JP2016050783A - Earth detection device and earth detection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an earth detection device and an earth detection method which safely measure an earth fault resistance value with high accuracy.SOLUTION: In an earth detection device (12), a controller (27) measures an earth fault resistance value. A detection first changeover switch (23) switches connection of one end of a third inspection energizing path (25) which includes a detection resistor (R) between a ground energizing path (26) and a first inspection energizing path (22a). A detection second changeover switch (24) switches connection of the other end of the third inspection energizing path (25) between the ground energizing path (26) and a second inspection energizing path (22b).SELECTED DRAWING: Figure 1

Description

  The present invention relates to a ground fault detection device and a ground fault detection method for detecting a ground fault of a solar cell.

  A solar cell string that generates power using sunlight is formed by connecting a plurality of solar cell panels (solar cell modules) in series, and a solar cell panel is formed by connecting a plurality of solar cells in series. ing. The electric power generated by the solar cell string is supplied to the electric power transmission network through the power conditioner.

  The solar cell string is in a floating state without being grounded, and a ground fault occurs when the insulation resistance is lowered for some reason. Therefore, conventionally, as disclosed in Patent Document 1, a solar cell string is provided with a ground fault detection device that detects the occurrence of a ground fault.

  As shown in FIG. 11, the ground fault detection device 102 disclosed in Patent Document 1 includes first and second switches 111 and 112, a detection resistor R <b> 111, a voltage detector 114, and an arithmetic control unit 115.

  In the configuration shown in FIG. 11, the positive electrode of the solar cell string 101 is grounded via the first switch 111 and the detection resistor R111, and the negative electrode is grounded via the second switch 112 and the detection resistor R111. It has come to be. The first and second switches 111 and 112 are connected to the terminals on the detection resistor R111 side. Therefore, when the first switch 111 is on and the second switch 112 is off, the first voltage V111 is generated across the detection resistor R111, and the first switch 111 is off and the second switch 112 is on. Generates a second voltage V112 across the detection resistor R111.

  The voltage detector 114 detects the first and second voltages V111 and V112 at both ends of the detection resistor R111, and detects a voltage between the positive electrode and the negative electrode of the solar cell string 101. The arithmetic control unit 115 controls the on / off operation of the first and second switches 111 and 112, and is based on the first and second voltages V111 and V112, the voltage between the electrodes, and the resistance value of the detection resistor R111. A ground fault resistance value (insulation resistance value) of the string 101 is obtained.

JP 2012-119382 A (released on June 21, 2012)

  However, in the above-described conventional configuration, as shown in FIG. 12, the first and second switches 111 and 112 are both turned on, for example, the first and second switches 111 and 112 are both welded in the on state. When such a failure occurs, the positive electrode and the negative electrode of the solar cell string 101 are short-circuited, and a large current flows through a circuit between the positive electrode and the negative electrode. In such a case, the circuit generates heat and may cause a fire.

  On the other hand, in order to avoid such a situation, as shown in FIG. 13, the first and second switches 111 and 112 in the power feeding path between the first and second switches 111 and 112 and the solar cell string 101 are used. It is conceivable to provide protective resistors R112 and R113 in series with each other. In such a configuration, even when both the first and second switches 111 and 112 are turned on, the current flowing through the circuit between the positive electrode and the negative electrode of the solar cell string 101 is reduced, and the circuit Heat generation can be suppressed.

  However, in such a configuration, different protection resistances R112 and R113 are used for obtaining the first voltage V111 and for obtaining the second voltage V112. For this reason, the ground fault resistance value (insulation resistance value) of the solar cell string 101 cannot be obtained accurately.

  That is, the protective resistances R112 and R113, which are resistors, have some errors in their resistance values due to manufacturing errors even if the indicated resistance values are the same. Further, the resistance values of the protective resistors R112 and R113 change due to temperature changes. This change in resistance value is not the same between the protective resistors R112 and R113, and there are individual differences. In other words, the temperature coefficient of the resistance value differs between the protective resistors R112 and R113. Among these, the error of the resistance value at the time of manufacture can be dealt with by the initial adjustment. However, the change in resistance value due to temperature cannot be accommodated by the initial adjustment. Therefore, the first switch 111 is turned on and the second switch 112 is turned off, the first voltage V111 obtained through the protection resistor R112, and the first switch 111 is turned off and the second switch 112 is turned on, and the protection resistor The second voltage V112 obtained through R113 is inaccurate. As a result, the ground fault resistance value of the solar cell string 101 obtained by using the first and second voltages V111 and V112 is inaccurate.

  Accordingly, an object of the present invention is to provide a ground fault detection device and a ground fault detection method capable of obtaining a ground fault resistance value of a solar cell safely and with high accuracy.

  In order to solve the above-described problem, a ground fault detection device of the present invention includes a detection resistor and a measurement unit, and the measurement unit acquires a voltage generated at both ends of the detection resistor to obtain a ground fault of a solar cell. In the ground fault detection apparatus for measuring the resistance value of the solar cell, a first current path connected to the positive electrode of the solar cell, a second current path connected to the negative electrode of the solar cell, and the detection resistor at one end side And a first switching means for switching between a first energization path and a third energization path provided between the first energization path and the first energization path. And second switching means for switching the connection on the other end side of the third energization path between the ground energization path and the second energization path.

  According to said structure, a 1st switching means switches the connection of the one end side of a 3rd electricity supply path between a ground electricity supply path and a 1st electricity supply path. The second switching means switches the connection on the other end side of the third energization path between the ground energization path and the second energization path. The measuring means acquires the voltage generated at both ends of the detection resistor, and measures the resistance value of the ground fault of the solar cell.

  That is, in the measuring means, the first switching means switches the connection on one end side of the third energizing path to the first energizing path, and the second switching means switches the connection on the other end side of the third energizing path to the second energizing path. In the switched state, an inter-electrode voltage, which is a voltage between the positive and negative electrodes of the solar cell, generated at both ends of the detection resistor is acquired. Further, the measuring means is configured such that the first switching means switches the connection on one end side of the third energizing path to the first energizing path, and the second switching means switches the connection on the other end side of the third energizing path to the ground energizing path. In this state, the first voltage generated at both ends of the detection resistor is acquired. Further, the measuring means is configured such that the first switching means switches the connection on one end side of the third energizing path to the ground energizing path, and the second switching means switches the connection on the other end side of the third energizing path to the second energizing path. In this state, the second voltage generated at both ends of the detection resistor is acquired. The measuring means can determine the resistance value of the ground fault of the solar cell from the inter-electrode voltage, the first voltage, the second voltage, and the resistance value of the detection resistor.

  Moreover, according to said structure, a 1st switching means and a 2nd switching means are switched, and the positive electrode and negative electrode of a solar cell are a 1st electricity path, a 1st switching means, a 3rd electricity path, and a 2nd switching. When the positive electrode and the negative electrode of the solar cell are connected, such as when connected through the means and the second current path, the detection resistor provided in the third current path is necessarily interposed. Become. Therefore, a situation where the positive electrode and the negative electrode of the solar cell are short-circuited does not occur, and a situation where a large current flows through the circuit and the circuit generates excessive heat can be prevented.

  In the ground fault detection device described above, the third current path may be provided with a voltage dividing resistor in series with the detection resistor.

  According to the above configuration, since the voltage dividing resistor is provided in series with the detection resistor in the third energization path, the voltage generated at both ends of the detection resistor can be divided by the voltage dividing resistor and reduced. Thereby, the measurement means which acquires the voltage which generate | occur | produces at the both ends of detection resistance, and measures the resistance value of the ground fault of a solar cell can be comprised with a microcomputer, and can promote size reduction of an apparatus.

  Further, since the voltage dividing resistor is also provided in the third energization path in series with the detection resistor, the first and second switching means are switched to acquire a voltage necessary for measuring the resistance value of the ground fault. Commonly used in cases. Therefore, it is possible to eliminate the occurrence of ground fault resistance measurement errors due to differences in resistance values and temperature coefficients during the production of voltage divider resistors, and to maintain a highly accurate measurement function for ground fault resistance values. it can.

  The ground fault detection device includes a change value detection unit that detects a value that affects the power generation amount of the solar cell or a change value that is a power generation amount of the solar cell, and the measurement unit has the change value that is the solar power generation amount. It is good also as a structure which performs the said measurement operation | movement, when it exists in the range of the measurable value smaller than the value equivalent to the maximum electric power generation amount of a battery.

  According to the above configuration, the change value detecting means changes a value that affects the power generation amount of the solar cell, for example, the time (early morning or evening time), the amount of sunlight at the position of the solar cell, or the power generation amount of the solar cell itself. Detect as value. The measurement means performs a measurement operation on the ground fault of the solar cell when the detected change value is within a measurable value range that is smaller than a value corresponding to the maximum power generation amount of the solar cell.

  As a result, the breakdown voltage (power resistance) required for the components of the ground fault detection device is reduced, and a small and inexpensive device such as a relay constituting the first and second switching means can be used, and the device is small and inexpensive. It can be set as a simple structure.

  In the above-described ground fault detection device, the solar cell is a solar cell string having a plurality of solar cell modules connected in series, and the measuring unit includes a first switching unit on one end side of the third current path. The first voltage generated at both ends of the detection resistor in a state where the connection is switched to the first current path, and the second switching unit is switched the connection on the other end side of the third current path to the ground current path. And the first switching means switches the connection on one end side of the third energizing path to the ground energizing path, and the second switching means switches the connection on the other end side of the third energizing path to the second energizing path. It is good also as a structure which acquires the 2nd voltage which arose in the both ends of the said detection resistance in the state switched to, and calculates | requires the position of a ground fault from the ratio of the absolute value of these 1st voltages, and the absolute value of 2nd voltage .

  According to said structure, in addition to the resistance value of a ground fault, a ground fault position can be measured.

  Further, the ground fault detection method of the present invention is a ground fault detection method comprising a measuring step of measuring a resistance value of a ground fault of a solar cell by acquiring a voltage generated at both ends of a detection resistor, wherein the detection resistor is one end. A first energizing path that is connected between one end of a third energizing path provided between the side and the other end side between a grounded energizing path that is grounded and a first energizing path that is connected to the positive electrode of the solar cell. A switching step and a second switching step for switching the connection on the other end side of the third energization path between the ground energization path and the second energization path connected to the negative electrode of the solar cell. It is characterized by.

  According to said structure, there exists an effect similar to the said ground fault detection apparatus.

  According to the structure of this invention, the ground fault resistance of a solar cell can be calculated | required safely and with high precision.

It is a schematic circuit diagram which shows the basic composition of the solar power generation system provided with the ground fault detection apparatus of embodiment of this invention. It is a circuit diagram which shows the specific structure of a solar energy power generation system corresponding to the basic composition shown in FIG. FIG. 3 is a circuit diagram showing a state in a case where an interelectrode voltage of a solar cell string used for measurement of a ground fault resistance value is obtained in the photovoltaic power generation system shown in FIG. 2. FIG. 3 is a circuit diagram illustrating a state in which a first voltage used for measurement of ground fault resistance is obtained in the photovoltaic power generation system illustrated in FIG. 2. FIG. 3 is a circuit diagram showing a state in which a second voltage used for measuring a ground fault resistance value is obtained in the photovoltaic power generation system shown in FIG. 2. It is a circuit diagram at the time of rewriting the circuit of the photovoltaic power generation system at the time of calculating | requiring the 1st voltage shown in FIG. 4 to the circuit which paid its attention to the solar cell module, the 1st voltage, and the ground fault position. It is a circuit diagram at the time of rewriting the circuit of the photovoltaic power generation system at the time of calculating | requiring the 2nd voltage shown in FIG. 5 to the circuit which paid its attention to a solar cell module, a 2nd voltage, and a ground fault position. It is a circuit diagram which shows the modification of the ground fault detection apparatus shown in FIG. It is a graph which shows the change of the open circuit voltage and electric power generation amount in the solar cell string of the day when the measurement operation by the ground fault detection apparatus shown in FIG. 2 was performed. It is a flowchart which shows operation | movement of the ground fault detection apparatus in other embodiment of this invention. It is a circuit diagram which shows the structure of the conventional ground fault detection apparatus. FIG. 12 is a circuit diagram showing a state in which the first and second switches are turned on in the ground fault detection device shown in FIG. 11. FIG. 13 is a circuit diagram showing a configuration when a protective resistor is provided in the ground fault detection device shown in FIG. 12.

[Embodiment 1]
(Basic configuration of solar power generation system)
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic circuit diagram showing a basic configuration of a solar power generation system 1 including a ground fault detection device according to an embodiment of the present invention.

  As shown in FIG. 1, the photovoltaic power generation system 1 includes a solar cell string 11, a ground fault detection device 12, and a power conditioning system (hereinafter referred to as PCS) 13. In the solar power generation system 1, the electric power generated by the solar cell string 11 is output to the power energization paths 15 a and 15 b and is supplied to the power transmission network 14 via the PCS 13.

  The ground fault detection device 12 includes a power energization path changeover switch 21, an inspection first energization path (first energization path) 22a, an inspection second energization path (second energization path) 22b, and an inspection first changeover switch (first switching means). ) 23, a second inspection switch (second switching means) 24, a third inspection current path 25, a ground current path 26, a detection resistor R1, and a controller (measuring means) 27.

  The power supply path switching switch 21 switches the connection of the power supply paths 15a and 15b between the PCS 13 side and the inspection first and second power supply paths 22a and 22b side. The inspection first changeover switch 23 is connected to one end of the inspection third energization path 25 and switches the connection of one end of the inspection third energization path 25 between the inspection first energization path 22 a and the ground energization path 26. The inspection second changeover switch 24 is connected to the other end of the inspection third energization path 25, and connects the other end of the inspection third energization path 25 between the inspection second energization path 22 b and the ground energization path 26. Switch. The ground energization path 26 is grounded. The detection resistor R1 is provided between one end and the other end of the inspection third energization path 25.

  The controller 27 controls the switching operation of the power supply path switching switch 21, the inspection first switching switch 23, and the inspection second switching switch 24 to obtain the ground fault resistance value and the ground fault position of the solar cell string 11.

  In this case, the controller 27 causes the power energization path changeover switch 21 to be connected to the inspection first and second energization paths 22a and 22b during the measurement operation of the ground fault detection device 12. The state is switched.

  Further, the controller 27 detects that the inspection first changeover switch 23 is switched to the inspection first energization path 22a and the inspection second changeover switch 24 is switched to the inspection second energization path 22b (corresponding to FIG. 3). A voltage generated at both ends of the resistor R1 is obtained, and an interelectrode voltage Va-Vb that is a voltage between both positive and negative electrodes of the solar cell string 11 is obtained.

  The controller 27 sets the inspection first changeover switch 23 to the inspection first energization path 22a and the inspection second changeover switch 24 to the ground energization path 26 (corresponding to FIG. 4), and detects the detection resistor R1. The first voltage V <b> 1 generated at both ends is acquired. Further, the controller 27 sets the inspection first changeover switch 23 to the ground energization path 26 and the inspection second changeover switch 24 to the inspection second energization path 22b (corresponding to FIG. 5), and detects the detection resistor R1. The second voltage V <b> 2 generated at both ends is acquired. The controller 27 obtains the ground fault resistance value (insulation resistance value) and the ground fault position of the solar cell string 11 based on the acquired inter-electrode voltage Va-Vb and the first and second voltages V1, V2. Details thereof will be described later.

(Specific configuration of solar power generation system)
FIG. 2 is a circuit diagram showing a specific configuration of solar power generation system 1 including ground fault detection device 12 according to the embodiment of the present invention, corresponding to the basic configuration shown in FIG. FIG. 2 shows a state where the power generated by the solar cell string 11 is supplied to the PCS 13 and the ground fault detection device 12 is not performing a measurement operation (power output state).

  As shown in FIG. 2, the solar cell string 11 includes a plurality of solar cell modules 31 connected in series. Each solar cell module 31 includes a plurality of solar cells (not shown) connected in series, and is formed in a panel shape.

  In the inspection third energization path 25, voltage dividing resistors R2 and R3 are provided between the detection resistor R1 and the inspection first changeover switch 23, and between the inspection resistor R1 and the inspection second changeover switch 24, Voltage dividing resistors R4 and R5 are provided. The voltage across the detection resistor R1 is input to the controller 27 via the comparator 33. It is assumed that the resistance value of the detection resistor R1 is lower than the resistance values of the voltage dividing resistors R2 to R5.

  The voltage dividing resistors R <b> 2 to R <b> 5 reduce the first and second voltages V <b> 1 and V <b> 2 generated at both ends of the detection resistor R <b> 1 to reduce the voltage input to the controller 27. As a result, the controller 27 can be configured by a microcomputer, and the ground fault detection device 12 can be miniaturized. Further, the voltage dividing resistors R2 to R5 are present in any of a circuit for obtaining the interelectrode voltage Va-Vb, a circuit for obtaining the first voltage V1, and a circuit for obtaining the second voltage V2. .

  Further, for example, a current sensor 32 that detects the amount of current flowing through the power conduction path 15a is provided in the power conduction path 15a. Therefore, the current sensor 32 detects the generated current of the solar cell string 11. The controller 27 measures the power generation amount (change value) of the solar cell string 11 based on the power generation current detected by the current sensor 32.

(Operation of ground fault detector, measurement of ground fault resistance)
In the above configuration, the operation of the ground fault detection device 12 will be described below.

  FIG. 3 is a circuit diagram showing a state in the case of obtaining the interelectrode voltage Va-Vb in the photovoltaic power generation system 1 shown in FIG. FIG. 4 is a circuit diagram showing a state when the first voltage V1 is obtained in the photovoltaic power generation system 1 shown in FIG. FIG. 5 is a circuit diagram showing a state when the second voltage V2 is obtained in the photovoltaic power generation system 1 shown in FIG.

  In the ground fault detection device 12, when obtaining the inter-electrode voltage Va-Vb, the controller 27 changes the power conduction path switch 21 from the power output state shown in FIG. 2 to the power conduction path 15a, as shown in FIG. It switches so that 15b may be connected with test | inspection 1st and 2nd electricity supply path 22a, 22b. Thereby, the power supply paths 15a and 15b from the solar cell string 11 to the PCS 13 are blocked. In addition, the controller 27 connects the inspection first changeover switch 23 with one end of the inspection third energization path 25 to the inspection first energization path 22 a, and connects the inspection second changeover switch 24 with the other end of the inspection third energization path 25. Is switched to be connected to the inspection second energization path 22b.

  In this state, both positive and negative poles of the solar cell string 11 are connected via the detection resistor R1 and the voltage dividing resistors R2 to R5. Thereby, the voltage according to the resistance value of the detection resistor R1 when the voltage between the positive and negative of the solar cell string 11 is divided by the detection resistor R1 and the voltage dividing resistors R2 to R5 is generated at both ends of the detection resistor R1. This voltage is taken into the controller 27 via the comparator 33, and the controller 27 calculates the interelectrode voltage Va-Vb.

  Next, when obtaining the first voltage V1, as shown in FIG. 4, the controller 27 performs the inspection first in a state where the power conduction paths 15a and 15b are connected to the inspection first and second conduction paths 22a and 22b. The changeover switch 23 is switched so that one end of the inspection third energization path 25 is connected to the inspection first energization path 22a, and the inspection second changeover switch 24 is switched to the ground energization path 26 of the other end of the inspection third energization path 25. Switch to be connected to.

  In this state, the positive electrode (P terminal) of the solar cell string 11 is grounded via the detection resistor R1 and the voltage dividing resistors R2 to R5. Thereby, at both ends of the detection resistor R1, the resistance value of the detection resistor R1 when the voltage between the positive electrode of the solar cell string 11 and the ground potential is divided by the detection resistor R1 and the voltage dividing resistors R2 to R5 is determined. The first voltage V1 is generated. The first voltage V1 is taken into the controller 27 via the comparator 33, and the controller 27 obtains the first voltage V1.

  Next, when obtaining the second voltage V2, as shown in FIG. 5, the controller 27 performs the first inspection in the state where the power conduction paths 15a and 15b are connected to the first and second conduction paths 22a and 22b. The changeover switch 23 is switched so that one end of the inspection third energization path 25 is connected to the ground energization path 26, and the other end of the inspection third energization path 25 is switched to the inspection second energization path 22b. Switch to be connected to.

  In this state, the negative electrode (N terminal) of the solar cell string 11 is grounded via the detection resistor R1 and the voltage dividing resistors R2 to R5. As a result, both ends of the detection resistor R1 correspond to the resistance value of the detection resistor R1 when the voltage between the negative electrode of the solar cell string 11 and the ground potential is divided by the detection resistor R1 and the voltage dividing resistors R2 to R5. A second voltage V2 is generated. The second voltage V2 is taken into the controller 27 via the comparator 33, and the controller 27 obtains the second voltage V2. Note that the order of obtaining the interelectrode voltage Va-Vb, the first voltage V1, and the second voltage V2 is not fixed.

Next, the controller 27 calculates the inter-electrode voltage Va−Vb, the first and second voltages V1, V2 and the total resistance value Rsum (= R1 + R2 + R3 + R4 + R5) of the inspection third conduction path 25 by the following equation:
Rleake = Rsum × | Va−Vb | ÷ | V1−V2 | −Rsum (1)
Obtain the insulation resistance value Rleake.

(Operation of ground fault detection device, detection of ground fault position)
Moreover, the controller 27 calculates | requires the generation | occurrence | production position (ground fault position) of a ground fault from ratio of the absolute value of 1st and 2nd voltage V1, V2. As an example, the solar cell string 11 is obtained by connecting five solar cell modules 31 in series, and the ground fault is the third solar cell modules 31 and 4 when viewed from the P terminal side of the solar power generation system 1. It is assumed that it occurs between the individual solar cell modules 31. Reference numeral 34 denotes a ground fault resistance 34 at the ground fault position.

In this case, when the circuit (see FIG. 4) of the photovoltaic power generation system 1 when the first voltage V1 is obtained is rewritten to a circuit that focuses on the solar cell module 31, the first voltage V1, and the ground fault position, as shown in FIG. become. Similarly, when the circuit (see FIG. 5) of the photovoltaic power generation system 1 when the second voltage V2 is obtained is rewritten to a circuit that focuses on the solar cell module 31, the second voltage V2, and the ground fault position, as shown in FIG. become. Therefore, the ratio between the absolute value of the first voltage V1 and the absolute value of the second voltage V2 is
| V1 |: | V2 | = 3: 2
Thus, the ground fault position can be obtained from this ratio.

  As described above, in the ground fault detection device 12 of the photovoltaic power generation system 1 according to the present embodiment, all of the inspection first and second change-over switches 23 and 24 shown in FIGS. In the pattern, the positive and negative poles of the solar cell string 11 are not short-circuited. That is, even in a switching pattern in which the positive and negative poles of the solar cell string 11 are connected, at least the detection resistor R1 is interposed between the positive and negative poles. Therefore, for example, even when a failure occurs in which the inspection first and second change-over switches 23 and 24 are welded at any one of the switching positions, a large current flows through the circuit of the photovoltaic power generation system 1 and the circuit is An excessive heat generation can be prevented.

  When the ground fault resistance value (insulation resistance value) is obtained, a circuit including the same detection resistor R1 and the same voltage dividing resistors R2 to R5 is used, and the interelectrode voltage Va-Vb and the first and second voltages are used. V1 and V2 are measured. Therefore, it is possible to eliminate the occurrence of measurement errors due to differences in resistance values and temperature coefficients during the individual manufacturing of the detection resistor R1 and the voltage dividing resistors R2 to R5. Thereby, the resistance value of the ground fault resistance 34 can be measured accurately.

  As shown in FIG. 2, when the controller 27 is constituted by a microcomputer, one input port is required for measuring the interelectrode voltage Va-Vb and the first and second voltages V1, V2. Well, the number of ports required for the controller 27 can be reduced.

  Further, since the voltage dividing resistors R2 to R5 are provided in series with the detection resistor R1, when the controller 27 is configured by a microcomputer, the voltage input to the controller 27 can be easily lowered to an appropriate voltage. it can.

  In addition, although this Embodiment showed about the example in which the one solar cell string 11 is connected with respect to PCS13, it is not limited to this. That is, the photovoltaic power generation system 1 may have a configuration in which a plurality of solar cell strings 11 are connected to the PCS 13 and the ground fault detection device 12 is provided for each of the plurality of solar cell strings 11. Alternatively, the solar power generation system 1 may be configured such that only one ground fault detection device 12 is provided for the plurality of solar cell strings 11 and is switched to the plurality of solar cell strings 11. Good.

(Modification)
A modification of the photovoltaic power generation system 1 shown in FIG. 2 is shown in FIG. In the configuration of FIG. 8, a protective resistor R11 is provided between the solar cell string 11 and the inspection first changeover switch 23, and a protective resistor R12 is provided between the solar cell string 11 and the inspection second changeover switch 24. Yes.

  According to said structure, by providing protection resistance R11, R12 in test | inspection 1st and 2nd electricity supply path 22a, 22b, the conductor part of the solar cell string 11 which is in a floating state is made into other electroconductivity. Even when the member is touched, the amount of current flowing between the solar cell string 11 and the conductive member can be suppressed. Thereby, the safety | security of the ground fault detection apparatus 12 can further be improved.

  On the other hand, the protective resistors R11 and R12 are not used in common when the interelectrode voltage Va-Vb and the first and second voltages V1 and V2 are obtained. The error cannot be completely cancelled. However, by setting the resistance values of the protection resistors R11 and R12 to a value smaller than the resistance value of the detection resistor R1, the adverse effect due to the presence of the protection resistors R11 and R12 is suppressed, and the safety of the photovoltaic power generation system 1 is improved. Can increase the sex.

[Embodiment 2]
Another embodiment of the present invention will be described below with reference to the drawings.
In the present embodiment, the ground fault detection device 12 of the photovoltaic power generation system 1 performs a measurement operation (ground fault resistance value and ground fault position) when the power generation amount of the solar cell string 11 is small, such as early morning or evening. Measurement).

  The amount of current generated by the solar cell string 11 changes according to the amount of power generated. Therefore, the controller 27 monitors the power generation amount of the solar cell string 11 based on the power generation current amount detected by the current sensor 32, and the power generation amount is within the range in which the measurement operation of the ground fault detection device 12 is possible (measurement). When it is within the range of possible values, the measurement operation is performed. In addition, the configuration for determining the power generation amount of the solar cell string 11 (configuration for monitoring) is not limited to this, and the power generation amount detected by the current sensor 32 and the voltage between the positive and negative of the solar cell string 11 are determined. May be.

  Moreover, the upper limit of the range of the power generation amount that can be measured by the ground fault detection device 12 can be set, for example, based on the withstand voltage (power resistance) of each part of the ground fault detection device 12, and the lower limit value is, for example, The ground fault resistance value and the ground fault position can be set based on the lower limit value of the power generation amount that allows measurement.

  FIG. 9 is a graph showing changes in the open circuit voltage and the amount of power generation in the solar cell string on the day when the measurement operation is performed by the ground fault detection device 12. Between the sunrise and sunset of the place where the solar cell string 11 is installed, the open-circuit voltage and the power generation amount of the solar cell string 11 change as shown in FIG. 9, for example. In FIG. 9, the range A indicates the operating range of the PCS 13. In addition, the region B is a region included in the measurement operation possible range of the ground fault detection device 12 and exists in, for example, an early morning time zone in which the power generation amount (measurable value) of the solar cell string 11 is small. In the region B, the open circuit voltage of the solar cell string 11 reaches the vicinity of a predetermined maximum voltage. On the other hand, the amount of sunlight (change value) is small due to early morning, and the output current of the solar cell string 11 is a small value.

  FIG. 10 is a flowchart showing the operation of the ground fault detection device 12. As shown in FIG. 10, the controller 27 monitors the power generation amount of the solar cell string 11 based on the power generation current amount detected by the current sensor 32 (S11), and the power generation amount of the solar cell string 11 is grounded. It is determined whether or not the measurement operation of the detection device 12 is within a possible range (S12). This determination is preferably performed after monitoring the power generation amount of the solar cell string 11 for a predetermined time.

  As a result of the determination in S12, if the power generation amount of the solar cell string 11 is within a range where the measurement operation of the ground fault detection device 12 is possible, the controller 27 switches the power conduction path switch 21 to the power conduction paths 15a and 15b. It switches so that it may connect with inspection 1st and 2nd electricity supply ways 22a and 22b (S13). Thereby, the power supply paths 15a and 15b from the solar cell string 11 to the PCS 13 are blocked.

  Thereafter, as described above, the inspection first and second changeover switches 23 and 24 are switched to measure the ground fault resistance value and the ground fault position (S24), and the operation is finished when the measurement is finished.

  In addition, the configuration for detecting when the power generation amount (change value) is small is not limited to monitoring the power generation amount of the solar cell string 11, but the time (change) such as early morning or evening by a clock (for example, a timer provided in the controller 27). (Value) may be referred to. Or the structure which refers to the amount of sunshine (change value) with a sunshine meter may be sufficient. However, in the case of a configuration that refers to the amount of sunshine, the change in the amount of sunshine is monitored for a predetermined time in order to eliminate the case where the amount of sunshine, that is, the amount of power generation decreases due to a temporary change in weather, and the amount of sunlight (power generation amount) It is preferable that the measurement operation is started after confirming that the time period is small.

  Further, the power generation amount, the time, and the amount of sunshine as change values are used to determine whether or not they are within a range in which the measurement operation of the ground fault detection device 12 can be performed (a range of measurable values). Without being limited, when a plurality of change values among the power generation amount (power generation current), time, and amount of sunshine are used, and each of the plurality of change values is within a measurable value range, the ground fault detection device 12 is used. The measurement operation may be performed. In this case, the reliability of the measurement operation of the ground fault detection device 12 can be improved.

  For example, the ground fault detection device 12 is a measurement operation possible time zone in which the power generation amount of the solar cell string 11 is within a measurable value range and the time is set as a time zone in which the power generation amount is relatively small. In addition, a measurement operation may be performed. In this case, for example, the measurement operation of the ground fault detection device 12 is started when the power generation amount of the solar cell string 11 is reduced due to a sudden deterioration of weather in a time zone in which the solar cell string 11 generates a large amount of power. After that, the weather suddenly recovers and the power generation amount of the solar cell string 11 increases, so that it is possible to prevent a situation in which the operation of the ground fault detection device 12 is hindered. Thereby, the reliability of the ground fault detection apparatus 12 can be improved.

  Alternatively, the ground fault detection device 12 includes a sunshine meter that detects the amount of sunshine at the position of the solar cell string 11, the amount of power generation is within a measurable value range, and the amount of sunshine is equal to or less than a predetermined amount. A measurement operation may be performed. In this case, for example, a part of the solar cell string 11 is covered with some coating in a time zone where the power generation amount of the solar cell string 11 is large (a state in which the amount of sunlight is large). When the power generation amount of 11 decreases, the measurement operation of the ground fault detection device 12 is performed, and a situation in which an inappropriate measurement result is obtained can be prevented.

  In addition, the covering is removed during the measurement operation of the ground fault detection device 12 and the power generation amount of the solar cell string 11 is increased, thereby preventing a situation that hinders the operation of the ground fault detection device 12. be able to. Thereby, the reliability of the ground fault detection apparatus 12 can be improved.

  As described above, since the ground fault detection device 12 performs the measurement operation for the ground fault in the time zone when the power generation amount of the solar cell string 11 is small, the breakdown voltage required for the components of the ground fault detection device 12 is reduced. Can do. Accordingly, for example, small and inexpensive parts such as the inspection first and second change-over switches 23 and 24 made of a relay can be used, and the apparatus can be configured to be small and inexpensive.

  The ground fault detection device 12 is configured to measure the ground fault resistance value of the solar cell string 11 when the power generation amount of the solar cell string 11 is small. Therefore, the situation where the power generation amount of the solar cell string 11 is reduced by the operation of the ground fault detection device 12 can be suppressed. About another function, it is the same as that of the case of the above-mentioned ground fault detection apparatus.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  INDUSTRIAL APPLICABILITY The present invention can be used as an apparatus for detecting a ground fault resistance value and a ground fault position of a photovoltaic power generation system including a photovoltaic string configured by connecting a plurality of photovoltaic modules in series, for example.

DESCRIPTION OF SYMBOLS 1 Solar power generation system 11 Solar cell string 12 Ground fault detection apparatus 13 Power conditioning system 14 Electric power transmission network 15a Electric power supply path 15b Electric power supply path 21 Electric power supply path changeover switch 22a Inspection 1st electric current path 22b Inspection 2nd electric current path 23 Inspection 1st changeover switch 24 inspection 2nd changeover switch 25 inspection 3rd energization path 26 grounding energization path 27
31 Solar cell module 32 Current sensor 34 Ground fault resistance

Claims (5)

In the ground fault detection device comprising a detection resistor and a measurement unit, the measurement unit acquires a voltage generated at both ends of the detection resistor and performs a measurement operation of the resistance value of the ground fault of the solar cell.
A first current path connected to the positive electrode of the solar cell;
A second current path connected to the negative electrode of the solar cell;
A third energization path in which the detection resistor is provided between one end side and the other end side;
First switching means for switching the connection of one end of the third current path between a grounded current path and the first current path;
A ground fault detection device comprising: second switching means for switching the connection on the other end side of the third energization path between the ground energization path and the second energization path.   The ground fault detection device according to claim 1, wherein a voltage dividing resistor is provided in series with the detection resistor in the third current path. A change value detecting means for detecting a value that affects the power generation amount of the solar cell or a change value that is the power generation amount of the solar cell;
3. The measurement unit according to claim 1, wherein the measurement unit performs the measurement operation when the change value is within a measurable value range that is smaller than a value corresponding to the maximum power generation amount of the solar cell. The ground fault detection apparatus of description. The solar cell is a solar cell string having a plurality of solar cell modules connected in series,
In the measuring means, the first switching means switches the connection on one end side of the third energizing path to the first energizing path, and the second switching means connects the connection on the other end side of the third energizing path to the first energizing path. The first voltage generated at both ends of the detection resistor in the state switched to the ground current path, and the first switching means switch the connection on one end side of the third current path to the ground current path, and the second switch The means acquires the second voltage generated at both ends of the detection resistor in a state where the connection on the other end side of the third current path is switched to the second current path, and obtains the absolute value of the first voltage and the first voltage The ground fault detection device according to any one of claims 1 to 3, wherein the position of the ground fault is obtained from a ratio with the absolute value of the two voltages. In the ground fault detection method comprising a measuring step of acquiring the voltage generated at both ends of the detection resistor and measuring the resistance value of the ground fault of the solar cell,
The detection resistor is provided between the one end side and the other end side of the third energization path. The ground energization path is connected to one end of the third energization path, and the first energization path is connected to the positive electrode of the solar cell. A first switching step for switching between,
And a second switching step of switching the connection on the other end side of the third current path between the ground current path and the second current path connected to the negative electrode of the solar cell. Ground fault detection method.

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