阅读说明：本技术 级联变频器的预充电方法以及级联变频器 (Pre-charging method of cascade frequency converter and cascade frequency converter ) 是由 刘汝峰 周代平 王凯 郎永强 于 2020-04-27 设计创作，主要内容包括：本申请提供一种级联变频器的预充电方法以及级联变频器。级联变频器包括主变压器、多个功率单元、控制单元及预充电单元。与预充电单元连接的为第一组功率单元,其他功率单元为第二组功率单元。控制单元控制预充电单元中的第一开关闭合,预充电单元中的低压交流电源通过第一组功率单元中的逆变电路对母线电容进行预充电。当母线电容的电压达到第一电压阈值,控制单元控制第一组功率单元中的整流电路对主变压器进行励磁,从而为第二组功率单元中的母线电容进行预充电。无需额外增加预充电变换器等电路,利用自身单元实现可控软充电,有效避免了高压侧合闸造成的极大电流冲击,提高了系统高压合闸可靠性,极大地降低了预充电方案的投入成本。(The application provides a pre-charging method of a cascade frequency converter and the cascade frequency converter. The cascade frequency converter comprises a main transformer, a plurality of power units, a control unit and a pre-charging unit. The other power units are the second group of power units. The control unit controls a first switch in the pre-charging unit to be closed, and a low-voltage alternating current power supply in the pre-charging unit pre-charges the bus capacitor through an inverter circuit in the first group of power units. When the voltage of the bus capacitor reaches a first voltage threshold value, the control unit controls the rectifying circuits in the first group of power units to excite the main transformer, so that the bus capacitor in the second group of power units is pre-charged. The circuits such as a pre-charging converter and the like are not required to be additionally added, controllable soft charging is realized by utilizing the self unit, great current impact caused by high-voltage side switching-on is effectively avoided, the high-voltage switching-on reliability of the system is improved, and the input cost of a pre-charging scheme is greatly reduced.)

1. A cascaded frequency converter, comprising:

a main transformer including a primary side winding and a plurality of secondary side windings;

a plurality of power units connected in one-to-one correspondence with the plurality of secondary side windings; each power unit comprises a rectifying circuit, a bus capacitor and an inverter circuit, wherein the bus capacitor is connected with the rectifying circuit and the inverter circuit;

the pre-charging unit is connected with at least one power unit and comprises a low-voltage alternating current power supply and a first switch, and the low-voltage alternating current power supply is used for providing power supply voltage for the pre-charging process of the frequency converter; the at least one power unit connected with the pre-charging unit is a first group of power units, and the power units not connected with the pre-charging unit are a second group of power units;

and the control unit controls the first switch to be switched on so that the low-voltage alternating-current power supply pre-charges a corresponding bus capacitor through an inverter circuit in the first group of power units, and controls a rectifying circuit in the first group of power units to work after the voltage of the bus capacitor reaches a first voltage threshold value so as to excite the main transformer and pre-charge the bus capacitor in the second group of power units.

2. The cascaded frequency converter of claim 1, wherein the first group of power cells is located near a neutral point.

3. The cascaded frequency converter of claim 1, wherein the pre-charge unit further comprises: and the current-limiting starting circuit is connected between the low-voltage alternating current power supply and the first switch, and comprises a second switch and a current-limiting device which are connected in parallel.

4. The cascaded frequency converter of claim 3, wherein the pre-charge unit further comprises: the auxiliary transformer is connected between the current-limiting starting circuit and the first switch; the auxiliary transformer is used for transforming the voltage of the low-voltage alternating current power supply.

5. The cascaded frequency converter of claim 3, wherein the second switch is in an open state when the low voltage AC power source begins precharging the corresponding bus capacitance through the inverter circuit in the first group of power cells; when the voltage of the bus capacitor in the first group of power units reaches a current-limiting voltage threshold value or a first preset time length passes, the control unit controls the second switch to be closed so as to bypass the current-limiting device.

6. The cascade converter according to claim 5, wherein after the voltage of the bus capacitor in the first group of power cells reaches the first voltage threshold or after a second predetermined time period, the control unit starts PWM control on the rectifying circuits in the first group of power cells, so as to excite the main transformer through the secondary side winding connected to the first group of power cells.

7. The cascaded frequency converter according to claim 6, wherein the control unit controls the first group of power units to generate PWM voltages according to preset modulation commands to excite the main transformer, and other secondary side windings of the main transformer pre-charge corresponding bus capacitors through the rectifying circuits in the second group of power units.

8. The cascaded frequency converter according to claim 7, wherein the preset modulation command is gradually increased, and the voltage of a bus capacitor in the second group of power units is gradually increased; when the preset modulation command reaches a modulation command threshold value, pre-charging is completed; the preset modulation instruction is used for representing the magnitude of the PWM voltage.

9. The cascaded frequency converter of claim 7, wherein the control unit turns on closed loop PWM control of the rectifying circuits in the second group of power cells to complete the pre-charge when the voltage of the bus capacitance in the second group of power cells reaches a second voltage threshold.

10. The cascaded frequency converter according to claim 8 or 9, wherein after pre-charging is completed, the control unit starts a power-on device of the main transformer, turns off the PWM control and opens the first switch to separate the pre-charging unit from the frequency converter.

11. The cascade frequency converter according to claim 7, wherein when the rectifying circuits of the plurality of power units in the first group of power units start to operate, the control unit controls the preset modulation commands between the rectifying circuits of the corresponding plurality of power units to satisfy a preset phase relationship, so as to avoid mutual demagnetization.

12. The pre-charging method of the cascade frequency converter is characterized in that the frequency converter comprises a main transformer, a plurality of power units and a pre-charging unit; each power unit comprises a rectifying circuit, a bus capacitor and an inverter circuit, wherein the bus capacitor is connected with the rectifying circuit and the inverter circuit; the pre-charging unit is connected with at least one power unit and comprises a low-voltage alternating current power supply and a first switch; the at least one power unit connected with the pre-charging unit is a first group of power units, and the power units not connected with the pre-charging unit are a second group of power units; the method comprises the following steps:

closing the first switch to enable the low-voltage alternating-current power supply to pre-charge the corresponding bus capacitor through an inverter circuit in the first group of power units;

and when the voltage of the bus capacitor reaches a first voltage threshold value, controlling a rectifying circuit in the first group of power units to work so as to excite the main transformer and precharge the bus capacitor of the second group of power units.

13. The pre-charging method for a cascaded frequency converter according to claim 12, wherein the non-controlled rectification is performed by an inverter circuit in the first group of power units to pre-charge the corresponding bus capacitor.

14. The method of precharging a cascaded frequency converter according to claim 13, wherein the precharging unit further comprises: the current-limiting starting circuit is connected between the low-voltage alternating-current power supply and the first switch, and comprises a second switch and a current-limiting device which are connected in parallel; the method further comprises the following steps:

when the low-voltage alternating-current power supply starts to pre-charge the corresponding bus capacitor through the inverter circuit in the first group of power units, the second switch is in a disconnected state, and the low-voltage alternating-current power supply charges the bus capacitor in the first group of power units through the current limiting device;

and when the voltage of the bus capacitor in the first group of power units reaches a current-limiting voltage threshold value or a first preset time length passes, closing the second switch to bypass the current-limiting device.

15. The method of precharging a cascaded frequency converter according to claim 14, wherein the precharging unit further comprises: an auxiliary transformer connected between the current-limiting starting circuit and the first switch; the auxiliary transformer is used for transforming the voltage of the low-voltage alternating current power supply.

16. The pre-charging method for a cascade frequency converter according to claim 13 or 14, wherein after the voltage of the bus capacitor in the first group of power modules reaches the first voltage threshold or after a second preset time period, the PWM control is turned on for the rectifying circuits in the first group of power units, so as to excite the main transformer through the secondary side winding connected with the first group of power units.

17. The method of claim 16, wherein the first group of power cells are controlled to generate a PWM voltage according to a preset modulation command to excite the main transformer, and the other secondary side windings of the main transformer are rectified uncontrollably by the rectifying circuits in the second group of power cells to precharge the corresponding bus capacitors.

18. The method according to claim 17, wherein the preset modulation command is gradually increased, and the voltage of the bus capacitor in the second group of power units is gradually increased; when the preset modulation command reaches a modulation command threshold value, pre-charging is completed; the preset modulation instruction is used for representing the magnitude of the PWM voltage.

19. The method of pre-charging a cascaded frequency converter according to claim 18, wherein when the voltage of the bus capacitor in the second group of power cells reaches a second voltage threshold, closed loop PWM control is turned on for the rectifying circuits in the second group of power cells to complete pre-charging.

20. A method according to claim 18 or 19, wherein after the pre-charging is completed, the power-on device of the main transformer is started, the PWM control is turned off and the first switch is turned off, so that the pre-charging unit is separated from the frequency converter.

21. The method of precharging a cascaded frequency converter according to claim 17, further comprising:

when the rectifying circuits of the plurality of power units in the first group of power units start to work, the preset modulation instructions among the rectifying circuits of the corresponding plurality of power units meet a preset phase relationship, and mutual demagnetization is avoided.

22. A method of precharging a cascaded frequency converter according to claim 12, wherein said first group of power cells is located close to the neutral point.

Technical Field

The present application relates to the field of control technologies, and in particular, to a pre-charging method for a cascaded frequency converter and a cascaded frequency converter.

Background

With the rapid development of industrial production, the application of the cascade frequency converter is more and more extensive. For example, in equipment such as a mine hoist and a down belt conveyor, because different forms of energy conversion exist, a motor is in a power regeneration state, and in consideration of energy conservation, the regenerated energy of the motor is generally fed back to a power grid, so that a cascade frequency converter is required to realize energy feedback. Each power of the frequency converter comprises a rectifying unit, an inverting unit and a bus capacitor connected with the rectifying unit and the inverting unit. Due to the existence of the bus capacitor, when the high-voltage side of the frequency converter is switched on, the voltages at two ends of the bus capacitor suddenly change to generate larger impact current, so that the power semiconductor device at the rectifying unit side can be greatly impacted, and the performance of the power semiconductor device can be damaged to different degrees.

In order to reduce or avoid the current impact on the power semiconductor device, in the prior art, the bus capacitor is usually pre-charged to solve the problem. The current practice is to pre-charge the primary side winding of the transformer, for example, the pre-charging module is connected to the primary side winding of the transformer through a high voltage switch, and the pre-charging of the bus capacitor is realized through the transformer. Wherein the high-voltage switch can be a high-voltage circuit breaker or a contactor. It is also common practice to pre-charge the cell bus capacitors through the secondary winding of the transformer. For example, an auxiliary winding is provided on the secondary side of the transformer, and the low-voltage power supply precharges the bus capacitor in the power unit through the inverter circuit and the auxiliary winding. In addition, the bus capacitor is precharged by mutually matching a plurality of groups of high-voltage switches.

Firstly, the high-voltage high-power device is adopted at the high-voltage incoming line end, so that the cost is high, and the requirements on the fixation, the insulation design and the like of the pre-charging device are high; or more other devices that should be additionally configured are included in the precharge device. It can be seen that whichever of the above schemes introduces greater challenges to the cost investment and realizability of the precharge scheme.

Disclosure of Invention

The application provides a pre-charging method of a cascade frequency converter and the cascade frequency converter, which are used for solving the technical problems that the pre-charging scheme of the cascade frequency converter in the prior art is too high in input cost and larger in realizability challenge.

In a first aspect, the present application provides a cascaded frequency converter, including:

a main transformer including a primary side winding and a plurality of secondary side windings;

a plurality of power units connected in one-to-one correspondence with the plurality of secondary side windings; each power unit comprises a rectifying circuit, a bus capacitor and an inverter circuit, wherein the bus capacitor is connected with the rectifying circuit and the inverter circuit;

the pre-charging unit is connected with at least one power unit and comprises a low-voltage alternating current power supply and a first switch, and the low-voltage alternating current power supply is used for providing power supply voltage for the pre-charging process of the frequency converter; the at least one power unit connected with the pre-charging unit is a first group of power units, and the power units not connected with the pre-charging unit are a second group of power units;

and the control unit controls the first switch to be switched on so that the low-voltage alternating-current power supply pre-charges a corresponding bus capacitor through an inverter circuit in the first group of power units, and controls a rectifying circuit in the first group of power units to work after the voltage of the bus capacitor reaches a first voltage threshold value so as to excite the main transformer and pre-charge the bus capacitor in the second group of power units.

In one possible design, the first group of power cells is located near the neutral point.

In one possible design, the precharge unit further includes: and the current-limiting starting circuit is connected between the low-voltage alternating current power supply and the first switch, and comprises a second switch and a current-limiting device which are connected in parallel.

In one possible design, the precharge unit further includes: the auxiliary transformer is connected between the current-limiting starting circuit and the first switch; the auxiliary transformer is used for transforming the voltage of the low-voltage alternating current power supply.

In one possible design, when the low-voltage alternating-current power supply starts to pre-charge the corresponding bus capacitor through the inverter circuit in the first group of power units, the second switch is in an off state; when the voltage of the bus capacitor in the first group of power units reaches a current-limiting voltage threshold value or a first preset time length passes, the control unit controls the second switch to be closed so as to bypass the current-limiting device.

In a possible design, after the voltage of the bus capacitor in the first group of power units reaches a first voltage threshold or a second preset time period elapses, the control unit starts PWM control on the rectifying circuit in the first group of power units, so as to excite the main transformer through the secondary side winding connected to the first group of power units.

In a possible design, the control unit controls the first group of power units to generate PWM voltages according to preset modulation commands to excite the main transformer, and other secondary side windings of the main transformer pre-charge corresponding bus capacitors through the rectifying circuits in the second group of power units.

In one possible design, gradually increasing the preset modulation command, and gradually increasing the voltage of a bus capacitor in the second group of power units; when the preset modulation command reaches a modulation command threshold value, pre-charging is completed; the preset modulation instruction is used for representing the magnitude of the PWM voltage.

In one possible design, when the voltage of the bus capacitor in the second group of power units reaches a second voltage threshold, the control unit starts closed-loop PWM control on the rectifying circuits in the second group of power units to complete pre-charging.

In one possible design, after the pre-charging is completed, the control unit starts a power-on device of the main transformer, turns off the PWM control and turns off the first switch, so that the pre-charging unit is separated from the frequency converter.

Optionally, when the rectifying circuits of the plurality of power units in the first group of power units start to operate, the control unit controls the preset modulation instructions between the rectifying circuits of the corresponding plurality of power units to meet a preset phase relationship, so as to avoid mutual demagnetization.

In a second aspect, the present application provides a pre-charging method for a cascaded frequency converter, where the frequency converter includes a main transformer, a plurality of power units, and a pre-charging unit; each power unit comprises a rectifying circuit, a bus capacitor and an inverter circuit, wherein the bus capacitor is connected with the rectifying circuit and the inverter circuit; the pre-charging unit is connected with at least one power unit and comprises a low-voltage alternating current power supply and a first switch; the at least one power unit connected with the pre-charging unit is a first group of power units, and the power units not connected with the pre-charging unit are a second group of power units; the method comprises the following steps:

closing the first switch to enable the low-voltage alternating-current power supply to pre-charge the corresponding bus capacitor through an inverter circuit in the first group of power units;

and when the voltage of the bus capacitor reaches a first voltage threshold value, controlling a rectifying circuit in the first group of power units to work so as to excite the main transformer and precharge the bus capacitor of the second group of power units.

In one possible design, the uncontrolled rectification is performed by an inverter circuit in the first group of power units to pre-charge the corresponding bus capacitor.

In one possible design, the precharge unit further includes: the current-limiting starting circuit is connected between the low-voltage alternating-current power supply and the first switch, and comprises a second switch and a current-limiting device which are connected in parallel; the method further comprises the following steps:

when the low-voltage alternating-current power supply starts to pre-charge the corresponding bus capacitor through the inverter circuit in the first group of power units, the second switch is in a disconnected state, and the low-voltage alternating-current power supply charges the bus capacitor in the first group of power units through the current limiting device;

and when the voltage of the bus capacitor in the first group of power units reaches a current-limiting voltage threshold value or a first preset time length passes, closing the second switch to bypass the current-limiting device.

In one possible design, the precharge unit further includes: an auxiliary transformer connected between the current-limiting starting circuit and the first switch; the auxiliary transformer is used for transforming the voltage of the low-voltage alternating current power supply.

In one possible design, after the voltage of the bus capacitor in the first group of power modules reaches the first voltage threshold or a second preset time period elapses, the PWM control is started for the rectifying circuit in the first group of power units, so that the main transformer is excited by the secondary side winding connected to the first group of power units.

In one possible design, the first group of power units are controlled to generate PWM voltages according to preset modulation commands to excite the main transformer, and other secondary side windings of the main transformer are subjected to uncontrolled rectification through the rectification circuits in the second group of power units to pre-charge the corresponding bus capacitors.

In one possible design, gradually increasing the preset modulation command, and gradually increasing the voltage of a bus capacitor in the second group of power units; when the preset modulation command reaches a modulation command threshold value, pre-charging is completed; the preset modulation instruction is used for representing the magnitude of the PWM voltage.

In one possible design, when the voltage of the bus capacitor in the second group of power units reaches a second voltage threshold, the closed-loop PWM control is turned on for the rectifying circuit in the second group of power units to complete the pre-charging.

In one possible design, after the pre-charging is completed, the power-on device of the main transformer is started, the PWM control is turned off, and the first switch is turned off, so that the pre-charging unit is separated from the frequency converter.

Optionally, when the rectifying circuits of the plurality of power units in the first group of power units start to operate, the preset modulation commands between the rectifying circuits of the corresponding plurality of power units satisfy a preset phase relationship, so as to avoid mutual demagnetization.

Optionally, the first group of power cells is located close to the neutral point.

The cascade frequency converter comprises a main transformer, a plurality of power units, a control unit and a pre-charging unit, wherein each power unit comprises a rectifying circuit, a bus capacitor and an inverter circuit, the pre-charging unit is connected with at least one power unit, the at least one power unit connected with the pre-charging unit is a first group of power units, other power units not connected with the pre-charging unit are a second group of power units, and the pre-charging unit comprises a low-voltage alternating current power supply and a first switch. The control unit controls the first switch to be closed, so that the low-voltage alternating-current power supply pre-charges the corresponding bus capacitor through the inverter circuit in the first group of power units. And when the voltage of the bus capacitor reaches a first voltage threshold value, the control unit controls the rectifying circuit in the first group of power units to work so as to excite the main transformer, thereby precharging the bus capacitor in the second group of power units. According to the precharging method of the cascade frequency converter, circuits such as the precharging converter do not need to be additionally arranged, controllable soft charging is achieved for the capacitor of each unit by using the unit conversion device, great current impact on a power semiconductor device when a high-voltage side is switched on is effectively avoided, the high-voltage switching-on reliability of a system is improved, and the input cost of a precharging scheme is greatly reduced.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of a cascaded frequency converter in the prior art;

fig. 2 is a schematic structural diagram of another cascaded frequency converter in the prior art;

fig. 3 is a schematic diagram of a topology structure of a cascaded frequency converter according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a power unit according to an embodiment of the present disclosure;

fig. 5 is a schematic diagram of a topology structure of another cascaded frequency converter provided in an embodiment of the present application;

fig. 6 is a schematic structural diagram of another power unit provided in the embodiment of the present application;

fig. 7 is a schematic diagram of a precharge structure of a cascaded frequency converter according to an embodiment of the present application;

fig. 8 is a schematic diagram of a precharge structure of another cascaded frequency converter according to an embodiment of the present application;

fig. 9 is a schematic diagram illustrating a precharge structure of a cascaded frequency converter according to an embodiment of the present application;

fig. 10 is a schematic diagram of a precharge structure of another cascaded frequency converter according to an embodiment of the present application;

fig. 11 is a schematic diagram of a precharge structure of another cascaded frequency converter according to an embodiment of the present application;

fig. 12 is a schematic flowchart of a pre-charging method for a cascaded frequency converter according to an embodiment of the present disclosure;

fig. 13 is a schematic flowchart of another pre-charging method for a cascaded frequency converter according to an embodiment of the present application;

FIG. 14 is a diagram illustrating a simulation process of pre-charging according to an embodiment of the present application;

FIG. 15 is a comparative schematic diagram of a rush current provided in accordance with an embodiment of the present application;

fig. 16 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of methods and apparatus consistent with certain aspects of the present application, as detailed in the appended claims.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the above-described drawings (if any) are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Each power unit of the cascade frequency converter comprises a rectifying unit, an inverting unit and a bus capacitor connected with the rectifying unit and the inverting unit. Due to the existence of the bus capacitor, when the high-voltage side of the frequency converter is switched on, voltage at two ends of the bus capacitor suddenly changes, and larger impact current is generated, so that great impact is caused on a semiconductor device at the rectifying unit side, and the performance of the semiconductor device is damaged to different degrees. Based on this phenomenon, in order to avoid or reduce the current impact caused when the high-voltage side of the frequency converter is switched on, a scheme of pre-charging the bus capacitor is generally adopted to overcome the problem.

In the prior art, the existing precharging schemes can be classified into three categories according to the position of the adopted precharging device in the cascade topology frequency converter.

The first is a pre-charging scheme for the primary side winding of the transformer in a cascaded topology. Specifically, a pre-charging module is connected in series between the primary side winding of the transformer and the power grid, and the pre-charging module is composed of a charging resistor and a high-voltage switch in parallel. And when the high-voltage side of the transformer is switched on, the bus capacitor which is correspondingly connected is precharged through the charging resistor. And after the pre-charging is finished, closing the high-voltage switch to bypass the charging resistor, thereby finishing the pre-charging process of the bus capacitor of the power unit. In the scheme, the pre-charging module needs to adopt a high-power device with high voltage property, and in an actual working condition, the requirement of insulation design needs to be met for fixing the pre-charging module, so that the physical volume and the input cost of the pre-charging module are increased, and the realizability is also challenged.

The second type is to precharge the secondary side winding of the transformer as shown in fig. 1, and fig. 1 is a schematic diagram of a precharge structure of a cascaded frequency converter in the prior art. The scheme is that the corresponding bus capacitor is charged through an auxiliary winding of a transformer. As shown in fig. 1, the pre-charging module includes an ac or dc power source, a first contactor K1, an ac inverter unit, a filter, a second contactor K2, and an auxiliary winding. The pre-charging module excites the transformer through the auxiliary winding, and therefore the pre-charging function of the bus capacitor in the power unit is achieved. In the scheme, an auxiliary winding and an alternating current inversion unit are additionally required to be added, and a related control and acquisition circuit and the like are also required, so that the input cost of the scheme is increased.

The third type is to pre-charge the secondary side winding of the transformer as shown in fig. 2, and fig. 2 is a schematic diagram of another cascaded frequency converter in the prior art. The scheme is that the pre-charging is realized through the mutual cooperation of three groups of high-voltage switches. As shown in fig. 2, a first group of high voltage switches K1 is connected to the charging resistor R, a second group of high voltage switches K2 is connected to the phase-shifting primary winding, and a third group of high voltage switches K3 is connected to the motor. And (3) switching on the first group of high-voltage switches K1, pre-charging the corresponding bus capacitors by the charging resistor R and the inverter circuits in the connected power units, disconnecting the first group of high-voltage switches K1 and closing the second group of high-voltage switches K2 and the third group of high-voltage switches K3 after pre-charging is completed. The scheme additionally adds two groups of high-voltage switches, and simultaneously has the defect similar to the first scheme because the high-voltage high-power charging resistor R is selected.

Therefore, the existing precharging scheme has the technical problems of high investment cost and large realizability challenge. In view of the technical problem, embodiments of the present application provide a pre-charging method for a cascaded frequency converter and the cascaded frequency converter. The pre-charging method of the cascade frequency converter provided by the embodiment of the application can be used for pre-charging the cascade frequency converter. The pre-charging unit in the cascade frequency converter is connected with at least one power unit, the pre-charging unit comprises a low-voltage alternating-current power supply and a first switch, and when the first switch is closed, the low-voltage alternating-current power supply can pre-charge a bus capacitor in the power unit connected with the pre-charging unit. When the voltage of the bus capacitor reaches a threshold value, the main transformer in the frequency converter is excited by controlling a rectifying circuit in the power unit to start working, so that the bus capacitor corresponding to the power unit which is not connected with the pre-charging unit is pre-charged, and the pre-charging of the bus capacitor corresponding to the power unit in the cascade frequency converter is completed. Compared with the prior art, circuits such as a pre-charging converter and the like are not required to be additionally added, controllable soft charging is realized on the capacitor of each unit by utilizing the unit conversion device, great current impact on a power semiconductor device when a high-voltage side is switched on is effectively avoided, the high-voltage switching-on reliability of a system is improved, and the input cost of a pre-charging scheme is greatly reduced.

An exemplary application scenario of the embodiments of the present application is described below.

Fig. 3 is a schematic view of a topology structure of a cascaded frequency converter according to an embodiment of the present application. It is worth to be noted that the pre-charging method of the cascaded frequency converter provided in the embodiment of the present application is applicable toIn a frequency converter having a topology as characterized below. As shown in fig. 3, the cascaded frequency converter includes a main transformer 10 and a plurality of power units. The main transformer 10 includes a primary side winding and a plurality of secondary side windings. The plurality of power units are connected with the plurality of secondary side windings in a one-to-one correspondence manner. The primary side winding may be a three-phase winding (a phase, B phase, and C phase), and the secondary side winding may be a three-phase winding (as shown in fig. 3) or a single-phase winding. In the embodiment shown in fig. 3, the cascaded frequency converter has three-phase power unit groups, each of which has n power units, for example, the a-phase power unit group is power unit a₁～a_nB-phase power unit group power unit B₁～b_nPower unit C of C-phase power unit group₁～c_n. The output ends of the same-phase power units are sequentially cascaded, each phase of power unit group forms two output ends, and the output ends of the three-phase power unit groups can be connected in a Y shape. Wherein one output terminal of the three-phase power cell group is connected to the neutral point N and the other output terminal is connected to a load, such as a motor.

Further, fig. 4 is a schematic diagram of a topology structure of a power unit in a cascaded frequency converter according to an embodiment of the present application. As shown in fig. 4, each power unit includes a rectifying/feedback function unit (AFE), i.e., a rectifying circuit 110, an inverter circuit 111, and a bus capacitor 112 connecting the rectifying circuit 110 and the inverter circuit 111. The rectifying circuit 110 and the inverter circuit 111 both have the characteristic of bidirectional energy flow. In some embodiments, the frequency converter may also be, for example, a frequency converter with an H-bridge topology structure, a frequency converter with a three-level topology (NPC) structure, and the like, which are included in the embodiments of the present application but not limited thereto. According to the precharge method of the cascade frequency converter, the bus capacitor of the power unit of the cascade frequency converter can be precharged, so that the high current impact of the high-voltage side switch-on of the main transformer on the semiconductor device in the power unit is avoided. In addition, fig. 4 is a schematic structural diagram of each power unit of the main transformer in fig. 3 when the secondary side of the main transformer is a three-phase winding. S1 to S6 are semiconductor devices on the rectifier circuit 110 side, S7 to S10 are semiconductor devices on the inverter circuit 111 side, and the capacitor C is the bus capacitor 112. In some embodiments, the Semiconductor device may be, for example, a Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET), an Insulated Gate Bipolar Transistor (IGBT) integrated with an antiparallel diode, or the like.

Fig. 5 is a schematic diagram of a topology of another cascaded frequency converter according to an embodiment of the present application, wherein the secondary side of the main transformer 20 is a single-phase winding. The cascade frequency converter provided by the embodiment of the application is suitable for a single-phase winding or a three-phase winding on the secondary side. As shown in fig. 5, the primary side winding is a three-phase winding (a phase, B phase, C phase), and the secondary side winding may be a single-phase winding, each of which is connected to a corresponding power unit. Similar to the embodiment shown in fig. 3, in the embodiment shown in fig. 5, the cascaded frequency converter has three-phase power unit groups, each of which has n power units (e.g., a-phase power unit group a)₁～a_nGroup of B-phase power units B₁～b_nC-phase power unit group C₁～c_n) The output ends of the same-phase power units are sequentially cascaded, each phase of power unit group forms two output ends, and the output ends of the three-phase power unit groups can be connected in a Y shape. One output end of the three-phase power unit group is connected to a neutral point N, and the other output end of the three-phase power unit group is connected to a load, such as a motor load. Further, fig. 6 is a schematic diagram of a topology structure of another power unit in a cascaded frequency converter provided in the embodiment of the present application, as shown in fig. 6, each power unit includes a rectifying circuit 210, an inverter circuit 211, and a bus capacitor 212 connecting the rectifying circuit and the inverter circuit. Similarly, S1 to S4 in fig. 6 are semiconductor devices on the rectifier circuit 210 side, S5 to S8 are semiconductor devices on the inverter circuit 211 side, and the capacitor C is the bus capacitor 212.

In the above-described embodiments, the main transformer 10 in fig. 3 and the main transformer 20 in fig. 5 may be a phase-shifting transformer or a non-phase-shifting transformer, and the embodiments of the present invention are not limited thereto. The filter 113 in each power unit shown in fig. 4 and the filter 213 in each power unit shown in fig. 6 may be an L filter or an LC filter, or may not be provided with a filter, and the embodiment of the present application is not limited thereto.

It should be understood that fig. 4 and fig. 6 respectively show a schematic structural diagram of one power unit in fig. 3 and fig. 5, and the cascaded frequency converters in fig. 3 and fig. 5 may include a plurality of power units. Moreover, the number of the plurality of power units is different according to different voltage levels, fig. 3 and 5 of this embodiment are only exemplary diagrams, and the specific number of the power units may be set according to actual operating conditions, and the embodiment of this application is not limited.

The following describes the technical solutions of the present application and how to solve the above technical problems with specific embodiments. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments. Embodiments of the present application will be described below with reference to the accompanying drawings.

Fig. 7 is a schematic diagram of a precharge structure of a cascaded frequency converter according to an embodiment of the present disclosure, as shown in fig. 7, in this embodiment, a charging unit 300 is connected to at least one power unit, and fig. 7 illustrates an example in which the precharge unit 300 is connected to three power units. Further, the pre-charging unit 300 comprises a low-voltage ac power supply 301 and a first switch 302, wherein the low-voltage ac power supply 301 is used for providing a power supply voltage for the pre-charging process of the frequency converter. The power cells connected to the pre-charge unit 300 are the first group of power cells 201, and the power cells not connected to the pre-charge unit 300 are the second group of power cells. In some embodiments, the first group of power cells connected to precharge unit 300 may be power cell a in fig. 3 or fig. 5₁、b₁、c₁Or may be the power unit a₂、b₂、c₂Even power cell a_n、b_n、c_nThe present embodiment is not limited to this. In some embodiments, a control unit is further included, which is capable of controlling the first switch 302 to close so that the low-voltage ac power supply 301 passes through the second switchThe inverter circuits in one group of power units 201 pre-charge the corresponding bus capacitors, and after the voltage of the bus capacitors reaches the first voltage threshold, control the rectifier circuits in the first group of power units 201 to operate, so as to excite the main transformer 100, thereby pre-charging the bus capacitors in the second group of power units. In other embodiments, the control unit can also control the first switch 302 to close, so that the low-voltage ac power supply 301 pre-charges the corresponding bus capacitor through the inverter circuit in the first group of power units 201, and after a second preset time period, controls the rectifier circuit in the first group of power units 201 to operate to excite the main transformer 100, so as to pre-charge the bus capacitor in the second group of power units.

It is to be understood that in the embodiment shown in fig. 7, the number of power cells in the first group of power cells 201 is three. In other embodiments, when the number of the power units in the first group of power units 201 may also be two and one, respectively, the schematic diagrams of the precharge structures of the cascaded frequency converters provided in the embodiments of the present application are shown in fig. 8 and fig. 9, respectively. Fig. 8 is a schematic diagram of a precharge structure of another cascaded frequency converter according to an embodiment of the present application, where the first group of power cells 201 may be, for example, the power cell a in fig. 3 or fig. 5₁、b₁The present embodiment is not limited to this. Fig. 9 is a schematic diagram of a precharge structure of a further cascaded frequency converter according to an embodiment of the present disclosure, where the first group of power cells 201 may be, for example, any one of the power cells in fig. 3 or fig. 5, and may be, for example, a power cell a₁Or b₁Or c₁. When the number of the first group of power units 201 is one, the low-voltage ac power supply 301 may be a single-phase or two-phase power supply, as shown in fig. 9.

Optionally, the first group of power units 201 are located near the neutral point, that is, the pre-charging unit 300 may preferentially select the power unit connected to the neutral point, pre-charge the bus capacitors of the power units, pre-charge the corresponding bus capacitors through the inverter circuits of the power units, and control the rectifier circuits in the first group of power units 201 to operate after a second preset time period or after the voltage of the bus capacitors reaches a first voltage threshold, so as to excite the main transformer 100, thereby pre-charging other bus capacitors.

The precharge process will be described in detail below by taking the example that the number of power cells in the first group of power cells 201 shown in fig. 7 is three, where three power cells connected to the precharge cell 300 are referred to as the first group of power cells 201, and other power cells not connected to the precharge cell 300 are referred to as the second group of power cells. The structures or connection manners of the main transformer 100, the power unit, and the like can be shown with reference to fig. 3-6, and are not described herein again. In addition, the primary side winding of the main transformer 100 does not participate in the pre-charging process, and is not shown in fig. 7 to 9. As shown in fig. 7, the pre-charging unit 300 comprises a low-voltage ac power supply 301 and a first switch 302, wherein the low-voltage ac power supply 301 can provide a power supply voltage for the pre-charging process of the cascaded frequency converter, which may be a three-phase 380V mains power supply or a 220V mains power supply. The first switch 302 may be a contactor. It is understood that the first switch 302 connects the first group of power cells 201 to the low-voltage ac power source 301, for example, the output copper bars or terminals of three power cells in the first group of power cells 201 are connected to the low-voltage ac power source 301 through the first switch 302.

The control unit is used for controlling the pre-charging process of the frequency converter, for example, controlling the first switch 302 to be closed, and when the first switch 302 is closed, the low-voltage alternating-current power supply 301 pre-charges the corresponding bus capacitor through the inverter circuit in the first group of power units 201. Taking the power unit in fig. 6 as an example, the low-voltage ac power supply 301 may implement uncontrolled rectification through the anti-parallel diode of the semiconductor device in the inverter circuit 211, thereby precharging the bus capacitor 212. When the voltage of the bus capacitor of each power unit in the first group of power units 201, that is, the bus voltage, reaches the first voltage threshold, the control unit starts to control the corresponding rectifying circuit in the first group of power units 201 to operate, so as to excite the main transformer 100, and further charge the bus capacitor of each power unit in the second group of power units (the power units not connected to the pre-charging unit 300). The first voltage threshold may be set according to an actual working condition where the cascaded frequency converter is located, which is not limited in this embodiment of the application. It should be noted that the control unit can be understood as a control device for precharging the cascade frequency converter, which is not shown in fig. 7 to 9. In other embodiments, the low-voltage ac power supply 301 may implement uncontrolled rectification through the anti-parallel diode of the semiconductor device in the inverter circuit 211, pre-charge the bus capacitor 212, and after a second preset time period, the control unit starts to control the corresponding rectifying circuit in the first group of power units 201 to operate, so as to excite the main transformer 100, and further charge the bus capacitor of each power unit in the second group of power units. Similarly, the second preset time period may be set according to an actual working condition where the cascade frequency converter is located, which is not limited in this embodiment of the present application.

Optionally, the power unit connected to the pre-charge unit 300, i.e. the first group of power units 201, is located close to the neutral point, e.g. the first group of power units 201 includes the power unit a in fig. 3 or fig. 5₁、b₁、c₁Points N in fig. 7 to 9 are shown as points N in fig. 3 or 5.

According to the precharge scheme of the cascade frequency converter, the first switch is controlled to be closed, so that the low-voltage alternating-current power supply precharges the corresponding bus capacitor through the inverter circuit in the first group of power units. When the second preset time duration passes or the voltage of the bus capacitor in the first group of power units reaches the first voltage threshold value, the control unit controls the rectifying circuit in the first group of power units to work so as to excite the main transformer, thereby pre-charging the bus capacitor in the second group of power units and further completing the whole pre-charging process of the cascade frequency converter. The circuit such as a pre-charging power device or a converter is not required to be additionally added, the controllable soft charging of the capacitor of each unit is realized by utilizing the self unit conversion device, the great current impact on the power semiconductor device when the high-voltage side is switched on is effectively avoided, the high-voltage switching-on reliability of the system is improved, and the input cost of a pre-charging scheme is greatly reduced

On the basis of the embodiments shown in fig. 7 to fig. 9, optionally, fig. 10 is a schematic diagram of a precharge structure of another cascaded frequency converter provided in the embodiments of the present application. As shown in fig. 10, the precharge unit 300 in the cascaded frequency converter provided in the embodiment of the present application further includes: a current limited startup circuit 303.

The current-limiting start circuit 303 is connected between the low-voltage ac power supply 301 and the first switch 302, and includes a second switch 3031 and a current-limiting device 3032 connected in parallel. The second switch 3031 may be a relay or a common control switch, and the current limiting device 3032 may be a reactance and/or a resistance device, and the values thereof may be set according to actual operating conditions, which is not limited in this embodiment. The second switch 3031 functions to bypass the current limiting device 3032 when closed. Thereby enabling the current limit enable circuit 303 to act to limit current when starting the precharge.

For example, when the pre-charging is started, the control unit controls the first switch 302 to be closed, the second switch 3031 to be opened, and the low-voltage alternating-current power supply 301 pre-charges the bus capacitor connected correspondingly through the current limiting device 3032 and the inverter circuit in the first group of power units 201. When the voltage of the corresponding bus capacitor in the first group of power units 201, that is, the bus voltage, reaches a current-limiting voltage threshold or a first preset time (for example, a power frequency cycle) elapses, the control unit controls the second switch 3031 to be closed, and at this time, the second switch 3031 bypasses the current-limiting device 3032 connected in parallel with the second switch, so that the low-voltage ac power supply 301 further charges the bus capacitor, and the bus voltage is further increased. It can be seen that the existence of the current-limiting start-up circuit 303 enables controllability of the pre-charging process for the bus capacitors of the first group of power cells. The current-limiting voltage threshold of the bus voltage can be set according to actual working conditions, and therefore the embodiment of the application is not limited.

It is understood that fig. 10 is shown on the basis of fig. 7, i.e. three power units are included in the first group of power units 201.

Optionally, the precharge structure of the cascaded frequency converter provided in the embodiment of the present application further includes an auxiliary transformer. Fig. 11 is a schematic diagram of a precharge structure of another cascaded frequency converter according to an embodiment of the present application, and as shown in fig. 11, the precharge unit of the cascaded frequency converter further includes: an auxiliary transformer 304.

The auxiliary transformer 304 is connected between the current-limiting start circuit 303 and the first switch 302, and the auxiliary transformer 304 is used for transforming the voltage provided by the low-voltage ac power supply 301, so that the voltage of the power supply is further increased, and the voltage of the bus capacitor is further increased.

Optionally, the cascaded frequency converter provided in the embodiment of the present application may further include an auxiliary transformer 304 and does not include the current-limiting starting circuit 303, at this time, the auxiliary transformer 304 is connected between the low-voltage ac power supply 301 and the first switch 302, and the implementation effect and principle thereof are the same as those in the embodiment shown in fig. 11, and are not described again here.

In the above embodiment, after the bus voltage in the first group of power units 201 reaches the first voltage threshold, or after a second preset time period (for example, a power frequency cycle, etc.) elapses, that indicates that the bus capacitance of each power unit in the first group of power units 201 has completed the pre-charging process, at this time, the control unit controls the rectifying circuit in each power unit in the first group of power units 201 to operate, so as to excite the main transformer 100.

For example, the control unit turns on Pulse Width Modulation (PWM) control of the rectifying circuits in the first group of power units 201 to excite the main transformer through the secondary side winding connected to the first group of power units 201.

It should be noted that when the number of the power units included in the first group of power units 201 is more than one, and the control unit starts the PWM control on the rectifying circuits in the first group of power units 201, the control unit should further control the preset modulation commands between the rectifying circuits of the plurality of power units in the first group of power units 201 to satisfy the preset phase relationship, so as to avoid the demagnetization effect generated therebetween. In other words, if the pre-charging unit 300 is connected to a plurality of power units, when the rectifying circuits of the plurality of power units start to operate, the control unit controls the PWM control between the rectifying circuits of the corresponding plurality of power units to satisfy the predetermined phase relationship, so as to avoid mutual demagnetization.

In a possible design, when the PWM control is started for the rectifying circuits in the first group of power units 201, the control unit may control the first group of power units 201 to excite the main transformer 100 according to the preset modulation command by the generated PWM voltage, so that the other secondary side windings of the main transformer 100 pre-charge the respective corresponding bus capacitors through the corresponding rectifying circuits. Taking the power unit in fig. 6 as an example, the main transformer is excited by the first group of power units 201, so that other secondary side windings have voltages, and the other secondary side windings pre-charge the corresponding bus capacitors through the anti-parallel diodes in the rectifying circuits in the second group of power units. Note that the other secondary side windings refer to secondary side windings of the main transformer 100 other than the secondary side windings connected to the first group of power units 201.

Alternatively, the preset modulation command may be a slowly rising ac command, i.e., the modulation ratio of the PWM control is ramped up to ensure that the excitation process is performed slowly. In other words, when the preset modulation command is gradually increased, the voltage of the corresponding bus capacitor in the second group of power units is gradually increased, and the preset modulation command represents the magnitude of the PWM voltage to control the magnitude of the exciting current.

When the preset modulation command reaches a modulation command threshold value, namely the voltage of the bus capacitor in the second group of power units reaches a preset value, the excitation process is finished, namely the pre-charging process of the bus capacitor in the second group of power units is finished. In other words, the precharge process for the cascaded frequency converter is completed. The modulation command threshold may be set according to an actual working condition, which is not limited in the embodiment of the present application.

Optionally, when the voltage of the bus capacitor in the second group of power units reaches a second voltage threshold, the control unit may further start closed-loop PWM control on the rectifying circuit in the second group of power units, so that the closed-loop PWM control operates for a preset duration, and when the bus voltage of the second group of power units tends to a preset stable range, it indicates that the pre-charging process of the cascade converter is completed. The preset duration for the closed-loop PWM operation and the preset stable range for the bus voltage trend can be set according to actual working conditions, and the embodiment of the application does not limit the preset duration and the preset stable range. In addition, the second voltage threshold may be equal to or different from the first voltage threshold, and may be set according to an actual working condition, which is not limited in the embodiments of the present application.

Through the above description of the embodiments, after the pre-charging process of the cascaded frequency converter is completed, the control unit may start the power-on device of the main transformer 100, close the PWM control of each unit, and turn off the first switch 302, so that the pre-charging unit 300 is separated from the cascaded frequency converter, and the cascaded frequency converter performs a normal operation.

It should be noted that the second group of power units in the above embodiments completes the pre-charging process of the bus capacitance through the action of the main transformer excitation, and thus none of them is shown in the above figures.

Fig. 12 is a schematic flowchart of a pre-charging method for a cascaded frequency converter according to an embodiment of the present disclosure. As shown in fig. 12, the precharge method provided in this embodiment includes:

s101: and closing the first switch to enable the low-voltage alternating-current power supply to pre-charge the corresponding bus capacitor through the inverter circuit in the first group of power units.

S102: and when the voltage of the bus capacitor reaches a first voltage threshold value, controlling the rectifying circuits in the first group of power units to work so as to excite the main transformer and precharge the bus capacitor of the second group of power units.

The precharge method of the cascaded frequency converter provided by the embodiment of the application is applied to the cascaded frequency converter in the embodiment, wherein the cascaded frequency converter comprises a main transformer, a plurality of power units and a precharge unit, and the precharge method is executed by a control unit.

The pre-charging process includes firstly closing the first switch to enable the low-voltage ac power supply to provide a power supply voltage, and pre-charging the corresponding bus capacitor through the inverter circuit in the first group of power units, for example, performing uncontrolled rectification through the inverter circuit in the first group of power units to pre-charge the corresponding bus capacitor. After the voltage of the bus capacitor in the first group of power units, namely the bus voltage, reaches a first voltage threshold, the rectifying circuit in the first group of power units is controlled to work so as to excite the main transformer, and the bus capacitor of the second group of power units completes pre-charging through excitation.

Fig. 13 is a schematic flowchart of another precharging method for a cascaded frequency converter according to an embodiment of the present disclosure. As shown in fig. 13, the precharge method provided in this embodiment includes:

s201: and closing the first switch to enable the low-voltage alternating-current power supply to pre-charge the corresponding bus capacitor through the inverter circuit in the first group of power units.

S202: and when the voltage of the bus capacitor in the first group of power units reaches the current-limiting voltage threshold value or a first preset time length passes, controlling the second switch to be closed so as to bypass the current-limiting device.

S203: and when the voltage of the bus capacitor in the first group of power units reaches a first voltage threshold value, starting PWM control on a rectifying circuit in the first group of power units so as to excite the main transformer. Or

S203': and after a second preset time length, starting PWM control on a rectifying circuit in the first group of power units so as to excite the main transformer. Wherein S203 and S203' can be selected according to the requirement.

S204: and gradually increasing the preset modulation command, controlling the first group of power units to generate PWM voltage according to the preset modulation command, slowly exciting the main transformer, and slowly establishing the voltage of a secondary side winding of the transformer connected with other power units.

S205: and other secondary side windings of the main transformer are subjected to uncontrolled rectification through the rectification circuits in the second group of power units so as to pre-charge corresponding bus capacitors.

S206: and when the preset modulation command reaches a modulation command threshold value, the pre-charging is finished.

S206': and when the voltage of the bus capacitor in the second group of power units reaches a second voltage threshold value, starting closed-loop PWM control on a rectifying circuit in the second group of power units, operating for a preset time, and completing pre-charging. Wherein S206 and S206' can be selected as desired.

S207: and starting a power-on device of the main transformer, closing the PWM control of each power unit, and disconnecting the first switch so as to separate the pre-charging unit from the frequency converter. The closed PWM control is all the opened PWM control, namely the PWM control for opening the rectifier circuit and the closed loop PWM control for opening.

Optionally, when the rectifying circuits in the plurality of power units in the first group of power units start to operate, the preset modulation commands between the rectifying circuits of the corresponding plurality of power units should satisfy the preset phase relationship so as to avoid mutual demagnetization.

The precharging method of the cascade frequency converter provided by the embodiment is applied to the cascade frequency converter. According to the pre-charging method provided by the embodiment, circuits such as a pre-charging converter and the like are not required to be additionally arranged in the original cascade frequency converter, the controllable soft charging of the capacitor of each unit is realized by using the self unit conversion device, the great current impact on a power semiconductor device when a high-voltage side is switched on is effectively avoided, the high-voltage switching-on reliability of a system is improved, and the input cost of a pre-charging scheme is greatly reduced. Fig. 14 is a schematic diagram of a precharge simulation process provided in an embodiment of the present application, and as shown in fig. 14, in the precharge simulation process provided in this embodiment, during a time period from 0 to t1, a low-voltage ac power source precharges a corresponding bus capacitor through a rectifying circuit in a first group of power cells, for example, the first group of power cells in fig. 14 includes two power cells, i.e., c1 and b 1. The current limiting device is bypassed for a first predetermined period of time, such as at time t1, or when the bus voltage of the first group of power cells reaches a current limiting voltage threshold. The bus voltage now rises further. After a second preset time period, for example, at time t2, the PWM control is started for the rectifying circuits in the first group of power units, and a PWM voltage is generated according to a preset modulation command so that the excitation of the main transformer is slowly performed, so that the uncontrolled rectification is performed through the rectifying circuits in the second group of power units, thereby implementing the pre-charging process of the corresponding bus capacitor. At time t3, the preset modulation command reaches a modulation command threshold and the precharge process is complete. After time t3, the power-on device of the main transformer can be started, the PWM control of each unit is turned off, and the first switch is turned off, so that the pre-charging unit is separated from the cascade frequency converter, and the cascade frequency converter starts to operate normally.

Fig. 15 is a comparative illustration of a rush current provided in the present application, and t3 is the same as that in fig. 14. A comparison of the inrush current detected by the same power cell with and without the precharge provided by embodiments of the present application is shown in fig. 15. As can be seen from fig. 15, after the bus capacitor in the cascaded frequency converter is precharged by the precharge method according to the embodiment of the present application, when the high-voltage side of the main transformer is switched on, that is, at time t3, the value of the inrush current received by the power unit is 3547A²And s. If the pre-charging is not performed, the impact current value can be as high as 29220A²And s. Therefore, the pre-charging method of the cascade frequency converter provided by the embodiment of the application can effectively avoid overlarge impact caused by high-voltage switch-on and effectively improve the reliability of the high-voltage switch-on of the system.

Fig. 16 is a schematic structural diagram of an electronic device according to an embodiment of the present application. As shown in fig. 16, the electronic device 700 provided in the present embodiment includes:

a processor 701; and

a memory 702 communicatively coupled to the processor 701.

The memory 702 stores instructions executable by the processor 701, and the instructions are executed by the processor 701, so that the processor 701 can execute the steps of the method for precharging the cascaded frequency converter in the foregoing method embodiment, which may be referred to in detail in the foregoing method embodiment.

Alternatively, the memory 702 may be separate or integrated with the processor 701.

When the memory 702 is a separate device from the processor 701, the electronic device 700 may further include:

the bus 703 is used to connect the processor 701 and the memory 702.

In addition, the present embodiments also provide a non-transitory computer readable storage medium storing computer instructions for causing a computer to execute the steps of the pre-charging method for a cascaded frequency converter in the above embodiments. For example, the readable storage medium may be a ROM, a Random Access Memory (RAM), a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like.

Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It will be understood that the present application is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the application is limited only by the appended claims.