JP6709743B2 - Power converter and control method thereof - Google Patents

Description

The present invention relates to a power conversion device and a control method thereof.

Solar cells have a larger capacitance to ground than other devices. Therefore, the circuit breaker provided between the solar cell and the commercial power system may operate when it should not be operated due to the ground capacitance of the solar cell (hereinafter referred to as "unnecessary operation"). There is.

For example, when the ground capacitance is present, a ground fault current that flows to the ground via the ground capacitance is generated. When a large ground fault current (rush current) is temporarily generated due to the large ground capacitance of the solar cell, a large current flows into the circuit breaker connected to the commercial power system, causing the circuit breaker to operate unnecessarily. It may end up.

Therefore, methods for preventing unnecessary operation of the circuit breaker due to a ground fault current have been disclosed (Patent Documents 1 and 2). In Patent Document 1, when the ground fault current is detected, the unnecessary current of the circuit breaker is prevented by blocking the current flowing into the circuit breaker. Further, in Patent Document 2, when the ground fault current is detected, the unnecessary current of the circuit breaker is prevented by reducing the current flowing into the circuit breaker.

JP 2001-161032 A JP, 2002-252986, A

By the way, the circuit breaker may operate unnecessarily due to improper setting of the circuit breaker. For example, the circuit breaker operates based on the set sensitivity current value. If the setting of the sensitivity current value is inappropriate for the combined solar cell, the circuit breaker may operate unnecessarily.

Here, in Patent Documents 1 and 2, when the ground fault current occurs, that is, when the phenomenon causing the unnecessary operation of the circuit breaker occurs, a predetermined process is executed to prevent the unnecessary operation of the circuit breaker. To be done. In order to further reduce the occurrence of unnecessary circuit breaker operation, it is desirable to determine whether or not the circuit breaker settings are appropriate before the phenomenon that causes unnecessary circuit breaker operation occurs, that is, in advance. Be done.

An object of the present disclosure made in view of the above point is to provide a power conversion device that further reduces the occurrence of unnecessary operation of a circuit breaker.

An electric power converter according to an embodiment of the present disclosure is an electric power converter that converts DC power generated by a solar cell including a plurality of power generation modules into AC power. The power conversion device includes an acquisition unit that acquires the ground fault current value or format of the solar cell, and a control unit. The control unit acquires, as the minimum sensitivity current value, the sensitivity current value of the circuit breaker having the smallest sensitivity current value among the plurality of circuit breakers provided between the power conversion device and the commercial power system. , Get known information. The known information includes a combination of a known ground fault current value or format of each power generation module in a plurality of types of power generation modules and a known value of the inrush current caused by the ground capacitance of each power generation module. Further, the control unit calculates a predicted value of the inrush current generated due to the ground capacitance of the solar cell based on the ground fault current value or format of the solar cell and the known information. In addition, the control unit determines whether the calculated predicted value is larger than a determination threshold based on the minimum sensitivity current value. The control unit determines whether or not the circuit breaker for which the smallest sensitivity current value is set may operate unnecessarily.

A control method for a power converter according to an embodiment of the present disclosure is a control method for a power converter that converts DC power generated by a solar cell including a plurality of power generation modules into AC power. The control method of the power conversion device includes a step of acquiring a ground fault current value or a format of the solar cell, and a plurality of circuit breakers provided between the power conversion device and a commercial power system , which has the smallest sensitivity current. Acquiring the sensitivity current value of the circuit breaker for which the value has been set as the minimum sensitivity current value . Furthermore, the control method of the power converter includes a known ground fault current value or format of each power generation module in a plurality of types of power generation modules and a known value of the inrush current resulting from the ground capacitance of each power generation module. The step of acquiring known information including the combination is included. In addition, the control method of the power converter calculates the predicted value of the inrush current generated due to the ground capacitance of the solar cell based on the ground fault current value or format of the solar cell and the known information. Including the step of performing. In addition, the control method of the power converter includes a step of determining whether the calculated predicted value is larger than a determination threshold based on the minimum sensitivity current value, and a cutoff in which the smallest sensitivity current value is set. Determining whether there is a possibility that the device will perform unnecessary operation .

The power conversion device according to the embodiment of the present disclosure can further reduce the occurrence of unnecessary operation of the circuit breaker.

1 is a functional block diagram showing a schematic configuration of a power conversion system according to a first embodiment of the present disclosure. It is a functional block diagram which shows schematic structure of the distribution board shown in FIG. 5 is a table showing known information according to the first embodiment of the present disclosure. 3 is a flowchart showing an example of the operation of the power conversion device according to the first embodiment of the present disclosure. It is a figure which shows a mode when an inrush current generate|occur|produces in the power conversion system shown in FIG. It is a functional block diagram which shows the schematic structure of the distribution board which concerns on the modification 1. 9 is a table showing known information according to the second embodiment of the present disclosure. 9 is a first flowchart showing an example of operation of the power conversion device according to the second embodiment of the present disclosure. 9 is a second flowchart showing an example of the operation of the power conversion device according to the second embodiment of the present disclosure.

Hereinafter, embodiments according to the present disclosure will be described with reference to the drawings.

(First embodiment)
A power conversion system 1 including the power conversion device 30 according to the first embodiment of the present disclosure will be described with reference to FIG. 1. The power conversion system 1 is provided in a customer facility. The power conversion system 1 is connected to the commercial power system 2 and supplies power to the load device 3 installed in the customer facility. The power conversion system 1 includes a solar cell 10, a storage battery 11, a distribution board 20, and a power conversion device 30. The power conversion system 1 according to the present embodiment includes one solar cell 10 and one storage battery 11, but is not limited to this. The number of solar cells and the number of power storage devices included in the power conversion system 1 may be two or more.

In addition, in FIG. 1, solid lines connecting the respective functional blocks indicate the flow of electric power. In addition, in FIG. 1, a broken line connecting the functional blocks indicates a flow of control signals or information to be communicated. The communication indicated by the broken line may be wired communication or wireless communication.

The solar cell 10 includes a plurality of power generation modules. The solar cell 10 uses a plurality of power generation modules to generate DC power from the energy of sunlight. The solar cell 10 supplies the generated DC power to the power conversion device 30.

Further, the solar cell 10 has a ground capacitance C1. The electrode of the ground capacitance C1 is, for example, a power generation cell and a frame of the power generation module. The dielectric of the ground capacitance C1 is, for example, a sealing material that seals the power generation cell and the frame and a glass panel. The capacitance value of the ground capacitance C1 varies depending on the type of the power generation cell (for example, crystalline silicon, CIS compound semiconductor), the laminated structure of the power generation module, the material such as the sealing material used in the power generation module, and the like. In other words, the capacitance value of the ground capacitance C1 changes depending on the type of the power generation module included in the solar cell 10. For example, the value of the ground capacitance of a solar cell using a CIS compound semiconductor is often larger than the value of the ground capacitance of a solar cell using crystalline silicon.

In the power conversion system 1, a ground fault current is generated by the ground capacitance C1. Furthermore, in the power conversion system 1, an inrush current flowing from the commercial power system 2 into the power conversion device 30 is generated due to the ground capacitance C1. The inrush current is generated, for example, by temporarily flowing a large current from the commercial power system 2 to the ground electrostatic capacitance C1 when the ground electrostatic capacitance C1 is not charged. Here, both the ground fault current and the inrush current are generated due to the ground capacitance C1. Therefore, both the ground fault current value and the inrush current value depend on the capacitance value of the ground capacitance C1. As described above, the capacitance value of the ground capacitance C1 changes depending on the type of the power generation module included in the solar cell 10. Therefore, the ground fault current value and the inrush current value also change depending on the type of the power generation module included in the solar cell 10.

The storage battery 11 includes a lithium ion battery, a nickel hydrogen battery, and the like. The storage battery 11 supplies DC power to the power conversion device 30 by discharging the charged power. Further, the storage battery 11 is charged with electric power from the commercial power system 2 and the solar battery 10.

The distribution board 20 is provided between the power conversion device 30 and the commercial power system 2. The distribution board 20 distributes the power supplied from the power conversion device 30 and the power supplied from the commercial power system 2 to the load device 3.

Further, the distribution board 20 includes circuit breakers 21 and 22 as shown in FIG. The circuit breakers 21 and 22 operate based on the sensitivity current value set for each. In the present embodiment, the sensitivity current value of the circuit breaker 21 will be described as being smaller than the sensitivity current value of the circuit breaker 22 .

The circuit breaker 21 is, for example, a main power breaker using an earth leakage breaker. The circuit breaker 21 is provided between the load device 3 and the commercial power system 2. In the present embodiment, the circuit breaker 21 is provided between the power conversion device 30 and the load device 3 and the commercial power system 2.

When the circuit breaker 21 detects a current value larger than the sensitivity current value, the circuit breaker 21 disconnects the commercial power system 2 from the load device 3 and the power conversion device 30. The sensitivity current value of the circuit breaker 21 is set based on, for example, the type of the load device 3 and the total capacity of the load device 3. The selection of the circuit breaker 21 or the setting of the changeover switch of the sensitivity current value is performed by the contractor when the circuit breaker 21 is installed, for example.

The circuit breaker 22 is, for example, a breaker for photovoltaic power generation. The circuit breaker 22 is provided between the solar cell 10 and the commercial power system 2. In the present embodiment, the circuit breaker 22 is provided between the power conversion device 30 and the commercial power system 2 and the load device 3.

When the breaker 22 detects a current value larger than the sensitivity current value, the breaker 22 disconnects the commercial power system 2 and the load device 3 from the power conversion device 30. The sensitivity current value of the circuit breaker 22 is set based on, for example, the type of the solar cell 10. The selection of the circuit breaker 22 or the setting of the changeover switch of the sensitivity current value is performed by the contractor when the solar cell 10 is installed.

In FIG. 1, the power converter 30 converts the DC power generated by the solar cell 10 and the DC power discharged by the storage battery 11 into AC power. The power conversion device 30 is a so-called multi-DC link type. The power conversion device 30 includes DC power conversion units 31A and 31B, an orthogonal conversion unit 32, a filter unit 33, a grid interconnection switch 34, an acquisition unit 35, a communication unit 36, a display unit 37, and a storage unit. 38 and a control unit 39. The output of the power conversion device 30 according to the present embodiment is a single-phase three-wire system, but the output format of the power conversion device is not limited to this, and for example, a single-phase two-wire system or a three-phase system is also possible. Good.

The DC power transformers 31A and 31B are, for example, DC/DC converters. The DC power transformer 31A adjusts the voltage of the DC power supplied from the solar cell 10. The DC power transformer 31B adjusts the voltage of the DC power supplied from the storage battery 11. Further, the DC power transformation unit 31B adjusts the voltage of the DC power supplied from the DC power transformation unit 31A or the orthogonal transformation unit 32 when the storage battery 11 is charged.

The orthogonal transformation unit 32 is, for example, an inverter. The orthogonal converter 32 converts the DC power supplied from the DC power transformers 31A and 31B into AC power. Further, the orthogonal conversion unit 32 converts the AC power supplied from the commercial power grid 2 into DC power when the storage battery 11 is charged.

The filter unit 33 includes coils L1 and L2 and capacitors C2 and C3. The filter unit 33 reduces noise in the AC power output from the orthogonal transform unit 32.

The system interconnection switch 34 is provided between the filter unit 33 and the acquisition unit 35. The system interconnection switch 34 switches on/off under the control of the control unit 39. The grid interconnection switch 34 is turned on during grid interconnection of the power conversion device 30. The grid interconnection switch 34 is turned off when the power converter 30 is disconnected from the grid.

The acquisition unit 35 acquires the ground fault current value of the solar cell 10. For example, the acquisition unit 35 is a current sensor that detects an actual measurement value of the ground fault current value by measurement. In the present embodiment, the acquisition unit 35 is more specifically configured with a split-type clamp sensor that can be attached after installing the electric wire.

The acquisition unit 35 may be provided between the output sides of the DC power transformation units 31A and 31B, in other words, the downstream side of the circuit breaker 22 of the distribution board 20. In the present embodiment, the acquisition unit 35 is provided between the grid interconnection switch 34 and the distribution board 20.

An electric wire extending from the system interconnection switch 34 to the distribution board 20 is inserted into the acquisition unit 35. In this embodiment, U-phase, O-phase, and W-phase electric wires extending from the grid interconnection switch 34 to the distribution board 20 are inserted. Further, in the case of the two-wire type such as between the DC power transformation unit 31A and the orthogonal conversion unit 32, the forward and backward electric wires of the current are inserted into the acquisition unit 35.

The acquisition unit 35 measures the ground-fault current value of the solar cell 10 from the difference current flowing through the inserted wires. The acquisition unit 35 notifies the control unit 39 of the ground fault current value as a signal. Since the current value measured by the clamp sensor is in the form of voltage value, it is converted into a current value in the control unit 39. Examples of methods for measuring the ground fault current include a zero-phase current monitoring method, a resistance voltage dividing midpoint grounding method, and an AC signal injection method. In this embodiment, it is assumed that the ground fault current value is measured from the difference in current value by the zero-phase current monitoring method.

The communication unit 36 communicates with other devices via the network. For example, the communication unit 36 communicates with the server of the manufacturer of the solar cell 10 via the network.

The display unit 37 displays various information regarding the power conversion device 30 based on the signal acquired from the control unit 39. For example, the display part 37 will display a warning screen, if a warning signal is acquired from the control part 39. Further, for example, when the display unit 37 acquires a predetermined signal from the control unit 39, the display unit 37 displays an input reception screen for causing the power conversion device 30 to execute each function.

The display unit 37 also has a touch panel formed of a transparent member, and also functions as an interface that receives a user operation.

The storage unit 38 stores a program in which information necessary for the processing of the power conversion device 30 and processing contents for realizing each function of the power conversion device 30 are described. For example, the storage unit 38 stores the sensitivity current values of the circuit breakers 21 and 22, known information, the ground fault current value of the solar cell 10, and the like. The known information will be described later.

The control unit 39 controls and manages the entire power conversion device 30. The control unit 39 is configured by any suitable processor such as a general-purpose CPU (central processing unit) that reads software for executing processing of each function. Alternatively, the control unit 39 may be configured by, for example, a dedicated processor specialized for processing each function.

The control unit 39 according to the present embodiment determines whether or not the circuit breaker may perform an unnecessary operation due to an inrush current generated due to the ground capacitance C1 of the solar cell 10. The determination process will be described below. The control unit 39 may automatically execute the determination process, for example, once a month. Alternatively, the control unit 39 may execute this determination process when, for example, an execution request for this determination process is acquired from the display unit 37. The execution request for the determination process may be input from the display unit 37 by a contractor who installs the solar cell 10, for example.

The control unit 39 acquires at least the minimum sensitivity current value among the circuit breakers 21 and 22 provided between the power conversion device 30 and the commercial power system 2. In the present embodiment, the control unit 39 acquires the sensitivity current value of the circuit breaker 21 as the minimum sensitivity current value. The control unit 39 may acquire the sensitivity current value of the circuit breaker 21 from the storage unit 38 in which the sensitivity current value is stored in advance. Alternatively, the control unit 39 may acquire the sensitivity current value of the circuit breaker 21 from the display unit 37, for example, when the contractor inputs the sensitivity current value of the circuit breakers 21 and 22 from the display unit 37. When obtaining the minimum sensitivity current value, it is not necessary to consider the individual difference in each circuit breaker.

The control unit 39 acquires known information. The known information includes each combination of a known ground fault current value of each power generation module in a plurality of types of power generation modules and a known value of the inrush current caused by the ground capacitance of each power generation module. Further, the known information may include the type of each power generation module. The control unit 39 acquires known information from, for example, the storage unit 38 in which known information is stored in advance. Alternatively, the control unit 39 may acquire known information from a server of a business operator such as a power generation module manufacturing company on the network via the communication unit 36.

FIG. 3 shows known information according to the first embodiment of the present disclosure. The plurality of types of power generation modules are, for example, power generation module A to power generation module E. The solar cell 10 has one or more solar cell strings in which a predetermined number of power generation modules are connected in series or in parallel. Further, the solar cell string is configured by connecting power generation modules of the same type. Further, in the present embodiment, the known ground fault current value is caused by the ground capacitance of each of the power generation module A and the power generation module E when the power generation module A generates power at the rated voltage value. This is the ground fault current value that occurs. In addition, in this embodiment, the known values of the ground fault current value and the known inrush current are values per one sheet of the power generation module A to the power generation module E.

The known ground fault current value of the power generation module A is 0.30 [mA], and the known value of the inrush current due to the ground capacitance of the power generation module A is 0.70 [mA]. The model of the power generation module A is “ΔΔ01”.

The known ground fault current value of the power generation module B is 0.50 [mA], and the known value of the inrush current due to the ground capacitance of the power generation module B is 1.20 [mA]. The model of the power generation module B is “ΔΔ02”.

The known ground fault current value of the power generation module C is 0.70 [mA], and the known value of the inrush current due to the ground capacitance of the power generation module C is 1.50 [mA]. The model of the power generation module C is "☆☆21".

The known ground fault current value of the power generation module D is 0.10 [mA], and the known value of the inrush current due to the ground capacitance of the power generation module D is 0.20 [mA]. The model of the power generation module D is "□□30".

The known ground fault current value of the power generation module E is 0.13 [mA], and the known value of the inrush current due to the ground capacitance of the power generation module E is 0.25 [mA]. The model of the power generation module E is "□□60".

In the present embodiment, the known ground fault current values are based on the rated voltage values of the power generation modules A to E, respectively, but the present invention is not limited to this. For example, the known ground fault current value may be a value when each of the power generation module A to the power generation module E is generating power at an arbitrary voltage value (different from the rated voltage value). Further, in the present embodiment, the known ground-fault current value is a value for each sheet of the power generation module A to the power generation module E, but is not limited to this. For example, each known ground fault current value may be a value per solar cell string in which a predetermined number of power generation modules A to E are connected.

The control unit 39 acquires the ground-fault current value of the solar cell 10 measured by the acquisition unit 35 when the electric charge is sufficiently accumulated in the ground capacitance C1. For example, the control unit 39 acquires the ground fault current value of the solar cell 10 measured by the acquisition unit 35 while the solar cell 10 is generating power. Furthermore, when the solar cell 10 is generating power, the generated voltage of the solar cell 10 may be stable.

In the present embodiment, the control unit 39 acquires the ground fault current value of the solar cell 10 generated when the solar cell 10 is generating power at the rated voltage value. When the known ground fault current value is a value when the power generation module A is generating power at a voltage value (different from the rated voltage value) from the power generation module A, the control unit 39 causes the solar cell 10 to operate. A ground fault current value of the solar cell 10 that occurs during power generation with a voltage value is acquired.

The control unit 39 calculates the predicted value of the inrush current generated due to the ground capacitance C1 based on the acquired ground fault current value of the solar cell 10 and the known information. An example of calculating the predicted value of the inrush current will be described in <Calculation example 1 of the predicted value of the inrush current> below.

The control unit 39 determines whether the predicted value of the inrush current is larger than the determination threshold value. The determination threshold value is a value based on the minimum sensitivity current value of the at least one circuit breaker 21, 22 acquired by the control unit 39. The determination threshold may be, for example, a value smaller than the minimum sensitivity current value (sensitivity current value of the circuit breaker 21) by the first predetermined value. The first predetermined value includes, for example, a ground fault current value of another device (power conversion device 30 and load device 3) provided between the solar cell 10 and the circuit breaker 21. Alternatively, the determination threshold may be, for example, a predetermined ratio (for example, 2/3) of the sensitivity current value of the circuit breaker 21.

When it is determined that the predicted value of the inrush current is larger than the determination threshold value, the control unit 39 generates a warning signal. The control unit 39 may transmit the generated warning signal to the display unit 37 of the power conversion device 30 or may transmit it to the server of the construction company on the network via the communication unit 36.

For example, when the determination process is regularly executed, the control unit 39 may generate a warning signal for displaying a warning screen for the user on the display unit 37 and transmit the warning signal to the display unit 37. The warning screen for the user includes, for example, a warning for the user that "the breaker specifications may be inappropriate. Please contact us." In addition, the control unit 39 may generate a warning signal for the construction company and transmit it to the server of the construction company on the network via the communication unit 36.

Further, for example, when the determination process is executed based on the input of the execution request to the display unit 37, the control unit 39 generates and displays a warning signal for displaying a warning screen for the contractor on the display unit 37. It may be transmitted to the section 37. The warning screen for the installer includes, for example, a specific cause such as "the ground current value may exceed the breaker's sensitivity current value."

<Calculation Example 1 of Inrush Current Prediction Value>
The control unit 39 subtracts the ground fault current value of the power conversion device 30 from the ground fault current value of the solar cell 10 to calculate the subtracted value. As the ground fault current value of the power conversion device 30, a value defined as the specification of the power conversion device 30 may be used. At this time, the control unit 39 may acquire the ground fault current value of the power conversion device 30 from the storage unit 38 stored in advance. Alternatively, the control unit 39 may acquire the ground fault current value of the power conversion device 30 from the server of the manufacturer of the power conversion device 30 on the network via the communication unit 36.

Note that the control unit 39 subtracts the ground fault current value of the power conversion device 30 from the ground fault current value of the solar cell 10 and then further subtracts the ground fault current value of the load device 3 to calculate the subtracted value. Good. When the load device 3 includes an electric device such as a washing machine that is grounded and used, a ground fault current is also generated in the load device 3. When the minimum sensitivity current value is the circuit breaker 22, the ground fault current value of the load device 3 need not be considered.

The control unit 39 calculates the divided current value by dividing the calculated subtraction value by the number of power generation modules included in the solar cell 10. The control unit 39 may acquire the number of power generation modules included in the solar cell 10 from the storage unit 38 that is stored in advance or from the display unit 37. For example, when the contractor inputs the number of power generation modules from the display unit 37, the control unit 39 acquires from the display unit 37 the number of power generation modules included in the solar cell 10.

The control unit 39 selects, from the known information, the known value of the inrush current combined with the known ground fault current value that is the closest value to the division current value. For example, when the division current value is 0.65 [mA], in the known information, the known ground fault current value closest to the division current value is the ground fault current value 0.7 [mA] of the power generation module C. Is. At this time, the control unit 39 selects the known value of 1.5 [mA] of the inrush current of the power generation module C.

Note that the control unit 39 may generate a warning signal when it is determined that the divided current value is larger than each known ground fault current value included in the known information by the second predetermined value or more. The second predetermined value can be set based on, for example, a measurement error of the acquisition unit 35 or a known standard error of the ground fault current value.

The control unit 39 calculates the predicted value of the inrush current by multiplying the known value of the selected inrush current by the number of power generation modules included in the solar cell 10. After the multiplication, the control unit 39 may add the ground fault current value of the power conversion device 30 to calculate the predicted value of the inrush current. Alternatively, after the multiplication, the control unit 39 may add the ground fault current value of the power conversion device 30 and the ground fault current value of the load device 3 to calculate the predicted value of the inrush current.

[System operation]
Hereinafter, an example of the operation of the power conversion device 30 according to the first embodiment of the present disclosure will be described with reference to FIG. 4. The control unit 39 starts the determination process when acquiring the execution request for the determination process from the display unit 37. The execution request for the determination process is generally input from the display unit 37 by the contractor after the installation of the solar cell 10 is completed and the grid interconnection switch 34 is turned off. Further, the control unit 39 ends the determination process when the power conversion device 30 is turned off after the start of the determination process.

The control unit 39 acquires, for example, the sensitivity current value of the circuit breaker 22 as the minimum sensitivity current value from the display unit 37, and acquires known information from, for example, the storage unit 38 (step S101). The control unit 39 determines whether the solar cell 10 is generating power (step S102). When the control unit 39 determines that the solar cell 10 is generating power (step S102: Yes), the control unit 39 proceeds to the process of step S103. On the other hand, when the control unit 39 determines that the solar cell 10 is not generating power (step S102: No), the process of step S102 is repeated until the solar cell 10 starts power generation.

In the process of step S103, the control unit 39 turns on the grid interconnection switch 34.

Through the processes of steps S102 and S103, the grid interconnection switch 34 is turned on while the solar cell 10 is generating power. In other words, by the processing of steps S102 and S103, the system interconnection switch 34 is kept off when no electric charge is stored in the ground capacitance C1. As a result, in the present embodiment, it is possible to prevent an inrush current from being generated and the circuit breaker performing an unnecessary operation before the determination process is completed.

In the process of step S104, the control unit 39 acquires the ground fault current value of the solar cell 10 measured by the acquisition unit 35. In the process of step S105, the control unit 39 calculates the predicted value of the inrush current based on the ground fault current value of the solar cell 10 measured by the acquisition unit 35 and the known information acquired in the process of step S101.

In the process of step S106, the control unit 39 determines whether the predicted value of the inrush current is larger than the determination threshold value. When determining that the predicted value of the inrush current is larger than the determination threshold value (step S106: Yes), the control unit 39 proceeds to the process of step S107. On the other hand, when the control unit 39 determines that the predicted value of the inrush current is smaller than the determination threshold value (step S106: No), the process proceeds to step S108.

In the process of step S107, the control unit 39 generates a warning signal. After the elapse of a certain time (step S108), the control unit 39 performs the process of step S109 similarly to the process of step S102. When the control unit 39 determines that the solar cell 10 is generating power (step S109: Yes), the process proceeds to step S104. On the other hand, when the control unit 39 determines that the solar cell 10 is not generating power (step S109: No), the process of step S109 is repeated until the solar cell 10 starts power generation.

As described above, in the power conversion device 30 according to the first embodiment, the predicted value of the inrush current is calculated based on the ground fault current value measured by the acquisition unit 35 and the known information of the plurality of types of power generation modules. Further, in the present embodiment, it is determined whether the calculated predicted value of the inrush current is larger than the determination threshold value. As described above, in the present embodiment, it is possible to determine whether or not the setting of the circuit breaker 21 is appropriate before the inrush current is generated, that is, in advance.

Here, the setting of the circuit breaker 21 may be inappropriate. For example, a contractor may mistakenly set the sensitivity current value of the circuit breaker 21 due to an input error. Further, for example, the contractor may erroneously select the specifications of the circuit breaker 21. Even when the setting or the like of the circuit breaker 21 is inappropriate as described above, the power converter 30 according to the present embodiment allows the installer or the like to correct the setting or the like of the circuit breaker 21 in advance. Therefore, according to the power conversion device 30 according to the present embodiment, it is possible to further reduce the occurrence of unnecessary operation of the circuit breaker 21.

Further, according to the power conversion device 30 according to the first embodiment, the control unit 39 can acquire known information from the server of the manufacturer of the power generation module on the network via the communication unit 36. As a result, in this embodiment, the latest known information can be acquired. Furthermore, more known combinations of ground fault current values and known values of inrush current can be obtained.

In addition, according to the power conversion device 30 according to the present embodiment, it is possible to prevent a situation that may occur due to unnecessary operation of the circuit breaker 21 as described in <Situation that may occur due to unnecessary operation> below.

<Situations that can occur due to unnecessary operations>
Hereinafter, a situation that may occur due to an unnecessary operation of the circuit breaker 21 will be described. First, generation of an inrush current will be described with reference to FIG.

The inrush current is generated when the system interconnection switch 34 is turned from OFF to ON when electric charges are not stored in the ground capacitance C1.

For example, during the daytime when the solar cell 10 is generating power, the amount of charge of the ground capacitance C1 is kept constant by the generated current of the solar cell 10, so the grid interconnection switch 34 is turned on. Even if it does, inrush current does not occur, and only a fixed amount of ground fault current continues to flow. Further, for example, even during the nighttime when the solar cell 10 stops generating power, if the grid interconnection switch 34 is turned on, the charge amount of the electrostatic capacitance C1 from the ground is from the commercial power grid 2. Inrush current does not occur because it is kept constant by the current. However, during the nighttime when the solar cell 10 stops generating electricity, when a power failure occurs in the commercial power system 2 and the grid interconnection switch 34 is turned off, the current from the commercial power system 2 to the ground capacitance C1 is reduced. After that, the charge amount of the electrostatic capacitance C1 to ground is reduced. In addition, if the time during which the commercial power system 2 is out of power, that is, the time during which the system interconnection switch 34 is off is increased to some extent, no charge is stored in the ground capacitance C1. At this time, when the commercial power system is restored and the system interconnection switch 34 is switched from off to on, a current flows from the commercial power system 2 to the ground capacitance C1 all at once (see the thick arrow).

Here, in the power conversion device connected only to the solar cell, when the commercial power system is restored, the grid interconnection switch is switched from off to on in order to use the generated power of the solar cell. When the grid interconnection switch is switched from off to on, no inrush current occurs because the solar cell is generating power. In addition, when the solar cell stops generating electricity, such a power converter does not sell the generated power of the solar cell to the electric power company, and the grid interconnection switch can be switched from off to on. Inrush current does not occur because there is no

However, in the power conversion device 30 of the multi-DC link type, it is desired that the solar cell 10 be connected to a distributed power source such as the storage battery 11 even when the solar cell 10 stops generating power. When the grid interconnection switch 34 is switched from OFF to ON in such a situation, an inrush current is generated.

If the generated inrush current value is larger than the sensitivity current value of the circuit breaker 21, the circuit breaker 21 will operate unnecessarily. That is, the circuit breaker 21 disconnects the commercial power system 2 and the load device 3 from each other. When the load device 3 is disconnected from the commercial power system 2, even if the commercial power system 2 is restored, the power supply from the commercial power system 2 to the load device 3 may be interrupted. Further, when the circuit breaker 21 is provided between the commercial power system 2 and the power conversion device 30 as in the present embodiment, the circuit breaker 21 also disconnects the commercial power system 2 and the power conversion device 30. When the power conversion device 30 is disconnected from the commercial power system 2, a situation may occur in which the power of the storage battery 11 cannot be supplied to the load device 3. Further, it becomes impossible to charge the storage battery 11 with the electric power from the commercial power system 2 during the nighttime hours when the electricity rate becomes low.

On the other hand, according to the power conversion device 30 according to the present embodiment, when the setting etc. of the circuit breaker 21 is inappropriate, the setting etc. of the circuit breaker 21 can be corrected in advance by a contractor or the like. Therefore, according to the power conversion device 30 of the present embodiment, it is possible to prevent a situation that may occur due to an unnecessary operation of the circuit breaker 21.

The inrush current is generated under a specific condition such that the grid interconnection switch 34 is turned off during the time period when the solar cell 10 stops the power generation, as described above. Therefore, the breaker may suddenly perform an unnecessary operation several years after the solar cell 10 is installed. Determining the cause of a circuit breaker that has suddenly become unnecessary can be a difficult task.

On the other hand, according to the power conversion device 30 according to the present embodiment, it is possible to determine whether or not the setting of the circuit breaker is appropriate before the inrush current is generated, that is, in advance. Therefore, according to the power conversion device 30 according to the present embodiment, it is possible to prevent a situation in which the circuit breaker suddenly performs an unnecessary operation several years after the solar cell 10 is installed.

Further, in order to reduce the occurrence of unnecessary operation of the circuit breaker, a method of calculating the predicted value of the inrush current and setting the sensitivity current value of the circuit breaker higher than the calculated predicted value of the inrush current can be considered. In this method, the predicted value of the inrush current is calculated using the value of the capacitance of the solar cell to ground.

However, for example, due to a mistake made by a contractor, a different type of solar cell 10 from the expected one may be installed and connected to the power conversion device. That is, the solar cell that has obtained the value of the ground capacitance for calculating the predicted value of the inrush current and the solar cell 10 that is actually connected to the power conversion device may be of different types. In such a case, if the sensitivity current value of the circuit breaker is set based on the predicted value of the inrush power, the sensitivity current value of the circuit breaker becomes lower than the actual value of the inrush current, and the circuit breaker may operate unnecessarily. Can happen. Further, even with a power conversion device that is compatible with many types of solar cells, it is difficult to specify in advance the solar cells connected to the power conversion device.

On the other hand, in the power conversion device 30 according to the present embodiment, the predicted value of the inrush current is not calculated using the capacitance value of the ground capacitance C1 of the solar cell 10. The power conversion device 30 according to the present embodiment selects a power generation module suitable for the current state by using known information of a plurality of types of power generation modules, and calculates a predicted value of the inrush current in the solar cell 10. Therefore, according to the power conversion device 30 according to the present embodiment, the actual value of the inrush current increases due to the connection of the solar cell 10 of a type different from the scheduled one to the power conversion device, and the circuit breaker operates unnecessarily. It is possible to prevent such a situation.

In addition, in the first embodiment, the acquisition unit may be an interface that acquires the format of the solar cell 10. Hereinafter, a configuration in which the display unit 37 serves as the acquisition unit and acquires the format of the solar cell 10 will be described as Modification 1.

<Modification 1>
The known information according to Modification 1 includes each combination of the type of each power generation module in a plurality of types of power generation modules and the known value of the inrush current caused by the ground capacitance of each power generation module.

The display unit 37 according to the first modification acquires the format of the solar cell 10 that the user inputs from the display unit 37. When the display unit 37 acquires the format of the solar cell 10, the display unit 37 notifies the control unit 39 of the acquired format of the solar cell 10.

The control unit 39 calculates the predicted value of the inrush current based on the format of the solar cell 10 and the known information according to the first modification. For example, if the model of the solar cell 10 is "☆21", the control unit 39 selects the known value 1.50 [mA] of the inrush current of the power generation module C from the known information. Further, the control unit 39 multiplies the known value 1.50 [mA] of the selected inrush current by the number of power generation modules included in the solar cell 10 to calculate the predicted value of the inrush current.

In addition, the control unit 39 according to the first modification may not perform the processes of steps S102 to S104 described above.

In the power conversion device 30 according to the modified example 1, the predicted value of the inrush current is calculated based on the format of the solar cell 10 acquired by the display unit 37 and the known information of the plurality of types of power generation modules. Furthermore, also in the modification 1, it is determined whether the calculated predicted value of the inrush current is larger than the determination threshold value. As described above, also in Modification 1, it is possible to determine whether or not the setting of the circuit breaker 21 is appropriate before the inrush current is generated, that is, in advance. Therefore, even in the power conversion device 30 according to the first modification, it is possible to further reduce the occurrence of unnecessary operation of the circuit breaker 21. Further, also in the power conversion device 30 according to the first modification, it is possible to prevent a situation that may occur due to an unnecessary operation of the circuit breaker 21.

<Modification 2>
FIG. 6 shows a schematic configuration of a distribution board 20A according to Modification 2. 6, the same components as those shown in FIG. 2 are designated by the same reference numerals, and the description thereof will be omitted.

In the second modification, the circuit breaker 21, which is, for example, a main power breaker, is provided between the commercial power system 2 and the power conversion device 30 and the load device 3.

In the second modification, the control unit 39 acquires the sensitivity current value of the circuit breaker 22 provided between the power conversion device 30 and the commercial power system 2 as the minimum sensitivity current value.

The control unit 39 calculates the predicted value of the inrush current and determines whether the calculated predicted value of the inrush current is larger than the determination threshold value in the same manner as described above. In the second modification, the determination threshold may be, for example, a value smaller than the sensitivity current value of the circuit breaker 22 by the first predetermined value. In the second modification, the first predetermined value includes, for example, a ground fault current value of another device (for example, the power conversion device 30) provided between the solar cell 10 and the circuit breaker 22. Alternatively, the first predetermined value may be a predetermined ratio (for example, 2/3) of the sensitivity current value of the circuit breaker 22.

Here, a situation that may occur due to an unnecessary operation of the circuit breaker 22 will be described. If the generated inrush current value is larger than the sensitivity current value of the circuit breaker 22, the circuit breaker 22 will operate unnecessarily. That is, the circuit breaker 22 disconnects the commercial power system 2 and the power conversion device 30. When the power conversion device 30 is disconnected from the commercial power system 2, a situation may occur in which the power of the storage battery 11 cannot be supplied to the load device 3. Further, it becomes impossible to charge the storage battery 11 with the electric power from the commercial power system 2 during the nighttime hours when the electricity rate becomes low.

On the other hand, according to the power conversion device 30 according to the second modification, when the setting or the like of the circuit breaker 22 is inappropriate, the setting or the like of the circuit breaker 22 can be corrected in advance by a contractor or the like. Therefore, according to the power conversion device 30 according to the second modification, it is possible to prevent a situation that may occur due to an unnecessary operation of the circuit breaker 22.

(Second embodiment)
Next, a power conversion system according to the second embodiment of the present disclosure will be described. The power conversion system according to the second embodiment can employ the same configuration as the power conversion system 1 according to the first embodiment. Therefore, in the following, with reference to FIGS. 1 and 2, differences from the first embodiment will be mainly described.

In the second embodiment, the control unit 39 performs MPPT (Maximum Power Point Ranking) control on the solar cell 10. For example, the control unit 39 outputs the output of the solar cell string by the DC power transformer 31A so that the operating voltage value of the solar cell string forming the solar cell 10 follows the voltage value of the maximum power point of the solar cell string. Control the voltage value. In addition, when the solar cell 10 is composed of a plurality of solar cell strings, a DC power transformer may be provided for each solar cell string.

Also in the second embodiment, the control unit 39 acquires known information, as in the first embodiment. The known information according to the second embodiment is different from the known information according to the first embodiment in that each power generation module has a plurality of voltage values within a predetermined range, in other words, a plurality of known locations when power is generated by MPPT control. Includes the leakage current value.

FIG. 7 shows known information according to the second embodiment of the present disclosure. In the present embodiment, the known plurality of types of power generation modules are power generation module A to power generation module E. In addition, in the present embodiment, the plurality of voltage values within the predetermined range are {90 [V], 88 [V], 86 [V]}. The power generation module used in the second embodiment is the power generation module C, and the rated voltage value is 90 [V].

Known ground fault current values when the power generation module A is generating power at a plurality of voltage values {90 [V], 88 [V], 86 [V]} within a predetermined range are {0.30 [mA]. ], 0.24 [mA], 0.24 [mA]}. In the power generation module A, the known value of the inrush current is 0.70 [mA]. The model of the power generation module A is “ΔΔ01”.

Known ground fault current values when the power generation module B is generating power at a plurality of voltage values {90 [V], 88 [V], 86 [V]} within a predetermined range are {0.50 [mA]. ], 0.40 [mA], 0.40 [mA]}. In the power generation module B, the known value of the inrush current is 1.20 [mA]. The model of the power generation module B is “ΔΔ02”.

Known ground-fault current values when the power generation module C is generating power at a plurality of voltage values {90 [V], 88 [V], 86 [V]} within a predetermined range are {0.70 [mA]. ], 0.56 [mA], 0.55 [mA]}. In the power generation module C, the known value of the inrush current is 1.50 [mA]. The model of the power generation module C is "☆☆21".

Known ground fault current values when the power generation module D is generating power at a plurality of voltage values {90 [V], 88 [V], 86 [V]} within a predetermined range are {0.10 [mA]. ], 0.08 [mA], 0.08 [mA]}. In the power generation module D, the known value of the inrush current is 0.20 [mA]. The model of the power generation module D is "□□30".

Known ground fault current values when the power generation module E is generating power at a plurality of voltage values {90 [V], 88 [V], 86 [V]} within a predetermined range are {0.13 [mA]. ], 0.10 [mA], 0.09 [mA]}. In the power generation module E, the known value of the inrush current is 0.25 [mA]. The model of the power generation module E is "□□60".

The predetermined range is set to include a voltage value assumed as a voltage value near the maximum operating point of the power generation module, for example. In the present embodiment, the predetermined range is defined by setting the rated voltage value as the upper limit value and the voltage value that is several percent lower than the rated voltage value as the lower limit value. This is because the voltage value at the maximum operating point of the power generation module is often lower than the rated voltage value of the power generation module. Of course, in setting the predetermined range, it is not necessary to set the rated voltage value to the upper limit value, and for example, the rated voltage value may be the median value.

The control unit 39 measures the ground of the solar cell 10 when the solar cell 10 is generating power at a voltage value near the maximum power point in MPPT control (hereinafter also referred to as “maximum operating voltage value”) measured by the acquisition unit 35. Get the current value. Further, the control unit 39 also acquires the maximum operating voltage value of the solar cell 10.

The control unit 39, based on the ground fault current value of the solar cell 10, the maximum operating voltage value of the solar cell 10, and the known information according to the second embodiment, generates an inrush current due to the ground capacitance C1. Calculate the predicted value of. Hereinafter, an example of calculating the predicted value of the inrush current according to the second embodiment will be described.

<Calculation Example 2 of Prediction Value of Inrush Current>
The control unit 39 calculates the divided current value in the same manner as in <Calculation example 1 of predicted value of inrush current> described above.

The control unit 39 divides the maximum operating voltage value of the solar cell 10 by the number of series-connected power generation modules forming the solar cell string to calculate a divided voltage value. The control unit 39 may obtain the number of series of power generation modules forming the solar cell string from the storage unit 38 in which the number of series of power generation modules is stored in advance. Alternatively, the control unit 39 may obtain the number of series of power generation modules forming the solar cell string from the display unit 37, for example, when the contractor inputs the number of series of power generation modules from the display unit 37.

The control unit 39 selects, as the first selection value, the predetermined voltage value that is the closest to the division voltage value from the plurality of voltage values in the predetermined range of the known information. For example, the control unit 39, when calculating the divided voltage value as 88.4 [V], among a plurality of voltage values {90 [V], 89 [V], 88 [V]} within a predetermined range of known information. Therefore, the voltage value 88 [V] is selected as the first selection value.

The control unit 39 determines whether the difference between the divided voltage value and the first selection value is within the voltage threshold value. For example, the voltage threshold value is preset to 0.5 [V] in the second embodiment. In such a configuration, the control unit 39 selects the voltage value 88 [V] as the first selection value when calculating the division voltage value as 88.4 [V]. At this time, the difference between the divided voltage value 88.4 [V] and the first selection value 88 [V] is within the voltage threshold value 0.5 [V]. Therefore, the control unit 39 determines that the difference between the divided voltage value and the first selection value is within the voltage threshold value.

When the control unit 39 determines that the difference between the divided voltage value and the first selection value is the voltage threshold, the control unit 39 selects the most divided current value from among the plurality of known ground fault current values corresponding to the first selection value. A known ground fault current value having a close value is selected as the second selection value. As in the above example, the known ground fault current values in the power generation module A to the power generation module E corresponding to the first selection value 88 [V] are {0.24 [mA], 0.40 [mA], 0. .56 [mA], 0.08 [mA], 0.10 [mA]}. Therefore, the control unit 39 selects a known ground fault current value of 0.56 [mA] of the power generation module C that is the closest value to the divided current value of 0.55 [mA] from the plurality of ground fault current values. Is selected as the second selection value.

Further, the control unit 39 selects the known value of the inrush current combined with the second selected value from the known information. For example, the control unit 39 selects the known value 1.50 [mA] of the inrush current of the power generation module C combined with the second selection value 0.56 [mA].

When the known value of the inrush current is selected, the control unit 39 calculates the predicted value of the inrush current in the same manner as in <Calculation example 1 of the predicted value of the inrush current>.

When the control unit 39 refers to the known information and determines that the difference between the divided voltage value and the first selection value exceeds the voltage threshold, the operating voltage of the solar cell 10 is a voltage value based on the first selection value. You may control so that it may correspond with. The voltage value based on the first selection value is calculated, for example, by multiplying the first selection value by the total number of the power generation modules forming the solar cell string, which are the number of series and the number of parallel. Furthermore, the control unit 39 may measure the ground fault current value of the solar cell 10 by the acquisition unit 35 when the operating voltage of the solar cell 10 matches the first selected value.

[System operation]
Hereinafter, an example of the operation of the power conversion device 30 according to the second embodiment of the present disclosure will be described with reference to FIGS. 8 and 9. The control unit 39 starts the determination process when acquiring the execution request for the determination process from the display unit 37. After starting the determination process, the control unit 39 ends the determination process when shifting the power conversion device 30 to the power-off mode. The processing of steps S201 to S203 shown in FIG. 8 is the same as the processing of steps S101 to S103 shown in FIG.

The control unit 39 performs MPPT control on the solar cell 10 (step S204). After that, the control unit 39 acquires the ground fault current value of the solar cell 10 measured by the acquisition unit 35 when the solar cell 10 is generating power at a voltage value near the maximum power point in MPPT control (step S205). .. At this time, the control unit 39 also acquires the maximum operating voltage value of the solar cell 10.

The control unit 39 divides the maximum operating voltage value of the solar cell 10 by the number of series of power generation modules forming the solar cell string to calculate a divided voltage value (step S206). The control unit 39 selects, as the first selected value, the voltage value that is the closest to the divided voltage value from the plurality of voltage values within the predetermined range of the known information (step S207).

The control unit 39 determines whether the difference between the divided voltage value and the first selection value is within the voltage threshold value (step S208). When the control unit 39 determines that the difference between the divided voltage value and the first selection value is within the voltage threshold value (step S207: Yes), the process proceeds to step S210 shown in FIG. On the other hand, when the control unit 39 determines that the difference between the divided voltage value and the first selection value exceeds the voltage threshold value (step S207: No), the process proceeds to step S209.

In the process of step S209, the control unit 39 causes the solar cell 10 to generate power with the voltage value based on the first selection value, and further acquires the ground fault current value of the solar cell 10 when generating power with the voltage.

The processing of steps S210 to S214 shown in FIG. 8 is the same as the processing of steps S105 to S109 shown in FIG.

As described above, also in the power conversion device 30 according to the second embodiment, the solar cell 10 calculates the predicted value of the inrush current based on the maximum operating voltage value, the ground fault current value of the solar cell 10, and the known information. To do. Further, also in the second embodiment, it is determined whether the predicted value of the calculated inrush current is larger than the determination threshold value. Therefore, also in the second embodiment, as in the first embodiment, the occurrence of unnecessary operation of the circuit breaker can be further reduced.

Further, in the power conversion device 30 according to the second embodiment, the predicted value of the inrush current is calculated using the ground fault current value of the solar cell 10 when the solar cell 10 is generating power at a voltage value near the maximum power point. To do. Thereby, in the second embodiment, while performing the MPPT control on the solar cell 10, it is possible to calculate the predicted value of the inrush current and determine whether or not the circuit breaker may operate unnecessarily. You can Therefore, in the second embodiment, the MPPT control does not have to be interrupted in order to determine whether the circuit breaker may operate unnecessarily. As a result, in the present embodiment, it is possible to prevent the power supply to the load device 3 from being reduced by interrupting the MPPT control. In addition, since the power conversion device 30 according to the second embodiment does not need to interrupt the MPPT control, it is suitable for more regular determination processing.

Further, according to the power conversion device 30 according to the second embodiment, when it is determined that the difference between the divided voltage value and the first selection value exceeds the voltage threshold value, the solar cell 10 outputs the voltage value based on the first selection value. The ground fault current value of the solar cell 10 during power generation is measured. The voltage value based on the first selection value is a voltage value close to the maximum operating voltage value of the solar cell 10. Therefore, the power conversion device 30 can reduce the difference between the operating voltage value of the solar cell 10 when measuring the ground fault current value and the maximum operating voltage value of the solar cell 10. Therefore, the power conversion device 30 can perform the determination process while suppressing a decrease in the output power of the solar cell 10.

The modifications 1 and 2 of the first embodiment can also be applied to the second embodiment.

(Third Embodiment)
In the third embodiment, a method of correcting the predicted value of the inrush current calculated by the method according to the first embodiment or the method according to the second embodiment will be described.

The control unit 39 according to the third embodiment corrects the predicted value of the inrush current based on the correction coefficient. The correction coefficient is calculated by dividing the division current value calculated by the method according to the first embodiment or the method according to the second embodiment by the known ground fault current value that is the closest value to the division current value.

For example, the control unit 39 calculates the division current value as 0.65 [mA] by the method according to the first embodiment. At this time, in the known information of the first embodiment shown in FIG. 4, the known ground fault current value that is the closest to the division current value of 0.65 [mA] is the known ground fault current value of the power generation module C of 0. It is 7 [mA]. The control unit 39 calculates the correction coefficient as 0.928 (=0.65 [mA]/0.7 [mA]). The control unit 39 multiplies the known value 1.50 [mA] of the inrush current of the power generation module C by the number of power generation modules included in the solar cell 10 (assuming 32) to calculate the predicted value 48 of the inrush current. mA] (=1.50 [mA]×32 sheets) is calculated. The control unit corrects the predicted value of the inrush current by multiplying the predicted value 48 [mA] of the inrush current by the correction coefficient 0.928. The predicted value of the corrected inrush current is calculated to be 44.54 [mA] (=48 [mA]×0.928).

The ground fault current value and the inrush current value of the solar cell 10 change according to the capacitance value of the ground capacitance C1 of the solar cell 10. Therefore, if the difference between the divided current value and the known ground fault current value that is the closest to the divided current value is large, it occurs due to the predicted value of the calculated inrush current and the ground capacitance C1. The difference from the actual value of the inrush current can be large.

On the other hand, in the power conversion device 30 according to the third embodiment, the predicted value of the inrush current is corrected by the correction coefficient. Thereby, in the third embodiment, the difference between the predicted value of the calculated inrush current and the actual value of the inrush current generated due to the ground capacitance C1 can be reduced. Therefore, the power conversion device 30 according to the third embodiment can improve the accuracy of the predicted value of the inrush current.

(Fourth Embodiment)
In the fourth embodiment, a method of correcting the predicted value of the inrush current calculated by the method according to the first embodiment or the method according to the second embodiment will be described.

The actual value of the inrush current generated due to the ground capacitance C1 may vary depending on the weather. For example, when it rains and the light receiving surface of the solar cell 10 is wet, the capacitance value of the ground capacitance C1 increases, and the actual value of the inrush current generated due to the ground capacitance C1 increases. Further, for example, if the light-receiving surface of the solar cell 10 is dry and is sunny, the capacitance value of the ground capacitance C1 becomes small, and the actual value of the inrush current generated due to the ground capacitance C1 becomes small.

Moreover, the ground fault current value of the solar cell 10 may fluctuate depending on the condition of the ground on which the power conversion device 30 is installed. For example, when the ground on which the power conversion device 30 is installed is wet, the ground resistance value between the ground capacitance C1 and the ground decreases, and the ground fault current value of the solar cell 10 increases. Further, for example, when the ground to which the power conversion device 30 is grounded is dry, the ground resistance value between the ground capacitance C1 and the ground increases, and the ground fault current value of the solar cell 10 decreases.

Therefore, in the fourth embodiment, the control unit 39 acquires the weather information of the place where the power conversion device 30 is arranged or the ground information regarding the wetness of the place, and based on the acquired weather information or the ground information, the control of the inrush current is performed. Correct the predicted value. Hereinafter, this processing will be described in <Correction processing based on weather information> and <Correction processing based on ground information>.

<Correction process based on weather information>
The weather information includes, for example, information about whether or not it will rain on the execution day of the determination process. The control unit 39 acquires weather information from, for example, the server in the weather forecast period on the network via the communication unit 36.

When it is determined that it will rain on the execution day of the determination process based on the acquired weather information, the control unit 39 corrects by multiplying the predicted value of the inrush current by the correction coefficient. The correction coefficient is calculated, for example, by dividing the capacitance value of the ground capacitance C1 when the light receiving surface is dry by the capacitance value of the ground capacitance C1 when the light receiving surface is wet.

<Correction process based on ground information>
The ground information includes, for example, information on whether or not the place where the power conversion device 30 is placed is wet on the execution day of the determination process. The control unit 39 acquires ground information from the contractor via the display unit 37, for example. For example, the control unit 39 causes the display unit 37 to display a request to input the ground information and presents it to the contractor. The contractor who sees this display visually checks whether or not the place where the power conversion device 30 is arranged is wet, and inputs the ground information from the display unit 37.

When the control unit 39 determines that the place where the power conversion device 30 is placed is wet based on the acquired ground information, the control unit 39 multiplies the predicted value of the inrush current by the correction coefficient to correct the predicted value. The correction coefficient is calculated, for example, based on the ground resistance value when the ground is dry and the ground resistance value when the ground is wet.

In a general house or the like, the ground in which the grounding member for grounding the power conversion device 30 is embedded may be separated from the place where the power conversion device 30 is arranged. At this time, the ground information may include information on whether or not the ground in which the grounding member is embedded is wet on the execution day of the determination process.

As described above, in the fourth embodiment, the predicted value of the inrush current can be accurately calculated by correcting the predicted value of the inrush current based on the correction coefficient. Therefore, according to the fourth embodiment, it is possible to more accurately determine whether or not there is a possibility that the circuit breaker will operate unnecessarily.

Although one embodiment of the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various variations and modifications based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, the functions and the like included in each constituent unit and each step can be rearranged so as not to logically contradict, and a plurality of constituent units and steps can be combined or divided into one. Is. Moreover, one embodiment of the present invention has been described focusing on the apparatus. However, the present invention can also be realized as a method executed by a processor included in the device, a program, or a storage medium recording the program. Therefore, it should be understood that these are also included in the scope of the present invention.

1, 1a Power conversion system 2 Commercial power system 3 Load equipment 10 Solar battery 11 Storage battery 20 Distribution board 21, 22 Circuit breaker 30, 30a Power conversion device 31A, 31B DC power conversion part 32 Orthogonal conversion part 33 Filter part 34 System connection System switch 35 Acquisition unit 36 Communication unit 37 Display unit 38 Storage unit 39 Control unit

Claims (14)

A power conversion device for converting DC power generated by a solar cell including a plurality of power generation modules into AC power,
An acquisition unit that acquires the ground fault current value or format of the solar cell,
Of the plurality of circuit breakers provided between the power converter and the commercial power system, the sensitivity current value of the circuit breaker in which the smallest sensitivity current value is set is acquired as the minimum sensitivity current value, and a plurality of types of power generation are generated. The known information including each combination of the known ground fault current value or format of each power generation module in the module and the known value of the inrush current due to the ground capacitance of each power generation module is acquired, and the ground fault of the solar cell is obtained. Calculate the predicted value of the inrush current generated due to the ground capacitance of the solar cell based on the current value or format and the known information, the calculated predicted value is a determination threshold based on the minimum sensitivity current value and a control section for determining whether or not greater than,
The control unit determines whether or not the circuit breaker to which the smallest sensitivity current value is set may perform an unnecessary operation.
Power converter. The power converter according to claim 1,
The power conversion device, wherein the control unit generates a warning signal when it is determined that the predicted value is larger than the determination threshold. The power converter according to claim 1 or 2,
The power conversion device, wherein the determination threshold is a predetermined ratio of the minimum sensitivity current value. The power converter according to any one of claims 1 to 3,
The acquisition unit acquires the format of the solar cell,
The known information includes a format of each power generation module in the plurality of types of power generation modules,
The control unit selects, from the known information, the known value combined with the type of the solar cell, and further multiplies the selected known value by the number of power generation modules included in the solar cell to obtain the predicted value. A power conversion device for calculating. The power converter according to any one of claims 1 to 3,
The acquisition unit acquires a ground fault current value of the solar cell when the solar cell is generating power at a rated voltage value,
The known information is a power conversion device including a plurality of ground fault current values based on rated voltage values of the power generation modules in the plurality of types of power generation modules. The power converter according to any one of claims 1 to 3 and 5,
The known ground fault current value is a value per one of the plurality of types of power generation modules,
The control unit subtracts the ground fault current value of the power converter from the ground fault current value of the solar cell, and further calculates a divided current value by dividing by the number of power generation modules included in the solar cell,
The control unit selects, from the known information, the known value that is combined with the known ground fault current value that is the closest to the division current value, and further selects the number of the power generation modules to the selected known value. A power conversion device that multiplies to calculate the predicted value. The power converter according to any one of claims 1 to 3,
The control unit performs MPPT control on the solar cell,
The acquisition unit measures a ground fault current value of the solar cell when the solar cell is generating power at a voltage value near a maximum operating point in MPPT control,
The known ground fault current value includes a plurality of known ground fault current values based on a plurality of voltage values within a predetermined range of each power generation module in the plurality of types of power generation modules. The power converter according to claim 7,
The control unit calculates a divided voltage value by dividing the voltage value near the maximum operating point by the number of series of power generation modules that form the solar string that the solar cell forms, and a plurality of voltage values within the predetermined range. A voltage value closest to the divided voltage value is selected as the first selected value, and when the difference between the divided voltage value and the first selected value exceeds a voltage threshold, the solar cell is A power converter that measures a ground-fault current value of the solar cell during power generation at a voltage value based on a selected value. The power converter according to claim 7,
The known ground fault current value is a value per one of the plurality of types of power generation modules,
The control unit subtracts the ground fault current value of the power converter from the ground fault current value of the solar cell, and further calculates a divided current value by dividing by the number of power generation modules included in the solar cell,
The control unit calculates a divided voltage value by dividing the voltage value near the maximum operating point by the number of series of power generation modules that form the solar string that the solar cell forms, and from the known information, within the predetermined range. When a voltage value having a value closest to the divided voltage value is selected as a first selected value from the plurality of voltage values, and it is determined that the difference between the divided voltage value and the first selected value is within a voltage threshold value, Of the plurality of known ground fault current values corresponding to the first selected value, a known ground fault current value closest to the division current value is selected as the second selected value and combined with the second selected value. A power conversion device that selects the known value that has been set. The power conversion device according to claim 6 or 9,
The power conversion device, wherein the control unit calculates the predicted value by multiplying the selected known value by the number of the power generation modules and further adding the ground fault current value of the power conversion device. The power conversion device according to claim 6 or 9,
The circuit breaker having the minimum sensitivity current value is provided between the commercial power system and a load device to which the power conversion device supplies power,
The control unit calculates the predicted value by multiplying the selected known value by the number of power generation modules and then adding the ground fault current value of the power converter and the leak current value of the load device. Power converter. The power conversion device according to any one of claims 6 and 9 to 11,
The control unit corrects the predicted value based on a correction coefficient calculated by dividing the divided current value by the known ground fault current value that is the closest to the divided current value. The power conversion device according to any one of claims 6 and 9 to 11,
The power conversion device, wherein the control unit acquires at least one of weather information and ground information of a place where the power conversion device is arranged, and corrects the predicted value based on the acquired information. A method for controlling a power converter that converts DC power generated by a solar cell including a plurality of power generation modules into AC power,
Acquiring a ground fault current value or format of the solar cell,
Of the plurality of circuit breakers provided between the power converter and the commercial power system, a step of acquiring the sensitivity current value of the circuit breaker in which the smallest sensitivity current value is set as the minimum sensitivity current value ,
Obtaining known information including each combination of a known ground fault current value or format of each power generation module in a plurality of types of power generation modules and a known value of an inrush current resulting from the ground capacitance of each power generation module,
Calculating a predicted value of an inrush current generated due to the ground capacitance of the solar cell based on the ground fault current value or format of the solar cell and the known information;
Determining whether the predicted value is greater than a determination threshold based on the minimum sensitivity current value ,
And a step of determining whether or not there is a possibility that the circuit breaker for which the smallest sensitivity current value is set may perform unnecessary operation .

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