposite to a direction of currents or voltages provided to the two non-test phases; orthe test current or the voltage provided by the power converter to the test phase of the induction motor respectively equals the magnitude of current or the magnitude of voltage provided to one non-test phase of the induction motor, and the direction of the test current or the voltage is opposite to the direction of current or voltage provided to said one non-test phase, and another non-test phase of the induction motor is electrically disconnected from the power converter or none of current or voltage is provided by the power converter to said another non-test phase of the induction motor. 16. The method according to claim 15, wherein the test current is a single periodic test current or a periodic test current with the magnitude varying. 17. The method according to claim 16, wherein a periodic waveform of the test current comprises a point-symmetric waveform with respect to a point in a periodic time zone, and the point-symmetric waveform comprises three waveform segments: a negative direct-current waveform segment, a positive-negative alternating waveform segment, and a positive direct-current waveform segment. 18. The method according to claim 17, wherein the magnitude of the test current equals a magnitude of the positive direct-current waveform segment or an absolute value of a magnitude of the negative direct-current waveform segment, and the magnitude of the test current approximately equals a magnitude of an excitation current. 19. The method according to claim 18, wherein obtaining, based on the voltage of the test phase of the induction motor corresponding to the magnitude of the test current, the stator flux linkage corresponding to the magnitude of the excitation current or a curve of the stator flux linkage corresponding to different magnitudes of the excitation current. 20. The method according to claim 19, wherein, calculating, based on the stator flux linkage and corresponding magnitude of the excitation current, an air gap flux linkage; or calculating, based on the curve of the stator flux linkage corresponding to different magnitudes of the excitation current, a curve of the air gap flux linkage corresponding to different magnitudes of the excitation current. 21. The method according to claim 19, wherein obtaining, based on the curve of the stator flux linkage and a nominal stator flux linkage, a nominal excitation current corresponding to the nominal stator flux linkage. 22. The method according to claim 21, wherein obtaining, based on the nominal stator flux linkage and the nominal excitation current, a nominal air gap flux linkage and a nominal excitation inductance. 23. The method according to claim 17, wherein the periodic waveform of the test current is a point-symmetric trapezoidal waveform with respect to a midpoint in the periodic time zone. 24. The method according to claim 17, wherein the calculated stator flux linkage is a half of an absolute value of a variation of the stator flux linkage ranged from the negative direct-current waveform segment to the positive direct-current waveform segment of the point-symmetric waveform in each period of the test current. 25. The method according to claim 17, wherein each periodic waveform of the test current comprises two half waveform segments which are axis-symmetric to each other, and each half waveform segment is a point-symmetric waveform with respect to a point in the periodic time zone corresponding to the half waveform segment. 26. The method according to claim 25, wherein the periodic waveform of the test current consists of two half-periodic waveform segments which are axis-symmetric to each other, and each half-periodic waveform segment is a point-symmetric trapezoidal waveform with respect to a midpoint in the periodic time zone corresponding to the half-periodic waveform segment. 27. The method according to claim 25, wherein calculating the stator flux linkage corresponding to a single period of the test current comprises: calculating the stator flux linkage respectively corresponding to the two half waveform segments to obtain a first stator flux linkage and a second stator flux linkage in the period of the test current; andcalculating a half of the absolute value of difference value between the first stator flux linkage and the second stator flux linkage as the stator flux linkage in the period of the test current.
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