JP7482983B2 - Insulation Resistance Test Method - Google Patents

Description

The present invention relates to an insulation resistance testing method.

In a photovoltaic power generation system, DC power generated by a solar cell device is sent via a power cable to a power conversion device (power conditioner), which converts the power into AC power. In order to detect ground faults and other conditions that occur on the DC side of the solar cell device and the power conversion device, an insulation resistance test is performed using an insulation resistance tester.
By the way, there are power conversion devices that have a relatively small capacity but have major functions mounted in a small housing. For example, some of these power conversion devices use a connector for the connection of the power cable, making it easy to attach and detach the power cable.

JP 2012-146931 A

However, in procedures such as performing an insulation resistance test on the DC input side of the power conversion device after undoing each of the connections between the power conversion device and the power cables from each solar cell device, or performing an insulation resistance test on each solar cell device and the power cables from the solar cell device individually, it is difficult to perform an insulation resistance test on each of the power conversion devices, which can reduce workability when performing the insulation resistance test.

The present invention has been made in consideration of the above-mentioned circumstances, and aims to provide an insulation resistance measurement method that can improve maintainability when conducting an insulation resistance test that includes, in the test range, the DC input side of a power conversion device that can accommodate multiple non-grounded solar cell devices connected in parallel with each other .

(1) In order to solve the above problems, one aspect of the present invention is an insulation resistance testing method that includes, as a test subject for an insulation resistance test, the DC input side of a power conversion device capable of converting DC power supplied respectively from a non-grounded first solar cell device and a non-grounded second solar cell device, the power conversion device having a first input terminal and a second input terminal electrically connected to the first input terminal, and includes a step of performing an insulation resistance test of the power conversion device using the second input terminal to which the second solar cell device is not connected, while the first solar cell device capable of supplying the DC power is connected to the first input terminal and the DC power is being supplied.

(2) In the insulation resistance test support device described above, a first power cable for supplying the DC power to the first input terminal is connected to the first input terminal during the insulation resistance test.

(3) In the insulation resistance test support device described above, a solar cell device is connected to the first input terminal via the first power cable during the insulation resistance test.

(4) In the insulation resistance test support device described above, the solar cell device is installed outdoors and is generating electricity during the insulation resistance test.

(5) In the above-mentioned insulation resistance test support device, either the positive electrode or the negative electrode of the solar cell device connected to the first input terminal is insulated from the first electrode of the first input terminal, and the other of the positive electrode or the negative electrode of the solar cell device connected to the first input terminal is connected to the second electrode of the first input terminal.
(6) In the above-described insulation resistance test support apparatus, the power conversion device is provided with a switch that electrically disconnects the first input terminal and the second input terminal from a main body of a power conversion unit of the power conversion device that converts the DC power.
(7) In the above-mentioned insulation resistance test support device, the switch opens a circuit leading from the first input terminal and the second input terminal to the power conversion unit main body of the power conversion device, and the insulation resistance test is performed after the circuit is opened.
(8) Furthermore, in the above-mentioned insulation resistance test support device, the power conversion device further has a third input terminal and a fourth input terminal electrically connected to the third input terminal, and in a state in which a first pole of the first solar cell device capable of supplying the DC power is connected to the first input terminal and a second pole of the first solar cell device is connected to the third input terminal to supply the DC power, the first pole of the second solar cell device is not connected to the second input terminal and the second pole of the second solar cell device is connected to the fourth input terminal, and an insulation resistance test of the power conversion device is performed using the second input terminal.

According to each aspect of the present invention, it is possible to provide an insulation resistance measurement method that makes it possible to improve maintainability when conducting an insulation resistance test that includes, in the test range, the DC input side of a power conversion device that can accommodate multiple non-grounded solar cell devices connected in parallel with each other.

1 is a schematic configuration diagram of a photovoltaic power generation system to which an insulation resistance test support device according to an embodiment is applied; 1 is a diagram for explaining a power conversion device according to an embodiment; FIG. 2 is a configuration diagram of the photovoltaic power generation system 1 during an insulation resistance test according to the embodiment. FIG. 11 is a configuration diagram of a photovoltaic power generation system 1 during an insulation resistance test in a first modified example of an embodiment. 1 is a flowchart showing an outline of a procedure for an insulation resistance test according to an embodiment. 4 is a flowchart showing a procedure of an insulation resistance test according to the embodiment. FIG. 11 is a diagram for explaining the arrangement of an insulation resistance test support device 10 according to a second modified example of the embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
The solar cell device in the embodiment represents a non-grounded solar cell panel, a solar cell string, a solar cell array, etc. In the embodiment, "connected" includes electrically connected. The insulation resistance test in the embodiment is a test in which insulation measurement using an insulation resistance meter applied to a low-voltage power distribution system (electrical circuits and equipment in which the power supply is cut off in a direct current power distribution system) is applied to the solar cell device and its electric circuit. The switch in the embodiment may be anything that switches between an electrically conductive state and a non-conductive state, and may be, for example, a switch having a mechanical contact or a semiconductor switch, or may be a state in which impedance is higher than a predetermined value instead of a non-conductive state.

Figure 1 is a schematic diagram of a solar power generation system to which an insulation resistance test support device of an embodiment is applied. The solar power generation system 1 shown in Figure 1 includes a solar cell device 2 and a power conversion device 3. The solar cell device 2 shown in the figure includes a solar cell device 21, a solar cell device 22, and a solar cell device 23. In the following description, when the solar cell device 21, the solar cell device 22, and the solar cell device 23 are described collectively, they are simply referred to as the solar cell device 2. The solar cell device 21 is an example of a first solar cell device, and the solar cell device 22 is an example of a second solar cell device.

The solar cell device 2 is connected to the power conversion device 3 by a power cable. The power conversion device 3 converts the DC power supplied from the solar cell device 2 into AC power. As described above, the solar power generation system 1 collects the DC power generated by the solar cell device 2 in the power conversion device 3, and outputs the AC power converted by the power conversion device 3 to the power grid.

For example, as shown in FIG. 3A described below, the solar cell device 21 is connected to the power conversion device 3 by a positive power cable L21P and a negative power cable L21N. Similarly, the solar cell device 22 is connected to the power conversion device 3 by power cables L22P and L22N. Similarly, the solar cell device 23 is connected to the power conversion device 3 by power cables L23P and L23N. Each of the above power cables has an insulation resistance exceeding the test voltage of the insulation resistance test.

The solar power generation system 1 of the embodiment is placed, for example, on the ground or the rooftop of a building. In this case, the solar cell device 2 is placed on a mounting stand TRE provided on the ground or the like, and fixed to the mounting stand TRE. The power conversion device 3 is attached to the supports, diagonal braces, etc. of the mounting stand TRE. For example, the solar cell device 2 is placed so that its light receiving surface is on the upper side. The height of the light receiving surface of the solar cell device 2 is lower the farther it is from the user U in the Y-axis direction, and higher the closer it is to the user U, so that the height on the near side to the user U makes the user U look up.

Depending on the relative positions of the solar cell device 2 and the power conversion device 3, the user U may need to perform work related to the power conversion device 3 under the solar cell device 2. The solar power generation system 1 shown in the figure is an example of the above. X, Y, and Z in the figure indicate the axes of a three-dimensional coordinate system. Note that some of the cables in the figure have been omitted.

Figure 2 is a diagram for explaining the power conversion device of the embodiment. The diagram in Figure 2 shows the power conversion device 3 installed in a standard manner, viewed from diagonally below.

The housing 3C of the power conversion device 3 is made of insulating resin and is waterproof (rainproof) by itself. The housing 3C houses the power conversion device main body inside.

For example, the housing 3C is formed into a substantially rectangular parallelepiped. The solar cell device 2 and the power grid are electrically connected by connectors. Each connector is provided on one surface 3F of the housing 3C. When the power conversion device 3 is placed in an operable state in a standard manner, the surface 3F (Figure 1) is located on the lower side of the housing 3C (in the negative direction of the Z axis).

Connectors CN1P, CN2P, and CN3P for the positive power supply line, and connectors CN1N, CN2N, and CN3N for the negative power supply line are provided on face 3F. Connectors CN1P and CN1N, CN2P and CN2N, and CN3P and CN3N are each paired with a positive and negative pole.

For example, one end of a power cable L21P (first power cable) is connected to the positive electrode of the solar cell device 21. A plug P21P (first plug) is provided at the other end of the power cable L21P. The plug P21P is connected to the connector CN1P. As a result, the positive electrode of the solar cell device 21 is connected to the connector CN1P via the power cable L21P.

One end of the power cable L21N is connected to the negative electrode of the solar cell device 21. A plug P21N is provided at the other end of the power cable L21N. The plug P21N is connected to the connector CN1N. As a result, the negative electrode of the solar cell device 21 is connected to the connector CN1N via the power cable L21N. As a result, DC power from the solar cell device 21 is supplied to the power conversion device 3 via the connectors CN1P and CN1N.

One end of the power cable L22P (second power cable) is connected to the positive electrode of the solar cell device 22. A plug P22P (second plug) is provided at the other end of the power cable L22P. The plug P22P is connected to the connector CN2P. As a result, the positive electrode of the solar cell device 22 is connected to the connector CN2P via the power cable L22P.

One end of the power cable L22N is connected to the negative electrode of the solar cell device 22. A plug P22N is provided at the other end of the power cable L22N. The plug P22N is connected to the connector CN2N. As a result, the negative electrode of the solar cell device 22 is connected to the connector CN2N via the power cable L22N. As a result, DC power from the solar cell device 22 is supplied to the power conversion device 3 via the connectors CN2P and CN2N.

One end of the power cable L23P (second power cable) is connected to the positive electrode of the solar cell device 22. The other end of the power cable L23P is provided with a plug P23P (second plug). The plug P23P is connected to the connector CN3P. As a result, the positive electrode of the solar cell device 23 is connected to the connector CN3P via the power cable L23P.

One end of the power cable L23N is connected to the negative pole of the solar cell device 23. A plug P23N is provided at the other end of the power cable L23N. The plug P23N is connected to the connector CN3N. As a result, the negative pole of the solar cell device 23 is connected to the connector CN3N via the power cable L23N. As a result, DC power from the solar cell device 23 is supplied to the power conversion device 3 via the connectors CN3P and CN3N.

The state shown in the figure shows the state in which plug P21P provided at the end of power cable L22P (second power cable) has been removed from connector CN1P. The positive plug P21P, plug P22P, and plug P23P are formed to at least the same shape. The negative plug P21N, plug P22N, and plug P23N are formed to at least the same shape. Plugs P21P, plug P22P, and plug P23P, and plugs P21N, plug P22N, and plug P23N may also be of the same shape. There is no restriction on changing the shape of the connectors for the positive power cable and the negative power cable.

Note that the connector CN1P is an example of a first input terminal, and the connector CN2P is an example of a second input terminal. As described above, when the power conversion device 3 is placed in an operable state, each connector such as the connector CN1P is provided at the bottom of the housing of the power conversion device 3.

Furthermore, face 3F is provided with a connector CN4 for connecting a power cable L4 for connecting the power conversion device 3 to the power grid, and a ground terminal ET.

FIG. 3A is a configuration diagram of the photovoltaic power generation system 1 during an insulation resistance test according to the embodiment.
The photovoltaic power generation system 1 shown in FIG. 3A includes an insulation resistance meter 4 and an insulation resistance test support device 10 in addition to a solar cell device 2 and a power conversion device 3 .

The electrical configuration of the power conversion device 3 includes at least a first connecting conductor 31, a second connecting conductor 32, a power converter body 33, and a switch 34.

The first connecting conductor 31 includes a first connecting conductor 31P on the positive side and a first connecting conductor 31N on the negative side. The second connecting conductor 32 includes a second connecting conductor 32P on the positive side and a second connecting conductor 32N on the negative side.

The first connecting conductor 31P connects the connector CN1P, the connector CN2P, and the connector CN3P inside the housing 3C of the power conversion device 3. The second connecting conductor 32P connects the first connecting conductor 31P to the positive electrode of the input side of the power converter main body 33.

The first connecting conductor 31N connects the connectors CN1N, CN2N, and CN3N inside the housing 3C of the power conversion device 3. The second connecting conductor 32N connects the first connecting conductor 31N to the negative electrode of the input side of the power converter main body 33.

The power converter body 33 converts the DC power supplied to the input side into AC power and outputs it to the power grid via connector CN4. The power converter body 33 can be connected to the power grid. The AC side of the power converter body 33 may be three-phase AC with a grounded neutral point.

The switch 34 is an overcurrent circuit breaker provided on the second connecting conductor 32. The switch 34 is normally kept in a conductive state. At least when an insulation resistance test is performed, the switch 34 electrically disconnects the first connecting conductor 31P from the positive electrode of the input side of the power converter main body 33 and the first connecting conductor 31N from the negative electrode of the input side of the power converter main body 33. When the user opens the switch 34, the connectors CN1P, CN2P, and CN3P, the connectors CN1N, CN2N, and CN3N, and the power converter main body 33 are each insulated inside the housing 3C, making it possible to perform an insulation resistance test.

After completing the insulation resistance test, user U returns switch 34 to a conductive state, enabling power conversion by power conversion device 3.

The insulation resistance tester 4 outputs a test voltage for the target test location to perform an insulation resistance test. For example, the test voltage is determined based on the voltage of the target test location relative to the ground. Well-known insulation resistance tests can be used as the insulation resistance tester 4.

The insulation resistance test support device 10 includes at least a terminal 11, a test terminal 12, a circuit breaker 13, a ground side test terminal 14, a ground terminal 19, and a cable L11 (first connection cable).

The terminal 11 is connected to the power conversion device 3 during an insulation resistance test. For example, one end of a cable L11 is connected to the terminal 11. The other end of the cable L11 is provided with a connection plug P11 for connecting the cable L11 to a connector CN1P of the power conversion device 3 or the like. The fitting portion on the connector CN1P side of this connection plug P11 should preferably have the same shape as the fitting portion on the connector CN1P side of the aforementioned plug P21P. The insulation resistance test support device 10 is connected to the power conversion device 3 via the cable L11.

The test terminal 12 is a terminal to which the electrode of the insulation resistance meter 4 is connected. For example, the test terminal 12 may be a terminal capable of engaging the electrode of the insulation resistance meter 4. For example, the test terminal 12 is arranged on the surface of the housing 10C (support). The insulation resistance test support device 10 is formed so that the surface on which the test terminal 12 is arranged becomes the top or side surface of the housing 10C during the insulation resistance test, allowing the user U to have an overview of the state of the test terminal 12 during the test, and making it easy to see the test terminal 12 even when standing.

The circuit breaker 13 is provided between the terminal 11 and the test terminal 12, and can be operated by the user to disconnect or connect the electrical connection between the terminal 11 and the test terminal 12. When the user U is ready to perform an insulation resistance test on the solar cell device 2, the user U sets the circuit breaker 13 to a conductive state. After completing the insulation resistance test, the user U sets the circuit breaker 13 to a cut-off state.

The ground side test terminal 14 is a terminal on the ground electrode side that is used in combination with the test terminal 12 when performing an insulation resistance test using the insulation resistance meter 4. The ground terminal 19 is connected to the ground side test terminal 14 and connects the ground side test terminal 14 to the earth. The ground terminal 19 is connected, for example, to the ground terminal ET of the power conversion device 3. The ground terminal ET of the power conversion device 3 is grounded under conditions suitable for the power conversion device 3.

The insulation resistance test support device 10 may further include a terminal 15, a measurement terminal 16, a circuit breaker 17, and a cable L15.

The terminal 15 is connected to the solar cell device 2 when performing an insulation resistance test on the solar cell device 2. One end of a cable L15 is connected to the terminal 11. The other end of the cable L15 is provided with a connector CN15 for connecting to, for example, the plug P21P of the power cable L22P. This connector CN15 may have the same shape as the connector CN1P described above. The insulation resistance test support device 10 is connected to one of the solar cell devices 2 via the cable L15.

The measurement terminal 16 is a terminal to which the electrodes of the insulation resistance meter 4 are connected, similar to the test terminal 12. The shape of the measurement terminal 16 may be the same as that of the test terminal 12.

The circuit breaker 17 is provided between the terminal 15 and the measurement terminal 16, and can be operated by the user to disconnect or connect the electrical connection between the terminal 15 and the measurement terminal 16. When the user U is ready to perform the insulation resistance test of the solar cell device 2, the user U sets the circuit breaker 17 to a conductive state. After completing the insulation resistance test, the user U sets the circuit breaker 17 to a cut-off state.

An insulation resistance test using the insulation resistance test support device 10 will be described.
FIG. 4 is a flowchart showing an outline of the procedure of the insulation resistance test according to the embodiment.
The user U stops the operation of the power electronics device 3 (step Sa1). The user U opens the switch 34 of the power electronics device 3 and the circuit breaker (not shown) to which the power electronics device 3 is connected (step Sa2).

Next, the user U connects the insulation resistance test support device 10 between the solar cell device 21 and the power conversion device 3 as shown in FIG. 3A, and performs a first insulation resistance test in which a test voltage is directly applied to the power conversion device 3, and a second insulation resistance test in which a test voltage is directly applied to the solar cell device 21 (step Sa3). The procedure of step Sa3 will be described in more detail later.

Next, the insulation resistance meter 4 displays the results of the first insulation resistance test and the results of the second insulation resistance test (step Sa4).

Based on the results of the first insulation resistance test and the second insulation resistance test, the user U determines whether the insulation resistance of the test range TG on the DC side of the insulation resistance photovoltaic power generation system 1 is equal to or greater than a reference value (step Sa5). The reference value is determined by the operating voltage of the test target location.

Here, if an abnormality is detected in either the results of the first insulation resistance test or the results of the second insulation resistance test, the user U determines that there is an abnormality in the insulation resistance in the test range TG on the DC side of the photovoltaic power generation system 1 (step Sa6) and ends the test.

Alternatively, if no abnormality is detected in either the results of the first insulation resistance test or the second insulation resistance test, the user U determines that there is no abnormality in the insulation resistance in the test range TG on the DC side of the photovoltaic power generation system 1 (step Sa7) and ends the test.

Next, a more specific procedure for the insulation resistance test will be described with reference to Figures 3A, 4, and 5. Figure 5 is a flowchart showing the procedure for the insulation resistance test of the embodiment.

In the solar power generation system 1, the user U performs two types of insulation resistance tests on the DC side: a first insulation resistance test on the DC input side of the power conversion device 3, and a second insulation resistance test that directly tests the solar cell device 2. The insulation resistance test support device 10 supports the implementation of these tests.

After completing steps Sa1 and Sa2 in FIG. 4 described above, the user U, if necessary, disconnects the positive cable from the power conversion device 3 and changes the connection to a configuration for performing an insulation resistance test (FIG. 3A) (step Sa31). For example, the plug P21P corresponding to the positive pole of the solar cell device 21 is disconnected from the connector CN1P of the power conversion device 3, and the solar cell device 22 and the solar cell device 23 are left connected to the power conversion device 3. This puts the cable L11 in a state of being unplugged from the power conversion device 3. Furthermore, the user U connects the connection plug P11 of the cable L11 to the connector CN1P of the insulation resistance test support device 10. The user U connects the connector CN15 of the insulation resistance test support device 10 to the connection plug P11 of the cable L11. This step Sa31 may be omitted if not necessary.

Next, a first insulation resistance test is performed (step Sa32). The first insulation resistance test is performed on the area connected via the test terminal 12.

Specifically, the targets of the first insulation resistance test include both the DC input side of the power conversion device 3 and the solar cell device 2 to which the power cable is connected to the power conversion device 3. In this state, when an insulation resistance test is performed on the DC input side of the power conversion device 3, since they are electrically connected inside the housing 3C of the power conversion device 3, the test voltage for the insulation resistance test can be applied to the positive pole sides of the power conversion device 3, the solar cell device 22, and the solar cell device 23.

Therefore, the presence or absence of a fault location where the insulation resistance has dropped to the above range can be identified with a single test. With the above test method, all the solar cell devices 2 connected in parallel except for one of the solar cell devices 2 housed in the power conversion device 3 can be tested together by simply changing one connection of the power cable.

The results of the first insulation resistance test in step Sa32 are evaluated (step Sa33).

If an abnormality is detected in the results of the first insulation resistance test, it is determined that there is an abnormality in the insulation resistance within the measurement range, and an analysis is performed to individually identify the location of the fault within the measurement range (step Sa34). The method for this individual analysis may be a general insulation resistance test method for each solar cell device 20.

If no abnormality is detected in the results of the first insulation resistance test in step Sa32, proceed to the next step Sa36 (step Sa35).

Next, a second insulation resistance test is performed (step Sa36). The target of the second insulation resistance test is the range connected via the measurement terminal 16.

Specifically, the subject of the second insulation resistance test includes the solar cell device 21 with one side of the power cable disconnected from the power conversion device 3. When an insulation resistance test is performed on the solar cell device 21 in this state, the test voltage for the insulation resistance test can be applied to the positive electrode side of the solar cell device 21.

If an abnormality is detected in the results of the second insulation resistance test, it is determined that there is an abnormality in the insulation resistance within the measurement range, and an analysis is further performed to individually identify the location of the fault within the measurement range (step Sa38), and the process ends. The method for this individual analysis may be a general insulation resistance test method for each solar cell device 20.

If no abnormality is detected in the results of the second insulation resistance test in step Sa36, the process ends (step Sa39).

As described above, it is possible to identify the presence or absence of a fault location where insulation resistance has decreased within the positive electrode side of the solar cell device 21. With the above test method, it is possible to test the positive electrode side of the solar cell device 21, which could not be tested in the first insulation resistance test described above.

(First Modification of the Embodiment)
A first modification of the embodiment will be described.
In the embodiment, a procedure for measuring insulation resistance by applying a specified voltage to the positive electrode side is exemplified. Instead, in this modified example, a procedure for measuring insulation resistance by applying a specified voltage to the negative electrode side in a similar manner is described.
3B is a configuration diagram of the photovoltaic power generation system 1 during an insulation resistance test in a modified example of the embodiment. The difference between the case of testing the negative electrode side shown in FIG. 3B and the case of testing the positive electrode side shown in FIG. 3A is that the connection destination of the insulation resistance test support device 10 is different. When testing the positive electrode side described above (FIG. 3A), the positive electrode side power cable L21P is removed from the connector CN1P of the power conversion device 3, and the insulation resistance test support device 10 is connected thereto. Instead, when testing the negative electrode side (FIG. 3B), for example, the negative electrode side power cable L23N is removed from the connector CN3N of the power conversion device 3, and the cable L11 of the insulation resistance test support device 10 is connected to the connector CN3N thereto.

Similarly, instead of the solar cell device 21, the connection cable L15 of the insulation resistance test support device 10 is connected to the negative electrode plug P23N of the solar cell device 23.

The above shows how to change the connection destination, but the test procedure should be the same as that shown in Figure 4 above. In this case, the test object and poles are different from the example shown in Figure 1 above. Therefore, it is recommended that the polarity of the test voltage be reversed from that of the test voltage in the example shown in Figure 1 so that the current during the test flows in the forward current direction of the solar cell device.

(Second Modification of the Embodiment)
As a second modification of the embodiment, the layout of the insulation resistance test support device 10 will be described with reference to Fig. 6. Fig. 6 is a diagram for explaining the layout of the insulation resistance test support device 10 of the second modification of the embodiment.

The placement of the insulation resistance test support device 10 is limited by the length of the cable L11. It is advisable to approximate the shape of the housing 3C of the power conversion device 3 to a rectangular parallelepiped, and make the length of the cable L11 longer than the length of the shortest side of the rectangular parallelepiped.

FIG. 6A illustrates an example in which the length of the cable L11 is relatively short.
For example, assume that the housing 3C in the installed state is approximated to a rectangular parallelepiped, and that the depth direction of the rectangular parallelepiped (positive direction of the Y axis) is the shortest side among all sides. A more specific example of the length is assumed to be about 10 centimeters. This value is merely an example, and may be determined based on the size of the housing 3C.

If the length of cable L11 is the same as the depth, then insulation resistance test support device 10 will be located directly below surface 3F, which corresponds to the bottom of housing 3C, by a distance equal to the depth. Even in this state, if user U stands at a suitable distance from the front of housing 3C, he or she can see insulation resistance test support device 10 without bending over. In the above, the front of housing 3C refers to, for example, the surface facing user U.

In reality, as shown in FIG. 6(b), multiple power cables are connected to the housing 3C, and the insulation resistance test support device 10 can be placed closer to the user (in the negative direction of the Y axis) than these power cables, further improving the visibility of the insulation resistance test support device 10.

The above example illustrates the case where the cable L11 is simply hung from the bottom of the housing 3C, but by making the length of the cable L11 longer, it becomes possible to place the insulation resistance test support device 10 in the horizontal direction (X-axis direction) of the housing 3C or at a position higher than the height of the surface 3F, so the length of the cable L11 should be determined to be appropriate with consideration given to workability and safety. For example, by setting the length of the cable L11 to a length that allows the user U to place the insulation resistance meter 4 and the insulation resistance test support device 10 close at hand, the user U can work without having to assume an awkward working position, improving workability.

The arrangement of the solar cell device 2 and the power conversion device 3 in the solar power generation system 1 shown in FIG. 1 is merely an example, and is not limited to this. The solar cell device 2 may be provided on a wall or roof of a building, and the power conversion device 3 may be disposed on a wall of a building, etc.

According to the above embodiment, the insulation resistance test support device 10 is applied to an insulation resistance test of a test range of a photovoltaic power generation system 1 including an ungrounded solar cell device 2 and a power conversion device 3 connected to the solar cell device. When testing the insulation resistance of the test range of the photovoltaic power generation system 1 using an insulation resistance meter 4 that outputs a test voltage, the insulation resistance test support device 10 supports the test work related to the insulation resistance test.

The insulation resistance test support device 10 includes at least a cable L11, a terminal 11, and a test terminal 12. A first end of the cable L11 connected to the power conversion device 3 is provided with a connection plug P1P that can be fitted into the connector CN1P of the power conversion device 3. The second end of the cable L11 is electrically connected to the terminal 11. The insulation resistance meter 4 and the terminal 11 are connected to the test terminal 12. The test terminal 12 can apply a test voltage for an insulation resistance test of the solar cell device 22 and the power cable L22P to the connector CN1P via the terminal 11. The insulation resistance test support device 10 is disposed between the insulation resistance meter 4 and the test target range, so that the test voltage output from the insulation resistance meter 4 can be applied to the circuit in the test target range, thereby improving maintainability when performing an insulation resistance test of a solar power generation system.

When the power conversion device 3 is placed in an operable state, the connector CN1P is provided on the surface 3F corresponding to the lower part of the housing 3C of the power conversion device 3, and the connection plug P1P is connected to it. If the shape of the housing 3C of the power conversion device 3 is approximated to a rectangular parallelepiped, it is preferable to make the length of the first connection cable L11 longer than the length of the shortest side of the above-mentioned rectangular parallelepiped. This allows the insulation resistance test support device 1 to be placed in a position that makes it easy to perform the test.

The insulation resistance test support device 1 may further include a box-shaped housing 10C (support). In this case, the test terminal 12 and the test terminal 15 may be arranged on the top or side of the housing 10C when the connection plug P1P is connected to the connector CN1P.

In addition, as described above, the insulation resistance test support device 10 provides a connection plug P1P on the cable L11 that can be fitted into the connector CN1P of the power conversion device 3, eliminating the need to hold the tester rod that is placed against the connector CN1P of the power conversion device 3 during testing and the cable to which the tester rod is connected, and therefore eliminating the need to perform testing in a bent-over position.

In addition, by connecting the cable L21P removed from the connector CN1P of the power conversion device 3 to the cable L15 connected to the insulation resistance test support device 10, the end of the cable L21P (plug P21P) can be prevented from falling to the ground, reducing the effort required to protect it from contamination during testing.

The insulation resistance test support device 10 is equipped with a circuit breaker 13 and a circuit breaker 17, and even if the solar cell device 2 installed outdoors is generating electricity and there is a potential difference between the cables L21P and L21N, the test terminal 12 and the measurement terminal 16 can be made voltage-free to connect the insulation resistance meter 4, thereby improving safety during work and reducing the risk of electric shock.

Even when there are differences in the type of power conversion device 3 or the shape of the connector CN1P, the cable L11 and cable L15 provided in the insulation resistance test support device 10 can be easily replaced, making it possible to apply the device.

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the gist of the invention. These embodiments and their modifications are within the scope of the invention and its equivalents as set forth in the claims, as well as the scope and gist of the invention.

Although the example described above shows that only one power cable is removed from the power conversion device 3 during the insulation resistance test, the present invention is not limited to this example, and instead, the insulation resistance test may be performed by removing a pair of power cables from the positive and negative electrodes of the solar cell device 2.

1...Photovoltaic power generation system, 2...Photovoltaic cell device, 3...Power conversion device, 31...First connecting conductor, 32...Second connecting conductor, 33...Power converter body, 34...Switch, 4...Insulation resistance meter, 10...Insulation resistance test support device, 11...Terminal, 12...Test terminal, 13...Circuit breaker, 14...Ground side test terminal, 15...Terminal, 16...Measurement terminal, 17...Circuit breaker, 19...Ground terminal, L11...Cable (first connecting cable), L15...Cable (second connecting cable)

Claims (8)

A power conversion device capable of converting DC power supplied from each of the first and second non-grounded solar cell devices is included in the test subject of the insulation resistance test,
The power conversion device includes:
A first input terminal;
a second input terminal electrically connected to the first input terminal;
are placed,
an insulation resistance testing method comprising: a step of conducting an insulation resistance test of the power conversion device using the second input terminal to which the second solar cell device is not connected, while the first solar cell device capable of supplying DC power is connected to the first input terminal and the DC power is being supplied thereto . The insulation resistance testing method according to claim 1 , wherein a first power cable for supplying the DC power to the first input terminal is connected to the first input terminal during the insulation resistance test. The insulation resistance testing method according to claim 2 , wherein a solar cell device is connected to the first input terminal via the first power cable during the insulation resistance test. The insulation resistance testing method according to claim 3 , wherein the solar cell device is installed outdoors and in a power generating state during the insulation resistance testing. One of a positive electrode and a negative electrode of a solar cell device connected to the first input terminal is insulated from a first electrode of the first input terminal,
the other of the positive electrode and the negative electrode of the solar cell device connected to the first input terminal is connected to a second electrode of the first input terminal;
The insulation resistance testing method according to claim 3. The power conversion device is provided with a switch that electrically disconnects the first input terminal and the second input terminal from a power conversion unit main body of the power conversion device that converts the DC power.
The insulation resistance testing method according to claim 3. a circuit is opened from the first input terminal and the second input terminal to a power conversion unit of the power conversion device by the switch, and the insulation resistance test is performed after the circuit is opened.
The insulation resistance testing method according to claim 6. The power conversion device further includes:
A third input terminal;
a fourth input terminal electrically connected to the third input terminal;
are arranged,
In a state in which the first pole of the first solar cell device capable of supplying the DC power is connected to the first input terminal and the second pole is connected to the third input terminal to supply the DC power, the first pole of the second solar cell device is not connected to the second input terminal and the second pole of the second solar cell device is connected to the fourth input terminal, and an insulation resistance test of the power conversion device is performed using the second input terminal.
The insulation resistance test method according to claim 1.

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