Inverter control device and power conversion device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H02P-021/00
H02P-027/04
출원번호
US-0989799
(2009-04-28)
등록번호
US-8736220
(2014-05-27)
우선권정보
JP-2008-117102 (2008-04-28)
국제출원번호
PCT/JP2009/001939
(2009-04-28)
§371/§102 date
20101027
(20101027)
국제공개번호
WO2009/133700
(2009-11-05)
발명자
/ 주소
Ogawa, Takurou
Hibino, Hiroshi
Tomoe, Masanobu
출원인 / 주소
Daikin Industries, Ltd.
대리인 / 주소
Birch, Stewart, Kolasch & Birch, LLP.
인용정보
피인용 횟수 :
18인용 특허 :
18
초록▼
A DC voltage value from a DC voltage detection section is input directly to a voltage correction section without passing through a compensator or a filter. Therefore, even when rapid voltage change occurs, such as short power interruptions, instantaneous voltage drop and return from instantaneous vo
A DC voltage value from a DC voltage detection section is input directly to a voltage correction section without passing through a compensator or a filter. Therefore, even when rapid voltage change occurs, such as short power interruptions, instantaneous voltage drop and return from instantaneous voltage drop, the voltage correction section can quickly perform the correction operation in response to the rapid voltage change. Since the amount of link resonance compensation is limited by the limitation section to a certain range, it is possible to prevent the amount of link resonance compensation from fluctuating excessively upon rapid voltage change. Since the amount of link resonance compensation which is limited by the limitation section to a certain range is input to one compensator that has an appropriate control band, among all control calculation sections, the response does not have to be unnecessarily fast, thus realizing a stable control.
대표청구항▼
1. An inverter control device for controlling an inverter which converts DC power supplied thereto via an LC filter including a reactor and a capacitor into AC power having an intended frequency and an intended voltage value, and supplies the converted power to an AC motor, wherein a fluctuation com
1. An inverter control device for controlling an inverter which converts DC power supplied thereto via an LC filter including a reactor and a capacitor into AC power having an intended frequency and an intended voltage value, and supplies the converted power to an AC motor, wherein a fluctuation component detection section configured to allow passage of a resonance frequency of the LC filter allows the inverter control device, within a predetermined frequency band of fluctuation of a DC voltage supplied to the inverter, to increase an inverter output voltage supplied from the inverter to a motor when the DC voltage increases, and to decrease the inverter output voltage when the DC voltage decreases, whereas the inverter control device is configured, within a frequency region that is an upper frequency region above the predetermined frequency band of the DC voltage and that is a frequency region of fluctuation when a power supply and a voltage rapidly change and a lower frequency region below the predetermined frequency band, to reduce fluctuation of the inverter output voltage due to fluctuation of the DC voltage, the predetermined frequency band of the DC voltage fluctuation including at least the resonance frequency of the LC filter, and being less than or equal to a frequency band of a feedback control in a current controller configured to control such that a current supplied to the AC motor follows a command value. 2. The inverter control device of claim 1, wherein the predetermined frequency band is set to be less than a frequency of voltage ripples due to an AC power supply. 3. The inverter control device of claim 2, wherein the inverter control device operates based on an amount of fluctuation of a predetermined frequency band component of the DC voltage so as to decrease a rate of increase in an inverter output voltage supplied from the inverter to the motor with respect to an amount of increase in the DC voltage, and to decrease a rate of decrease in the inverter output voltage with respect to an amount of decrease in the DC voltage, as the amount of fluctuation is larger. 4. The inverter control device of claim 1, wherein the inverter control device operates based on an amount of fluctuation of a predetermined frequency band component of the DC voltage so as to decrease a rate of increase in an inverter output voltage supplied from the inverter to the motor with respect to an amount of increase in the DC voltage, and to decrease a rate of decrease in the inverter output voltage with respect to an amount of decrease in the DC voltage, as the amount of fluctuation is larger. 5. An inverter control device for controlling an inverter which converts DC power supplied thereto via an LC filter including a reactor and a capacitor into AC power having an intended frequency and an intended voltage value, and supplies the converted power to an AC motor, the inverter control device comprising: control calculation sections for calculating an output voltage command;an output voltage correction section for directly receiving a DC voltage value from a DC voltage detection section which detects a voltage of DC power supplied to the inverter so as to correct an output voltage command from the control calculation sections based on the DC voltage value;a PWM calculation section for calculating a control signal for PWM-controlling the inverter based on an output voltage command from the output voltage correction section;a fluctuation component detection section for detecting a fluctuation component (the fluctuation component at least not including a DC component and including a resonance frequency (f0) component of the LC filter) of the DC voltage detected by the DC voltage detection section;a link resonance compensation section for calculating an amount of compensation (amount of link resonance compensation) for reducing link resonance due to the LC filter based on the fluctuation component detected by the fluctuation component detection section;a limitation section for limiting the amount of link resonance compensation to a predetermined range; anda correction section for correcting, by the amount of link resonance compensation limited by the limitation section, an input command to one of the compensators in the control calculation section that has such a control band with which it is possible to control the resonance frequency (f0) of the LC filter. 6. The inverter control device of claim 5, wherein the input command to the one compensator in the control calculation section is a torque command or a current command. 7. The inverter control device of claim 5, wherein a limitation value of the limitation section is set to a value that is smaller than an amplitude of a resonance component due to the LC filter where there is no correction by the amount of link resonance compensation. 8. The inverter control device of claim 5, wherein the DC power supplied to the inverter is supplied by a converter which converts AC power from the AC power supply into DC power, andthe fluctuation component detection section includes a voltage ripple detection section for detecting the ripple component due to the AC power supply of the DC voltage detected by the DC voltage detection section, and removes the ripple component detected by the voltage ripple detection section from the fluctuation component. 9. The inverter control device of claim 5, wherein the DC power supplied to the inverter is supplied by a converter which converts AC power from the AC power supply into DC power, andthe reactor and the capacitor of the LC filter are selected so that the resonance frequency (f0) thereof is a frequency excluding frequencies that are integral multiples of the ripple component due to the AC power supply of a voltage of the DC power supplied to the inverter and frequencies in vicinity thereof. 10. The inverter control device of claim 5, wherein the inverter control device further includes a voltage abnormality detection section for detecting voltage abnormality of the DC voltage detected by the DC voltage detection section, andthe limitation section adjusts the range of limitation based on a detection result of the voltage abnormality detection section. 11. The inverter control device of claim 5, wherein the inverter control device further includes a voltage abnormality detection section for detecting voltage abnormality of the DC voltage detected by the DC voltage detection section, andthe link resonance compensation section adjusts the amount of link resonance compensation based on a detection result of the voltage abnormality detection section. 12. A power conversion device comprising: a converter section for converting AC power from an AC power supply into DC power;an LC filter including a reactor and a capacitor;an inverter section, to which the DC power from the converter section is supplied via the LC filter, for converting the DC power into AC power having an intended frequency and an intended voltage value, and supplying the converted power to an AC motor; andan inverter control section for controlling the inverter section, whereinwithin a predetermined frequency band of fluctuation of a DC voltage supplied to the inverter, a fluctuation component detection section configured to allow passage of a resonance frequency of the LC filter allows the inverter control section to increase an inverter output voltage supplied from the inverter to a motor when the DC voltage increases, and to decrease the inverter output voltage when the DC voltage decreases, whereas, within a frequency region that is an upper frequency region above the predetermined frequency band of the DC voltage and that is a frequency region of fluctuation when a power supply and a voltage rapidly change and a lower frequency region below the predetermined frequency band, the inverter control section reduces fluctuation of the inverter output voltage due to fluctuation of the DC voltage, the predetermined frequency band of the DC voltage fluctuation including at least the resonance frequency of the LC filter, and being less than or equal to a frequency band of a feedback control in a current controller configured to control such that a current supplied to the AC motor follows a command value. 13. The power conversion device of claim 12, wherein the predetermined frequency band is set to be less than a frequency of voltage ripples due to the AC power supply. 14. The power conversion device of claim 13, wherein the power conversion device operates based on an amount of fluctuation of a predetermined frequency band component of the DC voltage so as to decrease a rate of increase in an inverter output voltage supplied from the inverter to the motor with respect to an amount of increase in the DC voltage, and to decrease a rate of decrease in the inverter output voltage with respect to an amount of decrease in the DC voltage, as the amount of fluctuation is larger. 15. The power conversion device of claim 12, wherein the power conversion device operates based on an amount of fluctuation of a predetermined frequency band component of the DC voltage so as to decrease a rate of increase in an inverter output voltage supplied from the inverter to the motor with respect to an amount of increase in the DC voltage, and to decrease a rate of decrease in the inverter output voltage with respect to an amount of decrease in the DC voltage, as the amount of fluctuation is larger. 16. A power conversion device comprising: a converter section for converting AC power from an AC power supply into DC power;an LC filter including a reactor and a capacitor;an inverter section, to which the DC power from the converter section is supplied via the LC filter, for converting the DC power into AC power having an intended frequency and an intended voltage value, and supplying the converted power to an AC motor; andan inverter control section for controlling the inverter section, the inverter control section comprising:a DC voltage detection section for detecting a voltage of the DC power supplied to the inverter section;control calculation sections for calculating an output voltage command;an output voltage correction section for directly receiving a DC voltage value detected by the DC voltage detection section so as to correct an output voltage command from the control calculation sections based on the DC voltage value;a PWM calculation section for calculating a control signal for PWM-controlling the inverter section based on an output voltage command from the output voltage correction section;a fluctuation component detection section for detecting a fluctuation component (the fluctuation component at least not including a DC component and including a resonance frequency (f0) component of the LC filter) of the DC voltage detected by the DC voltage detection section;a link resonance compensation section for calculating an amount of compensation (amount of link resonance compensation) for reducing link resonance due to the LC filter based on the fluctuation component detected by the fluctuation component detection section;a limitation section for limiting the amount of link resonance compensation to a predetermined range; anda correction section for correcting, by the amount of link resonance compensation limited by the limitation section, an input command to one of the compensators in the control calculation section that has such a control band with which it is possible to control the resonance frequency (f0) of the LC filter. 17. The power conversion device of claim 16, wherein the input command to the one compensator in the control calculation section is a torque command or a current command. 18. The power conversion device of claim 16, wherein a limitation value of the limitation section is set to a value that is smaller than an amplitude of a resonance component due to the LC filter where there is no correction by the amount of link resonance compensation. 19. The power conversion device of claim 16, wherein the fluctuation component detection section includes a voltage ripple detection section for detecting the ripple component due to the AC power supply of the DC voltage detected by the DC voltage detection section, and removes the ripple component detected by the voltage ripple detection section from the fluctuation component. 20. The power conversion device of claim 16, wherein the reactor and the capacitor of the LC filter are selected so that the resonance frequency (f0) thereof is a frequency excluding frequencies that are integral multiples of the ripple component due to the AC power supply of a voltage of the DC power supplied to the inverter section and frequencies in vicinity thereof. 21. The power conversion device of claim 16, wherein the power conversion device further includes a voltage abnormality detection section for detecting voltage abnormality of the DC voltage detected by the DC voltage detection section, andthe limitation section adjusts the range of limitation based on a detection result of the voltage abnormality detection section. 22. The power conversion device of claim 16, wherein the power conversion device further includes a voltage abnormality detection section for detecting voltage abnormality of the DC voltage detected by the DC voltage detection section, andthe link resonance compensation section adjusts the amount of link resonance compensation based on a detection result of the voltage abnormality detection section. 23. An air conditioner comprising the power conversion device of claim 16.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (18)
Haydock, Lawrence; Koczara, Wlodzimierz; Al-Khayat, Nazar; Brown, Neil; Dalby, Denis Hedley; Al-Tayie, Jawad; Dziuba, Robert Pawel; Leonarski, Jaroslaw; Laird, George Williamson, AC power generating system.
Royak, Semyon; Liu, Jingbo; Dai, Jingya; Nondahl, Thomas; Al-Nabi, Ehsan; Schmidt, Peter B., Control of motor drives with output sinewave filter capacitor current compensation using sinewave filter transfer function.
Royak, Semyon; Breitzmann, Robert J.; Liu, Jingbo; Nondahl, Thomas A.; Dai, Jingya; Schmidt, Peter B., Current control of motor drives with output sinewave filter.
Royak, Semyon; Dai, Jingya; Nondahl, Thomas A.; Liu, Jingbo; Breitzmann, Robert J.; Schmidt, Peter B., Feedforward control of motor drives with output sinewave filter.
Nondahl, Thomas; Liu, Jingbo; Royak, Semyon; Schmidt, Peter B.; Dai, Jingya; Al-nabi, Ehsan, Method and apparatus for speed reversal control of motor drive.
Nondahl, Thomas; Liu, Jingbo; Schmidt, Peter; Royak, Semyon; Rowan, Timothy M., Method and apparatus for stability control of open loop motor drive operation.
Liu, Jingbo; Nondahl, Thomas; Schmidt, Peter; Royak, Semyon, Position sensorless open loop control for motor drives with output filter and transformer.
Liu, Jingbo; Nondahl, Thomas; Schmidt, Peter; Royak, Semyon, Position sensorless open loop control for motor drives with output filter and transformer.
Taniguchi, Shun; Yasui, Kazuya; Yuuki, Kazuaki; Kamijo, Yoshitake, Power conversion device having improved noise characteristics, and control method thereof.
Royak, Semyon; Dai, Jingya; Liu, Jingbo; Nondahl, Thomas A.; Al-Nabi, Ehsan, Sensorless motor drive vector control with feedback compensation for filter capacitor current.
Nondahl, Thomas; Liu, Jingbo; Schmidt, Peter; Royak, Semyon; Dai, Jingya; Al-Nabi, Ehsan, Transition scheme for position sensorless control of AC motor drives.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.