JP7262048B2 - POWER CONVERSION SYSTEM, TEST METHOD AND PROGRAM - Google Patents

Description

The present disclosure relates generally to power conversion systems, test methods, and programs. More specifically, the present disclosure relates to a power conversion system having a function of testing for the presence or absence of electrical leakage, a method for testing the presence or absence of electrical leakage, and a program.

Patent Literature 1 discloses a grid interconnection system (power conversion system). This grid interconnection system includes a power converter, a self-sustaining breaker, and an operation mode switching circuit. The power converter converts DC power supplied from distributed power sources into AC power. The self-sustaining operation breaker is inserted between the load to which power is supplied during self-sustaining operation and the power converter. The operation mode switching circuit switches between grid-connected operation and isolated operation according to a mode switching signal input from the outside.

JP 2010-259170 A

In the power conversion system described in Patent Literature 1, when providing a function of detecting the presence or absence of earth leakage during self-sustained operation, it is conceivable to install an earth leakage breaker. However, in the earth leakage breaker, there is a problem that an operation test of whether or not the earth leakage breaker (earth leakage detection function) is operating normally must be manually performed, which takes time and effort.

The present disclosure has been made in view of the above points, and an object thereof is to provide a power conversion system, a test method, and a program that can reduce the labor required for an operation test of an earth leakage detection function.

A power conversion system according to an aspect of the present disclosure includes an earth leakage measurement unit, a current supply unit, and a control unit. The earth leakage measurement unit measures an earth leakage current flowing through the isolated system. The isolated system outputs power from distributed power sources independently of the power system. The current supply unit supplies a test current to the earth leakage measurement unit from an external power source other than the isolated system. The control section executes an operation test. The operation test is a process of controlling the current supply section to supply the test current to the leakage measurement section, and determining the state of the leakage measurement section based on the measurement result of the leakage measurement section. The external power source is the power system.
A power conversion system according to an aspect of the present disclosure includes an earth leakage measurement unit, a current supply unit, and a control unit. The earth leakage measurement unit measures an earth leakage current flowing through the isolated system. The isolated system outputs power from distributed power sources independently of the power system. The current supply unit supplies a test current to the earth leakage measurement unit from an external power source other than the isolated system. The control section executes an operation test. The operation test is a process of controlling the current supply section to supply the test current to the leakage measurement section, and determining the state of the leakage measurement section based on the measurement result of the leakage measurement section. The power conversion system further includes a voltage measurement unit that measures the system voltage of the power system. The control section obtains a predetermined current range based on the measurement result of the voltage measurement section. The control section compares the magnitude of the test current measured by the leakage measurement section with the predetermined current range to determine the state of the leakage measurement section.

A test method according to an aspect of the present disclosure has a supply step and a determination step. The supply step is a step of supplying a test current from an external power source other than the isolated system to an earth leakage measurement unit that measures an earth leakage current flowing through the isolated system. The isolated system outputs power from distributed power sources independently of the power system. The determination step is a step of determining the state of the earth leakage measurement unit based on the measurement result of the earth leakage measurement unit. The external power source is the power system.
A test method according to an aspect of the present disclosure has a supply step and a determination step. The supply step is a step of supplying a test current from an external power source other than the isolated system to an earth leakage measurement unit that measures an earth leakage current flowing through the isolated system. The isolated system outputs power from distributed power sources independently of the power system. The determination step is a step of determining the state of the earth leakage measurement unit based on the measurement result of the earth leakage measurement unit. The test method further includes a voltage measurement step of measuring system voltage of the power system. In the determination step, a predetermined current range is obtained based on the measurement result in the voltage measurement step. In the determination step, the magnitude of the test current measured by the leakage measurement unit is compared with the predetermined current range to determine the state of the leakage measurement unit.

A program according to an aspect of the present disclosure causes one or more processors to execute the above test method.

The present disclosure has the advantage of being able to reduce the labor required for the operation test of the earth leakage detection function.

FIG. 1 is a schematic circuit diagram showing main parts of a power conversion system according to an embodiment of the present disclosure. FIG. 2 is a schematic circuit diagram showing the same power conversion system. FIG. 3 is a flow chart showing the operation of the same power conversion system. FIG. 4 is a schematic circuit diagram showing main parts of a power conversion system of a comparative example.

(1) Outline As shown in FIGS. 1 and 2, the power conversion system 100 of the present embodiment is a system that interconnects a distributed power source 1 with a single-phase three-wire power system SY1. The “power system” referred to in the present disclosure means the entire system for an electric power company such as an electric power company to supply electric power to power receiving facilities of consumers. In this embodiment, as an example, a case where such a power conversion system 100 is introduced into non-residential facilities such as office buildings, hospitals, commercial facilities, and schools will be described.

The power conversion system 100 includes, as shown in FIG. 1, an earth leakage measurement unit 7, a current supply unit 8, and a control unit .

The earth leakage measurement unit 7 measures the earth leakage current flowing through the isolated system SY2. In this embodiment, the earth leakage measuring unit 7 does not measure the earth leakage current when no earth leakage occurs in the isolated system SY2, but measures the earth leakage current when the earth leakage occurs in the isolated system SY2. become. Isolated system SY2 outputs power from distributed power supply 1 independently of power system SY1. For example, in the event of an abnormality such as a power outage in the power system SY1, the power conversion system 100 opens the parallel-off relay 5 and performs self-sustained operation in which AC power is output while being disconnected from the power system SY1. The isolated system SY2 outputs AC power to the load connected to the isolated system SY2 during this isolated operation. "Connecting" as used in the present disclosure includes mechanically connecting elements such as terminals, electronic components, or electric wires, as well as electrically connecting elements to each other.

The current supply unit 8 supplies a test current I1 to the leakage measurement unit 7 from an external power source P1 other than the isolated system SY2. In this embodiment, the external power supply P1 is the power system SY1. The “test current” referred to in the present disclosure is a current experimentally supplied to the earth leakage measurement unit 7 when performing an operation test of the earth leakage measurement unit 7, and when an earth leakage actually occurs in the isolated system SY2 It is a current of about the same magnitude as the leakage current flowing through the isolated system SY2. In other words, the test current is a current that can be measured as a pseudo leakage current by the leakage measurement unit 7 .

The control unit 10 has a function of executing an operation test. The operation test is a process of controlling the current supply unit 8 to supply the test current I1 to the earth leakage measurement unit 7 and determining the state of the earth leakage measurement unit 7 based on the measurement result of the earth leakage measurement unit 7 . The “state of the earth leakage measurement unit” referred to in the present disclosure represents the state of whether or not the earth leakage measurement unit is operating normally.

As described above, in this embodiment, the operation test can be executed by the control section 10 controlling the current supply section 8 . For this reason, in this embodiment, for example, even if an operator does not go to the installation place of the power conversion system 100, it is possible to perform an operation test by remote control. Further, in the present embodiment, for example, it is possible to periodically and automatically execute the operation test without the operator's operation for performing the operation test. Therefore, in this embodiment, there is an advantage that the trouble required for the operation test of the earth leakage detection function can be reduced.

(2) Details The power conversion system 100 according to the present embodiment, as shown in FIG. It has 2, the power conversion system 100 includes an input capacitor C0, an output capacitor C1, a rectifying element D1, a DC/DC converter 2, an inverter 3, a noise filter 4, and a parallel-off relay 5. , and a self-contained relay 6 . The earth leakage measurement unit 7 , current supply unit 8 , voltage measurement unit 9 , control unit 10 and output unit 20 are all housed in one housing 101 . The housing 101 also houses an input capacitor C0, an output capacitor C1, a rectifying element D1, a DC/DC converter 2, an inverter 3, a noise filter 4, a parallel-off relay 5, and an independent relay 6.

A distributed power source 1 is connected to the power conversion system 100 as shown in FIG. In this embodiment, the distributed power source 1 is a photovoltaic power generation device including solar cells. Although the distributed power source 1 is not included in the power conversion system 100 below, the distributed power source 1 may be included in the power conversion system 100 .

The input capacitor C0 is connected between the distributed power source 1 and the DC/DC converter 2, as shown in FIG. A first electrode 13 of the input capacitor C0 is connected to the positive electrode 11 of the distributed power supply 1 and the high-potential input terminal of the DC/DC converter 2 . A second electrode 14 of the input capacitor C0 is connected to the negative electrode 12 of the distributed power supply 1 and the low potential input end of the DC/DC converter 2 . The input capacitor C0 has a function of stabilizing the DC voltage output from the distributed power supply 1. FIG.

The DC/DC converter 2 is a non-insulated step-up DC/DC converter, and includes an inductor L0, a diode D0, and a switching element Q0, as shown in FIG. A first end of the inductor L0 is connected to the high-potential input end of the DC/DC converter 2 and to the first electrode 13 of the input capacitor C0. A second end of inductor L0 is connected to the anode of diode D0. The cathode of the diode D0 is connected to the high-potential output end of the DC/DC converter 2 and to the first electrode 15 of the output capacitor C1.

The switching element Q0 consists of an enhancement-type n-channel MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor). The source of the switching element Q0 is connected to the low potential input terminal and output terminal of the DC/DC converter 2, and is connected to the second electrode 14 of the input capacitor C0. A drain of the switching element Q0 is connected to a connection point between the second end of the inductor L0 and the anode of the diode D0. The switching element Q0 is turned on/off by a control signal S0 provided from the control section 10. FIG. The switching element Q0 is not limited to a MOSFET, and may be, for example, an IGBT (Insulated Gate Bipolar Transistor) or another semiconductor switching element such as a bipolar transistor.

The DC/DC converter 2 can boost the voltage across the input capacitor C0 by PWM (Pulse Width Modulation) control of the switching element Q0 by the control unit 10 . Specifically, the control unit 10 boosts the voltage across the input capacitor C0 by controlling the switching of the switching element Q0, and outputs the boosted DC voltage to the output capacitor C1 and the inverter 3.

The output capacitor C1 is connected between the DC/DC converter 2 and the inverter 3, as shown in FIG. A first electrode 15 of the output capacitor C1 is connected to the high potential output end of the DC/DC converter 2 and the high potential input end of the inverter 3 . A second electrode 16 of the output capacitor C1 is connected to the low potential output end of the DC/DC converter 2 and the low potential input end of the inverter 3 . The output capacitor C1 has a function of stabilizing the DC voltage output from the DC/DC converter 2. FIG.

The anode of the rectifying element D1 is connected to the second electrode 16 of the output capacitor C1 and the low potential input end of the inverter 3, as shown in FIG. The cathode of the rectifying element D1 is connected to the low-potential input terminal of the DC/DC converter 2, and is connected to the source of the switching element Q0. The rectifying element D1 prevents current from flowing from the negative electrode 12 of the distributed power supply 1 toward the output capacitor C1.

The inverter 3, as shown in FIG. 2, has four switching elements Q1 to Q4 connected in a full bridge. The switching elements Q1 to Q4 are all depletion-type n-channel MOSFETs. The switching elements Q1 to Q4 are not limited to MOSFETs, and may be other semiconductor switching elements such as IGBTs or bipolar transistors.

In the inverter 3, a series circuit of the switching elements Q1 and Q3 and a series circuit of the switching elements Q2 and Q4 are connected in parallel across the output capacitor C1. The drains of the switching elements Q1 and Q2 are connected to the high-potential output end of the DC/DC converter 2 and the first electrode 15 of the output capacitor C1. The sources of the switching elements Q3 and Q4 are both connected to the low-potential output end of the DC/DC converter 2 and the second electrode 16 of the output capacitor C1.

A connection point (first connection point) between the source of the switching element Q1 and the drain of the switching element Q3 is connected to the first contact portion 51 of the parallel-off relay 5 via the inductor L11 of the noise filter 4 and the first contact portion 51 of the parallel-off relay 5. It is connected to the voltage phase (“U” phase in FIG. 1). The first connection point is also connected to the first voltage phase (“L1” phase in FIG. 1) of the isolated system SY2 via the inductor L11 of the noise filter 4 and the first contact portion 61 of the isolated relay 6. there is A connection point (second connection point) between the source of the switching element Q2 and the drain of the switching element Q4 is connected to the second contact portion 52 of the parallel-off relay 5 via the inductor L12 of the noise filter 4 and the second contact portion 52 of the parallel-off relay 5. It is connected to the voltage phase (“W” phase in FIG. 1). The second connection point is also connected to the second voltage phase (“L2” phase in FIG. 1) of the isolated system SY2 via the inductor L12 of the noise filter 4 and the second contact portion 62 of the isolated relay 6. there is

Inverter 3 is a bidirectional DC/AC converter. In the inverter 3, the switching elements Q1 to Q4 are PWM-controlled by the control unit 10 to convert the DC voltage to the AC voltage or the AC voltage to the DC voltage. That is, the inverter 3 has a function of converting the DC power from the output capacitor C1 into AC power and outputting it to the power system SY1, and a function of converting the AC power from the power system SY1 into DC power and outputting it to the output capacitor C1. and have Further, the inverter 3 has a function of converting the DC power from the output capacitor C1 into AC power and outputting it to the isolated system SY2 when the parallel-off relay 5 is opened and the isolated relay 6 is closed.

The noise filter 4 has two inductors L11 and L12 and a capacitor C2, as shown in FIG. A first end of the inductor L11 is connected to a connection point (first connection point) between the source of the switching element Q1 and the drain of the switching element Q3. A second end of the inductor L11 is connected to the first contact portion 51 of the parallel-off relay 5 and the first contact portion 61 of the isolation relay 6 . A first end of the inductor L12 is connected to a connection point (second connection point) between the source of the switching element Q2 and the drain of the switching element Q4. A second end of the inductor L12 is connected to the second contact portion 52 of the parallel-off relay 5 and the second contact portion 62 of the isolation relay 6 . A capacitor C2 is connected between the second end of the inductor L11 and the second end of the inductor L12. The noise filter 4 has a function of removing high-frequency components from the AC voltage output from the inverter 3 and generating a sinusoidal voltage.

The parallel-off relay 5 includes a first contact portion 51 and a second contact portion 52, as shown in FIG. The first contact portion 51 and the second contact portion 52 are turned on or off at the same time by a control signal S10 given from the control portion 10 . The parallel-off relay 5 parallels the inverter 3 to the power system SY1 when the first contact portion 51 and the second contact portion 52 are turned on at the same time, and disconnects the inverter 3 from the power system SY1 when they are turned off at the same time.

The self-sustaining relay 6 includes a first contact portion 61 and a second contact portion 62, as shown in FIG. The first contact portion 61 and the second contact portion 62 are turned on or off at the same time by a control signal S20 given from the control portion 10 . The isolation relay 6 parallels the inverter 3 to the isolation system SY2 when the first contact portion 61 and the second contact portion 62 are turned on at the same time, and disconnects the inverter 3 from the isolation system SY2 when they are turned off at the same time. In other words, the isolated relay 6 corresponds to the switching unit 6 that opens and closes the isolated system SY2.

As shown in FIG. 1, the earth leakage measurement unit 7 includes a first voltage phase ("L1" phase in FIG. 1), a second voltage phase ("L2" phase in FIG. 1), and a neutral phase ("L2" phase in FIG. 1) of the isolated system SY2. It is installed in the electric circuit of "N" phase in FIG. 1) and measures the leakage current flowing through the isolated system SY2. In this embodiment, the leakage measuring unit 7 includes a zero-phase current transformer (ZCT). The earth leakage measurement unit 7 measures the difference between the currents flowing through each of the first voltage phase (“L1” phase), the second voltage phase (“L2” phase), and the neutral phase (“N” phase) of the isolated system SY2. output a corresponding signal. Specifically, when there is no leakage in the isolated system SY2, the leakage measurement unit 7 outputs a signal of almost zero level because there is almost no difference between the currents flowing through the phases. On the other hand, when a leakage occurs in the isolated system SY2, the leakage measurement unit 7 outputs a signal corresponding to the magnitude of the leakage current because there is a difference in the current flowing through each phase. A signal output from the leakage measurement unit 7 is input to the control unit 10 .

The current supply unit 8 supplies a test current I1 to the leakage measurement unit 7 from an external power source P1 other than the isolated system SY2. In this embodiment, the current supply unit 8 has a relay 81 and a resistor 82, as shown in FIG. A first end of relay 81 is connected to a first voltage phase (“U” phase) of power system SY1. A first end of the resistor 82 is connected to the neutral phase (“O” phase) of the electric power system SY1. An electric circuit connecting the second end of the relay 81 and the second end of the resistor 82 passes through the zero-phase current transformer (leakage measurement unit 7).

The relay 81 is turned on or off by a control signal S30 given from the control section 10 . When the relay 81 is turned off, no voltage (first system voltage V1, which will be described later) is applied to the resistor 82, so no current flows through the resistor 82, and a current also flows through the electric path passing through the leakage measuring unit 7. do not have. On the other hand, when the relay 81 is turned on, a voltage (the first system voltage V1) is applied to the resistor 82, so that a current flows through the resistor 82, and a current also flows through the electric path passing through the earth leakage measurement unit 7.

In this way, the current supply unit 8 is controlled by the control unit 10 to supply the current (test current I1) flowing through the resistor 82 from the electric power system SY1, which is the external power supply P1, to the leakage measurement unit 7. Since the test current I1 is a current flowing from the power system SY1, it is an alternating current. The resistance value of the resistor 82 is set so that a current (test current I1) on the order of several tens [mA] flows when the first system voltage V1 is applied.

The voltage measurement unit 9 measures the system voltage V0 of the power system SY1. In the present embodiment, as shown in FIG. 1, the voltage measurement unit 9 measures the voltage between the first voltage phase (“U” phase) and the neutral phase (“O” phase) as the system voltage V0 of the power system SY1. The first system voltage V1, which is the phase-to-phase voltage, is measured. Further, the voltage measurement unit 9 measures the second system voltage V2, which is the phase-to-phase voltage between the second voltage phase (“W” phase) and the neutral phase (“O” phase), as the system voltage V0 of the electric power system SY1. to measure A result measured by the voltage measurement unit 9 is input to the control unit 10 .

The control unit 10 is composed of, for example, a microcontroller having one or more processors and memory. In other words, the control unit 10 is realized by a computer system having one or more processors and memory, and the computer system functions as the control unit 10 by executing a program stored in the memory by the one or more processors. Function. Although the program is pre-recorded in the memory of the control unit 10 here, it may be provided through an electric communication line such as the Internet or recorded in a non-temporary recording medium such as a memory card. The control unit 10 may be configured by, for example, an FPGA (Field-Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit).

The control unit 10 outputs control signals S0-S4 for controlling the five switching elements Q0-Q4. The control signals S0-S4 are applied to the gates of the switching elements Q0-Q4 either directly or through a drive circuit to individually turn on/off the switching elements Q0-Q4. The control unit 10 controls the switching elements Q0 to Q4 by a PWM method with an adjustable duty ratio.

Further, the control unit 10 outputs a control signal S10 for controlling on/off of the first contact portion 51 and the second contact portion 52 of the parallel-off relay 5, the first contact portion 61 and the second contact portion 61 of the self-sustaining relay 6. A control signal S20 for controlling the on/off of the unit 62 is output. The control unit 10 causes the parallel-off relay 5 to be paralleled off from the power system SY1 and parallels the isolation relay 6 to the isolation system SY2 in the event of an abnormality such as a power failure in the power system SY1. Then, the control unit 10 controls the DC/DC converter 2 and the inverter 3 to perform self-sustained operation in which AC power is output from the inverter 3 to the self-sustaining system SY2 when there is an abnormality in the power system SY1.

Further, the control unit 10 has a function of shutting off the isolated system SY2 when an electric leakage occurs in the isolated system SY2. Specifically, when the level of the signal output from the earth leakage measurement unit 7 exceeds the threshold, the control unit 10 determines that an earth leakage has occurred in the isolated system SY2, and provides the control signal S20 to the isolated relay 6 to The first contact portion 61 and the second contact portion 62 of the relay 6 are turned off at the same time. That is, the control unit 10 controls the independent relay (opening/closing unit) 6 based on the measurement result of the earth leakage measurement unit 7 .

Furthermore, the control unit 10 has a function of executing an operation test. Specifically, in the operation test, the control unit 10 applies a control signal S30 (see FIG. 1) to the relay 81 of the current supply unit 8 to turn on the relay 81, thereby supplying the leakage measurement unit 7 with the test current I1. supply. Further, the control unit 10 determines the state of the earth leakage measurement unit 7 based on the measurement result of the earth leakage measurement unit 7 in the operation test. In this embodiment, the control unit 10 determines the state of the leakage measurement unit 7 by comparing the level of the signal output from the leakage measurement unit 7 with a predetermined current range stored in memory in advance.

Here, in the present embodiment, the control unit 10 executes an operation test during a period in which self-sustained operation is not performed, as will be described later. That is, the operation test is performed during a period in which no current is flowing through the isolated system SY2. Therefore, the difference between the currents measured by the leakage measuring section 7 corresponds to the test current I1. Therefore, the level of the signal output from the leakage measuring section 7 corresponds to the magnitude (current value) of the test current I1.

In the operation test, when the current value of the test current I1 is within a predetermined current range, the control unit 10 determines that the leakage measurement unit 7 is operating normally, that is, the leakage detection function is operating normally. judge. On the other hand, when the current value of the test current I1 deviates from the predetermined current range, the control unit 10 determines that an abnormality such as a failure has occurred in the earth leakage measurement unit 7, that is, there is an abnormality in the earth leakage detection function. judge.

Further, in the present embodiment, the control unit 10 obtains a predetermined current range based on the measurement result of the voltage measurement unit 9. FIG. Specifically, the control unit 10 sets the average value of the first system voltage V1 and the second system voltage V2 to be 100 [V] as the reference voltage, and the first system voltage V1 measured by the voltage measuring unit 9 And the average value of the second system voltage V2 is compared with the reference voltage to update the predetermined current range. As an example, assume that the predetermined current range is 20 to 25 [mA] when the average value of the first system voltage V1 and the second system voltage V2 is the reference voltage (100 [V]). Here, when the control unit 10 executes the operation test, if the average value of the first system voltage V1 and the second system voltage V2 measured by the voltage measurement unit 9 is 110 [V], the control unit 10 , the predetermined current range is updated to 21 to 27.5 [mA], which is 1.1 (=110/100) times.

In this embodiment, the control unit 10 executes the operation test during a period when the isolated operation is not performed, that is, while the inverter 3 is disconnected from the isolated system SY2. Specifically, the control unit 10 executes an operation test at predetermined timings during a period in which self-sustained operation is not performed. In other words, the control unit 10 automatically executes the operation test each time the predetermined time is counted using, for example, a built-in timer. Note that the control unit 10 does not execute the operation test when the predetermined time is counted during the period during which the self-sustained operation is being performed.

Further, in the present embodiment, the control unit 10 has a communication interface for communicating with an external terminal outside the power conversion system 100, and when a test input is received from the external terminal via the communication interface, also run a performance test. In other words, the control unit 10 also executes an operation test by being remotely controlled by an operator using an external terminal. Note that if a test input is received while the self-sustained operation is being performed, the control unit 10 does not execute the operation test.

The output unit 20 outputs test results of the operation test under the control of the control unit 10 . In this embodiment, the output unit 20 is, for example, a light source provided in the housing 101, and is controlled by the control unit 10 to emit light in a specific light color or light emission pattern, thereby notifying the test result of the operation test. (Output. Further, in the present embodiment, the output unit 20 outputs the test result when the test result of the operation test indicates that the earth leakage measurement unit 7 is abnormal. Therefore, in this embodiment, the output unit 20 does not output the test result when the test result of the operation test indicates that the earth leakage measuring unit 7 is normal.

(3) Operation Hereinafter, the operation of the power conversion system 100 of the present embodiment, specifically the operation test will be described with reference to FIG. 3 . While the self-sustained operation is not performed (ST1: Yes), the control unit 10 receives the test input (ST2: Yes), or when a predetermined timing is reached (ST3: Yes), the control unit 10 performs the operation test. Start. On the other hand, while the self-sustained operation is being performed (ST1: No), the control unit 10 does not execute the operation test even when the test input is received or when the predetermined timing is reached.

First, the control unit 10 acquires the measurement result of the system voltage V0 from the voltage measurement unit 9 (ST4). Then, the control unit 10 updates the predetermined current range based on the obtained measurement result of the system voltage V0 (ST5).

Next, the control section 10 supplies the test current I1 from the current supply section 8 to the leakage measurement section 7 by giving the control signal S30 to the relay 81 of the current supply section 8 (ST6). Then, the control unit 10 acquires the measurement result of the test current I1 from the leakage measurement unit 7, and compares the acquired measurement result of the test current I1 with a predetermined current range to determine the state of the leakage measurement unit 7. (ST7).

When the current value of the test current I1 is within the predetermined current range (ST8: Yes), the control section 10 determines that the leakage measuring section 7 is operating normally (ST9). On the other hand, when the current value of the test current I1 is out of the predetermined current range (ST8: No), the control section 10 determines that the leakage measuring section 7 is abnormal (ST10). Then, the control unit 10 controls the output unit 20 to output information indicating that an abnormality has occurred in the earth leakage measurement unit 7 (ST11).

Advantages of the power conversion system 100 of the present embodiment will be described below in comparison with the power conversion system 200 of the comparative example. The power conversion system 200 of the comparative example, as shown in FIG. It is different from the power conversion system 100 in the form.

The earth leakage breaker 201 has a function of shutting off the isolated system SY2 when an earth leakage current flows through the isolated system SY2. Also, the earth leakage breaker 201 has a test switch 202 . When the operator operates the test switch 202 , a pseudo leakage current flows through the leakage breaker 201 . This allows the operator to perform an operation test to determine whether or not the earth leakage breaker 201 normally shuts down, that is, whether or not the earth leakage breaker 201 is operating normally.

In the power conversion system 200 of the comparative example, an operator must operate the test switch 202 in order to perform an operation test of the earth leakage breaker 201, that is, an operation test of the earth leakage detection function. Therefore, in the power conversion system 200 of the comparative example, the operation test cannot be performed unless the operator goes to the installation location of the earth leakage breaker 201, and it takes time and effort to perform the operation test of the earth leakage detection function. There's a problem. Further, in the power conversion system 200 of the comparative example, if the operation test is forgotten and the state where an abnormality occurs in the earth leakage breaker 201 is left unattended, the earth leakage breaker 201 has the earth leakage detection function when performing self-sustained operation. There is a problem that it may not be possible to demonstrate Furthermore, in the power conversion system 200 of the comparative example, when the operator operates the test switch 202 during the isolated operation, the earth leakage breaker operates to cut off the isolated system SY2, and the load connected to the isolated system SY2 is interrupted. There is a problem that the power supply is interrupted.

On the other hand, in the power conversion system 100 of the present embodiment, instead of installing the earth leakage breaker 201, the control unit 10 controls the current supply unit 8, so that the operation test can be executed. For this reason, in this embodiment, for example, even if an operator does not go to the installation place of the power conversion system 100, it is possible to perform an operation test by remote control. Further, in the present embodiment, for example, it is possible to periodically and automatically execute the operation test without the operator's operation for performing the operation test. Therefore, in this embodiment, there is an advantage that the trouble required for the operation test of the earth leakage detection function can be reduced.

In addition, in the power conversion system 100 of the present embodiment, it is possible to automatically perform an operation test on a regular basis, so that the operator does not forget to perform the operation test. There is an advantage that it is possible to reduce the possibility of not being able to demonstrate

Furthermore, in the power conversion system 100 of the present embodiment, if the control unit 10 is set to prohibit execution of the operation test during self-sustained operation, when a trigger for executing the operation test occurs during self-sustained operation But you don't have to run a performance test. Further, in the power conversion system 100 of the present embodiment, the control unit 10 can perform an operation test without operating the self-sustaining relay (switching unit) 6 . Therefore, in this embodiment, there is an advantage that a situation in which the power supply to the load connected to the isolated system SY2 is interrupted during the isolated operation is less likely to occur.

(4) Modifications The embodiment described above is just one of various embodiments of the present disclosure. The above-described embodiments can be modified in various ways according to design and the like as long as the object of the present disclosure can be achieved. Also, functions similar to those of the power conversion system 100 may be embodied by a test method, a (computer) program, or a non-temporary recording medium recording the program.

A test method according to one aspect includes a supply step and a determination step. The supply step is a step of supplying the test current I1 from the external power supply P1 other than the isolated system SY2 to the earth leakage measurement unit 7 that measures the earth leakage current flowing through the isolated system SY2. Isolated system SY2 outputs power from distributed power supply 1 independently of power system SY1. The determination step is a step of determining the state of the earth leakage measurement unit 7 based on the measurement result of the earth leakage measurement unit 7 . A program according to one aspect causes one or more processors to execute the above test method.

Modifications of the above-described embodiment are listed below. Modifications described below can be applied in combination as appropriate.

The power conversion system 100 in the present disclosure includes a computer system in the control unit 10, for example. A computer system is mainly composed of a processor and a memory as hardware. The function of the control unit 10 in the present disclosure is realized by the processor executing a program recorded in the memory of the computer system. The program may be recorded in advance in the memory of the computer system, may be provided through an electric communication line, or may be recorded in a non-temporary recording medium such as a computer system-readable memory card, optical disk, or hard disk drive. may be provided. A processor in a computer system consists of one or more electronic circuits, including semiconductor integrated circuits (ICs) or large scale integrated circuits (LSIs). The integrated circuit such as IC or LSI referred to here is called differently depending on the degree of integration, and includes integrated circuits called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). In addition, a field-programmable gate array (FPGA) that is programmed after the LSI is manufactured, or a logic device capable of reconfiguring the bonding relationship inside the LSI or reconfiguring the circuit partitions inside the LSI may also be adopted as the processor. can be done. A plurality of electronic circuits may be integrated into one chip, or may be distributed over a plurality of chips. A plurality of chips may be integrated in one device, or may be distributed in a plurality of devices. A computer system, as used herein, includes a microcontroller having one or more processors and one or more memories. Accordingly, the microcontroller also consists of one or more electronic circuits including semiconductor integrated circuits or large scale integrated circuits.

Further, it is not an essential configuration of the control unit 10 that a plurality of functions of the control unit 10 are integrated into one housing. The constituent elements of the control unit 10 may be distributed over a plurality of housings. Furthermore, at least part of the functions of the control unit 10 may be implemented by, for example, a server device and a cloud (cloud computing). Conversely, all functions of the control unit 10 may be integrated into one housing as in the above-described embodiment.

In the above-described embodiments, the output unit 20 is not limited to outputting the test result of the operation test by light emission from the light source. For example, the output unit 20 may be a display and display (output) test results. Further, the output unit 20 may be a speaker and output the test result by voice. In addition, the output unit 20 may store the test result of the operation test in the storage device by outputting the test result of the operation test to the storage device.

In the above-described embodiment, the external power supply P1 is not limited to the power system SY1, and may be another power supply. For example, the external power supply P1 may be an operating power supply (control power supply) for the control unit 10 .

In the above-described embodiment, the test current I1 is not limited to alternating current, and may be direct current. In this case, the leakage measurement unit 7 may measure the test current I1 by using, for example, a Hall element type current sensor.

In the above-described embodiments, the storage battery and the charge/discharge circuit, which is a bidirectional DC/DC converter, may be connected in parallel to the distributed power supply 1 . In this aspect, for example, when the distributed power supply 1 receives sufficient sunlight and generates power, such as during the daytime, the storage battery can be charged by outputting surplus power to the storage battery via the charging/discharging circuit. is. In addition, in this aspect, when the distributed power supply 1 cannot receive sufficient sunlight and does not generate power, such as when the weather is cloudy or rainy, or at night, the power system SY1 is supplied from the storage battery to the power system SY1 through the charging/discharging circuit. Power can be supplied.

Although the power conversion system 100 includes the input capacitor C0, the DC/DC converter 2, the output capacitor C1, and the noise filter 4 in the above-described embodiment, some or all of these may be omitted. For example, in the power conversion system 100, the DC/DC converter 2 may not be connected between the distributed power source 1 and the inverter 3.

In the above-described embodiment, the distributed power source 1 is a photovoltaic power generation device, but it is not intended to be limited to this. For example, the distributed power source 1 may be a storage battery (including a storage battery for electric vehicles) or a power generation device such as a fuel cell. Also, the distributed power source 1 may be a power generator that uses renewable energy other than sunlight, such as wind power, water power, geothermal power, and biomass.

In the above-described embodiments, the power conversion system 100 is not limited to being installed in non-residential facilities, but may be installed in houses, and may be installed in places other than facilities such as electric vehicles.

(summary)
As described above, the power conversion system (100) according to the first aspect includes an earth leakage measurement section (7), a current supply section (8), and a control section (10). The earth leakage measurement unit (7) measures the earth leakage current flowing through the isolated system (SY2). The isolated system (SY2) outputs power from the distributed power supply (1) independently of the power system (SY1). A current supply unit (8) supplies a test current (I1) from an external power source (P1) other than the isolated system (SY2) to the earth leakage measurement unit (7). A control unit (10) executes an operation test. In the operation test, the current supply unit (8) is controlled to supply the test current (I1) to the leakage measurement unit (7), and based on the measurement result of the leakage measurement unit (7), the leakage measurement unit (7) This is the process of determining the state.

According to this aspect, there is an advantage that the labor required for the operation test of the earth leakage detection function can be reduced.

In the power conversion system (100) according to the second aspect, in the first aspect, the external power source (P1) is the power system (SY1).

According to this aspect, there is an advantage that it is not necessary to prepare a separate power supply as the external power supply (P1).

The power conversion system (100) according to the third aspect further includes an opening/closing unit (6) for opening/closing the isolated system (SY2) in the first or second aspect. A control section (10) controls an opening/closing section (6) based on the measurement result of the earth leakage measurement section (7).

According to this aspect, there is an advantage that power supply to the isolated system (SY2) can be cut off when an electric leakage occurs in the isolated system (SY2).

In the power conversion system (100) according to the fourth aspect, in any one of the first to third aspects, the control unit (10) executes the operation test during the period when the self-sustained operation is not performed.

According to this aspect, there is an advantage that the operation test of the earth leakage detection function hardly disturbs the self-sustained operation.

In the power conversion system (100) according to the fifth aspect, in any one of the first to fourth aspects, the control unit (10) measures the magnitude of the test current (I1) measured by the leakage measurement unit (7) and a predetermined current range to determine the state of the earth leakage measuring section (7).

According to this aspect, there is an advantage that it is easy to determine whether or not the leakage measuring section (7) is normal.

A power conversion system (100) according to a sixth aspect, in the fifth aspect, further includes a voltage measuring section (9) that measures the system voltage (V0) of the power system (SY1). A control section (10) obtains a predetermined current range based on the measurement result of the voltage measurement section (9).

According to this aspect, there is an advantage that it is possible to improve the accuracy of determining whether or not the leakage measuring section (7) is normal.

In the power conversion system (100) according to the seventh aspect, in any one of the first to sixth aspects, the test current (I1) is alternating current.

According to this aspect, since the operation test is performed with the same type of current as the current actually flowing through the isolated system (SY2), the operation test is performed in comparison with the case where the test current (I1) is a direct current. It has the advantage of being easy.

In the power conversion system (100) according to the eighth aspect, in any one of the first to seventh aspects, the control unit (10) performs an operation test at each predetermined timing during a period in which self-sustained operation is not performed. to run.

According to this aspect, there is an advantage that convenience is improved because the operator does not need to manually perform the operation test.

A power conversion system (100) according to a ninth aspect, in any one of the first to eighth aspects, further comprises an output section (20) for outputting the test result of the operation test.

According to this aspect, there is an advantage that the operator can easily grasp the test result of the operation test.

A test method according to a tenth aspect has a supply step and a determination step. The supply step is a step of supplying the test current (I1) from an external power supply (P1) other than the isolated system (SY2) to the earth leakage measurement unit (7) that measures the leakage current flowing through the isolated system (SY2). The isolated system (SY2) outputs power from the distributed power supply (1) independently of the power system (SY1). The determining step is a step of determining the state of the earth leakage measuring section (7) based on the measurement result of the earth leakage measuring section (7).

According to this aspect, there is an advantage that the labor required for the operation test of the earth leakage detection function can be reduced.

A program according to an eleventh aspect causes one or more processors to execute the test method according to the tenth aspect.

According to this aspect, there is an advantage that the labor required for the operation test of the earth leakage detection function can be reduced.

The configurations according to the second to ninth aspects are not essential configurations for the power conversion system (100), and can be omitted as appropriate.

1 Distributed power supply 6 Independent relay (switching part)
7 earth leakage measurement unit 8 current supply unit 9 voltage measurement unit 10 control unit 20 output unit 100 power conversion system I1 test current SY1 power system SY2 independent system P1 external power supply V0 system voltage

Claims (10)

A leakage measurement unit that measures leakage current flowing through an isolated system that outputs power from a distributed power supply independently of the power system;
a current supply unit that supplies a test current from an external power supply other than the isolated system to the earth leakage measurement unit;
a control unit that controls the current supply unit to supply the test current to the leakage measurement unit, and executes an operation test that determines the state of the leakage measurement unit based on the measurement result of the leakage measurement unit; prepared ,
The external power supply is the power system,
power conversion system. A leakage measurement unit that measures leakage current flowing through an isolated system that outputs power from a distributed power supply independently of the power system;
a current supply unit that supplies a test current from an external power supply other than the isolated system to the earth leakage measurement unit;
a control unit that controls the current supply unit to supply the test current to the leakage measurement unit, and executes an operation test that determines the state of the leakage measurement unit based on the measurement result of the leakage measurement unit; prepared,
Further comprising a voltage measurement unit for measuring the system voltage of the power system,
The control unit obtains a predetermined current range based on the measurement result of the voltage measurement unit,
The control unit compares the magnitude of the test current measured by the leakage measurement unit and the predetermined current range to determine the state of the leakage measurement unit.
power conversion system. Further comprising an opening/closing unit for opening/closing the independent system,
The control unit controls the opening/closing unit based on the measurement result of the earth leakage measurement unit.
The power conversion system according to claim 1 or 2. The control unit executes the operation test during a period in which self-sustained operation is not performed.
The power conversion system according to any one of claims 1 to 3. wherein the test current is alternating current;
The power conversion system according to any one of claims 1-4. The control unit executes the operation test at predetermined timings during a period in which self-sustained operation is not performed.
The power conversion system according to any one of claims 1-5. Further comprising an output unit for outputting test results of the operation test,
The power conversion system according to any one of claims 1-6. A supply step of supplying a test current from an external power source other than the isolated system to an earth leakage measurement unit that measures the leakage current flowing through the isolated system that outputs power from the distributed power supply independently of the power system;
a determination step of determining the state of the earth leakage measurement unit based on the measurement result of the earth leakage measurement unit;
The external power supply is the power system,
Test method. A supply step of supplying a test current from an external power source other than the isolated system to an earth leakage measurement unit that measures the leakage current flowing through the isolated system that outputs power from the distributed power supply independently of the power system;
a determination step of determining the state of the earth leakage measurement unit based on the measurement result of the earth leakage measurement unit;
Further comprising a voltage measurement step of measuring the system voltage of the power system,
In the determination step, a predetermined current range is obtained based on the measurement result in the voltage measurement step,
In the determination step, the magnitude of the test current measured by the leakage measurement unit is compared with the predetermined current range to determine the state of the leakage measurement unit.
Test method. one or more processors,
Execute the test method according to claim 8 or 9,
program.

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