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Power conversion system and communication method thereof

專利號(hào)
US12160165B2
公開日期
2024-12-03
申請(qǐng)人
Delta Electronics (Shanghai) Co., Ltd.(CN Shanghai)
發(fā)明人
Hong Liu; Wen Zhang; Yuxin Han; Cheng Lu
IPC分類
H02J13/00; H02J3/01; H02M1/00; H02M1/12; H02M7/04; H02M7/217; H02M7/49; H02M7/493
技術(shù)領(lǐng)域
conversion,harmonic,power,ac,mth,in,resonance,voltage,cells,cell
地域: Shanghai

摘要

The present disclosure discloses a power conversion system and a communication method for transmitting common mode information in the power conversion system. The communication method comprises the following steps: (a) providing at least two power conversion cells; (b) generating, by each of the power conversion cells, an AC harmonic according to a first electrical signal at the first terminal of the power conversion cell, wherein an amplitude of each AC harmonic represents first information of the power conversion cell, and all the AC harmonics are at the same frequency; and (c) injecting the AC harmonic generated by the corresponding power conversion cells into the first terminal of the corresponding power conversion cell and applying a closed-loop suppression to the AC harmonic generated by the corresponding power conversion cell, and controlling the resonance control unit to output a second electrical signal related to the first information.

說明書

CROSS REFERENCE TO RELATED APPLICATION

This application claims the benefit of priority to Chinese Application No. 202210871900.8, filed on Jul. 22, 2022, the content of which is incorporated herein by reference in its entirety.

BACKGROUND OF THE DISCLOSURE 1. Field of the Disclosure

The present disclosure relates to a power conversion technology, and in particular to a power conversion system and a communication method thereof.

2. Related Art

Power electronic modules may be connected in series-parallel to implement applications with a high voltage or a large current, so as to achieve purposes such as expanding capacity or improving reliability in redundant power supply. Such a series-parallel system is widespread. For example, in a power electronic transformer system as shown in FIG. 1A, each phase includes a plurality of modules M1 which are cascaded at a AC side for receiving a medium voltage, and connected in parallel at a DC side, such that DC outputs of three phases may be connected in parallel to provide an appropriate DC voltage to a load. Each of the plurality of modules M1 includes, for example, an AC-DC sub-module at a pre-stage and a DC-DC sub-module at a post-stage. The system may convert AC power at the medium voltage to DC power at a low voltage, exhibiting extensive application prospects in a data center, a charging station, new energy power generation and other fields in the future.

權(quán)利要求

1
What is claimed is:1. A communication method for transmitting common mode information in a power conversion system, comprising:(a) providing at least two power conversion cells, first terminals of the at least two power conversion cells being electrically coupled, and each of the power conversion cells comprising a resonance control unit;(b) generating, by each of the power conversion cells, an AC harmonic according to a first electrical signal at the first terminal of the corresponding power conversion cell, wherein an amplitude of each AC harmonic represents first information of the power conversion cell generating the AC harmonic correspondingly, and all the AC harmonics are at a same frequency; and(c) injecting the AC harmonic generated by the corresponding power conversion cell into the first terminal of the corresponding power conversion cell, and applying, by the resonance control unit in the corresponding power conversion cell, a closed-loop suppression to the AC harmonic generated by the corresponding power conversion cell, and controlling the resonance control unit to output a second electrical signal related to the first information, wherein the second electrical signal comprises the common mode information of the power conversion cell, or is used to generate the common mode information of the power conversion cell with the injected AC harmonic.2. The communication method in the power conversion system according to claim 1, wherein the step (b) of generating, by each of the power conversion cells, the AC harmonic according to the first electrical signal at the first terminal of the corresponding power conversion cell comprises:(b1) performing a phase-locking operation on the first electrical signal at the first terminal of the corresponding power conversion cell and performing a frequency-doubling operation on result of the phase-locking operation to generate a phase of the AC harmonic; and(b2) setting K times the amplitude of the first information of the power conversion cell as the amplitude of the AC harmonic, where K is a positive number.3. The communication method in the power conversion system according to claim 1, whereinthe power conversion system is a single-phase system, andthe first terminals of the at least two power conversion cells are connected in series, and the first electrical signal is a current flowing through each of the first terminals.4. The communication method in the power conversion system according to claim 1, whereinthe power conversion system is a single-phase system, andthe first terminals of the at least two power conversion cells are connected in parallel, and the first electrical signal is a voltage at each of the first terminals.5. The communication method in the power conversion system according to claim 1, whereinthe power conversion system is a three-phase system and comprises three power conversion cells,the first terminal of each of the power conversion cells comprises a positive input terminal and a negative input terminal, respectively,the positive input terminal of each of the power conversion cells is correspondingly connected to a phase input source, and the negative input terminals of all the power conversion cells are connected commonly, andthe first electrical signal is a voltage at the first terminal of the corresponding power conversion cell.6. The communication method in the power conversion system according to claim 5, whereinthe first information is K times of the amplitude of the first electrical signal, where K is a positive number, andthe common mode information is a zero-sequence component of the voltage at the first terminal.7. The communication method in the power conversion system according to claim 6, wherein each of the power conversion cells comprises a power conversion module and a controller that are coupled electrically, each controller comprising a voltage outer-loop control unit and a current inner-loop control unit, andeach current inner-loop control unit generates a voltage reference value at the first terminal of the corresponding power conversion cell according to the current at the first terminal, a current reference value at the first terminal, and the AC harmonic of the corresponding power conversion cell, and each voltage outer-loop control unit generates the current reference value at the first terminal of the corresponding power conversion cell according to the voltage reference value at the first terminal of the corresponding power conversion cell, so that each of the power conversion cells applies a double loop control.8. The communication method in the power conversion system according to claim 7, wherein each current inner-loop control unit comprises the resonance control unit and a first arithmetic unit, each resonance control unit comprising a first proportional controller and a third-order resonance controller, and each first arithmetic unit comprising a first arithmetic element and a second arithmetic element, whereinthe first proportional controller performs a proportional operation on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs a first output signal correspondingly;the third-order resonance controller performs a harmonic control on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs a third-order harmonic signal correspondingly; andthe first arithmetic element generates the common mode information of the corresponding power conversion cell according to the third-order harmonic signal and the injected AC harmonic of the corresponding power conversion cell, and the second arithmetic element generates the voltage reference value at the first terminal of the corresponding power conversion cell according to the first output signal and the common mode information of the corresponding power conversion cell.9. The communication method in the power conversion system according to claim 1, whereineach of the first information represents a variable value or an integral value of a current, a voltage, a power or a temperature of the corresponding power conversion cell, andthe common mode information is a mean value of all the first information.10. The communication method in the power conversion system according to claim 9, wherein each of the power conversion cells comprises a power conversion module and a controller that are coupled electrically, each controller comprising a voltage outer-loop control unit and a current inner-loop control unit, andeach current inner-loop control unit generates a voltage reference value at the first terminal of the corresponding power conversion cell according to the current at the first terminal, a current reference value at the first terminal, and the injected AC harmonic of the corresponding power conversion cell, and each voltage outer-loop control unit generates the current reference value at the first terminal of the corresponding power conversion cell according to the voltage reference value at the first terminal of the corresponding power conversion cell, so that each of the power conversion cells applies a double loop control.11. The communication method in the power conversion system according to claim 10, whereineach current inner-loop control unit comprises the resonance control unit and a first arithmetic unit, each resonance control unit comprising a first proportional controller and an Mth-order resonance controller, where M is a positive integer greater than 1,wherein,the first proportional controller performs a proportional operation on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs a first output signal correspondingly;the Mth-order resonance controller performs a harmonic control on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs an Mth-order harmonic signal correspondingly, wherein the Mth-order harmonic signal is the second electrical signal comprising the common mode information; andthe first arithmetic unit generates the voltage reference value at the first terminal of the corresponding power conversion cell according to the first output signal, the Mth-order harmonic signal and the injected AC harmonic of the corresponding power conversion cell, andwherein, M is not equal to a multiple of 3 when the power conversion system is a three-phase system.12. The communication method in the power conversion system according to claim 11, wherein each controller further comprises a mean value extraction unit for extracting the mean value of all the first information in the Mth-order harmonic signal.13. A power conversion system, comprising:at least two power conversion cells, first terminals of the at least two power conversion cells being electrically coupled, and each of the power conversion cells comprising a controller, and each controller comprising a resonance control unit,wherein the controller in each of the power conversion cells is configured to:generate an AC harmonic according to a first electrical signal at the first terminal of a corresponding power conversion cell, wherein an amplitude of the AC harmonic represents first information of the power conversion cell generating the AC harmonic correspondingly, and all the AC harmonics are at a same frequency; andinject the AC harmonic generated by the corresponding power conversion cell into the first terminal of the corresponding power conversion cell, and apply, by the resonance control unit in the corresponding power conversion cell, a closed-loop suppression to the AC harmonic generated by the corresponding power conversion cell, and control the resonance control unit to output a second electrical signal related to the first information, wherein the second electrical signal comprises the common mode information of the power conversion cell, or is used to generate the common mode information of the power conversion cell with the injected AC harmonic.14. The power conversion system according to claim 13, wherein the resonance control unit in the controller in each of the power conversion cells is configured to:perform a phase-locking operation on the first electrical signal at the first terminal of the corresponding power conversion cell and perform a frequency-doubling operation on result of the phase-locking operation to generate a phase of the AC harmonic; andset K times the amplitude of the first information of the power conversion cell as the amplitude of the AC harmonic, where K is a positive number.15. The power conversion system according to claim 13, whereinthe power conversion system is a single-phase system, andthe first terminals of the at least two power conversion cells are connected in series, and the first electrical signal is a current flowing through each of the first terminals.16. The power conversion system according to claim 13, whereinthe power conversion system is a single-phase system, andthe first terminals of the at least two power conversion cells are connected in parallel, and the first electrical signal is a voltage at each of the first terminals.17. The power conversion system according to claim 13, whereinthe power conversion system is a three-phase system and comprises three power conversion cells,the first terminal of each of the power conversion cells comprises a positive input terminal and a negative input terminal, respectively,the positive input terminal of each of the power conversion cells is correspondingly connected to a phase input source, and the negative input terminals of all the power conversion cells are connected commonly, andthe first electrical signal is a voltage at the first terminal of the corresponding power conversion cell.18. The power conversion system according to claim 17, whereinthe first information is K times of the amplitude of the first electrical signal, where K is a positive number, andthe common mode information is a zero-sequence component of the voltage at the first terminal.19. The power conversion system according to claim 18, wherein each of the power conversion cells comprises a power conversion module and a controller that are coupled electrically, each controller comprising a voltage outer-loop control unit and a current inner-loop control unit, andeach current inner-loop control unit is configured to generate a voltage reference value at the first terminal of the corresponding power conversion cell according to the current at the first terminal, a current reference value at the first terminal, and the AC harmonic of the corresponding power conversion cell, and each voltage outer-loop control unit is configured to generate the current reference value at the first terminal of the corresponding power conversion cell according to the voltage reference value at the first terminal of the corresponding power conversion cell, so that each of the power conversion cells applies a double loop control.20. The power conversion system according to claim 19, wherein each current inner-loop control unit comprises the resonance control unit and a first arithmetic unit, each resonance control unit comprising a first proportional controller and a third-order resonance controller, and each first arithmetic unit comprising a first arithmetic element and a second arithmetic element, whereinthe first proportional controller is configured to perform a proportional operation on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs a first output signal correspondingly;the third-order resonance controller is configured to perform a harmonic control on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs a third-order harmonic signal correspondingly; andthe first arithmetic element is configured to generate the common mode information of the corresponding power conversion cell according to the third-order harmonic signal and the injected AC harmonic of the corresponding power conversion cell, and the second arithmetic element is configured to generate the voltage reference value at the first terminal of the corresponding power conversion cell according to the first output signal and the common mode information of the corresponding power conversion cell.21. The power conversion system according to claim 13, whereineach of the first information represents a variable value or an integral value of a current, a voltage, a power or a temperature of the corresponding power conversion cell, andthe common mode information is a mean value of all the first information.22. The power conversion system according to claim 21, wherein each of the power conversion cells comprises a power conversion module and a controller that are coupled electrically, each controller comprising a voltage outer-loop control unit and a current inner-loop control unit, andthe current inner-loop control unit is configured to generate a voltage reference value at the first terminal of the corresponding power conversion cell according to the current at the first terminal, a current reference value at the first terminal, and the injected AC harmonic of the corresponding power conversion cell, and the voltage outer-loop control unit is configured to generate the current reference value at the first terminal of the corresponding power conversion cell according to the voltage reference value at the first terminal of the corresponding power conversion cell, so that each of the power conversion cells applies a double loop control.23. The power conversion system according to claim 22, wherein each current inner-loop control unit comprises the resonance control unit and a first arithmetic unit, each resonance control unit comprising a first proportional controller and an Mth-order resonance controller, where M is a positive integer greater than 1,wherein,the first proportional controller is configured to perform a proportional operation on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs a first output signal correspondingly;the Mth-order resonance controller is configured to perform a harmonic control on the current at the first terminal and the current reference value at the first terminal of the corresponding power conversion cell, and outputs an Mth-order harmonic signal correspondingly, wherein the Mth-order harmonic signal is the second electrical signal comprising the common mode information; andthe first arithmetic unit is configured to generate the voltage reference value at the first terminal of the corresponding power conversion cell according to the first output signal, the Mth-order harmonic signal and the injected AC harmonic of the corresponding power conversion cell, andwherein, M is not equal to a multiple of 3 when the power conversion system is a three-phase system.24. The communication method in the power conversion system according to claim 23, wherein each controller further comprises a mean value extraction unit for extracting the mean value of all the first information in the Mth-order harmonic signal.
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