JP6760872B2 - Power conversion system - Google Patents

Description

The present invention relates to a power conversion system such as a multi-source power conditioning system (hereinafter referred to as "multi-PCS") provided with a power information transmission circuit.

FIG. 7 is a block diagram showing a configuration of a main part of a conventional multi-PCS.
The multi-PCS 1 is a device for connecting a storage battery 2, a solar cell (not shown), and a power system 3. The storage battery 2 is connected to a storage battery converter unit (hereinafter referred to as “BAT unit”) 10 via a power line 4, and the BAT unit 10 is referred to as a grid interconnection inverter unit (hereinafter referred to as “INV unit”) via a power line 5. ) 20 is connected. The INV unit 20 is connected to the power system 3 via a power line 6 and a switch (not shown). A load 7 is connected to the power line 6. Further, a solar cell (not shown) is connected to a photovoltaic power generation converter unit (hereinafter referred to as "PV unit") via a power line, and this PV unit is connected to an INV unit 20 via a power line.

The BAT unit 10 includes a converter 11 that performs direct current / direct current conversion (hereinafter referred to as "DC / DC conversion") in both directions, and a control unit 12 that controls on / off of switching elements in the converter 11. There is. The INV unit 20 includes a grid interconnection inverter 21 that performs direct current / alternating current conversion (hereinafter referred to as “DC / AC conversion”) in both directions, a control unit 22 that controls on / off of switching elements in the inverter 21. It has. Although not shown, the PV unit also includes a converter that performs DC / DC conversion and a control unit that controls on / off of switching elements in the converter.

The control unit 12 on the BAT unit 10 side and the control unit 22 on the INV unit 20 side control the switching of the converter 11 and the inverter 21 based on the control command from the system control device 25 connected by the communication lines 7 and 8. It has a function. The control units 12 and 22 and the system control device 25 are composed of a microcomputer (hereinafter referred to as a “microcomputer”) or the like.

In the multi-PCS 1 of FIG. 7, for example, the DC generated power on the PV unit side (not shown) is converted into AC power by the INV unit 20 and supplied to the load 7 and back-fed to the power system 3. When the power consumption of the load 7 exceeds the power generated on the PV unit side (not shown), the power generated on the PV unit side and the DC discharge power on the BAT unit 10 side are converted into AC power by the INV unit 20. Along with being supplied to the load 7, the AC power of the power system 3 is supplied to the load 7.

When charging the storage battery 2, the AC power of the power system 3 is converted into DC power by the INV unit 20, and then the storage battery 2 is charged by the BAT unit 10. When the generated power on the PV unit side (not shown) is larger than the power consumption of the load 7, the surplus power on the PV unit side is supplied to the BAT unit 10 to charge the storage battery 2.

In the BAT unit 10, the electric power stored in the storage battery 2 must not be reverse-flowed to the power system 3, so that the discharge electric power of the storage battery 2 is controlled according to the output power of the INV unit 20. In order to control the discharge power of the storage battery 2, the controller uses the communication paths of the control unit 22, the communication line 8, the system control device 25, the communication line 7, and the control unit 12 in the BAT unit 10 in the INV unit 20. -It is common to transmit and update power information using communication standards such as the Controller Area Network (CAN).

This information transmission technique is described in the power supply device of Patent Document 2.

Reference numerals (1) to (4) attached in FIG. 7 indicate the timing of transmission of output power information.

Further, although not shown, in Patent Document 1, two BAT units controlled by a system control device are arranged in parallel, and power information supplied to one BAT unit is provided in the system control device. There is described a wind power generation facility that optimizes power fluctuation compensation by incorporating it into the other BAT unit via a frequency passing filter and using the power information for control in the other BAT unit.

FIG. 8 is a schematic functional block diagram showing a control unit 12 in the BAT unit 10 and a control unit 22 in the INV unit 20 in FIG. 7.
The control unit 12 in the BAT unit 10 and the control unit 22 in the INV unit 20 are connected to each other via a communication line 9 (that is, communication lines 7 and 8 in FIG. 7 and a system control device 25). ..

The control unit 12 in the BAT unit 10 includes a control unit main body 13 that program-controls the entire control unit, a transmission / reception unit 14 that transmits / receives power information, and the like. On the receiving side in the transmitting / receiving unit 14, there is a receiving unit 14a that receives power information sent from the control unit 22 in the INV unit 20 via the communication line 9, and a telegram that analyzes the telegram of the received power information. An analysis unit 14b and a correction unit 14c for correcting the analyzed telegram are provided. The corrected power information is used in the control unit main body 13 as a target value of the power output by the BAT unit 10.

Further, the control unit 22 in the INV unit 20 includes a control unit main body 23 that program-controls the entire control unit, a transmission / reception unit 24 that transmits / receives power information, and the like. The transmission side in the transmission / reception unit 24 is converted into an analog / digital conversion (hereinafter referred to as "A / D conversion") unit 24a that converts the power information of the analog value input from the input port PT into a digital value. A power value calculation unit 24b that calculates power information composed of digital values, a message creation unit 24c that creates a message of the calculated power value, and a transmission unit 24d that transmits the created message to the communication line 9 are provided. Has been done.

FIG. 9 is a timing chart showing the power information transmission process in the multi-PCS1 of FIGS. 7 and 8.
When transmitting the output power information on the inverter 21 side to the converter 11 side via the communication lines 9 (that is, the communication lines 7 and 8 and the system control device 25), the output power information is transmitted at the following timings (1) to (4). ..

First, in the timing (1), on the INV unit 20 side, the output measurement information of the inverter 21 is input to the input port PT of the control unit 22.

At the timing (2), in the transmission / reception unit 24 in the control unit 22, the output measurement information consisting of the input voltage value is converted into a digital value by the A / D conversion unit 24a. The power value calculation unit 24b calculates the output power value from the converted digital value, and the telegram creation unit 24c creates a transmission message including the output power value. Then, in the transmission unit 24d, the created transmission message is transmitted at an arbitrary communication cycle (for example, 10 Hz), and the update is performed at a predetermined update cycle.

At the timing (3), the system control device 25 generates an output power command value according to an arbitrary communication standard, and this output power command value is transmitted every arbitrary communication cycle (for example, 10 Hz) to determine a predetermined value. The update is performed in the update cycle.

After that, at the timing (4), the output power value of the converter 11 is controlled by the control unit 12 in the BAT unit 10 based on the received output power command value. That is, in the transmission / reception unit 14 in the control unit 12, the reception unit 14a receives the output power command value sent from the communication line 9, and the telegram analysis unit 14b analyzes the message of the received output power command value. Will be done. The analyzed telegram is corrected by the correction unit 14c. The corrected message controls the converter 11 and controls the output power value to a constant value.

JP-A-2002-349417 Japanese Unexamined Patent Publication No. 2011-101523

However, in the conventional multi-PCS1, in order to control the discharge power of the BAT unit 10, the system control device 25 is used to transmit and update the power information according to a communication standard such as CAN. Therefore, the following (a) There are problems such as (c).

(A) The cycle of transmitting and updating power information depends on the communication cycle of the communication standard, and high-speed control cannot be performed.
(B) A high-speed communication standard can be used, but the cost is increased.
(C) Compared to the PV unit (not shown), the BAT unit 10 has more functions to be controlled such as reverse power flow prevention, so that the control load amount of the system control device 25 and the control units 12 and 22 increases, and feedback is provided. It doesn't turn around.

In order to solve the problems (a) to (c), it is conceivable to use the power information transmission technique described in Patent Document 1, but the control load of the system control device 25 and the control units 12 and 22 Since the amount increases, the problem (c) cannot be solved.

The power conversion system of the present invention converts the DC power supplied from the DC power source into a predetermined DC power and outputs the DC power, converts the DC power supplied from the second power converter into a predetermined DC power, and converts the DC power into the predetermined DC power. The first power converter supplied to the power supply and the DC power supplied from the first power converter are converted into AC power and supplied to the load, and the AC power supplied from the power system is converted into DC power. The second power converter that supplies the first power converter to the first power converter is provided.

Further, in the power conversion system of the present invention, the power conversion of the first power converter is controlled, a voltage value is input to perform A / D conversion, and the converted digital value is corrected and output. The first control unit that generates a power command value and controls the output power of the first power converter, controls the power conversion of the second power converter, and outputs the power of the second power converter. A second control unit that outputs a pulse width modulation (hereinafter referred to as "PWM") signal according to information and the PWM signal are input and converted into the voltage value according to the pulse width of the PWM signal to obtain the said. It includes a transmission circuit for transmitting power to the first control unit.

According to the power conversion system of the present invention, the following effects (A) to (C) are obtained.

(A) Since the output power information of the second power converter is transmitted to the first control unit on the first power converter side using a transmission circuit (for example, a filter circuit), the cycle of the conventional communication standard is used. Output power information can be transmitted and updated at any time without depending on it. As a result, high-speed control and response to fluctuations in the output power of the second power converter can be realized.
(B) Since only an inexpensive transmission circuit is added, the cost is lower than that of replacing with a high-speed communication standard.
(C) Since the transmission / reception processing in the first control unit and the second control unit can be simplified, the control load of the first control unit and the second control unit can be suppressed.

The block diagram which shows the structure of the main part of FIG. 2 in Example 1 of this invention. Schematic block diagram showing a configuration example of a power conversion system (for example, multi-PCS) according to the first embodiment of the present invention. Schematic functional block diagram showing control units 52 and 62 in FIG. The figure which shows the example of the correction formula in the correction part 54b in FIG. The figure which shows the conversion image in the transmission circuit 80 in FIG. Timing chart of power information transmission processing of FIGS. 1 and 3 Block diagram showing the configuration of the main parts of the conventional multi-PCS Schematic functional block diagram showing control units 12 and 22 in FIG. Timing chart of power information transmission processing in FIGS. 7 and 8

The embodiments for carrying out the present invention will become clear when the following description of preferred embodiments is read in light of the accompanying drawings. However, the drawings are for illustration purposes only and do not limit the scope of the present invention.

(Multi-PCS of Example 1)
FIG. 2 is a schematic block diagram showing a configuration example of a power conversion system (for example, multi-PCS) according to the first embodiment of the present invention.
This multi-PCS30 is, for example, a system that interconnects a solar cell 31 having a power generation voltage of 80V to 450V DC, a storage battery 32 having a discharge voltage of 60V to 330V DC, and a power system 33 having a single-phase three-wire AC 202V. is there.

The multi-PCS 30 includes a PV unit 40 that performs DC / DC conversion on the generated power of the solar cell 31, a BAT unit 50 that uses a bidirectional DC / DC converter that charges and discharges the storage battery 32, and a power system 33. It has an INV unit 60 for grid interconnection and a system control device 70 for controlling the PV unit 40, the BAT unit 50, and the INV unit 60.

The PV unit 40, the BAT unit 50, and the INV unit 60 are connected to each other via, for example, a DC bus 44 of DC 350V to 450V. Further, the PV unit 40, the BAT unit 50, and the INV unit 60 are connected to the system control device 70 via a control bus 71 such as CAN.

The system control device 70 is, for example, an operation command from a system controller (not shown) (for example, when charging the storage battery 32, an operation command such as receiving power of 3 kW each from the power system 33 and the PV unit 40 to charge the storage battery 32). In response to this, control signals are sent to the PV unit 40, BAT unit 50, and INV unit 60 via the control bus 71 so that the PV unit 40, the BAT unit 50, and the INV unit 60 operate according to the operation command. Further, the system control device 70 has a function of receiving and processing signals from the units 40, 50, and 60 via the control bus 71. The system control device 70 is composed of a microcomputer or the like.

The PV unit 40 includes a converter 41 for DC / DC conversion connected between the solar cell 31 and the DC bus 44, and a control unit 42 that controls the operation of the converter 41.

The converter 41 is a non-isolated converter that converts the DC power generated by the solar cell 31 input via a switch (not shown) into a predetermined DC power and outputs the DC power to the DC bus 44. It has a circuit including a plurality of switching elements and the like that convert electric power and output it to the DC bus 44. The control unit 42 has a switching control function or the like that outputs a PWM signal to control the on / off operation of the switching element in the converter 41 based on the control signal given from the system control device 70, and is composed of a microcomputer or the like. ing.

The BAT unit 50 is a first power converter (for example, a converter for bidirectional DC / DC conversion) 51 connected between the storage battery 32 and the DC bus 44, and a first control for controlling the operation of the converter 51. It has a part 52 and.

The converter 51 converts the DC discharge power of the storage battery 32 input via a switch (not shown) into a predetermined DC power and outputs the DC power to the DC bus 44, or converts the DC power input from the DC bus 44 into a predetermined DC power. It is a non-isolated converter that converts to DC power and charges the storage battery 32 via a switch (not shown), and has a circuit composed of a plurality of switching elements and the like. The control unit 52 has a switching control function or the like that outputs a PWM signal to control the on / off operation of the switching element in the converter 51 based on the control signal given from the system control device 70, and is composed of a microcomputer or the like. ing.

The INV unit 60 controls the operation of a second power converter (for example, a grid interconnection inverter) 61 for bidirectional DC / AC conversion connected between the DC bus 44 and the power system 33, and the operation of the inverter 61. It has a second control unit 62 and the like.

The inverter 61 is a constant voltage constant frequency (CVCF) type that converts the direct current power input from the direct current bus 44 into alternating current power and outputs it to the power system 33 and the load 34 via a switch (not shown). It is an inverter of the above, and has a circuit composed of a plurality of switching elements and the like. The control unit 62 has a switching control function or the like that outputs a PWM signal to control the on / off operation of the switching element in the inverter 61 based on the control signal given from the system control device 70, and is composed of a microcomputer or the like. ing.

In the multi-PCS 30 having such a configuration, the following discharge operation (i) and charge operation (ii) are performed on the storage battery 32.

(I) Discharge operation The flow of the generated power of the solar cell 31 is as follows: solar cell 31 → PV unit 40 → DC bus 44 → INV unit 60 → load 34 (or load 34 and power system 33). The PV unit 40 performs maximum power point tracking control, and the INV unit 60 converts the power into AC power and supplies it to the load 34. If the generated power exceeds the power consumption of the load 34, the power flows back to the power system 33. In this case, the converter 51 in the BAT unit 50 is controlled by the control unit 52 so as not to exceed the power consumption of the load 34.

The power flow when the power consumption of the load 34 exceeds the power generated by the solar battery 31 is (output DC power of the PV unit 40 on the solar battery 31 side + output DC power of the BAT unit 50 on the storage battery 32 side) → AC power is supplied to the load 34 by two routes: the DC bus 44 → the output AC power of the INV unit 60 → the load 34, and the power system 33 → the load 34.

In this case, the PV unit 40 performs maximum power point tracking control, and the INV unit 60 converts the power into AC power and supplies it to the load 34. Further, the insufficient power is supplemented by the discharge power of the storage battery 32.

(Ii) Charging operation The flow of electric power during charging operation is a route of power system 33 → load 34 and a route of power system 33 → INV unit 60 → DC bus 44 → BAT unit 50 → storage battery 32. By the forward conversion operation of the inverter 61 in the INV unit 60, the converter 51 in the BAT unit 50 charges the storage battery 32 by controlling the charging current and the charging power of the control unit 52. However, when the generated power of the solar cell 31 is larger than the power consumption of the load 34, the BAT unit 50 performs the charging operation while performing the maximum power point tracking control by the PV unit 40. Further, under the control of the system control device 70, the BAT unit 50 can also charge the storage battery 32 from the power system 33 and the solar cell 31.

(Structure of a main part of the multi-PCS of Example 1)
FIG. 1 is a block diagram showing a configuration of a main part of FIG. 2 in the first embodiment of the present invention. Further, FIG. 3 is a schematic functional block diagram showing a first control unit 52 in the BAT unit 50 and a second control unit 62 in the INV unit 60 in FIG. 1.
Reference numerals (5) to (8) attached in FIG. 1 indicate the timing of transmission of output power information.

As shown in FIG. 1, the first control unit 52 in the BAT unit 50 and the second control unit 62 in the INV unit 60 are connected to the system control device 70 via communication lines 71a and 71b in the control bus 71. Has been done. One input / output terminal of the converter 51 as the first power converter in the BAT unit 50 is connected to the storage battery 32 as a DC power source via the power line 35, and the other input / output terminal is a DC bus which is a power line. It is connected to 44. One input / output terminal of the inverter 61 as the second power converter in the INV unit 60 is connected to the DC bus 44, and the other input / output terminal of the inverter 61 is connected to the power system 33 via the power line 36. It is connected.

In the converter 51 and the control unit 52 in the BAT unit 50, the converter 51 is controlled by the control unit 52 as described above, converts the DC discharge power supplied from the storage battery 32 into a predetermined DC power, and outputs the power. Further, it is a device that charges the storage battery 32 by converting the DC power supplied from the inverter 61 in the INV unit 60 into a predetermined DC power via the DC bus 44.

In the inverter 61 and the control unit 62 in the INV unit 60, the inverter 61 is controlled by the control unit 62 as described above, and the DC discharge power supplied from the converter 51 in the BAT unit 50 via the DC bus 44. Is converted into AC power and supplied to the load 34, and the AC power supplied from the power system 33 is converted into DC power and supplied to the converter 51.

The control unit 62 in the INV unit 60 is connected to the input terminal of the transmission circuit 80 via the communication line 72a, and the output terminal of the transmission circuit 80 is connected to the control unit 52 in the BAT unit 50 via the communication line 72b. It is connected. The transmission circuit 80 is a circuit that transmits the output power information of the inverter 61 output from the control unit 62 to the control unit 52.

As shown in FIG. 3, the control unit 62 in the INV unit 60 includes a control unit main body 63 having the above-mentioned switching control function, a transmission unit 64 controlled by the control unit main body 63, and the like. The transmission unit 64 inputs the output measurement information of the inverter 61 measured by the measurement unit (not shown) from the input port PT, A / D converts the output measurement information, and calculates the effective value and output power of each measurement information. It has a function of outputting a PWM signal having a pulse width corresponding to the output measurement information to the communication line 72a.

The transmission unit 64 includes an A / D conversion unit 64a that converts the output measurement information input from the input port PT into a digital value, and a power that calculates the output measurement information converted into a digital value to obtain the output power information. A value calculation unit 64b and a PWM output unit 64c that converts the obtained output power information into a PWM signal and outputs it to the communication line 72a are provided.

The control unit 52 in the BAT unit 50 includes a control unit main body 53 having the above-mentioned switching control function, a receiving unit 54 controlled by the control unit main body 53, and the like. The receiving unit 54 has an A / D input unit 54a that inputs a voltage value sent from the communication line 72b and converts it into a digital value, and an output power command of the control unit main body 53 that corrects the converted digital value. A correction unit 54b as a value is provided.

The transmission circuit 80 between the control units 62 and 52 has a function of converting the PWM signal sent from the communication line 72a into a voltage value corresponding to the pulse width and outputting it to the communication line 72b, for example, smoothing. It is composed of a filter circuit for.

(Operation of the main part of the multi-PCS of Example 1)
FIG. 4 is a diagram showing an example of a correction formula in the correction unit 54b in FIG. 3, in which the horizontal axis is the input A / D conversion value and the vertical axis is the power information grid corrected in a grid pattern (Grid). It is P [W].

The correction unit 54b corrects the input A / D conversion value according to the following equation, and outputs the corrected power information Grid P.
Grid P [W] = k * A / D conversion value + offset voltage
However, k; coefficient

5 (a) and 5 (b) are diagrams showing a conversion image in the transmission circuit 80 in FIG. 3, and FIG. 5 (a) shows an analog voltage value of a pattern I in which the pulse width of the input PWM signal is narrow. The image when converted to is and the figure (b) is an image when the pattern II having a wide pulse width of the input PWM signal is converted into an analog voltage value.

FIG. 6 is a timing chart showing a transmission process of power information via the transmission circuit 80 of FIGS. 1 and 3.

In the conventional power information transmission process, as shown in FIGS. 7, 8 and 9, the output power information is transmitted and updated at arbitrary communication cycles (for example, 10 Hz) in the timings (1) to (3). I do. Then, at the timings (3) to (4), the output power value of the converter 11 is controlled based on the received output power command value. Therefore, there is a problem as described above.

Therefore, in the first embodiment, in order to solve the conventional problem, when the output power information on the inverter 61 side is transmitted to the converter 51 side, the timings of the following (5) to (8) are transmitted via the transmission circuit 80. I am trying to transmit with.

First, at the timing (5), the output measurement information of the inverter 61 in the INV unit 60 is input to the input port PT of the control unit 62.

At the timing (6), in the transmission unit 64 in the control unit 62, the input output measurement information is converted into a digital value by the A / D conversion unit 64a. Next, the power value calculation unit 64b calculates the output power information from the converted digital value. After that, the PWM output unit 64c creates a PWM signal from the calculated output power information and transmits it to the communication line 72a. The pulse width of the PWM signal is updated in a predetermined cycle (for example, commercial power frequency 50/60 Hz).

As described above, at the timings (5) to (6), the PWM signal corresponding to the output power value of the inverter 61 is output to the communication line 72a.

As shown in FIGS. 5A and 5B, the PWM signal output to the communication line 72a is smoothed by the transmission circuit 80 and converted into an analog voltage value. For example, in the case of the pattern I in which the pulse width of the PWM signal is narrow as shown in FIG. 5A, the converted voltage value is low. On the other hand, in the case of the pattern II in which the pulse width of the PWM signal is wide as shown in FIG. 5B, the converted voltage value is high. Such an analog voltage value is transmitted to the control unit 52 on the converter 51 side via the communication line 72b.

Next, at the timing (7), in the receiving unit 54 in the control unit 52, the input voltage value is A / D converted by the A / D input unit 54a. This A / D conversion update is performed at an arbitrary cycle and timing. The converted digital value is corrected by the correction unit 54b as shown in FIG. 4, and the corrected power information Grid P is generated.

As described above, in the timings (6) to (7), the PWM signal is smoothed by the transmission circuit 80, converted into a voltage value corresponding to the PWM signal, and then A / D is performed by the A / D input unit 54a. It is converted and output at any timing. The output digital value is corrected by the correction unit 54b to generate the power information Grid P.

After that, at the timing (8), the generated power information Grid P is used as the output power command value of the control unit main body 53, and the output power value of the converter 51 is controlled. That is, at the timings (7) to (8), the converter 51 is controlled based on the A / D converted digital value.

(Effect of Example 1)
According to the first embodiment, the following effects (a) and (b) are obtained.

(A) Comparing the conventional information transmission process of FIG. 8 with the information transmission process of FIG. 3 of the first embodiment, conventionally, the inverter 21 side in the INV unit 20 and the converter 11 side in the BAT unit 10 are used. , Transmission / reception and telegram creation / analysis processing are performed via the communication line 9. On the other hand, in the first embodiment, a PWM signal having a pulse width corresponding to the output power information is output from the control unit 62 in the INV unit 60, smoothed by the transmission circuit 80, and controlled in the BAT unit 50. Since the processing is only input to 52, the processing amount of the information transmission processing can be reduced. Moreover, since the conventional processing of telegram creation and analysis can be omitted, the total amount of processing of information transmission can be reduced.

(B) In the first embodiment, the control load of the control units 52 and 62 is suppressed by simply adding the transmission circuit 80, which has a simple configuration and is inexpensive, and the BAT unit 50 side with respect to the fluctuation of the output power of the inverter 61. High-speed control and response can be realized.

(Modification example)
The present invention is not limited to the above-mentioned Example 1, and various usage forms and modifications are possible. Examples of this usage pattern and modification include the following (i) to (iii).

(I) The transmission circuit 80 may be composed of a circuit other than the filter circuit.
(Ii) Instead of the storage battery 32, it may be changed to another DC power source for which reverse power flow to the power system 33 is prohibited. Further, the control units 52 and 62 in FIG. 3 may be changed to functional blocks having other configurations, or the functional blocks may be configured by individual circuits.
(Iii) The overall configuration of the multi-PCS 30 shown in FIG. 2 and the configurations of the units 40, 50, and 60 may be changed to configurations other than those shown in the drawings. Further, the present invention can be applied to a power conversion system having another configuration instead of the multi-PCS30 shown in FIG.

30 Multi PCS
31 Solar cell 32 Storage battery (DC power supply)
33 Power system 40 PV unit (photovoltaic converter unit)
41 Converter 42 Control unit 50 BAT unit (storage battery converter unit)
51 converter (first power converter)
52 Control unit (1st control unit)
60 INV unit (system interconnection inverter unit)
61 Inverter (second power converter)
62 Control unit (second control unit)
70 System controller 80 Transmission circuit

Claims (3)

The first power conversion that converts the DC power supplied from the DC power supply into a predetermined DC power and outputs it, converts the DC power supplied from the second power converter into a predetermined DC power, and supplies the DC power to the DC power supply. With a vessel
The DC power supplied from the first power converter is converted into AC power and supplied to a load, and the AC power supplied from the power system is converted into DC power and supplied to the first power converter. With the second power converter,
The power conversion of the first power converter is controlled, a voltage value is input to perform analog / digital conversion, the converted digital value is corrected to generate an output power command value, and the first power converter is generated. The first control unit that controls the output power of the power converter,
A second control unit that controls power conversion of the second power converter and outputs a pulse width modulation signal according to the output power information of the second power converter.
A transmission circuit that inputs the pulse width modulation signal, converts it into the voltage value corresponding to the pulse width of the pulse width modulation signal, and transmits it to the first control unit.
A power conversion system characterized by being equipped with. The power conversion system according to claim 1, wherein the transmission circuit includes a filter circuit that smoothes the pulse width modulation signal to generate the voltage value. The DC power source is a storage battery.
The first power converter is a converter that performs direct current / direct current conversion in both directions.
The second power converter is an inverter for grid interconnection that performs DC / AC conversion in both directions.
The power conversion system according to claim 1 or 2, wherein the power conversion system is characterized in that.

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