CN116203409B

CN116203409B - Power conversion system and main switch short circuit detection method thereof

Info

Publication number: CN116203409B
Application number: CN202310034691.6A
Authority: CN
Inventors: 郑飞洋; 董浩; 申智; 汪昌友; 邓凯
Original assignee: Sungrow Power Supply Co Ltd
Current assignee: Sungrow Power Supply Co Ltd
Priority date: 2023-01-10
Filing date: 2023-01-10
Publication date: 2025-11-07
Anticipated expiration: 2043-01-10
Also published as: CN116203409A

Abstract

The application provides a power conversion system and a main switch short circuit detection method thereof. In the short-circuit fault detection method, when all the first side main switches in the power conversion system do not have short-circuit faults, the power converter in the power conversion system is utilized to charge the second side bus capacitor in the power conversion system, so that the second bus capacitor can be charged when the second side voltage of the power conversion system is equal to zero, the condition that the voltages at two ends of the second bus capacitor are consistent with the second side voltage all the time is avoided, and further misjudgment in the process of short-circuit fault detection of the second side main switch is avoided.

Description

Power conversion system and main switch short circuit detection method thereof

Technical Field

The invention relates to the technical field of power electronics, in particular to a power conversion system and a main switch short circuit detection method thereof.

Background

At present, in order to ensure safe operation of the direct current conversion system, adhesion fault detection is performed on contactors at two sides of the direct current conversion system before the direct current conversion system is started, and in general, before adhesion fault detection is performed on a contactor at one side, the side bus capacitor needs to be charged by using the side voltage of the direct current conversion system.

However, when the operation mode of the dc conversion system is the constant bus voltage operation mode, since the voltage on one side of the dc conversion system is equal to zero, the charging of the bus capacitor on the side of the dc conversion system cannot be achieved, so that the voltages on both ends of the bus capacitor on the side are always consistent with the voltages on the side, and further misjudgment occurs in adhesion fault detection, that is, the dc conversion system cannot be started normally.

Therefore, how to avoid erroneous judgment in the process of performing adhesion fault detection on the contactor at one side of the direct current conversion system when the voltage at the other side is equal to zero is a technical problem to be solved.

Disclosure of Invention

In view of the above, the present invention provides a power conversion system and a method for detecting a short circuit of a main switch thereof, so as to avoid erroneous judgment in the process of detecting a stuck fault of a contactor at one side of a dc conversion system when the voltage at the other side is equal to zero.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions:

The application provides a main switch short circuit detection method of a power conversion system, wherein a first side of the power conversion system is connected with a power supply, and a second side of the power conversion system is a direct current side:

Judging whether all first side main switches in the power conversion system have no short circuit fault;

If all the first side main switches do not have short-circuit faults, charging a second side bus capacitor in the power conversion system by using a first side voltage of the power conversion system and a power converter in the power conversion system;

And after the charging is completed, detecting the short-circuit fault of each second side main switch in a divided manner.

Optionally, the detecting the short-circuit fault of one of the second side main switches includes:

the second side main switches to be detected are in an off state and the rest second side main switches are in an on state through control of each second side main switch;

Judging whether the voltage of two ends of the second side bus capacitor after being charged is equal to the second side voltage of the power conversion system;

and if the voltage of the two ends of the second side bus capacitor after being charged is equal to the second side voltage of the power conversion system, judging that the second side main switch to be detected has a short-circuit fault.

Optionally, if the power converter is used as a voltage source, the voltages at two ends of the second side bus capacitor are charged to a first preset value, and the first preset value is smaller than or equal to a set voltage value of the second side bus capacitor.

Optionally, if the power converter is used as a current source, the voltage at two ends of the second side bus capacitor is charged to a second preset value, and the difference value of the second side voltage minus the second preset value of the power conversion system is smaller than or equal to the first preset overvoltage.

Optionally, charging a second side bus capacitor in the power conversion system with a power converter in the power conversion system includes:

and closing all the first side main switches, and controlling the power converter to perform power conversion.

Optionally, if the first side of the power conversion system is a dc side and each of the first side main switches is connected in parallel with a slow start circuit, determining whether all the first side main switches in the power conversion system have no short-circuit fault includes:

Charging a first side bus capacitor in the power conversion system by using the first side voltage of the power conversion system and all the slow start circuits;

after the charging is completed, short-circuit fault detection is carried out on each first side main switch in a divided manner, and a corresponding detection result is obtained;

and if each detection result is that the first side main switch to be detected has no short circuit fault, executing the step of charging the second side bus capacitor in the power conversion system by using the power converter in the power conversion system.

Optionally, detecting a short-circuit fault of one of the first side main switches, and obtaining a corresponding detection result, including:

the first side main switches to be detected are in an off state by controlling each first side main switch, and the rest first side main switches are in an on state;

judging whether the voltage of the first side of the power conversion system is equal to the voltage of two ends of the charged first side bus capacitor or not;

And if the voltage of the first side of the power conversion system is not equal to the voltage of the two ends of the charged first side bus capacitor, the corresponding detection result is that the first side main switch to be detected has no short circuit fault.

In another aspect, the application provides a power conversion system comprising a controller, a power converter, a first side bus capacitor, a second side bus capacitor, at least one first side main switch and at least one second side main switch, wherein:

the first side bus capacitor is connected between two poles of the first side of the power converter;

The second side bus capacitor is connected between two poles of the second side of the power converter;

A first side of the power converter is connected to a first side of the power conversion system, and a second side of the power converter is connected to a second side of the power conversion system;

The first side main switch is arranged between a first port of the first side of the power converter and a first port of the first side of the power conversion system, or between a second port of the first side of the power converter and a second port of the first side of the power conversion system;

the second side main switch is arranged between a positive electrode of the second side of the power converter and a positive electrode of the second side of the power conversion system, or between a negative electrode of the second side of the power converter and a negative electrode of the second side of the power conversion system;

the power converter and all the main switches are controlled by the controller, and the controller is used for executing the main switch short circuit detection method according to any one of the aspects of the application.

Optionally, the first side of the power conversion system is a direct current side or an alternating current side.

Optionally, if the first side of the power conversion system is a dc side, the power conversion system further includes at least one slow start circuit, wherein:

each slow start circuit is connected to two ends of a corresponding first side main switch;

all the slow start circuits are controlled by the controller.

Optionally, if the first side of the power conversion system is a dc side, the first side main switch is a circuit breaker, a contactor, a MOS transistor, or an IGBT;

If the first side of the power conversion system is an ac side, the first side main switch is a circuit breaker or contactor.

Optionally, the second side main switch is a breaker, a contactor, a MOS transistor or an IGBT.

According to the technical scheme, the application provides a main switch short circuit detection method of a power conversion system, which is suitable for the power conversion system with a power supply connected to a first side and a direct current side connected to a second side. In the short-circuit fault detection method, when all the first side main switches in the power conversion system do not have short-circuit faults, the power converter in the power conversion system is utilized to charge the second side bus capacitor in the power conversion system, so that the second bus capacitor can be charged when the second side voltage of the power conversion system is equal to zero, the condition that the voltages at two ends of the second bus capacitor are consistent with the second side voltage all the time is avoided, and further misjudgment in the process of short-circuit fault detection of the second side main switch is avoided.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present invention, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic flow chart of an implementation manner of a main switch short circuit detection method of a power conversion system according to an embodiment of the present application;

Fig. 2 is a flowchart illustrating a specific example of a method for detecting a short circuit of a main switch of a power conversion system according to an embodiment of the present application;

fig. 3 is a schematic flow chart of a specific implementation manner of short-circuit fault detection for a second side main switch according to an embodiment of the present application;

fig. 4 is a flow chart of another implementation of a method for detecting a short circuit of a main switch of a power conversion system according to an embodiment of the present application;

FIG. 5 is a schematic flow chart of a specific implementation manner of short-circuit fault detection for a first side main switch according to an embodiment of the present application;

fig. 6 is a schematic structural diagram of a power conversion system according to an embodiment of the present application.

Fig. 7 and fig. 8 are schematic structural diagrams of two specific examples of a power conversion system according to an embodiment of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In the present application, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises an element.

In order to avoid misjudgment in the process of carrying out adhesion fault detection on a contactor at one side of a direct current conversion system when the voltage at the other side is equal to zero, the application provides a main switch short circuit detection method of the power conversion system, which is suitable for the power conversion system with a first side connected with a power supply and a second side being a direct current side.

The power conversion system comprises two sides, namely a first side and a second side, respectively, alternatively, the first side of the power conversion system can be a direct current side, the power conversion system is a direct current conversion system, the power converter in the power conversion system is a direct current converter, the first side of the power conversion system can also be an alternating current side, the power conversion system is an ACDC conversion system, and the power converter is an ACDC converter.

If the first side of the power conversion system is a direct current side, that is, the power conversion system is a direct current conversion system, in the power conversion system, a first side bus capacitor is connected between two poles of the first side of the power converter, a second side bus capacitor is connected between two poles of the second side of the power converter, a first side main switch may be provided between a positive pole of the first side of the power converter and a positive pole of the first side of the power conversion system, or between a negative pole of the first side of the power converter and a negative pole of the first side of the power conversion system, and a second side main switch may be provided between a positive pole of the second side of the power converter and a positive pole of the second side of the power conversion system, or between a negative pole of the second side of the power converter and a negative pole of the second side of the power conversion system.

The specific flow of the main switch short circuit detection method of the rate conversion system is shown in fig. 1, and specifically comprises the following steps:

s110, judging whether all the first side main switches in the power conversion system have no short circuit fault.

And if all the first side main switches have no short-circuit fault, sequentially executing the steps S120 and S130, and if at least one first side main switch has short-circuit fault, stopping executing the main switch short-circuit detection method of the power conversion system.

Optionally, the first side main switch may be a mechanical switch such as a contactor or a circuit breaker, or may be an electronic switch such as a MOS transistor or an IGBT, which is not specifically limited herein, and may be within the protection scope of the present application according to the specific situation.

It should be noted that when the power conversion system is a dc conversion system, the first side main switch may be a mechanical switch or an electronic switch, and when the power conversion system is an ACDC conversion system, the first side main switch may be a mechanical switch only.

In practical applications, if the first side main switch is a mechanical switch, the short-circuit fault of the first side main switch is usually caused by adhesion of contacts in the mechanical switch, and if the first side main switch is an electronic switch, the short-circuit fault of the first side main switch is usually caused by damage of a PN junction in the electronic switch.

S120, charging a second side bus capacitor in the power conversion system by using a first side voltage of the power conversion system and a power converter in the power conversion system.

In practical application, the specific implementation manner of step S120 is to close all the first side main switches and control the power converter to perform power conversion, that is, convert the first side voltage into a corresponding voltage through power conversion to charge the second side bus capacitor, specifically, when the power conversion system is a dc conversion system, that is, when the power converter is a dc converter, charge the second side bus capacitor through chopping.

In a specific example, the second side voltage of the power conversion system is equal to zero before starting, that is, the power converter is used as a voltage source, the voltage at two ends of the second side bus capacitor after being charged is charged to a first preset value, wherein the first preset value is smaller than or equal to the set voltage value of the second side bus capacitor, and in addition, if the power conversion system is a direct current conversion system, the operation mode of the power conversion system is a constant bus voltage operation mode at the moment.

The set voltage value of the second side bus capacitor is preset according to actual requirements, and is not specifically limited herein, and is within the protection scope of the present application.

It should be noted that, in general, after determining that all the second side main switches have no short-circuit fault, the power conversion system will perform grid-connected operation, so in order to enable direct grid-connected operation subsequently, in practical application, a lower limit value is set for the voltages at two ends of the second side busbar capacitor after charging, and the lower limit value is set according to the practical grid-connected requirement, which is not limited specifically herein.

In another specific example, the second side voltage of the power conversion system is not equal to zero before starting, that is, the power converter is used as a current source, and the voltage between two ends of the second side bus capacitor after being charged is charged to a second preset value, wherein the difference value of the second side voltage of the power conversion system minus the second preset value is less than or equal to the first preset overvoltage, and in addition, if the power conversion system is a direct current conversion system, the operation mode of the power conversion system is a constant current operation mode or a constant power operation mode at this time.

The first preset overvoltage is determined according to the actual working requirement of the second side main switch and the impact capability range which can be born by the second side bus capacitor, so that the second side main switch is prevented from generating larger impact during closing, namely the second side main switch and the second side bus capacitor are prevented from being damaged, and the second side main switch and the second side bus capacitor are not particularly limited and are all in the protection scope of the application.

And S130, after the charging is completed, short-circuit fault detection is carried out on each second side main switch in a divided manner.

For example, assuming that the power conversion system includes two second-side main switches, which are respectively denoted as a positive second-side main switch and a negative second-side main switch, short-circuit fault detection is performed on each second-side main switch in a divided manner, specifically, short-circuit fault detection is performed on the positive second-side main switch for the first time, and short-circuit fault detection is performed on the negative second-side main switch for the second time.

At this time, in one example, as shown in fig. 2, step S130 includes the following steps;

s131, short-circuit fault detection is conducted on the positive electrode second side main switch.

And S132, detecting a short-circuit fault of the main switch at the second side of the negative electrode.

Optionally, the second side main switch may be a mechanical switch such as a contactor or a circuit breaker, or may be an electronic switch such as a MOS transistor or an IGBT, which is not specifically limited herein, and may be within the protection scope of the present application according to the specific situation.

In practical applications, if the second side main switch is a mechanical switch, the short-circuit fault of the second side main switch is usually caused by adhesion of contacts in the mechanical switch, and if the second side main switch is an electronic switch, the short-circuit fault of the second side main switch is usually caused by damage of a PN junction in the electronic switch.

When all the first side main switches in the power conversion system do not have short-circuit faults, the power converter in the power conversion system is utilized to charge the second side bus capacitor in the power conversion system, so that the second bus capacitor can be charged when the voltage of the second side of the power conversion system is equal to zero, the condition that the voltages of two ends of the second bus capacitor are consistent with the voltage of the second side all the time is avoided, and further misjudgment in the process of detecting the short-circuit faults of the second side main switch is avoided.

Another embodiment of the present application provides a specific implementation manner of short-circuit fault detection for a second side main switch, as shown in fig. 3 (fig. 3 only shows an example of short-circuit fault detection for a second side main switch), which specifically includes the following steps:

s210, controlling each second side main switch to enable the second side main switch to be detected to be in an off state and enable the rest second side main switches to be in an on state.

For example, assume that the power conversion system includes two second-side main switches, which are respectively denoted as an anode second-side main switch and a cathode second-side main switch, and short-circuit fault detection is performed on the anode second-side main switch, where the anode second-side main switch is the second-side main switch to be detected.

In practical application, the method for detecting the short circuit of the main switch is carried out before the power conversion system is started, so that if the short circuit fault detection carried out at the moment is carried out for the first time, each second side main switch is in a default state, namely an off state, before the short circuit fault detection is carried out, and if the short circuit fault detection carried out at the moment is not carried out for the first time, the second side main switches except the last time to be detected are in the off state, and other second side main switches are in the on state.

In a specific example, the short-circuit fault detection performed at this time is the first time, if the number of second side main switches included in the power conversion system is greater than 1, the second side main switches to be detected are kept in a current state by controlling the second side main switches to be detected and the rest of the second side main switches to be detected to be closed, so that the second side main switches to be detected are in an off state and the rest of the second side main switches to be detected are in an on state, and if the number of second side main switches included in the power conversion system is equal to 1, the second side main switches to be detected are kept in a current state by controlling the second side main switches to be detected, so that the second side main switches to be detected are in an off state and the rest of the second side main switches are in an on state.

In a specific example, the short-circuit fault detection performed at this time is not the first time, and the number of the second side main switches included in the power conversion system is greater than 1, and the second side main switches to be detected can be in an off state and the rest of the second side main switches are in an on state by controlling the second side main switches to be detected to be off, controlling the second side main switches to be detected last time to be on, and controlling other second side main switches to be in a current state.

S220, judging whether the voltage of two ends of the second side bus capacitor after being charged is equal to the second side voltage of the power conversion system.

If the voltage across the second side bus capacitor is equal to the second side voltage of the power conversion system, step S230 is executed, and if the voltage across the second side bus capacitor is not equal to the second side voltage of the power conversion system, step S240 is executed.

S230, judging that the second side main switch to be detected has a short-circuit fault.

S240, judging that the to-be-detected second side main switch has no short circuit fault.

In this embodiment, since the voltage across the second-side bus capacitor after the step S210 is performed is not equal to the second-side voltage of the power conversion system, if the voltage across the second-side bus capacitor after the charging is equal to the second-side voltage of the power conversion system, it may be determined that the second-side main switch to be detected has a short-circuit fault, and thus this embodiment may implement the short-circuit fault detection of the second-side main switch to be detected.

The present application provides a specific embodiment of step S110, which is suitable for a case where the first side of the power conversion system is a dc side and each of the first side main switches is connected in parallel with a slow start circuit, that is, for a case where the power conversion system is a dc conversion system and each of the first side main switches is connected in parallel with a slow start circuit, and the specific flow of this embodiment may be seen in fig. 4 (only shown on the basis of fig. 1), and specifically includes the following steps:

S310, charging a first side bus capacitor in the power conversion system by using the first side voltage of the power conversion system and all the slow start circuits.

And the difference value of the first side voltage minus the third preset value of the power conversion system is smaller than or equal to the second preset overvoltage.

In addition, the second preset overvoltage is determined according to the actual working requirement of the first side main switch and the impact capability range that the first side bus capacitor can bear, so as to avoid the first side main switch from generating larger impact during closing, namely, avoid damaging the first side main switch and the first side bus capacitor, and the second preset overvoltage is not particularly limited herein and is within the protection scope of the application.

S320, after the charging is completed, short-circuit fault detection is carried out on each first side main switch in a divided manner, and corresponding detection results are obtained.

The embodiment also provides a specific implementation manner of detecting a short-circuit fault of a first side main switch and obtaining a corresponding detection result, where a specific flow of this implementation manner may be referred to fig. 5 (fig. 5 is only based on fig. 4, and shows an example of detecting a short-circuit fault of a first side main switch), and specifically includes the following steps:

s410, controlling each first side main switch to enable the first side main switch to be detected to be in an off state and enabling the rest first side main switches to be in an on state.

For example, assume that the power conversion system includes two first side main switches, which are respectively denoted as a positive first side main switch and a negative first side main switch, and short-circuit fault detection is performed on the positive first side main switch, then the positive first side main switch is the first side main switch to be detected.

It should be noted that, the first side main switch to be detected is in an off state, and the other first side main switches are in an on state, which are the same as the second side main switch to be detected is in an off state, and the other second side main switches are in an on state, which are not described herein.

S420, judging whether the first side voltage of the power conversion system is equal to the voltage of two ends of the charged first side bus capacitor.

If the first side voltage of the power conversion system is not equal to the voltage between the two ends of the charged first side bus capacitor, step S430 is performed, and if the first side voltage of the power conversion system is equal to the voltage between the two ends of the charged first side bus capacitor, step S440 is performed.

And S430, the corresponding detection result is that the main switch at the first side to be detected has no short circuit fault.

S440, the corresponding detection result is that the first side main switch to be detected has a short circuit fault.

In this embodiment, since the first side voltage of the power conversion system is not equal to the voltage across the charged first side bus capacitor after step S410 is performed, when the first side voltage of the power conversion system is equal to the voltage across the charged first side bus capacitor, it may be determined that the short-circuit fault occurs in the first side main switch to be detected, thereby implementing the short-circuit fault detection on the first side main switch.

S330, after all the first side main switches are subjected to short-circuit fault detection, judging whether each detection result is that the first side main switch to be detected has no short-circuit fault.

And if the detection results are that the short-circuit fault does not occur in the first side main switch to be detected, executing the step S120, and if the detection results are that the short-circuit fault does not occur in the first side main switch to be detected, stopping executing the main switch short-circuit detection method.

The foregoing is only one specific embodiment of step S110, and in practical applications, including but not limited to this, the present application is not limited thereto, and the present application can be applied as the case may be.

The present application provides a power conversion system, the second side of which is a dc side, and the specific structure thereof can be seen in fig. 6, and specifically includes a controller (the controller is not shown in fig. 6 or fig. 7 for simplifying the drawing), a power converter 10, a first side bus capacitor 20, a second side bus capacitor 30, at least one first side main switch S1 (only two first side main switches S1 are shown in fig. 6 as an example), at least one second side main switch S2 (only two second side main switches S2 are shown in fig. 6 as an example), and at least one slow start circuit 40 (only two slow start circuits 40 are shown in fig. 6 as an example).

The first side of the power conversion system is connected with a power supply, the second side of the power conversion system is a direct current side, in practical application, the power supply can be a direct current power supply or an alternating current power supply, the power supply is not limited in particular, and can be determined according to the specific situation, however, the type of the power supply is matched with the type of the first side, for example, if the first side is a direct current side, the power supply is a direct current power supply.

Alternatively, the first side of the power conversion system may be a dc side, where the power conversion system is a dc conversion system, and the power converter 10 in the power conversion system is a dc converter, and the first side of the power conversion system may also be an ac side, where the power conversion system is an ACDC conversion system, and the power converter 10 is an ACDC converter, where practical applications include, but are not limited to, any specific limitation herein, and any specific situation is possible, and all are within the scope of the present application.

Optionally, the first side main switch S1 may be a mechanical switch such as a contactor or a circuit breaker, or may be an electronic switch such as a MOS transistor or an IGBT, which is not specifically limited herein, and may be within the protection scope of the present application according to the specific situation.

It should be noted that when the power conversion system is a dc conversion system, the first side main switch S1 may be a mechanical switch or an electronic switch, and when the power conversion system is an ACDC conversion system, the first side main switch S1 may be a mechanical switch only.

Optionally, the second side main switch S2 may be a mechanical switch such as a contactor or a circuit breaker, or may be an electronic switch such as a MOS transistor or an IGBT, which is not specifically limited herein, and may be within the protection scope of the present application according to the specific situation.

It is preferred that the first side bus capacitor 20 and the second side bus capacitor 30 each comprise one capacitor or at least two capacitors connected in series, not specifically defined herein, but rather, as the case may be, within the scope of the present application, and in practical applications, the first side bus capacitor 20 and the second side bus capacitor 30 each comprise two capacitors connected in series, such as the capacitors C1 and C2 in fig. 6.

The slow start circuit 40 may be a slow start circuit in the prior art, for example, as shown in fig. 6, a structure formed by connecting a slow start resistor and a MOS transistor in series is adopted, and in the prior art, various implementation manners of the slow start circuit are provided, which are not described in detail herein.

The connection relationship between the devices is specifically as follows:

the first side bus capacitor 20 is connected between the poles of the first side of the power converter 10 and the second side bus capacitor 30 is connected between the poles of the second side of the power converter 10.

A first side of the power converter 10 is connected to a first side of the power conversion system and a second side of the power converter 10 is connected to a second side of the power conversion system.

The first side main switch S1 may be disposed between a first port of the first side of the power converter 10 and a first port of the first side of the power conversion system, or between a second port of the first side of the power converter 10 and a second port of the first side of the power conversion system.

If the first side of the power conversion system may be a dc side, the first port and the second port are positive and negative, respectively.

The second side main switch S2 is disposed between a positive electrode of the second side of the power converter 10 and a positive electrode of the second side of the power conversion system, or between a negative electrode of the second side of the power converter 10 and a negative electrode of the second side of the power conversion system.

In practical application, the number of the first side main switches S1 and the number of the second side main switches S2 may be determined according to the specific situation, and are not specifically limited herein, and are within the protection scope of the present application, and preferably, the number of the first side main switches S1 is equal to 2, and the number of the second side main switches S2 is equal to 2.

In a specific example, as shown in fig. 6, the number of the first side main switches S1 is equal to 2, one first side main switch S1 is disposed between the positive electrode of the first side of the power converter 10 and the positive electrode of the first side of the power conversion system, and is denoted as a positive electrode first side main switch, and the other first side main switch S1 is disposed between the negative electrode of the first side of the power converter 10 and the negative electrode of the first side of the power conversion system, and is denoted as a negative electrode first side main switch.

In another specific example, as shown in fig. 6, the number of the second-side main switches S2 is equal to 2, one second-side main switch S2 is disposed between the positive electrode of the second side of the power converter 10 and the positive electrode of the second side of the power conversion system, and is denoted as a positive electrode second-side main switch, and the other second-side main switch S2 is disposed between the negative electrode of the second side of the power converter 10 and the negative electrode of the second side of the power conversion system, and is denoted as a negative electrode second-side main switch.

Each of the slow start circuits 40 is connected across a corresponding one of the first side main switches S1.

In a specific example, as shown in fig. 7, two sides of the power conversion system are both dc sides and are connected with a power supply, and the two sides are respectively denoted as a side and B side, where the first side of the power conversion system is denoted as a side and the second side is denoted as B side, the a side is provided with two main switches denoted as SA, the B side is provided with two main switches denoted as SB, and two ends of each main switch SA are connected in parallel with a slow start circuit 40.

In another specific example, as shown in fig. 8, two sides of the power conversion system are both dc sides and are connected with a power supply, and the two sides are respectively denoted as a side and B side, wherein the first side of the power conversion system is the B side, the second side is the a side, the a side is provided with two main switches, denoted as SA, the B side is provided with two main switches, denoted as SB, and two ends of each main switch SB are connected in parallel with a slow start circuit 40.

In practical application, if the power conversion system is provided with a slow start circuit, the power conversion system is further provided with at least one fuse Fu, wherein the fuse Fu and the slow start circuit are arranged on the same side of the power conversion system, and the specific connection relation of the fuse Fu is as follows:

In a specific example, as shown in fig. 7, the power conversion system is provided with two fuses Fu, one fuse Fu being provided between the positive electrode of the a side of the power converter 10 and the positive electrode of the a side of the power conversion system, and the other fuse Fu being provided between the negative electrode of the a side of the power converter 10 and the negative electrode of the a side of the power conversion system.

In another specific example, as shown in fig. 8, the power conversion system is provided with two fuses Fu, one fuse Fu being provided between the positive electrode on the B side of the power converter 10 and the positive electrode on the B side of the power conversion system, and the other fuse Fu being provided between the negative electrode on the B side of the power converter 10 and the negative electrode on the B side of the power conversion system.

The power converter 10, all main switches, and all slow start circuits 40 are controlled by a controller for performing the main switch short circuit detection method as provided in the above embodiments.

It should be noted that, in practical applications, the controller may be independently disposed or integrated in the power converter 10, which is not limited herein, and may be within the scope of the present application as appropriate.

In the prior art, a non-on-board circuit is needed to connect a slow start circuit in parallel at two ends of a contactor at one side of a direct current conversion system, but the possibility of wrong connection exists in the non-on-board circuit, for example, if the positive contactor at the side is arranged between the positive pole at the side of the direct current conversion system and the positive pole at the side of the direct current conversion converter in the direct current conversion system, the negative contactor at the side is arranged between the negative pole at the side of the direct current conversion system and the negative pole at the side of the direct current conversion converter in the direct current conversion system, one end of the positive slow start circuit is connected with the positive pole at the side of the direct current converter, the other end of the negative slow start circuit is connected with the negative pole at the side of the direct current converter, and when the wrong connection occurs, if a short circuit fault detection method is used for detecting the short circuit fault of the two contactors at the side in the direct current conversion system, the side voltage is directly applied to two ends of the slow start circuit, so that the slow start circuit is damaged, and the slow start circuit is greatly damaged, and the PCB is caused.

In the power conversion system provided by the application, if the slow start circuit is arranged on the first side of the power conversion system, the problem of misconnection of the off-board circuit can be solved, so that the economic loss is reduced, the overall cost of the power conversion system is optimized, and the slow start circuit is arranged on the first side of the power conversion system as a preferred implementation mode.

The features described in the various embodiments of the present disclosure may be interchanged or combined with one another in the description of the disclosed embodiments to enable those skilled in the art to make or use the application. The above description is only of the preferred embodiment of the present application, and is not intended to limit the present application in any way. While the application has been described with reference to preferred embodiments, it is not intended to be limiting. Any person skilled in the art can make many possible variations and modifications to the technical solution of the present application or modifications to equivalent embodiments using the methods and technical contents disclosed above, without departing from the scope of the technical solution of the present application. Therefore, any simple modification, equivalent variation and modification of the above embodiments according to the technical substance of the present application still fall within the scope of the technical solution of the present application.

Claims

1. A main switch short circuit detection method of a power conversion system is characterized in that a first side of the power conversion system is connected with a power supply, a second side of the power conversion system is a direct current side, and the main switch short circuit detection method comprises the following steps:

and after the charging is completed, short-circuit fault detection is carried out on each second side main switch in a divided manner.

2. The method of claim 1, wherein short-circuit fault detection for one of the second side main switches comprises:

3. The method according to claim 1, wherein if the power converter is used as a voltage source, the voltage across the second side bus capacitor is charged to a first preset value, and the first preset value is less than or equal to a set voltage value of the second side bus capacitor.

4. The method according to claim 1, wherein if the power converter is used as a current source, the voltage across the second-side bus capacitor is charged to a second preset value, and a difference between the second-side voltage of the power conversion system minus the second preset value is less than or equal to a first preset overvoltage.

5. The method according to any one of claims 1 to 4, wherein charging a second side bus capacitor in the power conversion system with a power converter in the power conversion system, comprises:

6. The method according to any one of claims 1 to 4, wherein if the first side of the power conversion system is a dc side and each of the first side main switches is connected in parallel with a slow start circuit, determining whether all of the first side main switches in the power conversion system have no short circuit fault comprises:

7. The method for detecting a short circuit of a main switch according to claim 6, wherein detecting a short circuit fault of one of the first side main switches and obtaining a corresponding detection result comprises:

8. The power conversion system is characterized by comprising a controller, a power converter, a first side bus capacitor, a second side bus capacitor, at least one first side main switch and at least one second side main switch, wherein:

The power converter, all main switches being controlled by the controller for performing the main switch short circuit detection method according to any one of claims 1 to 7.

9. The power conversion system of claim 8, wherein the first side of the power conversion system is a direct current side or an alternating current side.

10. The power conversion system of claim 9, wherein if the first side of the power conversion system is a DC side, the power conversion system further comprises at least one slow start circuit, wherein:

all the slow start circuits are controlled by the controller.

11. The power conversion system according to claim 9, wherein if the first side of the power conversion system is a dc side, the first side main switch is a circuit breaker, a contactor, a MOS transistor, or an IGBT;

12. The power conversion system according to any one of claims 8 to 11, wherein the second side main switch is a circuit breaker, a contactor, a MOS transistor, or an IGBT.