JP6830209B2 - Power conversion system, power conversion device - Google Patents

Description

The present invention relates to a power conversion system and a power conversion device that convert DC power into AC power.

Currently, distributed power sources connected to the grid include solar power generation devices, wind power generation devices, stationary storage batteries, in-vehicle storage batteries, and the like as power sources. Both are installed in one housing as a system configuration of a DC / DC converter that boosts the voltage of the distributed power supply to the voltage for grid interconnection and an inverter that converts the DC power of the DC / DC converter into AC power. There is an integrated configuration and a separate configuration installed in separate housings. In the future, it is expected that a separate configuration that can expand the system by retrofitting various distributed power sources to the intermediate bus between the DC / DC converter and the inverter will become widespread.

When a momentary power failure or momentary voltage drop (hereinafter referred to as a momentary low including both in the present specification) occurs in a commercial power system (hereinafter referred to as a power system), the FRT (Fault) stipulated in the grid interconnection regulations Ride Through) Requirements must be observed. The FRT requirement requires that the output power before the momentary drop be restored immediately after the momentary drop is released. A power conditioner for realizing this has been developed (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-50156

In the power conversion system having the separated type configuration described above, the voltage of the intermediate bus is controlled so that the control unit of the inverter keeps it constant. Further, when the voltage of the intermediate bus rises to a predetermined threshold voltage, the control unit of the DC / DC converter controls so as to suppress the rise of the bus voltage. In this control method, when a momentary drop occurs, the voltage of the intermediate bus rises to the threshold voltage. When the control unit of the inverter unconditionally releases the output suppression of the inverter after the instantaneous drop is released, the inverter tries to output a larger current in order to lower the voltage of the intermediate bus. At that time, an overcurrent may occur in the inverter.

The present invention has been made in view of such a situation, and an object of the present invention is to provide a power conversion system and a power conversion device capable of stably and promptly returning to the state before the instantaneous reduction after the instantaneous reduction is released. is there.

In order to solve the above problems, the power conversion system of one embodiment of the present invention includes a DC / DC converter that adjusts the voltage of the DC power output by the DC power supply and outputs the adjusted DC power to the intermediate bus. The voltage of the first control unit that controls the DC / DC converter, the inverter that converts the DC power of the intermediate bus into AC power and outputs the converted AC power to the power system, and the voltage of the intermediate bus are first predetermined. A second control unit that controls the inverter so as to maintain the value is provided. The first control unit controls the DC / DC converter so that the voltage of the intermediate bus becomes higher than the first predetermined value and equal to or lower than the second predetermined value, and when a momentary drop occurs in the power system, the first control unit said. The second control unit suppresses the output of the inverter, and when the momentary voltage drop is released, the second control unit outputs an output up to a value corresponding to the output power of the inverter before the occurrence of the momentary voltage drop. The state of the inverter is changed to an allowable state, and the first control unit controls the DC / DC converter so that the voltage of the intermediate bus drops to the first predetermined value.

According to the present invention, it is possible to stably and quickly return to the state before the momentary drop after the momentary drop is released.

1 (a) and 1 (b) are diagrams for comparing a power converter having an integrated inverter and a converter and a power converter having a separate inverter and a converter. It is a figure for demonstrating the power conversion system which concerns on embodiment of this invention. 3 (a) and 3 (b) are diagrams schematically depicting the voltage state of the intermediate bus. It is a figure which shows each output waveform at the momentary low. It is a figure which shows the specific example of each output value at the time of a momentary low. It is a figure which shows an example of each output waveform at the time of releasing a momentary low. It is a flowchart for demonstrating the operation at the moment of momentary low in the power conversion system which concerns on embodiment of this invention. It is a figure for demonstrating the power conversion system which concerns on a modification.

1 (a) and 1 (b) are diagrams for comparing a power converter having an integrated inverter and a converter and a power converter having a separate inverter and a converter. FIG. 1A shows a schematic configuration of a power conversion device integrated with an inverter and a converter, and FIG. 1B shows a schematic configuration of a power conversion device with an inverter and a converter separated. FIGS. 1 (a) and 1 (b) show a system configuration in which three distributed power sources, a solar cell 2, a stationary storage battery 3a, and an in-vehicle storage battery 3b, can be connected to the power system 4.

In the integrated configuration shown in FIG. 1A, a power conversion device 15 including a DC / DC converter 11 and an inverter 21 is installed for each distributed power source. On the other hand, in the separate configuration shown in FIG. 1B, one DC / AC power converter 20 including the inverter 21 and a DC / DC power converter 10 including the DC / DC converter 11 are provided for each distributed power source. Will be installed.

In the integrated configuration shown in FIG. 1A, the efficiency of power transfer between distributed power sources is reduced. For example, when charging the generated power of the solar cell 2 into the stationary storage battery 3a, it is necessary to pass through four converters: a first DC / DC converter 11a → a first inverter 21a → a second inverter 21b → a second DC / DC converter 11b. is there. On the other hand, in the separation type configuration shown in FIG. 1B, it is sufficient to pass through the two converters of the first DC / DC converter 11a → the second DC / DC converter 11b. Therefore, the separate type configuration shown in FIG. 1B has less loss when power is exchanged between distributed power sources.

Further, in the integrated configuration, it is necessary to add both the DC / DC converter 11 and the inverter 21 each time a distributed power source is added. On the other hand, in the separated type configuration, it is sufficient to add the DC / DC converter 11. Therefore, the separate configuration can reduce the cost of adding a distributed power source.

Further, in the integrated configuration, since the DC / DC converter 11 and the inverter 21 are provided, the size of the power conversion device 15 becomes large. On the other hand, in the separate type configuration, since only one of the DC / DC converter 11 and the inverter 21 is provided, the sizes of the power converters 10 and 20 can be reduced. Therefore, the separation type configuration has a greater degree of freedom in installation.

However, in the separate type configuration, the power balance control for maintaining the balance between the power input to the inverter 21 and the power output from the inverter 21 becomes complicated. Hereinafter, a power conversion system using a separate power conversion device will be described.

FIG. 2 is a diagram for explaining the power conversion system 1 according to the embodiment of the present invention. The power conversion system 1 according to the embodiment includes a first DC / DC power conversion device 10a, a second DC / DC power conversion device 10b, and a DC / AC power conversion device 20. The first DC / DC power conversion device 10a and the second DC / DC power conversion device 10b are connected in parallel, and the first DC / DC power conversion device 10a and the second DC / DC power conversion device 10b and the DC / AC power conversion are connected in parallel. The device 20 is connected via the intermediate bus 30.

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 solar cell, an organic thin-film solar cell, or the like is used. The solar cell 2 is connected to the first DC / DC power conversion device 10a, and the generated power is output to the first DC / DC power conversion device 10a.

The first DC / DC power conversion device 10a includes a first DC / DC converter 11a and a first converter control unit 12a. The first DC / DC converter 11a is a converter capable of adjusting the voltage of the DC power output from the solar cell 2. The first DC / DC converter 11a can be configured by, for example, a step-up chopper.

The first converter control unit 12a controls the first DC / DC converter 11a. The first converter control unit 12a can be realized by the collaboration of hardware resources and software resources, or only by hardware resources. Analog devices, microcomputers, DSPs, ROMs, RAMs, FPGAs, and other LSIs can be used as hardware resources. Programs such as firmware can be used as software resources.

As a basic control, the first converter control unit 12a controls the first DC / DC converter 11a by MPPT (Maximum Power Point Tracking) so that the output power of the solar cell 2 is maximized. Specifically, the first converter control unit 12a measures the input voltage and input current of the first DC / DC converter 11a, which are the output voltage and output current of the solar cell 2, and estimates the generated power of the solar cell 2. The first converter control unit 12a 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 first DC / DC converter 11a performs a switching operation according to a drive signal based on the generated command value.

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 DC / DC power conversion device 10b, and is charged / discharged controlled by the second DC / DC power conversion device 10b.

The second DC / DC power converter 10b includes a second DC / DC converter 11b and a second converter control unit 12b. The second DC / DC converter 11b is a bidirectional converter connected between the power storage unit 3 and the intermediate bus 30 to charge and discharge the power storage unit 3.

The second converter control unit 12b controls the second DC / DC converter 11b. The second converter control unit 12b can be realized by the cooperation of the hardware resource and the software resource, or only by the hardware resource. Analog devices, microcomputers, DSPs, ROMs, RAMs, FPGAs, and other LSIs can be used as hardware resources. Programs such as firmware can be used as software resources.

As basic control, the second converter control unit 12b controls the second DC / DC converter 11b based on the command value transmitted from the DC / AC power converter 20, and causes the power storage unit 3 to have a constant current (CC) / Charges / discharges at a constant voltage (CV). For example, the second converter control unit 12b receives a power command value from the inverter control unit 22 of the DC / AC power conversion device 20 at the time of discharge, and divides the power command value by the voltage of the power storage unit 3 to obtain a current command value. As a result, the second DC / DC converter 11b is discharged with a constant current.

The DC / AC power conversion device 20 includes an inverter 21, an inverter control unit 22, and a system voltage detection unit 23. The inverter 21 is a bidirectional inverter, converts DC power input from the intermediate bus 30 into AC power, and outputs the converted AC power to the distribution line 40 connected to the power system 4. A load 5 is connected to the distribution line 40. Further, the inverter 21 converts the AC power supplied from the power system 4 into DC power, and outputs the converted DC power to the intermediate bus 30. An electrolytic capacitor (not shown) for smoothing is connected to the intermediate bus 30.

The inverter control unit 22 controls the inverter 21. The inverter control unit 22 can be realized by the collaboration of hardware resources and software resources, or only by hardware resources. Analog devices, microcomputers, DSPs, ROMs, RAMs, FPGAs, and other LSIs can be used as hardware resources. Programs such as firmware can be used as software resources.

As basic control, the inverter control unit 22 controls the inverter 21 so that the voltage of the intermediate bus 30 maintains the first threshold voltage. Specifically, the inverter control unit 22 detects the voltage of the intermediate bus 30 and generates a command value for matching the detected bus voltage with the first threshold voltage. The inverter control unit 22 generates a command value for increasing the duty ratio of the inverter 21 when the voltage of the intermediate bus 30 is higher than the first threshold voltage, and the inverter when the voltage of the intermediate bus 30 is lower than the first threshold voltage. A command value for lowering the duty ratio of 21 is generated. The inverter 21 performs a switching operation according to a drive signal based on the generated command value.

The system voltage detection unit 23 detects the system voltage and outputs the detected voltage to the inverter control unit 22. The system voltage detection unit 23 detects the voltage on the power system 4 side from a relay (not shown) interposed between the inverter 21 and the distribution line 40.

A communication line 50 connects the first converter control unit 12a of the first DC / DC power conversion device 10a, the second converter control unit 12b of the second DC / DC power conversion device 10b, and the inverter control unit 22 of the DC / AC power conversion device 20. They are connected and communication conforming to a predetermined communication standard (for example, RS-485 standard, TCP-IP standard, CAN standard) is performed between those control units.

In the above circuit configuration, it may be necessary to suppress the output power of the inverter 21. The main reasons for suppressing output are the generation of reverse current from the inverter 21 to the power system 4, the instantaneous drop in the power system 4, the rise in the system voltage exceeding the set voltage, the reception of remote output commands, and the set temperature of the parts in the inverter 21. The temperature rise exceeds the rated power of the inverter 21, the power rise exceeds the rated power of the inverter 21, and the current rise exceeds the rated current of the inverter 21.

As a method of suppressing the output power of the inverter 21, a method of suppressing the output power of the first DC / DC converter 11a of the solar cell 2, a method of suppressing the output power of the second DC / DC converter 11b of the power storage unit 3, a method of suppressing the output power of the inverter 21 There is a way to suppress the output power. The method of suppressing the output power of the first DC / DC converter 11a of the solar cell 2 leads to wasting the amount of power generated by the solar cell 2. Therefore, the output suppression of the first DC / DC converter 11a 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 second DC / DC converter 11b of the power storage unit 3 is the most straightforward control. However, when the second DC / DC power converter 10b is separated from the DC / AC power converter 20 and installed at a position away from the power system 4, the second DC / DC converter of the power storage unit 3 is detected from the reverse power flow detection. A time lag is likely to occur before the output of 11b is suppressed.

Therefore, in the method in which the DC / AC power converter 20 detects reverse power flow, generates communication data instructing output suppression, and transmits the communication data to the second DC / DC power converter 10b via the communication line 50, the grid interconnection is specified. There is a possibility that the time limit (500ms) specified in is not observed. 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 21 first and then suppressing the output power of the second DC / DC converter 11b of the power storage unit 3 can be considered. As described above, the inverter control unit 22 controls the inverter 21 so that the voltage of the intermediate bus 30 maintains the first threshold voltage as basic control (hereinafter, referred to as power balance control). When the output suppression should be performed, the inverter control unit 22 executes the output suppression control in preference to the power balance control. Specifically, the limit value (upper limit value) of the current command value of the inverter 21 is set to zero. In the normal state, the limit value of the current command value of the inverter 21 is set to the rated output value of the inverter 21.

At the time when the output suppression of the inverter 21 is started, the output suppression of the first DC / DC converter 11a of the solar cell 2 and / or the second DC / DC converter 11b of the power storage unit 3 is not started. Therefore, the input power of the inverter 21 becomes excessive with respect to the output power of the inverter 21, and the voltage of the intermediate bus 30 rises. More specifically, electric charges are accumulated in the electrolytic capacitor connected to the intermediate bus 30.

As described above, as the basic control of the second converter control unit 12b, the amount of discharge from the power storage unit 3 to the second DC / DC converter 11b or the amount of charge from the second DC / DC converter 11b to the power storage unit 3 is the DC / AC power. The second DC / DC converter 11b is controlled so as to have a command value transmitted from the conversion device 20. Further, the second converter control unit 12b controls the second DC / DC converter 11b so that the voltage of the intermediate bus 30 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 DC / AC power converter 20. The second threshold voltage is set to a value higher than the first threshold voltage.

As described above, the first converter control unit 12a performs MPPT control of the first DC / DC converter 11a so as to maximize the output power of the solar cell 2 as basic control. Further, the first converter control unit 12a controls the first DC / DC converter 11a so that the voltage of the intermediate bus 30 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 intermediate bus 30. When the system voltage is AC200V, the first threshold voltage is set in the range of DC300V to 370V, for example. In the following description, it is assumed that the voltage is set to 300V. 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 intermediate bus 30 rises due to the output suppression of the inverter 21, and when the voltage of the intermediate bus 30 reaches the second threshold voltage, the control of suppressing the rise of the bus voltage by the second DC / DC converter 11b of the power storage unit 3 is activated. When the energy of the voltage rise of the intermediate bus 30 is larger than the rise suppression energy of the second DC / DC converter 11b of the power storage unit 3, the voltage of the intermediate bus 30 further rises. When the voltage of the intermediate bus 30 reaches the third threshold voltage, the control of suppressing the increase in the bus voltage by the first DC / DC converter 11a of the solar cell 2 is activated.

3 (a) and 3 (b) are diagrams schematically depicting the voltage state of the intermediate bus 30. FIG. 2A shows the voltage state of the intermediate bus 30 in the steady state. The voltage of the intermediate bus 30 at a constant time is maintained at the first threshold voltage by the inverter 21. FIG. 3B shows the voltage state of the intermediate bus 30 when the output of the inverter 21 is suppressed. The voltage of the intermediate bus 30 during output suppression is maintained at the third threshold voltage by the first DC / DC converter 11a of the solar cell 2. Alternatively, it may be maintained at the second threshold voltage by the second DC / DC converter 11b of the power storage unit 3. When the output suppression of the inverter 21 is released from the state shown in FIG. 3B, the inverter 21 returns to the normal power balance control. Specifically, the limit value of the current command value of the inverter 21 is returned to the rated output value of the inverter 21.

FIG. 4 is a diagram showing each output waveform at the momentary low. When a momentary drop occurs in the power system 4, the system voltage and the output current of the inverter 21 become zero, and the voltage of the intermediate bus 30 rises. The inverter control unit 22 detects the occurrence and cancellation of the instantaneous drop in the power system 4 based on the detection value of the system voltage detection unit 23. The output power of the solar cell 2 becomes zero by the control of suppressing the rise of the bus voltage by the first DC / DC converter 11a, and the discharge power of the storage unit 3 becomes zero by the control of suppressing the rise of the bus voltage by the second DC / DC converter 11b. Become. If there is a vacancy in the capacity of the power storage unit 3, charging may be switched to.

When the instantaneous decrease of the power system 4 is released, it is necessary to promptly return the output power of the inverter 21 to the state before the instantaneous decrease. For example, it is preferable to restore the output power to 80% or more of the output power before the instantaneous reduction within 0.1 s. At that time, it is required that the output current at the time of recovery does not exceed 100% of the output current before the momentary decrease. The output power of the solar cell 2 and the discharge power of the power storage unit 3 return to the state before the instantaneous voltage drop as the bus voltage decreases.

FIG. 5 is a diagram showing a specific example of each output value at the time of instantaneous low. In the specific example shown below, the rated output power of the inverter is 5.5 kW. In the section 1, the power system 4 is in a normal state, the solar cell 2 outputs 3.0 kW, the power storage unit 3 discharges 2.0 kW, and the inverter 21 outputs 5.0 kW. The voltage of the intermediate bus 30 is balanced at 300V.

Section 2 is a state when a momentary drop occurs in the power system 4, and the output power of the inverter 21 is reduced to 0.0 kW due to output suppression. As a result, the power balance of the inverter 21 is disrupted, and the voltage of the intermediate bus 30 rises sharply. When the voltage of the intermediate bus 30 exceeds 390V, the control for suppressing the increase in the bus voltage by the second DC / DC converter 11b of the power storage unit 3 is activated, and when the voltage of the intermediate bus 30 exceeds 410V, the first DC / DC converter of the solar cell 2 is activated. The bus voltage rise suppression control by 11a is activated.

Section 3 is a state in which the instantaneous low continues, and the discharge power of the power storage unit 3 drops to 0.0 kW due to the control of suppressing the rise of the bus voltage by the second DC / DC converter 11b of the power storage unit 3, and the solar cell. The output power of the solar cell 2 is reduced to 0.0 kW due to the control of suppressing the increase in the bus voltage by the first DC / DC converter 11a of 2. As a result, the power balance of the inverter 21 is restored, and the voltage of the intermediate bus 30 stabilizes at 410V.

The section 4 is a state when the instantaneous decrease of the power system 4 is released, and the output suppression control of the inverter 21 is released. Specifically, the limit value of the current command value of the inverter 21 is returned to the output value before the momentary decrease (in this specific example, the current value corresponding to the 5.0 kW output). As a result, the output power of the inverter 21 increases, and the voltage of the intermediate bus 30 decreases. If the limit value of the current command value of the inverter 21 is returned to the rated value (in this specific example, the current value corresponding to the 5.5 kW output), a current (overcurrent) equal to or greater than the current before the instantaneous decrease will occur. It will flow. When the voltage of the intermediate bus 30 becomes less than 410V, the first DC / DC converter 11a of the solar cell 2 returns to the control before the instantaneous decrease and outputs 3.0 kW. When the voltage of the intermediate bus 30 becomes less than 390V, the second DC / DC converter 11b of the power storage unit 3 returns to the control before the instantaneous decrease and discharges 2.0 kW.

In the section 5, the power system 4 is in a normal state, the solar cell 2 outputs 3.0 kW, the power storage unit 3 discharges 2.0 kW, and the inverter 21 outputs 5.0 kW. The voltage of the intermediate bus 30 is balanced at 390V.

FIG. 6 is a diagram showing an example of each output waveform when the instantaneous low is released. The inverter 21 outputs an overcurrent when the instantaneous low current is released and the normal operating state is restored. When the output of the inverter 21 is restored while the voltage of the intermediate bus 30 has not dropped (a large charge is accumulated in the electrolytic capacitor connected to the intermediate bus 30), an overcurrent occurs. Hereinafter, a mechanism for suppressing an overcurrent when the output of the inverter 21 is restored will be introduced.

FIG. 7 is a flowchart for explaining the operation at the moment of instantaneous reduction in the power conversion system 1 according to the embodiment of the present invention. During normal operation, the inverter control unit 22 controls the inverter 21 to execute power balance control (S20). The first converter control unit 12a of the solar cell 2 controls the first DC / DC converter 11a to execute MPPT control and bus voltage rise suppression control. The second converter control unit 12b of the power storage unit 3 controls the second DC / DC converter 11b to execute charge / discharge control and bus voltage rise suppression control (S10).

When the inverter control unit 22 detects the occurrence of a momentary drop in the power system 4 (Y in S21), the inverter control unit 22 suppresses the output of the inverter 21 (S22). Specifically, the limit value of the current command value of the inverter 21 is set to zero. When the inverter control unit 22 detects that the instantaneous voltage drop of the power system 4 is released (Y in S23), the inverter control unit 22 transmits the first converter control unit 12a of the solar cell 2 and the second converter control unit 12b of the power storage unit 3 via the communication line 50. Is transmitted to the bus voltage drop control start instruction (S24). The inverter control unit 22 transmits a bus voltage drop control start instruction, and sets the limit value of the current command value of the inverter 21 to a current value corresponding to the output power before the instantaneous decrease (S25).

When the first converter control unit 12a of the solar cell 2 receives the start instruction of the bus voltage drop control from the inverter control unit 22, the first converter control unit 12a reduces the voltage of the intermediate bus 30 to the first threshold voltage (300 V in the above example). It controls the 1DC / DC converter 11a. When the second converter control unit 12b of the power storage unit 3 receives the start instruction of the bus voltage drop control from the inverter control unit 22, the second converter control unit 12b causes the second DC / DC converter 11b to reduce the voltage of the intermediate bus 30 to the first threshold voltage. Control (S11).

When the voltage of the intermediate bus 30 drops to the first threshold voltage (Y in S26), the inverter control unit 22 controls the first converter control unit 12a of the solar cell 2 and the second converter of the power storage unit 3 via the communication line 50. The end instruction of the bus voltage drop control is transmitted to the unit 12b (S27). When the first converter control unit 12a of the solar cell 2 and the second converter control unit 12b of the power storage unit 3 receive the end instruction of the bus voltage decrease control from the inverter control unit 22, the bus voltage decrease control ends (S12). The inverter control unit 22 returns the limit value of the current command value of the inverter 21 to the rated output value of the inverter 21 (S28).

As described above, according to the present embodiment, when the instantaneous voltage reduction of the power system 4 is released, the inverter control unit 22 sets the limit value of the current command value of the inverter 21 to the output current value before the instantaneous voltage reduction, and the first The 1-converter control unit 12a and the 2nd converter control unit 12b are instructed to reduce the voltage of the intermediate bus 30 to the first threshold voltage. As a result, the amount of current output from the inverter 21 can be suppressed when the instantaneous low is released, and the occurrence of overcurrent can be prevented. That is, by reducing the output power of the solar cell 2 and the discharge power of the power storage unit 3, it is possible to prevent excessive charge from being accumulated in the intermediate bus 30. Further, by setting the limit value of the current command value of the inverter 21 to the output current value before the instantaneous decrease, the output power before the instantaneous decrease can be quickly restored while preventing the overcurrent from flowing from the inverter 21. Can meet the FRT requirements.

Further, when the voltage of the intermediate bus 30 drops to the first threshold voltage, the limit value of the current command value of the inverter 21 is returned to the value before the instantaneous decrease. As a result, the inverter control unit 22 controls to reduce the voltage of the intermediate bus 30 by the power balance control, so that an overcurrent can be prevented from flowing from the inverter 21.

The present invention has been described above based on the embodiments. Embodiments are examples, and it is 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. ..

FIG. 8 is a diagram for explaining the power conversion system 1 according to the modified example. In the modified example, the first converter control unit 12a of the solar cell 2 and the second converter control unit 12b of the power storage unit 3 acquire the system voltage without communication. In the example shown in FIG. 8, the output wiring of the system voltage detection unit 23 of the DC / AC power conversion device 20 is branched and brought into the first converter control unit 12a and the second converter control unit 12b. In this case, the first converter control unit 12a and the second converter control unit 12b can detect the occurrence and cancellation of the instantaneous drop in the power system 4 earlier and more reliably than in the case of using communication. ..

Instead of the system voltage detection unit 23 in the DC / AC power conversion device 20, a dedicated system voltage detection unit for the first converter control unit 12a of the solar cell 2 may be provided. Further, a dedicated system voltage detection unit for the second converter control unit 12b of the power storage unit 3 may be provided.

In the flowchart of FIG. 7, the specification is such that the inverter control unit 22 does not notify the first converter control unit 12a and the second converter control unit 12b of the occurrence of the instantaneous decrease when the instantaneous decrease occurs, but the first converter control is performed when the instantaneous decrease occurs. The occurrence of a momentary decrease may be notified to the unit 12a and the second converter control unit 12b. In the first converter control unit 12a and the second converter control unit 12b, the voltage of the intermediate bus 30 does not become less than the third threshold voltage / the second threshold voltage even after a predetermined time (for example, 1s) has elapsed from the occurrence of the instantaneous drop. In this case, the bus voltage drop control may be started without receiving the bus voltage drop control start instruction from the inverter control unit 22.

In the above-described embodiment, the configuration (creation cooperation system) in which the first DC / DC power conversion device 10a and the second DC / DC power conversion device 10b are connected to the intermediate bus 30 is shown. In this respect, the present technology can be applied to a configuration in which only one of them is connected (photovoltaic power generation system / power storage system). The present technology can also be applied to a configuration in which three or more DC / DC power converters 10 are connected to the intermediate bus 30.

In addition, the embodiment may be specified by the following items.

[Item 1]
DC / DC converters (11a, 11b) that adjust the voltage of the DC power output by the DC power supply (2, 3) and output the adjusted DC power to the intermediate bus (30).
The first control unit (12a, 12b) that controls the DC / DC converters (11a, 11b) and
An inverter (21) that converts the DC power of the intermediate bus (30) into AC power and outputs the converted AC power to the power system (4).
A second control unit (22) that controls the inverter (21) so that the voltage of the intermediate bus (30) maintains the first predetermined value is provided.
The first control unit (12a, 12b) controls the DC / DC converter (11a, 11b) so that the voltage of the intermediate bus (30) becomes equal to or lower than the second predetermined value higher than the first predetermined value. And
When a momentary drop occurs in the power system (4), the second control unit (22) suppresses the output of the inverter (21).
When the flash is released,
The second control unit (22) shifts the state of the inverter (21) to a state that allows output up to a value corresponding to the output power of the inverter (21) before the occurrence of the instantaneous drop.
The first control unit (12a, 12b) controls the DC / DC converter (11a, 11b) so that the voltage of the intermediate bus (30) drops to the first predetermined value. Conversion system (1).
According to this, the output of the inverter (21) can be stably and quickly returned to the state before the momentary drop after the momentary drop is released.
[Item 2]
When the voltage of the intermediate bus (30) drops to the first predetermined value after the instantaneous drop is released.
Item 1 according to item 1, wherein the second control unit (22) shifts the state of the inverter (21) to a state that allows an output up to a value corresponding to the rated output of the inverter (21). Power conversion system (1).
According to this, after the voltage of the intermediate bus (30) drops to the first predetermined value, the output suppression of the inverter (21) is completely released, so that the voltage of the intermediate bus (30) becomes the first predetermined value. It is possible to prevent an overcurrent from being output from the inverter (21) in the process of decreasing the voltage.
[Item 3]
When the voltage of the intermediate bus (30) drops to the first predetermined value after the instantaneous drop is released.
The power conversion system (1) according to item 1 or 2, wherein the first control unit (12a, 12b) terminates control for reducing the voltage of the intermediate bus (30) to the first predetermined value. ).
According to this, the voltage of the intermediate bus (30) can be returned to the state before the instantaneous reduction after the instantaneous reduction is released.
[Item 4]
The second control unit (22) acquires the system voltage from the voltage detection unit (23) that detects the voltage of the power system (4).
When the second control unit (22) detects that the instantaneous drop in the power system (4) has been released based on the system voltage, the voltage of the intermediate bus (30) is increased to the first predetermined value. Notifying the first control unit (12a, 12b) of the instruction to start the control to be lowered,
When the first control unit (12a, 12b) obtains the start instruction from the second control unit (22), the first control unit (12a, 12b) starts control to reduce the voltage of the intermediate bus (30) to the first predetermined value. The power conversion system (1) according to any one of items 1 to 3, characterized in that.
According to this, the voltage of the intermediate bus (30) can be returned to the steady value by the DC / DC converters (11a, 11b) instead of the inverter (21) after the instantaneous drop is released.
[Item 5]
The first control unit (12a, 12b) acquires a system voltage from a voltage detection unit (23) that detects the voltage of the power system (4), and based on the acquired system voltage, the power system (4) The item according to any one of items 1 to 3, wherein when it is detected that the instantaneous voltage reduction is released, the control for lowering the voltage of the intermediate bus (30) to the first predetermined value is started. Power conversion system (1).
According to this, the voltage of the intermediate bus (30) can be returned to the steady value by the DC / DC converters (11a, 11b) instead of the inverter (21) after the instantaneous drop is released.
[Item 6]
DC / DC converters (11a, 11b) that adjust the voltage of the DC power output by the DC power supply (2, 3) and output the adjusted DC power to the intermediate bus (30).
A first control unit (12a, 12b) for controlling the DC / DC converters (11a, 11b) is provided.
This power converter (10a, 10b)
The voltage of the inverter (21) that converts the DC power of the intermediate bus (30) into AC power and outputs the converted AC power to the power system (4) and the voltage of the intermediate bus (30) have the first predetermined value. It is connected to a second control unit (22) that controls the inverter (21) so as to maintain it, and another power conversion device (20) including.
The first control unit (12a, 12b) controls the DC / DC converter (11a, 11b) so that the voltage of the intermediate bus (30) becomes equal to or lower than the second predetermined value higher than the first predetermined value. And
When a momentary drop occurs in the power system (4), the second control unit (22) suppresses the output of the inverter (21).
When the flash is released,
The second control unit (22) shifts the state of the inverter (21) to a state that allows output up to a value corresponding to the output power of the inverter (21) before the occurrence of the instantaneous drop.
The first control unit (12a, 12b) controls the DC / DC converter (11a, 11b) so that the voltage of the intermediate bus (30) drops to the first predetermined value. Conversion device (10a, 10b).
According to this, the output of the inverter (21) can be stably and quickly returned to the state before the momentary drop after the momentary drop is released.
[Item 7]
A DC / DC converter (11a, 11b) that adjusts the voltage of the DC power output by the DC power supply (2, 3) and outputs the adjusted DC power to the intermediate bus (30), and the DC / DC converter (the DC / DC converter). A power conversion device (20) connected to another power conversion device (10a, 10b) including a first control unit (12a, 12b) that controls 11a, 11b).
An inverter (21) that converts the DC power of the intermediate bus (30) into AC power and outputs the converted AC power to the power system (4).
A second control unit (22) that controls the inverter (21) so that the voltage of the intermediate bus (30) maintains the first predetermined value is provided.
The first control unit (12a, 12b) controls the DC / DC converter (11a, 11b) so that the voltage of the intermediate bus (30) becomes equal to or lower than the second predetermined value higher than the first predetermined value. And
When a momentary drop occurs in the power system (4), the second control unit (22) suppresses the output of the inverter (21).
When the flash is released,
The second control unit (22) shifts the state of the inverter (21) to a state that allows output up to a value corresponding to the output power of the inverter (21) before the occurrence of the instantaneous drop.
The first control unit (12a, 12b) is characterized in that the DC / DC converter (11a, 11b) is controlled so that the voltage of the intermediate bus (30) drops to the first predetermined value. Power converter (20).
According to this, the output of the inverter (21) can be stably and quickly returned to the state before the momentary drop after the momentary drop is released.

1 Power conversion system, 2 Solar cell, 3 Power storage unit, 3a Stationary storage battery, 3b In-vehicle storage battery, 4 Power system, 5 Load, 10a 1st DC / DC power conversion device, 10b 2nd DC / DC power conversion device, 10c, 15a , 15b, 15c power converter, 11a 1st DC / DC converter, 11b 2nd DC / DC converter, 11c 3rd DC / DC converter, 12a 1st converter control unit, 12b 2nd converter control unit, 20 DC / AC power converter , 21 Inverter, 22 Inverter control unit, 23 system voltage detector, 30 intermediate bus, 40 distribution line, 50 communication line.

Claims (7)

A DC / DC converter that adjusts the voltage of the DC power output by the DC power supply and outputs the adjusted DC power to the intermediate bus.
A first control unit that controls the DC / DC converter,
An inverter that converts the DC power of the intermediate bus into AC power and outputs the converted AC power to the power system.
A second control unit that controls the inverter so that the voltage of the intermediate bus maintains the first predetermined value is provided.
The first control unit controls the DC / DC converter so that the voltage of the intermediate bus becomes equal to or lower than the second predetermined value higher than the first predetermined value.
When a momentary drop occurs in the power system, the second control unit suppresses the output of the inverter.
When the flash is released,
The second control unit shifts the state of the inverter to a state that allows output up to a value corresponding to the output power of the inverter before the occurrence of the instantaneous drop.
The first control unit is a power conversion system characterized in that the DC / DC converter is controlled so that the voltage of the intermediate bus drops to the first predetermined value. When the voltage of the intermediate bus drops to the first predetermined value after the instantaneous drop is released,
The power conversion system according to claim 1, wherein the second control unit shifts the state of the inverter to a state that allows an output up to a value corresponding to the rated output of the inverter. When the voltage of the intermediate bus drops to the first predetermined value after the instantaneous drop is released,
The power conversion system according to claim 1 or 2, wherein the first control unit terminates control for lowering the voltage of the intermediate bus to the first predetermined value. The second control unit acquires the system voltage from the voltage detection unit that detects the voltage of the power system, and obtains the system voltage.
When the second control unit detects that the instantaneous drop in the power system has been released based on the system voltage, the second control unit issues a control start instruction for reducing the voltage of the intermediate bus to the first predetermined value. 1 Notify the control unit and
Any of claims 1 to 3, wherein when the first control unit acquires the start instruction from the second control unit, the first control unit starts control for lowering the voltage of the intermediate bus to the first predetermined value. The power conversion system according to item 1. The first control unit acquires a system voltage from a voltage detection unit that detects a voltage of the power system, and detects that the instantaneous drop in the power system has been released based on the acquired system voltage. The power conversion system according to any one of claims 1 to 3, wherein the control for lowering the voltage of the bus to the first predetermined value is started. A DC / DC converter that adjusts the voltage of the DC power output by the DC power supply and outputs the adjusted DC power to the intermediate bus.
A first control unit that controls the DC / DC converter is provided.
This power converter is
An inverter that converts DC power of the intermediate bus into AC power and outputs the converted AC power to the power system, and a second control that controls the inverter so that the voltage of the intermediate bus maintains the first predetermined value. It is connected to another power converter that has a unit and
The first control unit controls the DC / DC converter so that the voltage of the intermediate bus becomes equal to or lower than the second predetermined value higher than the first predetermined value.
When a momentary drop occurs in the power system, the second control unit suppresses the output of the inverter.
When the flash is released,
The second control unit shifts the state of the inverter to a state that allows output up to a value corresponding to the output power of the inverter before the occurrence of the instantaneous drop.
The first control unit is a power conversion device that controls the DC / DC converter so that the voltage of the intermediate bus drops to the first predetermined value. Another one including a DC / DC converter that adjusts the voltage of the DC power output by the DC power supply and outputs the adjusted DC power to the intermediate bus, and a first control unit that controls the DC / DC converter. A power converter connected to a power converter
An inverter that converts the DC power of the intermediate bus into AC power and outputs the converted AC power to the power system.
A second control unit that controls the inverter so that the voltage of the intermediate bus maintains the first predetermined value is provided.
The first control unit controls the DC / DC converter so that the voltage of the intermediate bus becomes equal to or lower than the second predetermined value higher than the first predetermined value.
When a momentary drop occurs in the power system, the second control unit suppresses the output of the inverter.
When the flash is released,
The second control unit shifts the state of the inverter to a state that allows output up to a value corresponding to the output power of the inverter before the occurrence of the instantaneous drop.
The first control unit is a power conversion device that controls the DC / DC converter so that the voltage of the intermediate bus drops to the first predetermined value.

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