JP6857828B2 - Power converter - Google Patents

Description

The present invention relates to a power conversion equipment for converting DC power to AC power.

Currently, distributed power sources that are grid-connected include solar cells, fuel cells, stationary storage batteries, and in-vehicle storage batteries as power sources. Typical configurations of a distributed power supply system connected to a grid include a configuration in which a single distributed power supply is used and the grid is connected via a DC-DC converter, a DC bus, and an inverter, and a plurality of distributed power supplies. There is a configuration in which each DC-DC converter, a common DC bus, and one inverter are connected to the grid using the above (see, for example, Patent Document 1).

In the latter, there is a configuration in which a plurality of DC-DC converters and one inverter are installed in one housing, and a configuration in which at least one DC-DC converter and one inverter are installed in a separate housing.

Further, even if the DC-DC converter and the inverter are physically installed in one housing, the DC-DC converter and the inverter are controlled independently by separate control devices (for example, a microcomputer) in terms of control. It may be done. In such a distributed power supply system in which the DC-DC converter and the inverter are physically or controlledly separated, the inverter and various distributed power supplies can be freely combined.

In such a distributed power supply system, in order to operate stably, it is necessary to control the input / output power of the system so as to be balanced. Furthermore, it is necessary to carry out suppression processing to comply with the grid interconnection regulations in order to connect to the grid, and to perform suppression treatment to prevent overcurrent and temperature abnormalities from occurring in order to operate safely.

Japanese Unexamined Patent Publication No. 2015-733668

In an integrated distributed power supply system, basically one control unit manages all information collectively, and adjusts the input / output power of the system according to the situation. In response to suppression instructions according to various output suppression reasons, adaptive suppression control is performed on the input side and / or output side to control the power balance of the entire system.

In a separate distributed power supply system, each control unit is separated, and it is difficult to collectively control the adjustment of the input / output power of the system. If appropriate suppression control is not performed for suppression instructions according to various output suppression reasons, the power balance of the entire system will be disrupted.

The present invention has been made in view of the foregoing circumstances, and its object is to the occurrence of various output suppression grounds for, it is to provide a power conversion equipment that can perform accurate output suppression control.

In order to solve the above problems, the power conversion device of a certain aspect of the present invention converts the voltage of the DC power output by the power generation device that generates power based on the renewable energy, and outputs the converted DC power to the DC bus. An inverter that is connected to the first DC-DC converter via the DC bus, converts the DC power of the DC bus into AC power, and supplies the converted AC power to the load or the power system. And a control circuit for controlling the inverter. The control circuit changes the amount of suppression of the output of the inverter according to the type of the reason for suppressing the output of the power conversion device.

According to the present invention, it is possible to perform accurate output suppression control in response to the occurrence of various output suppression events.

It is a figure for demonstrating the power conversion system which concerns on embodiment of this invention. 2 (a) and 2 (b) are diagrams schematically depicting the voltage state of the DC bus. 3A and 3B are diagrams showing an example of an output suppression reason when the second power conversion device is not connected and an output suppression reason when the second power conversion device is in the connected state. It is a figure which shows an example of the output of an inverter when a plurality of types of output suppression events occur at the same time.

FIG. 1 is a diagram for explaining a power conversion system 1 according to an embodiment of the present invention. The power conversion system 1 includes a first power conversion device 10 and a second power conversion device 20. The first power conversion device 10 is a power conditioner system for the solar cell 2, and the second power conversion device 20 is a power conditioner system for the power storage unit 3. FIG. 1 shows an example in which a power conditioner system for the power storage unit 3 is retrofitted to the power conditioner system for the solar cell 2.

The solar cell 2 is a power generation device that directly converts light energy into electric power by utilizing the photovoltaic effect. As the solar cell 2, a silicon solar cell, a solar cell made of a compound semiconductor or the like, a dye-sensitized type (organic solar cell), or the like is used. The solar cell 2 is connected to the first power conversion device 10 and outputs the generated power to the first power conversion device 10.

The first power converter 10 includes a DC-DC converter 11, a converter control circuit 12, an inverter 13, a temperature sensor T1, an inverter control circuit 14, and a system control circuit 15. The system control circuit 15 includes an output suppression control unit 15a and a command value generation unit 15b. The DC-DC converter 11 and the inverter 13 are connected by a DC bus 40. The converter control circuit 12 and the system control circuit 15 are connected by a communication line 41, and communication conforming to a predetermined serial communication standard (for example, RS-485 standard, TCP-IP standard) is performed between the two.

The DC-DC converter 11 converts the DC power output from the solar cell 2 into DC power having a desired voltage value, and outputs the converted DC power to the DC bus 40. The DC-DC converter 11 can be configured by, for example, a step-up chopper.

The converter control circuit 12 controls the DC-DC converter 11. As a basic control, the converter control circuit 12 controls the DC-DC converter 11 by MPPT (Maximum Power Point Tracking) so that the output power of the solar cell 2 is maximized. Specifically, the converter control circuit 12 measures the input voltage and input current of the DC-DC converter 11, which are the output voltage and output current of the solar cell 2, and estimates the generated power of the solar cell 2. The converter control circuit 12 generates a command value for setting the generated power of the solar cell 2 to the maximum power point (optimal operating point) based on the measured output voltage of the solar cell 2 and the estimated generated power. For example, the operating point voltage is changed by a predetermined step width according to the hill climbing method to search for the maximum power point, and a command value is generated so as to maintain the maximum power point. The DC-DC converter 11 performs a switching operation in response to a drive signal based on the generated command value.

The inverter 13 is a bidirectional inverter, converts the DC power input from the DC bus 40 into AC power, and outputs the converted AC power to the distribution line 50 connected to the commercial power system (hereinafter, simply referred to as system 4). To do. A load 5 is connected to the distribution line 50. Further, the inverter 13 converts the AC power supplied from the system 4 into DC power, and outputs the converted DC power to the DC bus 40. An electrolytic capacitor (not shown) for smoothing is connected to the DC bus 40.

The inverter control circuit 14 controls the inverter 13. As basic control, the inverter control circuit 14 controls the inverter 13 so that the voltage of the DC bus 40 maintains the first threshold voltage. Specifically, the inverter control circuit 14 detects the voltage of the DC bus 40 and generates a command value for matching the detected bus voltage with the first threshold voltage. The inverter control circuit 14 generates a command value for increasing the duty ratio of the inverter 13 when the voltage of the DC bus 40 is higher than the first threshold voltage, and the inverter when the voltage of the DC bus 40 is lower than the first threshold voltage. A command value for lowering the duty ratio of 13 is generated. The inverter 13 performs a switching operation according to a drive signal based on the generated command value.

The temperature sensor T1 detects the temperature in the first power converter 10 and outputs it to the system control circuit 15. For example, a thermistor, a thermocouple, or the like can be used for the temperature sensor T1.

The power storage unit 3 can charge and discharge electric power, and includes a lithium ion storage battery, a nickel hydrogen storage battery, a lead storage battery, an electric double layer capacitor, a lithium ion capacitor, and the like. The power storage unit 3 is connected to the second power conversion device 20.

The second power converter 20 includes a DC-DC converter 21 and a converter control circuit 22. The converter control circuit 22 and the system control circuit 15 of the first power conversion device 10 are connected by a communication line 42, and communication conforming to a predetermined serial communication standard is performed between the two.

The DC-DC converter 21 is a bidirectional converter connected between the power storage unit 3 and the DC bus 40 to charge and discharge the power storage unit 3. The converter control circuit 22 controls the DC-DC converter 21. As basic control, the converter control circuit 22 controls the DC-DC converter 21 based on the command value transmitted from the system control circuit 15, and causes the power storage unit 3 to have a constant current (CC) / constant voltage (CV). Charge / discharge. For example, the converter control circuit 22 receives a power command value from the system control circuit 15 at the time of discharging, and divides the power command value by the voltage of the power storage unit 3 to use a current command value as a constant current in the DC-DC converter 21. Discharge.

If the amount of power generated by the solar cell 2 increases due to fluctuations in solar radiation or the power consumption of the load 5 decreases during discharge from the power storage unit 3, reverse power flow to the system 4 is generated and the power is sold. Sometimes. In Japan, the grid interconnection regulations prohibit the reverse power flow of 5% or more of the rated capacity of the storage battery to the grid 4 for more than 500 ms from the power storage system. Therefore, when reverse power flow is detected in the power conversion system 1 to which the power storage unit 3 is connected, it is necessary to suppress the reverse power flow within 500 ms.

In Japan, due to the revision of the feed-in tariff system for renewable energy in January 2015, it is obligatory to introduce a remote output control system to the photovoltaic power generation and wind power generation facilities that are newly connected to the grid. The system control circuit 15 receives instructions regarding the amount of output power and the output timing to the system 4 from a system operating organization such as an electric power company via an external network (for example, the Internet or a dedicated line).

As a method of suppressing the output power of the inverter 13, a method of suppressing the output power of the DC-DC converter 11 of the solar cell 2, a method of suppressing the output power of the DC-DC converter 21 of the power storage unit 3, and a method of suppressing the output power of the inverter 13. There is a way to suppress. The method of suppressing the output power of the DC-DC converter 11 of the solar cell 2 leads to wasting the amount of power generated by the solar cell 2. Therefore, the output suppression of the DC-DC converter 11 of the solar cell 2 is the last control to be executed.

When reverse power flow is detected, the discharge from the power storage unit 3 may be stopped, so the method of suppressing the output power of the DC-DC converter 21 of the power storage unit 3 is the most straightforward control. However, when the second power conversion device 20 is separated from the first power conversion device 10 and installed at a position away from the system 4, from the detection of reverse power flow to the suppression of the output of the DC-DC converter 21 of the power storage unit 3. Time lag is likely to occur.

In the configuration shown in FIG. 1, the system control circuit 15 of the first power conversion device 10 is based on the measured values of the CT sensor (not shown) installed on the system 4 side of the distribution line 50 from the distribution board. Detects reverse power flow. The converter control circuit 22 of the second power conversion device 20 receives reverse power flow detection information from the system control circuit 15 via the communication line 42. The communication line 42 is often installed along the DC bus 40 connecting the first power conversion device 10 and the second power conversion device 20, and in this configuration, the communication line 42 is affected by noise from the DC bus 40. .. Further, in digital communication using a binary voltage, the shorter the unit period representing one bit, the more vulnerable to noise, and basically, the higher the communication speed, the more likely it is that a bit error will occur.

Therefore, a method in which the first power conversion device 10 detects reverse power flow, generates communication data instructing output suppression, and transmits the communication data to the second power conversion device 20 via the communication line 42 is defined in the grid interconnection rules. It may not be possible to comply with the time limit (500ms). In addition, the content of communication data may change on the way due to noise.

Therefore, a method of suppressing the output power of the inverter 13 first and then suppressing the output power of the DC-DC converter 21 of the power storage unit 3 can be considered. As described above, the inverter control circuit 14 controls the inverter 13 as basic control so that the voltage of the DC bus 40 maintains the first threshold voltage. When output suppression should be performed, the inverter control circuit 14 executes output suppression control as priority control. Specifically, the inverter control circuit 14 controls the inverter 13 so that the output of the inverter 13 does not exceed the command value (specifically, the upper limit current value or the upper limit power value) generated by the command value generation unit 15b. While the output is suppressed, the bus voltage stabilization control that controls the voltage of the DC bus 40 to be maintained at the first threshold voltage is stopped.

When the output suppression of the inverter 13 starts, the output suppression of the DC-DC converter 11 of the solar cell 2 and / or the DC-DC converter 21 of the power storage unit 3 has not started. Therefore, the input power of the inverter 13 becomes excessive with respect to the output power of the inverter 13, and the voltage of the DC bus 40 rises. More specifically, electric charges are accumulated in the electrolytic capacitor connected to the DC bus 40.

As described above, as basic control of the converter control circuit 22, the amount of discharge from the power storage unit 3 to the DC-DC converter 21 or the amount of charge from the DC-DC converter 21 to the power storage unit 3 is transmitted from the system control circuit 15. The DC-DC converter 21 is controlled so as to have a command value to come. Further, the converter control circuit 22 controls the DC-DC converter 21 as priority control so that the voltage of the DC bus 40 does not exceed the second threshold voltage. This control takes precedence over the control that matches the output with the command value transmitted from the system control circuit 15. The second threshold voltage is set to a value higher than the first threshold voltage.

As described above, the converter control circuit 12 MPPT-controls the DC-DC converter 11 so that the output power of the solar cell 2 is maximized as basic control. Further, the converter control circuit 12 controls the DC-DC converter 11 as priority control so that the voltage of the DC bus 40 does not exceed the third threshold voltage. This control takes precedence over MPPT control. The third threshold voltage is set to a value higher than the second threshold voltage.

The first threshold voltage is set to the steady state voltage of the DC bus 40. When the system voltage is AC200V, the first threshold voltage is set in the range of DC280V to 360V, for example. The second threshold voltage is set to, for example, 390V, and the third threshold voltage is set to, for example, 410V. The voltage of the DC bus 40 rises due to the output suppression of the inverter 13, and when the voltage of the DC bus 40 reaches the second threshold voltage, the control of suppressing the rise of the bus voltage by the DC-DC converter 21 of the power storage unit 3 is activated. When the energy of the voltage rise of the DC bus 40 is larger than the rise suppression energy of the DC-DC converter 21 of the power storage unit 3, the voltage of the DC bus 40 further rises. When the voltage of the DC bus 40 reaches the third threshold voltage, the control of suppressing the increase in the bus voltage by the DC-DC converter 11 of the solar cell 2 is activated.

2 (a) and 2 (b) are diagrams schematically depicting the voltage state of the DC bus 40. FIG. 2A shows the state of the voltage of the DC bus 40 in the steady state. The constant voltage of the DC bus 40 is maintained at the first threshold voltage by the inverter 13. FIG. 2B shows the voltage state of the DC bus 40 when the output of the inverter 13 is suppressed. Normally, the voltage of the DC bus 40 during output suppression is maintained at the second threshold voltage by the DC-DC converter 21 of the power storage unit 3.

When it is desired to suppress the initial investment in the power conversion system 1 shown in FIG. 1, the operation is performed in the state of the first power conversion device 10 alone (that is, the state of the photovoltaic power generation system) without connecting the second power conversion device 20. May start. Further, there is a case where the second power conversion device 20 is desired to be removed from the state of the power conversion system 1 shown in FIG. For example, when the power storage unit 3 is rarely used, deterioration of the power storage unit 3 can be suppressed by removing the second power conversion device 20 from the DC bus 40.

3A and 3B are diagrams showing an example of an output suppression reason when the second power conversion device 20 is in the disconnected state and an output suppression reason when the second power conversion device 20 is in the connected state. is there. As shown in FIG. 3A, five types of output suppression reasons are defined when the second power conversion device 20 is in the non-connected state.

Excessive rated current is a suppression reason that occurs when the inverter 13 outputs a current that exceeds the rated current of the inverter 13. For example, when the rated output current of the inverter 13 is 27.5 A, the suppression reason occurs when the inverter 13 outputs a current exceeding 27.5 A. Excessive rated power is a suppression reason that occurs when the inverter 13 outputs power that exceeds the rated power of the inverter 13. For example, when the rated output power of the inverter 13 is 5.5 kW, the suppression reason occurs when the inverter 13 outputs a power exceeding 5.5 kW.

The output voltage rise is a suppression reason that occurs when the output voltage of the inverter 13 exceeds a predetermined value. For example, the predetermined value is set to a value of 202V or more in the case of three-phase, and is set to a value of 107V or more in the case of single-phase. The remote output instruction is a suppression reason that occurs when it is received from a grid operating organization such as an electric power company via an external network. For example, an instruction such as "Please reduce the output power to XX kW from XX minutes to XX minutes" is transmitted.

The high temperature abnormality is a suppression reason that occurs when the temperature in the first power conversion device 10 exceeds a predetermined value. For example, the predetermined value is set to 95 degrees. The main heat generating source in the first power converter 10 is the inverter 13.

The output suppression control unit 15a of the first power conversion device 10 changes the output suppression amount of the inverter 13 according to the type of output suppression reason. Specifically, the output suppression control unit 15a determines the limit value and the response time according to the type of the output suppression reason with reference to the table shown in FIG. 3A. The command value generation unit 15b generates the current command value / power command value of the inverter 13 according to the limit value and the response time determined by the output suppression control unit 15a.

In the example shown in FIG. 3A, the rated current excess and rated power excess are defined as the first priority, the output voltage rise is defined as the second priority, the remote output instruction is defined as the third priority, and the high temperature abnormality is defined as the fourth priority. Has been done. Output suppression reasons with higher priority are more urgent and require faster response. The remote output instruction depends on the instruction of the system operation period, but is usually slower than the response when the output voltage rises. The high temperature abnormality is suppressed over a period of several minutes or more.

The output current / output power limit value of the inverter 13 changes depending on the plurality of types of output suppression reasons. When the rated current is exceeded, the limit value of the output current of the inverter 13 becomes the rated current value. The current value obtained by subtracting the margin from the rated current value may be used. When the rated power is exceeded, the limit value of the output power of the inverter 13 becomes the rated power value. The power value obtained by subtracting the margin from the rated power value may be used.

In the case of an increase in output voltage, the output current / output power of the inverter 13 is reduced at a specified response speed until the output voltage drops to a target value (for example, 202V for three-phase and 107V for single-phase). .. In the case of remote output instruction, the limit value of the output current / output power of the inverter 13 becomes the value specified by the system operating engine. In the case of a high temperature abnormality, the output current / output power of the inverter 13 is reduced at a specified response speed until the temperature in the first power converter 10 drops to a target value (for example, 80 degrees).

In the state where the second power conversion device 20 is connected to the first power conversion device 10, the reverse power flow to the system 4 is added to the system 4 at the first priority for the reason of output suppression. The output suppression control unit 15a determines the limit value and the response time according to the type of the output suppression reason with reference to the table shown in FIG. 3B. In the example shown in FIG. 3B, the reverse power flow to the system 4 is the first priority, the rated current excess, the rated power excess is the second priority, the output voltage rise is the third priority, and the remote output instruction is the priority. 4th place and high temperature abnormality are specified as 5th place priority. In the reverse power flow to the system 4, the limit value of the output current / output power of the inverter 13 is a value at which the output power to the system 4 becomes 0 W or less, and the response time is less than 500 ms. This response time is the shortest response time among the response times for the output suppression reasons shown in FIG. 3 (b).

When two or more types of output suppression events occur at the same time among a plurality of types of output suppression events, the output suppression control unit 15a outputs the output of the inverter 13 with the suppression amount and response time for the output suppression event having the highest priority. Suppress.

FIG. 4 is a diagram showing an example of the output of the inverter 13 when a plurality of types of output suppression events occur at the same time. The dotted line command value indicates the transition of the command value when a high temperature abnormality occurs, and the solid line command value indicates the transition of the command value when reverse power flow occurs. The output suppression control unit 15a selects a lower command value at each time point. The actual output power of the inverter 13 is the output power based on the command value when the high temperature abnormality occurs from the occurrence of the high temperature abnormality to the occurrence of the reverse power flow, and becomes the output power based on the command value when the reverse power flow occurs after the occurrence of the reverse power flow.

As described above, according to the present embodiment, suppression control according to the type of output suppression reason is possible, and responsiveness to each output suppression reason can be ensured. Therefore, the power balance between the input and output of the entire power conversion system 1 can be maintained.

Further, output suppression control is performed according to the system configuration by adding or eliminating reverse power flow to the system 4 as an output suppression reason depending on whether or not the second power conversion device 20 connected to the power storage unit 3 is connected. Can be optimized.

The present invention has been described above based on the embodiments. Embodiments are examples, and it will be understood by those skilled in the art that various modifications are possible for each of these components and combinations of each processing process, and that such modifications are also within the scope of the present invention. ..

In FIG. 1, the inverter control circuit 14 and the system control circuit 15 are drawn separately, but each of them may be realized by another microcomputer or may be realized by one microcomputer. Further, in the above-described embodiment, an example in which the first power conversion device 10 and the second power conversion device 20 are installed in different housings has been described. In this regard, a configuration example in which the system control circuit 15 and the converter control circuit 22 are connected by a communication line 42 while the first power conversion device 10 and the second power conversion device 20 are installed in one housing is also one of the present inventions. Included in embodiments.

Further, in the above embodiment, an example in which the solar cell 2 is connected to the first power conversion device 10 has been described. In this regard, instead of the solar cell 2, another power generation device using renewable energy, such as a wind power generation device or a micro hydroelectric power generation device, may be connected.

The embodiment may be specified by the following items.

[Item 1]
A first DC-DC converter (11) that converts the voltage of the DC power output by the power generation device (2) that generates power based on renewable energy and outputs the converted DC power to the DC bus (40).
The first DC-DC converter (11) is connected to the DC bus (40) via the DC bus (40), the DC power of the DC bus (40) is converted into AC power, and the converted AC power is used as the load (5) or the power system. The inverter (13) supplied to (4) and
A control circuit (14, 15) for controlling the inverter (13) is provided.
The power conversion device (10) is characterized in that the control circuits (14, 15) change the output suppression amount of the inverter (13) according to the type of output suppression reason of the power conversion device (10). ..
According to this, it is possible to secure responsiveness according to the type of output suppression reason.
[Item 2]
The control circuit (14, 15) suppresses the output suppression reason having the highest priority when two or more types of output suppression reasons occur among the multiple types of output suppression reasons of the power converter (10). The power conversion device (10) according to item 1, wherein the output of the inverter (14) is suppressed by the amount and the response time.
According to this, even if a plurality of types of output suppression events occur at the same time, the required output suppression can be realized.
[Item 3]
The second DC-DC converter (21) that controls the input / output of the power storage unit (3) can be connected to the DC bus (40).
In a state where the second DC-DC converter (21) is connected to the DC bus (40), reverse power flow to the power system (4) is included with the highest priority for the plurality of types of output suppression reasons. When the second DC-DC converter (21) is not connected to the DC bus (40), the reason for suppressing the output of the plurality of types does not include reverse power flow to the power system (4). The power conversion device (10) according to item 1 or 2, characterized in that.
According to this, the output suppression reason can be optimized depending on whether or not the second DC-DC converter (21) is connected to the DC bus (40).
[Item 4]
The control circuits (14, 15) are characterized in that when a reverse power flow to the system 4 occurs, the output of the inverter (13) is suppressed at the fastest response speed among the plurality of types of output suppression reasons. The power conversion device (10) according to item 3.
According to this, the grid interconnection rule can be satisfied.
[Item 5]
The plurality of types of output suppression reasons include an increase in the inverter output power exceeding the rated power, an increase in the inverter output current exceeding the rated current, an increase in the inverter output voltage exceeding a predetermined value, reception of a remote output command, and so on. The rise of the temperature in the power converter (10) exceeding a predetermined value is included, and among these, the rise exceeding the rated power of the inverter output power and the rise exceeding the rated current of the inverter output current are priorities. Is the highest, the rise of the inverter output voltage exceeding the predetermined value has the next highest priority, the reception of the remote output command has the next highest priority, and the rise of the temperature exceeding the predetermined value has the lowest priority. The power conversion device (10) according to any one of items 1 to 4, wherein the power conversion device (10) is characterized in that.
According to this, suppression control according to the priority of each output suppression reason becomes possible, and responsiveness to each output suppression reason can be ensured.
[Item 6]
A power conversion system (1) including a first power conversion device (10) and a second power conversion device (20).
The first power converter (10) is
A first DC-DC converter (11) that converts the voltage of the DC power output by the power generation device (2) that generates power based on renewable energy and outputs the converted DC power to the DC bus (40).
The first DC-DC converter (11) is connected to the DC bus (40) via the DC bus (40), the DC power of the DC bus (40) is converted into AC power, and the converted AC power is used as the load (5) or the power system. The inverter (13) supplied to (4) and
It has first control circuits (14, 15) for controlling the inverter (13), and has.
The second power converter (20)
A second DC-DC converter (21) that controls the input / output of the power storage unit (3),
It has a second control circuit (22) that controls the second DC-DC converter (21), and has.
The first control circuit (14, 15) is characterized in that the amount of suppression of the output of the inverter (13) is changed according to the type of the reason for suppressing the output of the first power conversion device (10). System (1).
According to this, it is possible to secure responsiveness according to the type of output suppression reason.

1 Power conversion system, T1 temperature sensor, 2 Solar cell, 3 Power storage unit, 4 systems, 5 Load, 10 1st power converter, 11 DC-DC converter, 12 Converter control circuit, 13 Inverter, 14 Inverter control circuit, 15 System control circuit, 15a output suppression control unit, 15b command value generator, 20 second power converter, 21 DC-DC converter, 22 converter control circuit, 30 operation display device, 40 DC bus, 41, 42, 43 communication lines , 50 distribution line.

Claims (3)

A first DC-DC converter that converts the voltage of DC power output by a power generator that generates power based on renewable energy and outputs the converted DC power to a DC bus.
An inverter that is connected to the first DC-DC converter via the DC bus, converts the DC power of the DC bus into AC power, and supplies the converted AC power to the load or the power system.
A control circuit for controlling the inverter is provided.
The control circuit defines a plurality of types of output suppression reasons for this power conversion device.
The control circuit changes the output limit value and response time of the inverter according to the type of output suppression reason of the power converter.
The second DC-DC converter that controls the input / output of the power storage unit has a configuration that can be connected to the DC bus.
In a state where the second DC-DC converter is connected to the DC bus, reverse power flow to the power system is included with the highest priority for the plurality of types of output suppression reasons, and the second DC-DC converter The power conversion device is characterized in that when the power is not connected to the DC bus, the reverse power flow to the power system is not included in the plurality of types of output suppression reasons. The power conversion according to claim 1 , wherein the control circuit suppresses the output of the inverter at the fastest response speed among the plurality of types of output suppression reasons when a reverse power flow to the power system occurs. apparatus. The plurality of types of output suppression reasons include an increase in the output power of the inverter exceeding the rated power, an increase in the output current of the inverter exceeding the rated current, an increase in the output voltage of the inverter exceeding a predetermined value, and a remote output command. Including the rise in reception and the temperature in the power converter exceeding a predetermined value, among these, the rise exceeding the rated power of the output power of the inverter and the rise exceeding the rated current of the output current of the inverter are included. The highest priority is given, the rise of the output voltage of the inverter exceeding the predetermined value has the next highest priority, the reception of the remote output command has the next highest priority, and the rise of the temperature exceeding the predetermined value has the highest priority. The power conversion device according to claim 1 or 2, wherein the degree is low.

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