JP2022098242A - Power conversion device - Google Patents

Abstract

To provide a power conversion device capable of detecting electric leak of AC power on which power conversion is performed.SOLUTION: A power conversion device comprises an input unit 1, a power storage unit 2, a power conversion unit 3, an output unit 4, an output switching unit 5, a leakage current detection unit 6 and a control unit 7. First AC power is inputted from a commercial power source 200 to the input unit 1. The power storage unit 2 stores DC power. The power conversion unit 3 converts DC power into second AC power. A load is electrically connected to the output unit 4. The output switching unit 5 transfers the first AC power and the second AC power to the output unit 4 in a switchable manner. The leakage current detection unit 6 detects a leakage current of the second AC power. The control unit 7 detects electric leakage on the basis of a result of the leak current detection unit 6 and stops the power conversion unit 3 in a case where the electric leakage is detected.SELECTED DRAWING: Figure 1

Description

The present disclosure generally relates to power converters. More specifically, the present disclosure relates to a power conversion device that can switchably output AC power from a commercial power source and AC power converted into power.

Patent Document 1 discloses a power control device. This power control device includes an inverter, a first interconnection relay and a second interconnection relay, a reference potential relay, a voltage sensor, and a control unit. The control unit determines whether or not the state of each of the first interconnection relay and the second interconnection relay is normal based on the voltage value measured by the voltage sensor.

Japanese Patent Application Laid-Open No. 2003-317598

The power control device described in Patent Document 1 has a problem that the leakage cannot be detected when the AC power converted by the inverter leaks.

An object of the present disclosure is to provide a power conversion device capable of detecting leakage of power-converted AC power.

The power conversion device according to one aspect of the present disclosure includes an input unit, a power storage unit, a power conversion unit, an output unit, an output switching unit, a leakage current detection unit, and a control unit. The input unit receives the first AC power from a commercial power source. The power storage unit stores DC power. The power conversion unit converts the DC power into a second AC power. A load is electrically connected to the output unit. The output switching unit transmits the first AC power and the second AC power to the output unit so as to be switchable. The leakage current detection unit detects the leakage current of the second AC power. The control unit detects the leakage based on the result of the leakage current detection unit, and stops the power conversion unit when the leakage is detected.

According to the present disclosure, there is an advantage that leakage of power-converted AC power can be detected.

FIG. 1 is a block diagram showing a schematic configuration of a power conversion device according to an embodiment of the present disclosure. FIG. 2 is a more detailed circuit configuration diagram of the same power conversion device. FIG. 3 is a flowchart showing the operation from the detection of leakage of the power conversion device to the stop of the power conversion unit. FIG. 4 is a flowchart showing the operation of output switching from the first AC power to the second AC power of the same power conversion device. FIG. 5 is a flowchart showing the operation of output switching from the second AC power to the first AC power of the same power conversion device. FIG. 6 is a block diagram showing a schematic configuration of the power conversion device according to the modification of the above.

(Embodiment)
(1) Overview As shown in FIG. 1, the power conversion device 100 according to the present embodiment includes an input unit 1, a power storage unit 2, a power conversion unit 3, an output unit 4, an output switching unit 5, and an electric leakage. A current detection unit 6 and a control unit 7 are provided.

In the power conversion device 100 according to the present embodiment, when the input unit 1 is electrically connected to the commercial power supply 200, the first AC power is input from the commercial power supply 200 to the input unit 1. Further, the power conversion unit 3 converts the DC power stored in the power storage unit 2 into the second AC power. After that, the output switching unit 5 transmits the first AC power input to the input unit 1 and the second AC power converted by the power conversion unit 3 to the output unit 4 in a switchable manner.

The leakage current detection unit 6 detects the leakage current of the second AC power, and the control unit 7 detects the leakage of the second AC power based on the detection result of the leakage current detection unit 6. When the leakage of the second AC power is detected, the control unit 7 stops the power conversion unit 3.

(2) Details Hereinafter, the power conversion device 100 according to the present embodiment will be described in detail with reference to FIGS. 1 and 2. The power conversion device 100 is used in each dwelling unit of an apartment house, a detached house, a factory, an office, and the like.

The input unit 1 can be electrically connected to the commercial power supply 200. As shown in FIG. 2, when the input unit 1 is electrically connected to the commercial power supply 200, the first AC power is input from the commercial power supply 200 to the input unit 1. The input unit 1 has a live input terminal 11 connected to the ungrounded electrode of the commercial power supply 200, a neutral input terminal 12 connected to the grounded electrode of the commercial power supply 200, and a ground input connected to the grounded electrode of the commercial power supply 200. A terminal 13 is provided. Further, the power conversion device 100 has a first live electric circuit C11, a first neutral electric circuit C12, and a first connected to the live input terminal 11, the neutral input terminal 12, and the ground input terminal 13, respectively. A ground electric circuit C13 is further provided. The first ground electric circuit C13 is grounded to the housing of the power conversion device 100. Further, it is preferable that the input unit 1 of the present embodiment includes an input plug. For example, the first AC power is input to the input unit 1 by inserting the input plug into an outlet provided in each dwelling unit of an apartment house, a detached house, a factory, an office, or the like. That is, it is preferable that the input unit 1 is provided with an input plug, a terminal, or the like, and the electrical connection state between the input unit 1 and the commercial power supply 200 can be switched between connected and non-connected.

The power storage unit 2 stores DC power. Then, the power conversion unit 3 converts the DC power stored in the power storage unit 2 into the second AC power. Further, the power conversion unit 3 supplies the second AC power via the output unit 4. The magnitude of the voltage output by the power conversion unit 3 is the same value as the rated voltage of the commercial power supply 200. As shown in FIG. 2, the power conversion device 100 has a second live electric circuit C21 and a second neutral electric circuit C22, which are connected to a pair of AC output ends of the power conversion unit 3, respectively. The power storage unit 2 and the power conversion unit 3 of the present embodiment form a stand-alone storage battery. The stand-alone storage battery is a power storage device that outputs AC power that is not grid-connected to the commercial power source 200 as the second AC power. The power storage unit 2 is preferably a secondary battery that can be repeatedly used by charging or discharging, such as a lithium ion battery or a solid-state battery.

The output unit 4 is electrically connected to the load. As shown in FIGS. 1 and 2, the output unit 4 of the embodiment is electrically connected to the electric device 300 which is a load. The electric device 300 is, for example, an air conditioner, a television receiver, or the like.

The leakage current detection unit 6 detects the leakage current due to the second AC power. In the present embodiment, the leakage current detection unit 6 is provided between the power conversion unit 3 and the output switching unit 5. Further, the line-to-ground leakage current detection unit 6 of the present embodiment is a zero-phase sequence current meter, and as shown in FIG. 2, the line-to-ground leakage current detection unit 6 transmits the second AC power output from the power conversion unit 3. The second live electric circuit C21 and the second neutral electric circuit C22 are provided so as to penetrate through each other. The zero-phase current transformer measures the current difference between the second live electric circuit C21 and the second neutral electric circuit C22, and detects the leakage current due to the second AC power.

The control unit 7 includes an electric leakage processing unit 71. The leakage processing unit 71 detects the leakage based on the result of the leakage current detection unit 6. When the power leakage processing unit 71 detects the power leakage, the power leakage processing unit 71 outputs an operation stop signal A4 to the power conversion unit 3. Therefore, the power conversion unit 3 stops the power conversion from the DC power to the second AC power. As an example, when the output switching unit 5 fails, the second AC power may be transmitted to the input unit 1. In this case, when a person who operates the power conversion device 100 comes into contact with the live input terminal 11, it is conceivable that the second AC power leaks.

The output switching unit 5 can switch between the first AC power transmitted from the input unit 1 and the second AC power transmitted from the power conversion unit 3 to the output unit 4. The output switching unit 5 includes a first relay unit 51 provided between the input unit 1 and the output unit 4, and a second relay unit 52 provided between the power conversion unit 3 and the output unit 4. Be prepared. The first relay unit 51 conducts and cuts off the electrical connection between the input unit 1 and the output unit 4, and the second relay unit 52 electrically connects the power conversion unit 3 and the output unit 4. Conduct and disconnect the connection.

The power conversion device 100 further includes a third live electric circuit C31 and a third neutral electric circuit C32 as a pair of electric circuits electrically connected to the output unit 4. The third live electric circuit C31 conducts or cuts off the electrical connection with the first live electric circuit C11 via the first relay unit 51, and is electrically connected to the second live electric circuit C21 via the second relay unit 52. The connection is conducted or disconnected. The third neutral electric circuit C32 is electrically connected to or disconnected from the first neutral electric circuit C12 via the first relay unit 51, and is electrically connected to the second neutral electric circuit C22 via the second relay unit 52. The connection is conducted or disconnected.

As shown in FIG. 1, the first relay unit 51 includes a plurality of first contact portions 511, and the second relay unit 52 includes a plurality of second contact portions 521. The plurality of first contact units 511 are connected in series between the input unit 1 and the output unit 4, and the plurality of second contact units 521 are connected in series between the power conversion unit 3 and the output unit 4.

As shown in FIG. 2, the power conversion device 100 of the present embodiment includes two first contact portions 511a and 511b as a plurality of first contact portions 511. In the first relay unit 51, two first contact portions 511a and 511b are connected in series via a pair of internal electric circuits. That is, the first contact portion 511a conducts or cuts off the electrical connection between the first live electric circuit C11 and the first neutral electric circuit C12 and the pair of internal electric circuits of the first relay unit 51. The first contact portion 511b conducts or cuts off the electrical connection between the third live electric circuit C31 and the third neutral electric circuit C32 and the pair of internal electric circuits of the second relay unit 52.

Further, as shown in FIG. 2, the power conversion device 100 includes two second contact portions 521a and 521b as a plurality of second contact portions 521. In the second relay unit 52, the two second contact portions 521a and 521b are connected in series via a pair of internal electric circuits. That is, the second contact portion 521a conducts or cuts off the electrical connection between the second live electric circuit C21 and the second neutral electric circuit C22 and the pair of internal electric circuits of the second relay unit 52. The second contact portion 521b conducts or cuts off the electrical connection between the third live electric circuit C31 and the third neutral electric circuit C32 and the pair of internal electric circuits of the second relay unit 52.

The output switching unit 5 includes a voltage detecting unit 53 that detects at least one internal voltage of the output switching unit 5. The control unit 7 controls the output switching unit 5 based on at least one internal voltage detected by the voltage detection unit 53.

Specifically, the voltage detection unit 53 includes a first voltage detection unit 531 and a second voltage detection unit 532. The first voltage detection unit 531 detects the first internal voltage Vs1, which is the voltage of the internal electric circuit between the pair of first contact units 511a and 511b, as the internal voltage. Similarly, the second voltage detection unit 532 detects the second internal voltage Vs2, which is the voltage of the internal electric circuit between the pair of second contact units 521a and 521b, as the internal voltage. As shown in FIG. 2, the first voltage detection unit 531 of the present embodiment is provided between the first contact unit 511a and the first contact unit 511b. Further, the second voltage detection unit 532 of the present embodiment is provided between the second contact portion 521a and the second contact portion 521b.

The first voltage detection unit 531 outputs the detection result of the first internal voltage Vs1 as the first detection signal A21. Specifically, the first voltage detection unit 531 sets the first detection signal A21 to the L level when the first internal voltage Vs1 is equal to or higher than the threshold value Vt1, and sets the first detection signal A21 to the L level when the first internal voltage Vs1 is less than the threshold value Vt1. Let the detection signal A21 be the H level.

The second voltage detection unit 532 outputs the detection result of the second internal voltage Vs2 as the second detection signal A22. Specifically, the second voltage detection unit 532 sets the second detection signal A22 to the L level when the second internal voltage Vs2 is equal to or higher than the threshold value Vt1, and sets the second detection signal A22 to the L level when the second internal voltage Vs2 is less than the threshold value Vt2. Let the detection signal A22 be the H level.

The control unit 7 drives the first relay unit 51 based on the second internal voltage Vs2. This is because when the first contact portion 511 is unintentionally brought into a conductive state due to factors such as welding, the first AC power and the second AC power are simultaneously transmitted to the third live electric circuit C31 and the third neutral electric circuit C32. There is a purpose to prevent it from being done. Similarly, the control unit 7 drives the second relay unit 52 based on the first internal voltage Vs1. This is because when the second contact portion 521 is unintentionally brought into a conductive state due to factors such as welding, the first AC power and the second AC power are simultaneously transmitted to the third live electric circuit C31 and the third neutral electric circuit C32. There is a purpose to prevent it from being done.

More specifically, the control unit 7 includes a signal generation unit 72, a first drive control unit 73, and a second drive control unit 74. The signal generation unit 72 generates and outputs a signal A11 that controls the first relay unit 51 and a signal A12 that controls the second relay unit 52.

The first drive control unit 73 drives the first contact units 511a and 511b based on the second detection signal A22 and the first control signal A11. Further, the second drive control unit 74 drives the second contact units 521a and 521b based on the first detection signal A21 and the second control signal A12.

In the present embodiment, the first drive control unit 73 is the first AND gate to which the second detection signal A22 and the first control signal A11 are input, and the second drive control unit 74 is the first detection signal A21 and the second. This is the second AND gate to which the control signal A12 is input.

When the second detection signal A22 and the first control signal A11 input to the first drive control unit 73 are all H level (for example, 5V), the first drive control unit 73 has the H level first drive signal A31. Is output. On the other hand, when at least one of the second detection signal A22 and the first control signal A11 input to the first drive control unit 73 is L level (for example, 0V), the first drive control unit 73 is the first L level. The drive signal A31 is output.

Similarly, when the first detection signal A21 and the second control signal A12 input to the second drive control unit 74 are all H level (for example, 5V), the second drive control unit 74 is the second H level. The drive signal A32 is output. On the other hand, when at least one of the first detection signal A21 and the second control signal A12 input to the second drive control unit 74 is at the L level (for example, 0V), the second drive control unit 74 is the second at the L level. The drive signal A32 is output.

The control unit 7 further includes an abnormality determination unit 75. The abnormality determination unit 75 receives the first detection signal A21 from the first voltage detection unit 531 and the second control signal A12 from the signal generation unit 72. When the second control signal A12 is at the H level and the state where the first detection signal A21 is at the L level continues for a certain period of time, the abnormality determination unit 75 causes the first contact units 511a and 511b due to factors such as welding. It is determined that an abnormality has occurred in which at least one of the above does not operate according to the first drive signal A31. After that, the abnormality determination unit 75 outputs an abnormality stop signal A5 for stopping the operation of the power conversion unit 3 to the power conversion unit 3. The power conversion unit 3 receives the abnormal stop signal A5 and stops the power conversion from the DC power stored in the power storage unit 2 to the second AC power.

Similarly, the abnormality determination unit 75 receives the second detection signal A22 from the second voltage detection unit 532 and the first control signal A11 from the signal generation unit 72. When the first control signal A11 is at H level and the state where the second detection signal A22 is at L level continues for a certain period of time, the abnormality determination unit 75 causes the second contact units 521a and 521b due to factors such as welding. It is determined that an abnormality has occurred in which at least one of the above does not operate according to the second drive signal A32. After that, the abnormality determination unit 75 outputs an abnormality stop signal A5 for stopping the operation of the power conversion unit 3 to the power conversion unit 3. The power conversion unit 3 receives the abnormal stop signal A5 and stops the power conversion from the DC power stored in the power storage unit 2 to the second AC power.

(3) Operation (3.1) From leakage detection to stop of the power conversion unit 3 Hereinafter, the operation from the leakage detection to the stop of the power conversion unit 3 of the present embodiment will be described with reference to FIG.

First, the leakage processing unit 71 determines whether or not leakage of the second AC power has occurred based on the leakage current data detected by the leakage current detection unit 6 (S11). When the electric leakage processing unit 71 determines that no electric leakage has occurred (S11: NO), the electric leakage processing unit 71 determines whether or not the electric leakage of the second AC power has occurred again after the lapse of a predetermined time (S11). ).

When the electric leakage processing unit 71 determines that the second AC power is leaking (S11: YES), the electric leakage processing unit 71 outputs the operation stop signal A4 to the power conversion unit 3 (S12).

The power conversion unit 3 receives the operation stop signal A4 and stops the power conversion from the DC power stored in the power storage unit 2 to the second AC power.

(3.2) Output switching from the first AC power to the second AC power Hereinafter, the operation of the output switching from the first AC power to the second AC power of the present embodiment will be described with reference to FIG. Further, the operation of turning off the signal means that the voltage of L level (for example, 0V) is output as a signal, and the operation of turning on the signal means that the voltage of H level (for example, 5V) is output as a signal. do.

First, the first control signal A11 is on, the second control signal A12 is off, the first detection signal A21 is off, and the second detection signal A22 is on. At this time, the first contact portion 511a and the first contact portion 511b are electrically connected to each other, the second contact portion 521a and the second contact portion 521b are cut off, respectively, and the first AC power is transmitted from the output unit 4 to the electric device 300. It is output (S21).

Then, the signal generation unit 72 turns off the first control signal A11 (S22). As a result, the first drive control unit 73 turns off the first drive signal A31, and the first contact unit 511a and the first contact unit 511b are cut off. The signal generation unit 72 turns on the second control signal A12 when a predetermined delay time elapses after turning off the first control signal A11 (S23).

Next, the first voltage detection unit 531 detects the first internal voltage Vs1 of the first relay unit 51, and determines whether or not the first internal voltage Vs1 of the first relay unit 51 is less than the threshold value Vt1 (S24). The threshold value Vt1 is lower than the first internal voltage Vs1 of the first relay unit 51 detected when at least one of the first contact portion 511a and the first contact portion 511b is conducting, and is higher than 0V. Set to a value.

When the first internal voltage Vs1 of the first relay unit 51 is less than the threshold value Vt1 (S24: YES), the first voltage detection unit 531 turns on the first detection signal A21 and turns on the first detection signal A21. Output to the second drive control unit 74 (S25). When the first internal voltage Vs1 of the first relay unit 51 is equal to or higher than the threshold value Vt1 (S24: NO), the first voltage detection unit 531 turns off the first detection signal A21 and turns off the first detection signal A21. Output to the second drive control unit 74 (S26).

The second drive control unit 74 determines whether or not both the input second control signal A12 and the first detection signal A21 are on (S27).

When both the second control signal A12 and the first detection signal A21 are on (S27: YES), the second drive control unit 74 turns on the second drive signal A32 and turns on the second drive signal. A32 is output to the second contact portion 521a and the second contact portion 521b. After that, the second contact portion 521a and the second contact portion 521b are all conductive, and the second AC power is output from the output unit 4 to the electric device 300 (S2A).

On the other hand, when the second control signal A12 is on and the first detection signal A21 is off (S27: NO), the second drive control unit 74 turns off the second drive signal A32 and turns it off. The drive signal A32 is output to the second contact portion 521a and the second contact portion 521b (S29). When the second control signal A12 is on and the first detection signal A21 is off for a certain period of time, the abnormality determination unit 75 welds at least one of the first contact units 511a and 511b. It is determined that an abnormality that does not operate according to the first drive signal A31 has occurred due to factors such as the above, and an abnormal stop signal A5 for stopping the operation of the power conversion unit 3 is output to the power conversion unit 3. The power conversion unit 3 receives the abnormal stop signal A5 and stops the power conversion from the DC power stored in the power storage unit 2 to the second AC power.

(3.3) Output switching from the second AC power to the first AC power Hereinafter, the operation of the output switching from the second AC power to the first AC power of the present embodiment will be described with reference to FIG. Further, the operation of turning off the signal means that the voltage of L level (for example, 0V) is output as a signal, and the operation of turning on the signal means that the voltage of H level (for example, 5V) is output as a signal. do.

First, the first control signal A11 is off, the second control signal A12 is on, the first detection signal A21 is on, and the second detection signal A22 is off. At this time, the first contact portion 511a and the first contact portion 511b are cut off, the second contact portion 521a and the second contact portion 521b are conducting, respectively, and the second AC power is transmitted from the output unit 4 to the electric device 300. It has been output (S31).

Then, the signal generation unit 72 turns off the second control signal A12 (S32). As a result, the second drive control unit 74 turns off the second drive signal A32, and the second contact unit 521a and the second contact unit 521b are cut off. The signal generation unit 72 turns on the first control signal A11 when a predetermined delay time elapses after turning off the second control signal A12 (S33).

Next, the second voltage detection unit 532 detects the second internal voltage Vs2 of the second relay unit 52, and determines whether or not the second internal voltage Vs2 of the second relay unit 52 is less than the threshold value Vt2 (S34). The threshold value Vt2 is lower than the second internal voltage Vs2 of the second relay unit 52 detected when at least one of the second contact portion 521a and the second contact portion 521b is conducting, and is higher than 0V. Set to a value.

When the second internal voltage Vs2 of the second relay unit 52 is less than the threshold value Vt2 (S34: YES), the second voltage detection unit 532 turns on the second detection signal A22 and turns on the second detection signal A22. Output to the first drive control unit 73 (S35). When the second internal voltage Vs2 of the second relay unit 52 is equal to or higher than the threshold value Vt2 (S34: NO), the second voltage detection unit 532 turns off the second detection signal A22 and turns off the second detection signal A22. Output to the first drive control unit 73 (S36).

The first drive control unit 73 determines whether or not both the input first control signal A11 and the second detection signal A22 are on (S37).

When both the first control signal A11 and the second detection signal A22 are on (S37: YES), the first drive control unit 73 turns on the first drive signal A31 and turns on the first drive signal. A31 is output to the first contact portion 511a and the first contact portion 511b. After that, the first contact portion 511a and the first contact portion 511b are all conductive, and the first AC power is output from the output unit 4 to the electric device 300 (S3A).

On the other hand, when the first control signal A11 is on and the second detection signal A22 is off (S37: NO), the first drive control unit 73 turns off the first drive signal A31 and turns it off. The drive signal A31 is output to the first contact portion 511a and the first contact portion 511b (S39). When the first control signal A11 is on and the second detection signal A22 is off for a certain period of time, the abnormality determination unit 75 welds at least one of the second contact units 521a and 521b. It is determined that an abnormality that does not operate according to the second drive signal A32 has occurred due to factors such as the above, and an abnormal stop signal A5 for stopping the operation of the power conversion unit 3 is output to the power conversion unit 3. The power conversion unit 3 receives the abnormal stop signal A5 and stops the power conversion from the DC power stored in the power storage unit 2 to the second AC power.

(4) Modifications The above embodiment is only one of the various embodiments of the present disclosure. The above-described embodiment can be variously modified depending on the design and the like as long as the object of the present disclosure can be achieved.

In the above-described embodiment, the leakage current detection unit 6 may be provided at a position where the leakage current of the second AC power can be detected, and may be provided between the input unit 1 and the output switching unit 5. Further, it may be provided between the output switching unit 5 and the output unit 4.

As shown in FIG. 6, the first relay unit 51 according to one aspect includes a first welding detection unit 512 that detects welding of at least one first contact portion 511, and the second relay unit 52 according to one aspect is provided. A second welding detection unit 522 that detects welding of at least one second contact unit 521 may be provided.

The control unit 7 preferably includes a computer system. In a computer system, a processor such as a CPU (Central Processing Unit) or an MPU (Micro Processing Unit) reads and executes a program stored in a memory, thereby realizing some or all the functions of the control unit 7. To. A computer system includes a processor that operates according to a program as a main hardware configuration. The type of processor does not matter as long as the function can be realized by executing the program. The processor is composed of one or more electronic circuits including a semiconductor integrated circuit (IC) or an LSI (Large Scale Integration). Here, it is called IC or LSI, but the name changes depending on the degree of integration, and it may be called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). A field programmable gate array (FPGA) programmed after the LSI is manufactured, or a reconfigurable logic device that can reconfigure the junction relationships inside the LSI or set up the circuit partitions inside the LSI may also be used for the same purpose. Can be done. The plurality of electronic circuits may be integrated on one chip or may be provided on a plurality of chips. A plurality of chips may be integrated into one device, or may be provided in a plurality of devices.

(5) Summary As described above, the power conversion device (100) according to the first aspect includes an input unit (1), a power storage unit (2), a power conversion unit (3), and an output unit (4). ), An output switching unit (5), a leakage current detection unit (6), and a control unit (7). The input unit (1) receives the first AC power from the commercial power source (200). The power storage unit (2) stores DC power. The power conversion unit (3) converts the DC power into the second AC power. The load is electrically connected to the output unit (4). The output switching unit (5) transmits the first AC power and the second AC power to the output unit (4) in a switchable manner. The leakage current detection unit (6) detects the leakage current of the second AC power. The control unit (7) detects the leakage based on the result of the leakage current detection unit (6), and stops the power conversion unit (3) when the leakage is detected.

According to this aspect, there is an advantage that leakage of the second AC power can be confirmed.

In the power conversion device (100) according to the second aspect, in the first aspect, the leakage current detection unit (6) is provided between the power conversion unit (3) and the output switching unit (5).

According to this aspect, there is an advantage that leakage of the second AC power can be confirmed in the electric circuit for transmitting the second AC power.

In the power conversion device (100) according to the third aspect, in the first aspect, the leakage current detection unit (6) is provided between the input unit (1) and the output switching unit (5).

According to this aspect, there is an advantage that leakage of the second AC power in the electric circuit on the input unit (1) side can be confirmed.

In the power conversion device (100) according to the fourth aspect, in the first aspect, the leakage current detection unit (6) is provided between the output switching unit (5) and the output unit (4).

According to this aspect, there is an advantage that leakage of the second AC power in the electric circuit on the output unit (4) side can be confirmed.

In the power conversion device (100) according to the fifth aspect, in any one of the first to fourth aspects, the output switching unit (5) is provided between the input unit (1) and the output unit (4). The first relay unit (51) is provided, and the second relay unit (52) provided between the power conversion unit (3) and the output unit (4) is provided. The first relay unit (51) conducts and disconnects the electrical connection between the input unit (1) and the output unit (4). The second relay unit (52) conducts and disconnects the electrical connection between the power conversion unit (3) and the output unit (4).

According to this aspect, the electrical connection between the input unit (1) and the output unit (4) and the electrical connection between the power conversion unit (3) and the output unit (4) are respectively. Has the advantage of being controllable.

In the power conversion device (100) according to the sixth aspect, in the fifth aspect, the first relay unit (51) includes a plurality of first contact portions (511), and the second relay unit (52) has a plurality of first contact portions (511). A plurality of second contact portions (521) are provided. The plurality of first contact units (511) are connected in series between the input unit (1) and the output unit (4). The plurality of second contact units (521) are connected in series between the power conversion unit (3) and the output unit (4).

According to this aspect, even if one or more first contact portions (511) are welded, the input portion (1) and the output portion (4) are connected by the remaining first contact portion (511) that has not been welded. It has the advantage of being able to control the electrical connections between them. Similarly, even if one or more second contact portions (521) are welded, the remaining second contact portion (521) that is not welded between the power conversion unit (3) and the output unit (4). It has the advantage of being able to control the electrical connection.

The power conversion device (100) according to the seventh aspect further includes a voltage detection unit (53) for detecting the internal voltage of at least one output switching unit (5) in the sixth aspect. Then, the control unit (7) controls the output switching unit (5) based on at least one internal voltage.

According to this aspect, there is an advantage that it is possible to confirm whether or not the contacts of the output switching unit (5) are welded.

In the power conversion device (100) according to the eighth aspect, in the seventh aspect, the voltage detection unit is the voltage of the electric circuit between the pair of first contact portions (511) among the plurality of first contact portions (511). The voltage of the electric circuit between the first voltage detection unit (531) that detects the first internal voltage (Vs1) as the internal voltage and the pair of second contact portions (521) among the plurality of second contact portions (521). It is provided with a second voltage detection unit (532) that detects the second internal voltage (Vs2) as an internal voltage. The control unit (7) controls the first relay unit (51) based on the second internal voltage (Vs2), and controls the second relay unit (52) based on the first internal voltage (Vs1).

According to this aspect, whether or not the contacts of the first relay unit (51) and the second relay unit (52) are welded is determined by the first relay unit (51) and the second relay unit (52). There is an advantage that each can be confirmed.

In the power conversion device (100) according to the ninth aspect, in the eighth aspect, the control unit (7) includes a signal generation unit (72), a first drive control unit (73), and a second drive control unit. (74) and. The signal generation unit (72) outputs a first control signal (A11) that controls the first relay unit (51) and a second control signal (A12) that controls the second relay unit (52). The first voltage detection unit (531) outputs the detection result of the first internal voltage (Vs1) as the first detection signal (A21), and the second voltage detection unit (532) is the second internal voltage (Vs2). The detection result is output as the second detection signal (A22). The first drive control unit (73) drives a plurality of first contact units (511) based on the second detection signal (A22) and the first control signal (A11), and the second drive control unit (74) Drives a plurality of second contact portions (521) based on the first detection signal (A21) and the second control signal (A12).

According to this aspect, when the first contact portion (511) is unintentionally brought into a conductive state due to factors such as welding, the first AC power and the second AC power are simultaneously transmitted to the output portion (4). There is an advantage that it can be prevented. Similarly, when the second contact portion (521) is unintentionally brought into a conductive state due to factors such as welding, the first AC power and the second AC power are simultaneously transmitted to the output portion (4). It has the advantage of being able to prevent it.

In the power conversion device (100) according to the tenth aspect, in the ninth aspect, the first drive control unit (73) receives a second detection signal (A22) and a first control signal (A11). It is a 1AND gate, and the second drive control unit (74) is a second AND gate to which the first detection signal (A21) and the second control signal (A12) are input.

According to this aspect, there is an advantage that the configuration of the first drive control unit (73) and the second drive control unit (74) can be simplified.

In the power conversion device (100) according to the eleventh aspect, in any one of the sixth to tenth aspects, the first relay unit (51) detects welding of at least one first contact portion (511). The first welding detection unit (512) is provided, and the second relay unit (52) includes a second welding detection unit (522) that detects welding of at least one second contact unit (521).

According to this aspect, there is an advantage that welding of the first contact portion (511) and the second contact portion (521) can be detected.

In the power conversion device (100) according to the twelfth aspect, in any one of the first to eleventh aspects, the power storage unit (2) and the power conversion unit (3) are composed of a stand-alone storage battery.

According to this aspect, there is an advantage that leakage of the second AC power can be confirmed in the configuration including the stand-alone storage battery.

100 Power converter 200 Commercial power supply 1 Input unit 2 Power storage unit 3 Power conversion unit 4 Output unit 5 Output switching unit 51 1st relay unit 511 1st contact unit 512 1st welding detection unit 52 2nd relay unit 521 2nd contact unit 522 2nd welding detection unit 53 Voltage detection unit 531 1st voltage detection unit 532 2nd voltage detection unit 6 Leakage current detection unit 7 Control unit 72 Signal generation unit 73 1st drive control unit 74 2nd drive control unit A11 1st control Signal A12 2nd control signal A21 1st detection signal A22 2nd detection signal Vs1 1st internal voltage Vs2 2nd internal voltage

Claims (12)

The input section where the first AC power is input from the commercial power supply,
A storage unit that stores DC power and
A power conversion unit that converts the DC power into a second AC power,
The output section to which the load is electrically connected and
An output switching unit that can switch between the first AC power and the second AC power and transmits the second AC power to the output unit.
The leakage current detection unit that detects the leakage current of the second AC power,
It includes a control unit that detects a power leakage based on the result of the power leakage current detection unit and stops the power conversion unit when the power leakage is detected.
Power converter. The leakage current detection unit is provided between the power conversion unit and the output switching unit.
The power conversion device according to claim 1. The leakage current detection unit is provided between the input unit and the output switching unit.
The power conversion device according to claim 1. The leakage current detection unit is provided between the output switching unit and the output unit.
The power conversion device according to claim 1. The output switching unit includes a first relay unit provided between the input unit and the output unit, and a second relay unit provided between the power conversion unit and the output unit.
The first relay unit conducts and cuts off the electrical connection between the input unit and the output unit.
The second relay unit conducts and cuts off the electrical connection between the power conversion unit and the output unit.
The power conversion device according to any one of claims 1-4. The first relay unit includes a plurality of first contact portions, and the first relay unit includes a plurality of first contact portions.
The second relay unit includes a plurality of second contact portions, and the second relay unit includes a plurality of second contact portions.
The plurality of first contact portions are connected in series between the input portion and the output portion, and are connected in series.
The plurality of second contact portions are connected in series between the power conversion unit and the output unit.
The power conversion device according to claim 5. Further, a voltage detection unit for detecting the internal voltage of at least one output switching unit is provided.
The control unit controls the output switching unit based on the at least one internal voltage.
The power conversion device according to claim 6. The voltage detection unit includes a first voltage detection unit that detects a first internal voltage, which is a voltage of an electric circuit between a pair of first contact portions among the plurality of first contact portions, as the internal voltage, and the plurality of first contact portions. A second voltage detection unit that detects a second internal voltage, which is a voltage of an electric circuit between a pair of second contact portions among the two contact portions, as the internal voltage is provided.
The control unit controls the first relay unit based on the second internal voltage, and controls the second relay unit based on the first internal voltage.
The power conversion device according to claim 7. The control unit includes a signal generation unit, a first drive control unit, and a second drive control unit.
The signal generation unit outputs a first control signal for controlling the first relay unit and a second control signal for controlling the second relay unit.
The first voltage detection unit outputs the detection result of the first internal voltage as a first detection signal.
The second voltage detection unit outputs the detection result of the second internal voltage as a second detection signal.
The first drive control unit drives the plurality of first contact units based on the second detection signal and the first control signal.
The second drive control unit drives the plurality of second contact units based on the first detection signal and the second control signal.
The power conversion device according to claim 8. The first drive control unit is a first AND gate to which the second detection signal and the first control signal are input.
The second drive control unit is a second AND gate to which the first detection signal and the second control signal are input.
The power conversion device according to claim 9. The first relay unit includes a first welding detection unit that detects welding of at least one first contact portion.
The second relay unit includes a second welding detection unit that detects welding of at least one second contact portion.
The power conversion device according to any one of claims 6-10. The power storage unit and the power conversion unit are composed of a stand-alone storage battery.
The power conversion device according to any one of claims 1-11.

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