JP2015177575A - Power transfer system and power transfer method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve efficiency of using power among a plurality of clusters (users).SOLUTION: A power transfer system 1 includes: a first cluster unit (master cluster unit 100) that is to be a power reception point of a commercial power system 2 to receive commercial power supply from the commercial power system 2; and second cluster units (slave cluster unit 200, and slave cluster unit 300 and the like) that receive commercial power supply through the first cluster unit. Each of the first cluster unit and the second cluster units comprises: a power generation apparatus and a load apparatus; or a power storage apparatus and a load apparatus. Power transfer using AC power and power transfer using DC power are performed between the first cluster unit and a second cluster unit and between a plurality of the second cluster units.

Description

  The present invention relates to a power accommodation system and a power accommodation method for accommodating power among a plurality of clusters (customers).

  In recent years, the introduction of distributed power sources using renewable energy using natural energy such as solar power generation and wind power generation has been actively conducted. However, since the generated power greatly depends on the weather and weather conditions, it is difficult to match the demand power, and if the generated power is more than the demand power, the power generation by the distributed power source using renewable energy is stopped. In many cases, natural energy cannot be fully utilized because it is necessary to use a simulated load or to reversely flow back to a commercial system. Thus, an electric power interchange system that efficiently matches the energy supply and demand of electric power among a plurality of clusters (between customers) has been attracting attention.

  For example, a power amount accommodation control method for a power system is disclosed (see Patent Document 1). In the power amount accommodation control method of the power system of the power system described in Patent Document 1, power amount accommodation control is performed between a plurality of consumers via the power amount accommodation control device. The electric power interchanged among a plurality of consumers is electric power charged in the power storage unit. The power supply for supplying the power charged in the power storage unit to the load in the consumer by direct current according to the power storage remaining amount charged in the power storage unit, and the control of power supply stop are executed.

JP 2006-288162 A

Even if the power charged in the power storage unit can be accommodated with a direct current by the power amount accommodation control method of Patent Document 1, the literature does not mention that the power is accommodated with an alternating current. For this reason, the mutual cooperation of the renewable energy was aimed at among several consumers, and it was an obstacle to raising the utilization efficiency of electric power.
The present invention has been made in view of such a situation, and provides a power accommodation system and a power accommodation method that can improve the power utilization efficiency among a plurality of clusters (between consumers). .

  The present invention has been made to solve the above-described problem, and a power interchange system of the present invention is a first cluster unit that serves as a power reception point of a commercial power system and receives supply of commercial power from the commercial power system, One or a plurality of second cluster units that receive supply of the commercial power via the first cluster unit, and a power interchange system comprising the first cluster unit and the second cluster unit Each includes a power generation device and a load device, or a power storage device and the load device, and is powered by AC power between the first cluster unit and the second cluster unit and between the plurality of second cluster units. And accommodation of electric power by DC power.

  In the power interchange system, the first cluster unit and the second cluster unit are connected by an AC bus serving as an AC power feeding path and connected by a DC bus serving as a DC power feeding path. The AC power is interchanged through the AC bus and the DC power is interchanged through the DC bus between the first cluster unit and the second cluster unit.

  In the power accommodation system, when power is interchanged between the first cluster unit and the second cluster unit and between the plurality of second cluster units, a mode in which only AC power is interchanged; Further, the present invention is characterized in that it can be selected between a mode for accommodating only DC power and a mode for accommodating both AC power and DC power.

  In the power accommodation system, the first cluster unit and the second cluster unit include a bidirectional AC / DC converter that performs bidirectional power conversion between AC power and DC power, and DC power and DC power. A bidirectional DC converter that performs bidirectional power conversion between the AC bus and the bidirectional AC / DC converter that distributes AC power supplied from the AC bus to a power supply path inside the cluster unit. The power is converted into electric power, the converted DC power is supplied to the DC load device, the operation mode for storing the converted DC power in the power storage device, and the power generation device or the power storage device provided in the own cluster unit is supplied. An operation mode for converting DC power into the ac power to be accommodated and supplying the AC power to the AC bus, wherein the bidirectional DC converter is configured to convert the DC power supplied from the DC bus into a class. An operation mode in which the converted DC power is supplied to a DC load device, and the converted DC power is stored in the power storage device; An operation mode for converting the DC power supplied from the power storage device into the flexible DC power and supplying the DC power to the DC bus.

  Further, in the power accommodation system, the first cluster unit converts the power supplied from the first power generation device into AC power and connects to the connection destination power supply path, and the first power conditioner. The power conditioner connection destination includes a power supply path for supplying power to the AC bus and a power supply path for supplying power to the commercial power system, and the power supply path for supplying power to the AC bus and the commercial power system A first switching unit that switches a power supply path for supplying electric power, and the first switching unit supplies power to the AC bus from the first power conditioner. The connection destination is a power supply path for supplying power to the AC bus.

  Further, in the power accommodation system, the first cluster unit converts the power supplied from the second power generation device into DC power and connects the second power conditioner to a connection power supply path, and the second power conditioner. The power conditioner connection destination includes a power supply path for supplying power to the DC bus and a power supply path for distributing DC power inside the own cluster unit, and the power supply path for supplying power to the DC bus and the own cluster unit A second switching unit that switches between a power supply path for distributing DC power inside the second switching unit, and when the second switching unit supplies power to the DC bus from the second power conditioner, the second switching unit The connection destination of the power conditioner is a power supply path for supplying power to the DC bus.

  Further, in the power accommodation system, the second cluster unit converts the power supplied from the third power generation device into AC power and connects to the power supply path of the connection destination, and the third power conditioner. A power supply path that supplies power to the AC bus and a power supply path that distributes AC power inside the own cluster unit are connected to the inverter, and the power supply path that supplies power to the AC bus and the own cluster A third switching unit that switches between a power supply path for distributing AC power inside the unit, and the third switching unit supplies power to the AC bus from the third power conditioner. The connection destination of the three power conditioners is a power supply path for supplying power to the AC bus.

  Further, in the power accommodation system, the second cluster unit converts the power supplied from the fourth power generation device into DC power and connects the power to a connection destination power supply path, and the fourth power conditioner. A power supply path for supplying power to the DC bus and a power supply path for distributing DC power inside the own cluster unit at a connection destination of the inverter, and a power supply path for supplying power to the DC bus and the own cluster A fourth switching unit that switches a power supply path that distributes DC power to the inside of the unit, and the fourth switching unit supplies power to the DC bus from the fourth power conditioner. The connection destination of the four power conditioners is a power supply path for supplying power to the DC bus.

  In the power accommodation system, in the first cluster unit and the second cluster unit, AC exchange is performed via the AC bus, DC exchange is performed via the DC bus, or the AC bus is performed. When determining whether to perform both AC interchange via DC and DC power via the DC bus, when performing conversion between AC power and DC power in the bidirectional AC / DC converter The DC power supply direction is determined.

  In the power interchange system, the first cluster unit and the second cluster unit may perform AC interchange via the AC bus, perform DC interchange via the DC bus, or use the AC bus. Of the power storage device provided in a cluster unit corresponding to a supply source of the first cluster unit and the second cluster unit for selecting whether to perform both AC interchange via the DC bus and DC interchange via the DC bus. It implements according to storage battery remaining capacity.

  The power interchange method of the present invention includes a first cluster unit that serves as a power receiving point of a commercial power system and receives commercial power from the commercial power system, and receives the commercial power supplied via the first cluster unit. Or each of the first cluster unit and the second cluster unit includes a power generation device and a load device, or a power storage device and the load device, each of which generates power. A power accommodation method in a power accommodation system including any one or all of a device, a power storage device, and a load device, wherein the plurality of second clusters are provided between the first cluster unit and the second cluster unit. Between the units, power is interchanged with AC power, and power is interchanged with DC power.

  ADVANTAGE OF THE INVENTION According to this invention, the utilization efficiency of electric power can be improved between several clusters (customer).

It is a lineblock diagram showing a schematic structure of electric power interchange system 1 concerning an embodiment of the present invention. 2 is a configuration diagram illustrating a configuration example of a power generation device 141 and a PCSAC 150. FIG. It is a block diagram which shows the structural example of conversion apparatus A120 and conversion apparatus D130. It is a block diagram which shows the structural example of converter B220. It is a block diagram which shows the modification of the electric power accommodation system shown in FIG. It is explanatory drawing which shows the outline | summary of the control operation | movement of the electric power accommodation in an electric power accommodation system. It is explanatory drawing for demonstrating the electric power interchange operation | movement in a cluster part. It is explanatory drawing which shows the example which selects AC accommodation and DC accommodation according to the storage battery remaining capacity SOC of an electrical storage apparatus. It is explanatory drawing which shows the example in the case of performing AC accommodation and DC accommodation using a switching part. It is a flowchart which shows the procedure of an electric power interchange process. It is explanatory drawing which shows the example of the starting process of AC accommodation mode and DC accommodation mode. It is a flowchart which shows the procedure of the completion | finish process of DC interchange mode. It is a flowchart which shows the procedure of the completion | finish process of AC interchange mode. It is explanatory drawing which shows the example of completion | finish of AC accommodation mode.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
(Schematic configuration of the power interchange system 1)
FIG. 1 is a configuration diagram showing a schematic configuration of a power interchange system 1 according to an embodiment of the present invention. As shown in FIG. 1, the power accommodation system 1 includes a parent cluster unit 100, a plurality of child cluster units 200 and child cluster units 300 placed under the parent cluster unit 100, an AC bus 31 and a DC bus. 32, and the power is interchanged. Further, the child cluster unit 400 is cascade-connected to the child cluster unit 400.

  Note that the AC bus 31 is a power supply path serving as a power supply bus for commonly connecting the parent cluster unit 100 and the plurality of child cluster units 200 and 300 to accommodate AC power. 31 may be referred to as a primary AC bus 31. In addition, the DC bus 32 is a power supply path that serves as a power supply bus for commonly connecting the parent cluster unit 100 and the plurality of child cluster units 200 and 300 to accommodate DC power. 32 may be referred to as a primary side DC bus 32. Also, in the parent cluster unit 100, the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400, a power supply path that distributes AC power is called a secondary AC bus, and a power supply path that distributes DC power is Sometimes called a secondary DC bus.

  In the power accommodation system 1, the control units of the parent cluster unit 100, the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400 are connected to the energy management apparatus (EMS) 11 via the communication network 12. ing. The energy management device (EMS) 11 monitors the power supply state in each cluster unit, and transmits a command signal to the control unit of each cluster unit to control its operation. For example, the energy management device (EMS) 11 collects information on the power consumption in each cluster, the power generation amount of the power generation device, and the storage battery remaining capacity SOC (State Of Charge) of the power storage device, and based on the collected information. Thus, power interchange control is performed so as to balance power consumption among the cluster units.

Note that the term “cluster” in the present embodiment refers to one unit (for example, a building unit) that includes a power generation device and a load device configured from a distributed power source using renewable energy, or a power storage device and a load device. This means an electric power cluster (electricity cluster).
For example, each of the parent cluster unit 100, the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400 includes a power generation device (for example, a solar power generation device) that uses renewable energy, and an energy storage system. And a load device of a consumer.

In the power interchange system 1, the parent cluster unit 100 includes the circuit breaker (CB) 101, the transformer 102, the control unit 110, the conversion device A120, the conversion device D130, the power generation device 141, the power generation device 142, the AC load device 143, and the direct current. A load device 144, a power storage device 145, a power conditioner (PCSAC) 150, a power conditioner (PCSDC) 150A, a distribution board 161, a distribution board 162, and a switching unit 160 are provided.
In the following description, a power conditioner (PCSAC) that outputs AC power may be simply referred to as “PCSAC”, and a power conditioner (PCSDC) that outputs DC power may be simply referred to as “PCSDC”.

  In the parent cluster unit 100, the transformer 102 steps down the high-voltage AC voltage (for example, 3-phase AC 6600V) supplied from the commercial power system 2 to a predetermined low-voltage AC voltage (for example, 3-phase AC 400V). The voltage is supplied to the converter A120.

  The control unit 110 is a control unit that controls the overall operation of the parent cluster unit 100. The control unit 110 is configured using, for example, a microcomputer and its peripheral circuits, and detects current and voltage detected by a current and voltage detection unit (not shown) installed in each part of the parent cluster unit 100. The operations of the conversion device A120, the conversion device D130, and the switching unit 160 are controlled according to the signal. In addition, the control unit 110 collects information on the power generation amount of the power generation device and the storage battery remaining capacity SOC of the power storage device, and transmits the collected information to the energy management device (EMS) 11.

The converter A120 is a converter that performs bidirectional power conversion between AC power and DC power, and the converter D130 is a converter that performs bidirectional power conversion between DC power and DC power. is there. The configurations of the conversion device A120 and the conversion device D130 will be described later.
A distribution board 161 is connected to the conversion device A 120 via a power supply path 175, and a distribution board 162 is connected via a power supply path 172. The distribution board 161 is connected to the primary side AC bus 31, the AC load device 143, and one end of the switching unit 160 via an unillustrated overcurrent breaker (breaker).
In addition, power distribution device 145, PCSDC 150A, and DC load device 144 are connected to distribution board 162 via an unillustrated overcurrent breaker (breaker). Note that the DC load device 144 is a device that operates with DC power, and is, for example, DC appliances, LED lighting, information devices such as personal computers and servers, and the like.
The distribution board 161 is an AC power distribution board, and the distribution board 162 is a DC power distribution board.

  The power generation devices 141 and 142 are, for example, natural energy type power generation devices such as solar power generation and wind power generation, engine power generation devices, and fuel cells. The power conditioner (PCSAC) 150 converts the power generated by the power generation device 141 into predetermined AC power and outputs it. Further, the power conditioner (PCSDC) 150A converts the power generated by the power generator 142 into predetermined DC power and outputs it. The configurations of the power generation devices 141 and 142 and the configurations of the PCSAC 150 and the PCSDC 150A will be described later.

  The power storage device 145 is connected to the distribution board 162. The power storage device 145 includes, for example, a secondary battery such as a lithium ion battery, a lead battery, or a nickel metal hydride battery. The power storage device 145 is charged with electric power output from the power generation device 142 via the PCSDC 150A. In addition, power storage device 145 is charged by DC current Idc output from conversion device A120. This power storage device 145 supplies electric power to the DC load device 144 via the distribution board 162 by the accumulated charge during a power failure when the AC voltage (AC6600V) is not supplied from the commercial power system 2, and the distribution board 162 Power is supplied to the AC load device 143 and the primary AC bus 31 via the conversion device A120. The power storage device 145 can also supply power to the primary DC bus 32 via the distribution board 162 and the conversion device D130.

The switching unit 160 is configured with a 1c contact, a make contact is configured with the common contact c and the contact a, and a break contact is configured with the common contact c and the contact b. The switching operation of the contact in the switching unit 160 is controlled by an open / close signal (not shown) output from the control unit 110, and the common contact c and the contact a are in a conductive state (the common contact c and the contact b are non-conductive). Any state in which the common contact c and the contact b are conductive (the common contact c and the contact a are non-conductive) is selected.
The power generator 141 is connected to the common contact c via the PCSAC 150, the power supply path 174 connected to the distribution board 161 is connected to the contact b, and the transformer 102 is connected to the contact a. A power supply path 171 connected to the secondary side is connected.

In the switching unit 160, when the contact b and the common contact c are brought into conduction, the power generated by the power generation device 141 is output to the distribution board 161 via the power supply path 174. In addition, in the switching unit 160, when the contact point a and the common contact point c are brought into conduction, the power generated by the power generation device 141 is supplied as surplus power to the commercial power system 2 side through the transformer 102. Is done.
The switching unit 160 shows an example of a switch using a mechanical contact, but actually, the switching unit 160 is configured by a semiconductor switch using a semiconductor switching element such as an IGBT (Insulated Gate Bipolar Transistor). Has been. The switching unit 160A (FIG. 5) of the parent cluster unit 100, the switching unit 260 of the child cluster unit 200, the switching unit 260A (FIG. 5), the switching unit 360 of the child cluster unit 300, and the child cluster unit 400 described later. The same applies to the switching unit 460 and the like.

The basic configuration of the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400 is the same as that of the parent cluster unit 100 except that it does not have a power reception point of the commercial power system 2.
For example, the child cluster unit 200 includes the control unit 210, the conversion device B220, the power generation device 241, the power generation device 242, the AC load device 243, the DC load device 244, the power storage device 245, the PCSAC250, the PCSDC250A, the switching unit 260, and the distribution board 261. , And a distribution board 262.

In the child cluster unit 200, the control unit 210 is a control unit that controls the overall operation of the child cluster unit 200. The conversion device B220 is a conversion device that performs bidirectional power conversion between AC power and DC power, and performs bidirectional power conversion between DC power and DC power. The configuration of the conversion device B220 will be described later.
A distribution board 261 is connected to the conversion device B220 via a secondary AC bus 41 inside the cluster, and a distribution board 262 is connected via a secondary DC bus 42 inside the cluster. The distribution board 261 is connected to the AC load device 243 and one end of the switching unit 260 via an unillustrated overcurrent breaker (breaker).

  The switching unit 260 is configured with a 1c contact similarly to the switching unit 160 of the parent cluster unit 100, and the power generator 241 is connected to the common contact c via the PCSAC 250, and the contact b of the switching unit 260 is connected. The side is connected to the distribution board 261, and the contact a side of the switching unit 260 is connected to the primary AC bus 31.

When the contact point b and the shared contact point c are brought into conduction in the switching unit 260, the power generated by the power generator 241 is output to the distribution board 261 via the PCSAC 250. Further, in the switching unit 260, when the contact a and the common contact c are brought into conduction, the power generated by the power generation device 241 is output to the primary AC bus 31 as surplus power.
In addition, the power distribution device 245, the PCSDC 250A, and the DC load device 244 are connected to the distribution board 262 via an unillustrated overcurrent circuit breaker (breaker).

In the child cluster unit 300, the control unit 310 is a control unit that controls the overall operation of the child cluster unit 300. The converter E320 is a converter that performs bidirectional power conversion between AC power and DC power, and performs bidirectional power conversion between DC power and DC power. The configuration of the conversion device E320 will be described later.
A distribution board 361 is connected to the converter E320 via the secondary AC bus 51 inside the cluster, and a distribution board 362 is connected via the secondary DC bus 52. The distribution board 361 is connected to an AC load device 343 and one end of a switching unit 360 via an unillustrated overcurrent breaker (breaker).

  Similarly to the switching unit 260 of the child cluster unit 200, the switching unit 360 is configured with a 1c contact (not shown), and the power generator 341 is connected to the common contact c via the PCSAC 350. The switching unit 360 The contact b side is connected to the distribution board 361, and the contact a side of the switching unit 360 is connected to the primary AC bus 31.

Then, in the switching unit 360, when the contact b (not shown) and the common contact c are brought into conduction, the power generated by the power generator 341 is output to the distribution board 361. Further, in the switching unit 360, when the contact a (not shown) and the common contact c are brought into conduction, the power generated by the power generation device 341 is output to the primary AC bus 31 as surplus power.
In addition, a power storage device 345 and a DC load device 344 are connected to the distribution board 362 via an unillustrated overcurrent circuit breaker (breaker).

The child cluster unit 400 is a cluster that is cascade-connected to the child cluster unit 300. In the child cluster unit 400, the control unit 410 is a control unit that controls the overall operation of the child cluster unit 400. The conversion device C420 is a conversion device that performs bidirectional power conversion between AC power and DC power, and performs bidirectional power conversion between DC power and DC power. The configuration of the conversion device C420 will be described later.
The conversion device C420 is connected to the child cluster unit 300 via the secondary side AC bus 61 and the secondary side DC bus 62. The secondary AC bus 61 is connected to the secondary AC bus 51 via the distribution board 361 in the child cluster unit 300. The secondary DC bus 62 is connected to the secondary DC bus 52 via the distribution board 362 in the child cluster unit 300. Further, a distribution board 461 and a distribution board 462 are connected to the conversion device C420. The distribution board 461 is connected to the AC load device 443 and one end of the switching unit 460 via an unillustrated overcurrent circuit breaker (breaker). In addition, a power storage device 445 and a DC load device 444 are connected to the distribution board 462 via an unillustrated overcurrent circuit breaker (breaker).

  Similar to the switching unit 260 of the child cluster unit 200, the switching unit 460 is configured with a 1c contact (not shown), and the power generator 441 is connected to the common contact c via the PCSAC 450. The contact b of the switching unit 460 is connected to the distribution board 461, and the contact a of the switching unit 460 is connected to the secondary AC bus 61.

  In the switching unit 460, when the contact b (not shown) and the common contact c are brought into conduction, the power generated by the power generation device 441 is output to the distribution board 461 via the power supply path 71. Further, in the switching unit 460, when the contact point a (not shown) and the common contact point c are brought into conduction, the power generated by the power generation device 441 is output to the secondary AC bus 61 as surplus power.

(Configuration of power generator and power conditioner)
Next, the configuration of the power generation device 141 and the PCSAC 150 of the parent cluster unit 100 will be described. The power generators 241 and PCSAC 250 of the child cluster unit 200, the power generators 341 and PCSAC 350 of the child cluster unit 300, and the power generators 441 and PCSAC 450 of the child cluster unit 400 have the same configuration.

  FIG. 2 is a configuration diagram illustrating a configuration example of the power generation device 141 and the PCSAC 150. The example shown in FIG. 2A shows an example in which a solar cell array 141a is used as the power generation device 141. The PCSAC 150 includes a power generation amount control unit 151, a grid interconnection control unit 152, and a DC / AC. A converter (inverter) 153 and a transformer 154 are provided.

  In order to extract the maximum power from the power generation device 141, the power generation amount control unit 151 has an operating point (maximum power point) that maximizes the output of the solar cell array 141a in the IV (current-voltage) characteristics of the solar cell array 141a. ) To control. The maximum power point of the solar cell array 141a is shifted depending on the voltage actually required by the connected load. Since the IV characteristic changes depending on the solar radiation intensity, the module temperature, the state, etc., in order to obtain the maximum power, the optimum voltage or current must be automatically followed. Therefore, the power generation amount control unit 151 controls the solar cell array 141a to operate at the maximum power point.

  Further, the grid interconnection control unit 152 can supply power output from the PCSAC 150 by being linked to the primary AC bus 31 by adjusting the phase of the output voltage of the DC / AC converter (inverter) 153. To control. The DC / AC converter (inverter) 153 converts the DC voltage output from the solar cell array 141a into an AC voltage, and supplies the AC voltage to the primary AC bus 31 via the transformer 154. It is an inverter.

  The PCSAC 150 temporarily stops its operation when a power failure occurs in the commercial power system 2. Thereafter, the supply of power from the backup power storage device 145 to the AC bus 31 via the conversion device A120 is started, and the charge stored in the power storage device 145 is eventually insufficient or depleted. When the power cannot be supplied to the PCSAC 150, the PCSAC 150 starts up again. That is, the PCSAC 150 is activated when power cannot be supplied from the power storage device 145 to the AC bus 31 during a power failure of the commercial power system 2, and supplies the power generated by the power generation device 141 to the AC bus 31. In this case, it goes without saying that the PCSAC 150 operates not in an operation mode linked to the grid but in a mode in which power is supplied independently.

FIG. 2B is a configuration diagram illustrating a configuration example of the power generation device 142 and the PCSDC 150A. The power generator 242 and the PCSDC 250A of the child cluster unit 200 have the same configuration.
In the example illustrated in FIG. 2B, an example in which a solar cell array 142a is used as the power generation device 142 is illustrated as in the example illustrated in FIG. The PCSDC 150A includes a power generation amount control unit 151, a grid interconnection control unit 152A, and a DC / DC converter 155.
The grid interconnection control unit 152 </ b> A supplies DC power to the distribution board 162 by adjusting the output voltage of the DC / DC converter 155.

(Configuration of Conversion Device A120 and Conversion Device D130)
FIG. 3 is a configuration diagram illustrating a configuration example of the conversion device A120 and the conversion device D130.
As illustrated in FIG. 3A, the conversion device A 120 includes a bidirectional AC / DC converter (bidirectional AC / DC converter) 121 and a switch unit (SW) 122.
When the switch unit 122 is in the closed state, the conversion device A120 converts a commercial AC voltage (for example, AC400V) output from the transformer 102 along the direction indicated by the broken line a through the distribution board 161. Output to the primary AC bus 31. When a power failure occurs in the commercial power system 2, the control unit 110 interrupts the switch unit 122 and disconnects (that is, disconnects) the load side of the converter A120 from the commercial power system 2.

  The bidirectional AC / DC converter 121 includes an AC / DC converter function and a DC / AC converter (inverter) function. The bi-directional AC / DC converter 121 converts AC power input from the transformer 102 into DC power along the direction indicated by the broken line b by the AC / DC converter function, and supplies the DC power feed path 172 in the cluster unit. To the distribution board 162.

Further, the bidirectional AC / DC converter 121 uses the DC / AC converter (inverter) function to accommodate the DC power supplied from the power generation device 142 and the power storage device 145 along the direction indicated by the broken line c to the primary AC bus 31. The AC power is converted to AC power, and the AC power is output to the primary AC bus 31.
The bidirectional AC / DC converter 121 converts AC power input from the primary AC bus 31 through the distribution board 161 into DC power along the direction indicated by the broken line d by the AC / DC converter function. Then, the power is output to the distribution board 162 via the DC power supply path 172 in the cluster unit.
The operation of outputting surplus power from the power generation device 141, the power generation device 142, etc. in the parent cluster unit 100 to the primary AC bus 31 as AC power may be referred to as “AC interchange” or “AC interchange”. The same applies to the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.

Further, as shown in FIG. 3B, the conversion device D130 includes a bidirectional DC converter (bidirectional DC / DC converter) 131, and is bidirectional between the DC bus 32 and the distribution board 162. The DC power is converted into and the DC power is transferred. For example, the bidirectional direct current converter 131 converts the direct current power supplied from the power generation device 142 and the power storage device 145 into the direct current power accommodated in the primary side DC bus 32 along the direction indicated by the broken line e. Is output to the primary side DC bus 32.
The bidirectional DC converter 131 receives DC power from the primary DC bus 32 along the direction indicated by the broken line f, converts the DC power into DC power distributed in the cluster unit, To the distribution board 162.
The operation of outputting surplus power from the power generation device 142, the power storage device 145, etc. in the parent cluster unit 100 to the primary DC bus 32 as DC power may be referred to as “DC interchange” or “DC interchange”. The same applies to the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.

(Configuration of Conversion Device B220, Conversion Device E320, and Conversion Device C420)
Next, the configuration of the conversion device B220, the conversion device E320, and the conversion device C420 will be described. Since the conversion device B220, the conversion device E320, and the conversion device C420 are conversion devices having the same configuration, the conversion device B220 is shown as a representative, and the configuration of the conversion device B220 will be described.
FIG. 4 is a configuration diagram illustrating a configuration example of the conversion device B220.
As shown in FIG. 4, the conversion device B220 includes a bidirectional AC / DC converter (bidirectional AC / DC converter) 221, a switch unit (SW) 222, and a bidirectional DC converter (bidirectional DC / DC converter). ) 223 and a switch unit (SW) 224. The bidirectional AC / DC converter 221 has a function of converting AC power into DC power by an AC / DC converter and a function of converting DC power into AC power by a DC / AC converter (inverter). The bidirectional DC converter 223 includes a DC / DC converter, and has a function of bidirectionally converting power between DC power and DC power.

When the switch unit 222 is in a closed state, the conversion device B220 applies an AC voltage (for example, AC400V) input from the primary AC bus 31 along the direction indicated by the broken line a to the secondary AC bus 41. To the distribution board 261. In addition, when the switch unit 222 is in the closed state, the converter B220 can output AC power from the secondary AC bus 41 toward the primary AC bus 31 in the direction opposite to the direction indicated by the broken line a. it can.
Further, the bidirectional AC / DC converter (bidirectional AC / DC converter) 221 converts the AC power supplied from the primary AC bus 31 along the direction indicated by the broken line b to DC when the switch unit 222 is closed. This can be converted into electric power, and this direct-current power can be output to the distribution board 262 via the secondary side DC bus 42.

  Further, the bidirectional AC / DC converter 221 converts the DC power input from the secondary side DC bus 42 into AC power along the direction indicated by the broken line c, and supplies this AC power to the primary side AC bus 31. be able to. In addition, when the switch unit 222 is in the open state, the bidirectional AC / DC converter 221 converts the DC power input from the secondary DC bus 42 into AC power along the direction indicated by the broken line d and converts it to the secondary side. The data can be output to the AC bus 41.

In addition, the bidirectional DC converter (bidirectional DC / DC converter) 223 is the DC power supplied to the primary DC bus 32 along the direction indicated by the broken line e when the switch unit 224 is closed. Can be converted into DC power distributed to the power supply path in the cluster unit and output to the secondary DC bus 42.
Further, the bidirectional DC converter 223 converts the DC power supplied to the secondary DC bus 42 into DC power that can be accommodated in the primary DC bus 32 along the direction indicated by the broken line f. DC power can be output to the primary DC bus 32.

  In FIG. 4, the PCSAC 250 is directly connected to the primary AC bus 31 by opening the switch unit 222 in the conversion device B220 and conducting the common contact c and the contact a of the switching unit 260. AC power can be supplied toward the primary AC bus 31. That is, AC interchange (AC interchange) can be performed from the PCSAC 250 to the primary AC bus 31 along the path indicated by the broken line A1. In this way, by making the common contact c and the contact a of the switching unit 260 conductive, when performing AC accommodation from the child cluster unit 200 to the primary AC bus 31, without passing through the conversion device B220, Power can be supplied directly from the PCSAC 250 to the primary AC bus 31. An example of performing AC interchange using this switching unit 260 will be described later.

(Modification of power interchange system 1)
FIG. 5 is a block diagram showing a modification of the power interchange system shown in FIG.
The power accommodation system 1A shown in FIG. 5 is compared with the power accommodation system 1 shown in FIG.
In the parent cluster unit 100A, the configuration is different in that the conversion device D130 in the parent cluster unit 100 shown in FIG. 1 is omitted and the switching unit 160A is newly added. Further, the configuration is different in that a switching unit 260A is newly added in the child cluster unit 200A shown in FIG. Other configurations are the same as those of the power interchange system 1 shown in FIG. For this reason, the same code | symbol is attached | subjected to the same component and the overlapping description is abbreviate | omitted.

  In this power interchange system 1A, by adding a switching unit 160A to the parent cluster unit 100A, it is possible to select whether the connection destination of the PCSDC 150A is the distribution board 162 or the primary side DC bus 32. There are features. In addition, by newly adding a switching unit 260A in the child cluster unit 200A, it is possible to select whether the connection destination of the PCSDC 250A is the distribution board 262 or the primary DC bus 32. There are features. The child cluster unit 300A is similar to the child cluster unit 200A.

  In the power interchange system 1A shown in FIG. 5, by providing the switching unit 160A in the parent cluster unit 100A, the DC power output from the power generator 142 via the PCSDC 150A is converted to the primary side DC via the switching unit 160A. There is an effect that the data can be directly connected to the bus 32 and output. Further, by providing the switching unit 260A in the child cluster unit 200A, there is an effect that the DC power output from the power generation device 242 via the PCSDC 250A can be directly connected to the primary side DC bus 32 and output.

(Power interchange control processing in the power interchange system 1)
Next, power interchange control processing in the power interchange system will be described.
In the power interchange system 1 configured as described above, a parent cluster unit 100, a child cluster unit 200, a child cluster unit 300, and a child cluster that serve as a power reception point of the commercial power system 2 and receive commercial power from the commercial power system 2 Each cluster with the unit 400 is configured such that AC power and DC power can be interchanged with each other via the primary side AC bus 31 and the primary side DC bus 32. Then, as a method of accommodating power among the parent cluster unit 100, the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400, the interchange of only AC power, the interchange of only DC power, or It is possible to select three ways of accommodation including accommodation of both DC power and AC power.

FIG. 6 is an explanatory diagram illustrating an outline of a control operation of power accommodation in the power accommodation system.
In FIG. 6, the power interchange control operation will be described by taking the parent cluster unit 100 as an example, but similar control operations are performed in the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.
In the parent cluster unit 100 shown in FIG. 6, AC interchange is a case where the AC power generation amount Pac of the power generation device 141 output via the PSAC 150 is left, and the power storage device 145 is fully charged or fully charged. This is the case in a state close to. That is, this is a case where the storage battery remaining capacity SOC of the power storage device 145 is equal to or greater than a predetermined threshold.

More specifically, the AC power generation amount Pac of the power generator 141 is larger than the AC power consumption Loadac of the AC load device 143 (Pac> Loadac), and the current Idc flowing from the converter A120 to the distribution board 162 is shown in the figure. When the storage battery SOC of the power storage device 145 flows in the charging direction and is equal to or greater than a predetermined threshold value, AC interchange is performed from the parent cluster unit 100 to another cluster via the primary AC bus 31. The same applies to the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.
Note that current Idc in FIG. 6 indicates the direction of current Idc when power storage device 145 is negatively grounded, and the direction of DC current Idc indicates the direction of accommodating DC power. That is, the direction of the current of the connection line paired with GND changes depending on whether the direct current system is positive ground or negative ground. FIG. 6 shows the direction of the current Idc under the condition that the power storage device 145 is negatively grounded, and is an example in the case where the direction of the DC current Idc matches the direction of accommodating DC power.

In addition, the DC interchange (DC interchange) is a case where the DC power generation amount Pdc of the power generator 142 output via the PCSDC 150A is surplus, and the power storage device 145 is in a fully charged state or near full charge. Is the case. That is, this is a case where the storage battery remaining capacity SOC of the power storage device 145 is equal to or greater than a predetermined threshold.
More specifically, the DC power generation amount Pdc of the power generator 142 is larger than the DC power consumption Loaddc of the DC load device 144 (Pdc> Loaddc), and the current Idc flowing from the converter A120 to the distribution board 162 is shown in the figure. When the storage battery SOC of the power storage device 145 flows in the discharging direction and is equal to or greater than a predetermined threshold value, direct current interchange is performed from the parent cluster unit 100 to another cluster via the primary DC bus 32. The same applies to the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.

As described above, the AC interchange is performed when the AC power output from the PCSAC 150 is large between the cluster units, and the DC interchange is performed when the DC power output from the PCSDC 150A is large. . Moreover, as will be described later, AC interchange and DC interchange can be performed simultaneously.
The primary AC bus 31 is not only supplied with power from the commercial power system 2 but also supplied with power from the power generation device 141, the power generation device 142, and the power storage device 145. Even in such a case, the power supply ready state is maintained without causing the primary AC bus 31 to immediately fail. On the other hand, the primary side DC bus 32 is supplied with power only at the time of DC interchange.

  FIG. 7 is an explanatory diagram for explaining a power interchange operation in the cluster unit. 7 shows, for example, the AC power generation amount Pac in the parent cluster unit 100, the AC power consumption Loadac of the AC load device 143, the DC power generation amount Pdc, the DC power consumption Loadc of the DC load device 144, and the direction of the current Idc. And the state of the power storage device 145 and the power interchange state corresponding to the state are shown in a table.

In this table, the symbol “CS” is AC power supplied from the commercial power system 2 in the case of the parent cluster unit 100.
The same applies to the child cluster units 200, 300, and 400 as in the case of the parent cluster unit 100, and the code “CS” in each case is the same in the child cluster unit 200 and the child cluster unit 300. AC power supplied from the primary AC bus 31, and in the child cluster unit 400, AC power supplied from the secondary AC bus 61 of the child cluster unit 300.
In this table, the current Idc indicates a state in which DC power is interchanged from the converter A120 toward the DC distribution board 162 when the direction of the current Idc is “charging direction”. In the case where the direction is “discharge direction”, a state is shown in which DC power is interchanged from the DC distribution board 162 toward the converter A120.

In FIG. 7, as shown in a state ST10 and a state ST11 described later, for example, the amount of AC power output from the PCSAC 150 of the power generation device 141 of the parent cluster unit 100 is larger than the load power of the AC load device 143. In addition, when the power storage device 145 is fully charged and the current Idc flows in the charging direction (see FIG. 6), AC interchange is performed to the other cluster unit via the primary side AC bus 31.
Further, as shown in a state ST13 to be described later, the power generation amount of the DC power output from the PCSDC 150A of the power generation device 142 is larger than the load power of the DC load device 144, and the power storage device 145 is fully charged, Further, when the current Idc flows in the discharge direction (see FIG. 6), DC interchange is performed to the other cluster unit via the primary side DC bus 32. The same applies to the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.

Hereinafter, the state ST1 to the state ST14 in the table shown in FIG. 7 will be described.
First, states ST1 to ST3 are sub-cluster consumption states, that is, no power is exchanged from the power generation device 141 in the cluster to the DC load device 144, and the power generation device 142 and the power storage device 145 are connected to the AC load device. A state in which power interchange is not performed on the 143 side is shown.
In the state ST1 to the state ST3, the AC power generation amount Pac and the DC power generation amount Pdc do not have enough room for AC interchange or DC interchange. Therefore, neither AC interchange nor DC interchange is performed.

The state ST1 is a case where the total value “Pac + CS” of the AC power generation amount Pac and the commercial power CS is equal to the AC power consumption Loadac in the AC load device 143 (Pac + CS = Loadac), and the DC power generation amount Pdc is This is a case where the DC power consumption Loaddc is smaller than the DC load device 144 (Pdc <Loaddc).
In this state ST1, in order to compensate for the shortage of the DC power consumption Loaddc, the battery current Ibatt flows in the discharging direction from the power storage device 145 to the DC load device 144. Further, DC current Idc does not flow from power storage device 145 toward conversion device A120, and Idc is zero.

State ST2 is a case where “Pac + CS = Loadac” and the DC power generation amount Pdc is equal to the DC power consumption Loaddc in the DC load device 144 (Pdc = Loaddc). In this state ST2, current Idc is 0, and no discharge from power storage device 145 is performed (Ibatt = 0).
The state ST3 is a case where “Pac + CS = Loadac” and the DC power generation amount Pdc is larger than the DC power consumption Loaddc in the DC load device 144 (Pdc> Loaddc). In this state ST3, a current Ibatt in the charging direction flows from the power generation device 142 toward the power storage device 145.

  In addition, states ST4 to ST8 indicate a case where power interchange is performed in the cluster. For example, in the parent cluster unit 100, power is interchanged from the PCSAC 150 to the DC load device 144 side, and power is interchanged from the PCSDC 150A or the power storage device 145 to the AC load device 143 side. In the state ST4 to the state ST8, the AC power generation amount Pac and the DC power generation amount Pdc do not have enough room for AC interchange or DC interchange. Therefore, neither AC interchange nor DC interchange is performed.

  In states ST4 to ST6, the total power amount “Pac + CS” of the AC power generation amount Pac by the power generation device 141 and the power CS supplied from the commercial power system 2 is smaller than the AC power consumption Loadac in the AC load device 143. Shows the case. That is, a state is shown in which AC power is interchanged from the power generation device 142 and the power storage device 145 to the AC load device 143 inside the parent cluster unit 100.

In the state ST4, the total value “Pac + CS” of the AC power generation amount Pac and the commercial power CS is smaller than the AC power consumption Loadac in the AC load device 143 (Pac + CS <Loadac), and the DC power generation amount Pdc is DC This is a case where the DC power consumption Loaddc in the load device 144 is smaller (Pdc <Loaddc).
In this state ST4, in order to compensate for the shortage of AC power and DC power, battery current Ibatt is supplied in the discharge direction from power storage device 145 toward AC load device 143 and DC load device 144. For this reason, direct current Idc flows in the discharge direction from power storage device 145 toward conversion device A120.

  In the state ST5, “Pac + CS <Loadac” is satisfied, and the DC power generation amount Pdc is equal to the DC power consumption Loaddc in the DC load device 144 (Pdc = Loaddc). In this state ST5, in order to compensate for the shortage of AC power, battery current Ibatt is caused to flow in the discharge direction from power storage device 145 toward AC load device 143. For this reason, direct current Idc flows in the discharge direction from power storage device 145 toward conversion device A120.

  In the state ST6, “Pac + CS <Loadac” and the DC power generation amount Pdc is larger than the DC power consumption Loaddc in the DC load device 144 (Pdc> Loaddc). In this state ST6, power is supplied from the power generation device 142 toward the AC load device 143 in order to compensate for the shortage of AC power. For this reason, the direct current Idc flows in the discharge direction from the power generator 142 toward the converter A120. Further, in the state where power is supplied from the power generation device 142 to the DC load device 144 and the AC load device 143, when there is a surplus in output power, the battery current Ibatt is supplied to the power storage device 145 in the charging direction.

In addition, the state ST7 and the state ST8 indicate a case where the AC power generation amount Pac by the power generation device 141 is larger than the power consumption of the AC load device 143 (Pac> Loadac).
In the state ST7 and the state ST8, the total power “Pdc + (Pac−Loadac)” of the difference power “Pac−Loadac” between the AC power generation amount Pac and the power consumption Laodac and the DC power generation amount Pdc of the power generator 142 is obtained. It can be used as DC power.

  The state ST7 is a case of “Pdc + (Pac−Loadac) <Loaddc”. In this case, in order to compensate for the shortage of DC power, the current Idc in the charging direction from the converter A120 toward the DC load device 144 While flowing, a battery current Ibatt is caused to flow from the power storage device 145 toward the DC load device 144 in the discharging direction.

  State ST8 is a case where “Pdc + (Pac−Loadac) = Loaddc”. In this case, in order to compensate for the shortage of DC power, current Idc is supplied from converter A120 toward DC load device 144 in the charging direction. In this case, battery current Ibatt of power storage device 145 is 0 (Ibatt = 0).

  Further, from state ST9 to state ST11, the AC power generation amount Pac by the power generation device 141 is larger than the power consumption Laodac of the AC load device 143. In this case, the total power “Pdc + (Pac−Loadac)” of the difference power “Pac−Loadac” between the AC power generation amount Pac and the consumed power Laodac and the DC power generation amount Pdc of the power generation device 142 can be used as the DC power. .

  The state ST9 is a case where “Pdc + (Pac−Loadac)> Loaddc”. In this case, whether or not the current Idc is supplied from the converter A120 to the DC load device 144 side is related to the magnitude of Pdc and Loaddc. Determined by.

The state ST10 and the state ST11 are cases where the power storage device 145 is fully charged and “Pac> Loadac”, and AC exchange is performed by the primary AC bus 31.
In other words, the state ST10 is “Pac> Loadac”, “Pdc + (Pac−Loadac) <Loaddc”, and the power storage device 145 is “fully charged”. In this case, in order to compensate for the shortage of DC power, the current Idc flows from the converter A120 toward the DC load device 144 in the charging direction, and the AC power generation amount Pac of the power generator 141 has a further margin, AC interchange for the side AC bus 31 is performed.

  The state ST11 is “Pac> Loadac”, “Pdc + (Pac−Loadac) = Loaddc”, and the power storage device 145 is “fully charged”. In this case, in order to compensate for the shortage of DC power, the current Idc flows from the converter A120 toward the DC load device 144 in the charging direction, and when the power generated by the power generator 141 has a further margin, the primary AC AC interchange for bus 31 is performed.

  The state ST12 is a case of “Pac> Loadac” and a case of “Pdc> Loaddc”. Whether to perform AC accommodation or AC accommodation is determined depending on the state of charge of power storage device 145.

  The state ST13 is a case where “Pac + CS <Loadac”, “Pdc> Loaddc”, and the power storage device 145 is “fully charged”. In this case, in order to compensate for the shortage of AC power, a current Idc is supplied from the power generation device 142 or the power storage device 145 to the conversion device A120 in the discharging direction. Further, since the power storage device 145 is fully charged, it is possible to perform direct current interchange with the primary side DC bus 32.

  The state ST14 is a case where “Pac + CS = Loadac”, “Pdc> Loaddc”, and the power storage device 145 is “fully charged”. In this case, since “Pac + CS = Loadac”, there is no need to flow current from the power generation device 142 toward the conversion device A120, and since “Pdc> Loaddc” and the power storage device 145 is fully charged, the primary side It becomes possible to perform direct current interchange with respect to the DC bus 32.

  As described above, the table of FIG. 7 has been described. As an actual determination process of whether to perform AC accommodation or DC accommodation, the battery current Ibatt flowing through the power storage device 145 is detected by a detector (not shown), and the controller 110 Determines the fully charged state based on the detected battery current Ibatt. Further, the current Idc flowing from the distribution board 162 to the conversion device A120 is detected by a detector (not shown), and the control unit 110 determines the direction of the detected current Idc. Control unit 110 determines whether to perform AC interchange or DC interchange based on the determination result of full charge determined based on battery current Ibatt and the determination result of the direction of current Idc.

(Example in which AC interchange and DC interchange are selected by the remaining battery SOC)
In the table shown in FIG. 7, for example, when the power storage device 145 is fully charged in the parent cluster unit 100, the AC power generation amount Pac output from the PCSAC 150 and the DC power generation amount Pdc output from the PCSDC 150A , Based on the direction of the current Idc flowing between the converter A120 and the distribution board 162, an example of determining AC interchange or DC interchange was shown, but depending on the remaining battery capacity SOC of the power storage device 145, It is also possible to decide whether to perform AC accommodation or DC accommodation.

FIG. 8 is an explanatory diagram showing an example in which AC accommodation and DC accommodation are selected according to the storage battery remaining capacity SOC of the power storage device. In the example illustrated in FIG. 8, an example is illustrated in which switching between AC accommodation or DC accommodation from the power storage device 145 is performed according to the remaining battery capacity SOC of the power storage device 145.
In FIG. 8, the vertical axis indicates the storage battery remaining capacity SOC, the horizontal axis indicates time t, the change in the remaining battery capacity SOC, and the AC interchange period and the DC interchange period corresponding to the change in the remaining battery capacity SOC. Shows changes.

In FIG. 8, the reference value SOC1A is a reference value corresponding to the value of the storage battery remaining capacity SOC in a state where the storage battery remaining capacity SOC is close to full charge, for example. Reference value SOC1B is, for example, a reference value having a value smaller than reference value SOC1A (that is, reference value SOC1A> reference value SOC1B). For example, in operation, power storage device 145 is charged. Is set to a value corresponding to the value of the remaining battery capacity SOC in a preferable state.
Further, in FIG. 8, the reference value SOC2A is a value of the remaining battery capacity SOC in a state where the remaining battery capacity SOC is in a fully charged state or in a state where it is preferable that the power storage apparatus 145 is not charged any more from the power generation apparatus 142 or the like in operation. Corresponding reference value. Reference value SOC2B is, for example, a reference value having a value smaller than reference value SOC2A (that is, reference value SOC2A> reference value SOC2B).

  For example, the control unit 110 of the parent cluster unit 100 uses the accumulated result of the detected value of the charge / discharge current of the power storage device 145, the detection result of the terminal voltage of the power storage device 145, or a signal indicating the state received from the power storage device 145. Based on this, the remaining battery capacity SOC is calculated. Controller 110 compares the remaining battery capacity SOC with reference value SOC1A and reference value SOC1B, and compares the remaining battery capacity SOC with reference value SOC2A and reference value SOC2B.

As shown in FIG. 8, when the AC power generation amount Pac output from the PCSAC 150 or the DC power generation amount Pdc output from the PCSDC 150 </ b> A is large, a charging current flows through the power storage device 145, thereby causing a storage battery of the power storage device 145. The remaining capacity SOC gradually increases.
And the control part 110 performs the following processes. When the remaining battery charge SOC of the power storage device 145 becomes equal to or greater than the reference value SOC1A at time t1, the AC interchange mode is first started. Then, after time t1, the remaining battery capacity SOC further increases, and when the remaining battery capacity SOC exceeds the reference value SOC2A at time t2, the DC interchange mode is started together with the AC interchange mode.
Thereafter, the remaining battery capacity SOC changes, and when the remaining battery capacity SOC decreases to the reference value SOC2B at time t3, the DC interchange mode is stopped.
After time t3, at time t4, when the remaining storage battery SOC decreases to the reference value SOC1B, the AC interchange mode is stopped.

As described above, the control unit 110 executes the AC interchange mode in the period from the time t1 to the time t2 and the period from the time t3 to the time t4, and the AC interchange mode and the DC interchange in the period from the time t2 to the time t3. Run both modes. That is, the control unit 110 has two stages, a first stage for performing the AC accommodation mode and a second stage for executing both the AC accommodation mode and the DC accommodation mode according to the remaining battery capacity SOC of the power storage device 145. Separate the power interchange process.
Thus, when power storage device 145 becomes nearly fully charged, control unit 110 performs AC interchange with another cluster. If there is a possibility that the power storage device 145 is overcharged during the AC interchange period, the control unit 110 performs the DC interchange in accordance with the AC interchange, thereby allowing power to be accommodated to another cluster. To prevent the power storage device 145 from being overcharged.

(Example of using a switching unit for AC interchange and DC interchange)
FIG. 9 is an explanatory diagram illustrating an example in the case of performing AC accommodation and DC accommodation using the switching unit.
For example, in the child cluster unit 200A shown in FIG. 9, the control unit 210 connects the common contact c and the contact a of the switching unit 260 to connect the PCSAC 250 directly to the primary side AC bus 31, and from the PCSAC 250 to the primary side AC AC interchange can be performed toward the bus 31. That is, AC interchange can be performed from the PCSAC 250 to the primary AC bus 31 along the path indicated by the broken line A1.

In addition, the control unit 210 causes the common contact c and the contact a of the switching unit 260A to be electrically connected, thereby directly connecting the PCSDC 250A to the primary side DC bus 32 and performing DC interchange from the PCSDC 150A toward the primary side DC bus 32. Can do. That is, DC interchange can be performed from the PCSDC 250A to the primary side DC bus 32 along the path indicated by the broken line A2.
Accordingly, when AC interchange is performed from the child cluster unit 200A to the primary AC bus 31, AC power is directly supplied to the primary AC bus 31 via the switching unit 260 without passing through the conversion device B220. be able to. Further, when DC interchange is performed from the child cluster unit 200A to the primary side DC bus 32, direct current power can be directly supplied to the primary side DC bus 32 via the switching unit 260A without passing through the conversion device B220. it can.

(Power interchange processing procedure)
FIG. 10 is a flowchart showing a procedure of power accommodation processing. Hereinafter, the procedure of the power interchange process will be described with reference to the flowchart of FIG.
In FIG. 10, AC interchange is described as “AC interchange”, and DC interchange is described as “DC interchange”.

Then, for example, the control unit 110 of the parent cluster unit 100 detects that power accommodation is necessary (step S100). For example, the control unit 110 detects that power accommodation is necessary based on the AC power generation amount Pac of the power generation device 141, the DC power generation amount Pdc of the power generation device 142, the remaining battery capacity SOC, and the like. Alternatively, the control unit 110 receives a power interchange request signal sent from the energy management apparatus (EMS) 11 and detects that the power interchange is necessary.
Subsequently, the control unit 110 determines whether or not AC accommodation is necessary (step S105). For example, the control unit 110 detects the battery current Ibatt flowing through the power storage device 145 to determine the fully charged state, determines the direction of the current Idc flowing between the conversion device A120 and the distribution board 162, and determines the alternating current. It is determined whether or not it is necessary to provide accommodation.

  If it is determined in step S105 that AC accommodation is necessary (step S105: Yes), the control unit 110 connects the PCSAC 150 to the primary AC bus 31 via the switching unit 160 (step S110). . Then, the controller 110 causes the PCSAC 150 to perform a connected operation detection process for the primary AC bus 31 (step S115).

Subsequently, the control unit 110 collects AC interchangeability information (step S120). For example, the control unit 110 determines whether there is a restriction on regulation due to an agreement with an electric power company when performing AC interchange (step S125).
Subsequently, the control unit 110 determines which AC power (AC) or DC power (DC) is to be accommodated according to the designated power supply mode (step S130).
When it is determined in step S130 that AC interchange (AC interchange) is to be performed (step S130: AC), the control unit 110 starts an AC interchange mode activation process (step S140).
Subsequently, the control unit 110 determines whether or not it is necessary to activate the DC interchange mode (step S145). If it is determined in step S145 that activation of the DC accommodation mode is not necessary (step S145: No), it is determined whether or not the activation state of the AC accommodation mode is maintained (step S180).
If it is determined in step S180 that the AC interchange mode activation state is not maintained (step S180: No), the control unit 110 proceeds to step S150 and executes an AC interchange mode end process (step S150). ).
Control unit 110 transitions to an AC interchange mode end process (step S150). And after performing the process of this step S150, the control part 110 complete | finishes this electric power accommodation process.
On the other hand, when it is determined in step S180 that the AC interchange mode activation state is maintained (step S180: Yes), that is, when the AC interchange mode is maintained, the control unit 110 repeats the determination in step S180. .

  On the other hand, if it is determined in step S105 that AC accommodation is not necessary (step S105: No), if it is determined in step S125 that AC accommodation is not possible (step S125: No), DC accommodation (DC accommodation) in step S130. ) (Step S130: DC) and when it is determined in step S145 that activation of the DC interchange mode is necessary (step S145: Yes), the process proceeds to step S160, and the control unit 110 Performs the activation process of the DC interchange mode (step S160).

  Subsequently, when detecting an instruction to end the DC accommodation mode, the control unit 110 performs an end process of the DC accommodation mode (Step S170), and after completing the processing of Step S170, proceeds to Step S180. The details of the DC interchange mode end process will be described later.

As described above, in the power accommodation system 1, it is possible to increase the power use efficiency between a plurality of clusters by performing AC accommodation and DC accommodation between the clusters.
In the flowchart of FIG. 10, the procedure for power interchange processing in the parent cluster unit 100 has been described. However, similar power interchange processing is performed in the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400. Is called.

(Start-up process of AC interchange mode and DC interchange mode)
FIG. 11 is an explanatory diagram illustrating an example of activation processing in the AC interchange mode and the DC interchange mode. FIG. 11A shows the AC interchange mode startup process, and FIG. 11B shows the DC interchange mode start process.

In FIG. 11A, the elapse of time t is shown in the horizontal direction, and the power supply state of the primary side AC bus 31 and the operation state of the PCSAC 150 are shown side by side in the vertical direction.
As shown in FIG. 11A, when the PCSAC 150 detects an interchange mode activation instruction sent from the control unit 110 at time t1, the PCSAC 150 temporarily stops its operation. Then, at time t2, the interconnection operation with the primary AC bus 31 is started, and supply of AC power to the primary AC bus 31 is started from time t3.

In FIG. 11B, the time t has elapsed in the horizontal direction, and the power supply state of the primary DC bus 32 and the operating state of the bidirectional DC converter 131 (see FIG. 3B) in the vertical direction. Are shown side by side.
As shown in FIG. 11 (B), when the bidirectional DC converter 131 detects an interchange mode start instruction sent from the controller 110 at time t1, the bidirectional DC converter 131 The interconnection operation with 32 is started, and the supply of DC power to the primary side DC bus 32 is started from time t3.
In the power accommodation system 1A shown in FIG. 5, when the PCSDC 150A is connected to the primary DC bus 32 via the switching unit 160A, the activation process in the DC accommodation mode is performed by using the PCSAC 150 shown in FIG. Processing according to the startup processing connected to the bus 31 is performed.

(End processing of DC interchange mode)
FIG. 12 is a flowchart illustrating a procedure of DC termination mode end processing. The termination process of the DC accommodation mode shown in FIG. 12 is an example in the case where DC accommodation is performed using the conversion device D130.
For example, in the parent cluster unit 100, the control unit 110 detects an instruction to end the DC accommodation mode while the DC accommodation mode is being executed (step S171). For example, the control unit 110 detects a DC interchange mode end instruction signal sent from the energy management device (EMS) 11. Then, the control unit 110 determines whether an end instruction has been detected (step S172).
And the control part 110 detects the completion | finish instruction | indication of DC accommodation mode (step S172: Yes), and the control part 110 detects the electric power feeding state of an accommodation destination, and the electric power feeding state of an own system (step S173), It is determined whether or not the DC interchange mode can be terminated (step S174).

If it is determined in step S174 that the DC accommodation mode cannot be ended (step S174: No), the control unit 110 waits until the DC accommodation mode can be ended.
When it is determined in step S174 that the DC interchange mode can be ended (step S174: Yes), the control unit 110 performs bidirectional DC conversion unit (bidirectional DC / DC conversion unit) 131 (FIG. 3 ( B)) is cut off (step S175).
And the control part 110 complete | finishes the completion | finish process of this DC accommodation mode, after performing the process of step S175.

  In the above-described DC interchange mode end processing, an example in which the output of the bidirectional AC / DC converter 121 is shut off at the end of the DC interchange mode has been shown. However, switching from the PCSDC 150A as in the parent cluster unit 100A shown in FIG. When DC power is supplied to the primary DC bus 32 via the unit 160A, the operation of the PCSDC 150A may be stopped.

(End processing of AC interchange mode)
FIG. 13 is a flowchart showing the procedure of the AC interchange mode end process. Note that the example shown in FIG. 13 is an example in which AC power is output from the PCSAC 250 to the primary DC bus 32 via the switching unit 260, as shown in FIG.
Hereinafter, the termination process of the AC interchange mode will be described using the child cluster unit 200 as an example.
First, in the child cluster unit 200, the control unit 210 detects an AC interchange mode end instruction during execution of the AC interchange mode (step S151). For example, the controller 210 detects an AC interchange mode end instruction sent from the energy management apparatus (EMS) 11. Then, control unit 210 determines whether or not an end instruction has been detected (step S152).

In step S152, if an AC interchange mode end instruction has not been detected (step S152: No), control unit 210 waits until an AC interchange mode end process is detected.
In step S152, when an instruction to end the AC accommodation mode is detected (step S152: Yes), the control unit 210 detects the state of the accommodation destination and the state of the own system (step S153). It is determined whether or not termination is possible (step S154).

If it is determined in step S154 that the AC accommodation mode cannot be ended (step S154: No), the control unit 210 waits until the AC accommodation mode can be ended.
When it is determined in step S154 that the AC interchange mode can be terminated (step S154: Yes), the control unit 210 stops the output of the PCSAC 250 (step S155).
Subsequently, the control unit 210 changes the connection destination of the PCSAC 250 from the primary AC bus 31 to the secondary AC bus 41 of the child cluster unit 200 (step S156). Then, the control unit 210 connects the output of the PCSAC 250 to the secondary AC bus 41 (step S157), and after this connection is completed, outputs power from the PCSAC 250 to the secondary AC bus 41 (step S158). ).
And the control part 210 finishes the completion | finish process of this AC accommodation mode after execution of the process of step S158.

  In the case of the configuration in which the PCSDC 250A is connected to the DC bus 32 as in the child cluster unit 200A shown in FIG. 9, when the DC interchange mode is terminated, processing according to the above-described AC interchange mode processing is performed. Is called.

FIG. 14 is an explanatory diagram showing an example of the AC interchange mode end processing. The end process shown in FIG. 14 is a time chart showing the processing procedure described in the flowchart of FIG. 13 described above.
In FIG. 14, the elapse of time t is shown in the horizontal direction, and the power supply state of the primary AC bus 31 and the operation state of the PCSAC 250 are shown side by side in the vertical direction.
As shown in FIG. 14, power is supplied from the PCSAC 250 to the primary AC bus 31 before time t1. Then, at time t1, the control unit 210 detects an AC interchange mode end instruction, and at subsequent time t2, detects the state of the accommodation destination and the state of the own system. Subsequently, at time t3, the control unit 210 determines whether or not the AC interchange mode can be ended. When it is determined that the AC interchange mode can be ended, at time t4 after time t3, the control unit 210 stops the output of the PCSAC 150 and supplies power from the PCSAC 250 to the primary AC bus 31. Stop.

  Then, at time t5, the switching unit 260 disconnects the connection between the PCSAC 250 and the primary AC bus 31. At time t6 following time t5, the control unit 210 switches the PCSAC 250 to the secondary AC bus 41. Connecting. Then, at time t7 following time t6, the control unit 210 connects the PCSAC 250 to the secondary AC bus 41, and from time t8 thereafter, the control unit 210 transmits AC power from the PCSAC 250 to the secondary AC bus 41. To supply.

  In the DC interchange mode, as shown in the parent cluster unit 100A in FIG. 5, in the case of the configuration in which the PCSDC 150A is connected to the primary DC bus 32 via the switching unit 160A, the DC interchange mode end processing is described above. The process is based on the AC interchange mode end process.

  The embodiment of the present invention has been described above. In the above embodiment, the control unit 110 in the parent cluster unit 100, the control unit 210 in the child cluster unit 200, the control unit 310 in the child cluster unit 300, The control unit 410 in the child cluster unit 400 has a computer system inside. A series of processes related to the above-described process is stored in a computer-readable recording medium in the form of a program, and the above-described process is performed by the computer reading and executing this program. Here, the computer-readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, and the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program. The “computer system” here includes an OS and hardware such as peripheral devices.

  Here, the correspondence between the present invention and the above-described embodiment will be supplementarily described. That is, the power interchange system in the present invention corresponds to the power interchange system 1 shown in FIG. 1 or the power interchange system 1A shown in FIG. The first cluster unit in the present invention corresponds to the parent cluster unit 100 or the parent cluster unit 100A (FIG. 5), and the second cluster unit in the present invention includes, for example, the child cluster unit 200 and the child cluster unit 200A (see FIG. 5). 5), the child cluster unit 300, and the like. The AC bus in the present invention corresponds to the primary side AC bus 31, and the DC bus in the present invention corresponds to the primary side DC bus 32.

  In addition, the first power generation device according to the present invention corresponds to the power generation device 141 of the parent cluster unit 100, and the second power generation device according to the present invention corresponds to the power generation device 142 of the parent cluster unit 100. The device corresponds to, for example, the power generation device 241 of the child cluster unit 200, and the fourth power generation device in the present invention corresponds to, for example, the power generation device 242 of the child cluster unit 200.

The first power conditioner in the present invention corresponds to the power conditioner (PCSAC) 150 of the parent cluster unit 100, and the second power conditioner in the present invention corresponds to the power conditioner (PCSDC) 150A of the parent cluster unit 100. The third power conditioner in the present invention corresponds to, for example, the power conditioner (PCSAC) 250 of the child cluster unit 200, and the fourth power conditioner in the present invention corresponds to, for example, the power of the child cluster unit 200. Conditioner (PCSDC) 250A corresponds.
Further, the first switching unit in the present invention corresponds to the switching unit 160 of the parent cluster unit 100, and the second switching unit in the present invention corresponds to the switching unit 160A of the parent cluster unit 100A (FIG. 5). The third switching unit corresponds to, for example, the switching unit 260 of the child cluster unit 200, and the fourth switching unit in the present invention corresponds to, for example, the switching unit 260A of the child cluster unit 200A (FIG. 5).
Further, the AC load device in the present invention corresponds to the AC load devices 143 and 243, and the DC load device in the present invention corresponds to the DC load devices 144 and 244 and the like.

(1) In the above embodiment, the power interchange system 1 includes a parent cluster unit 100 (first cluster unit) that serves as a power receiving point of the commercial power system and receives supply of commercial power from the commercial power system, and a parent cluster unit 100. 1 or a plurality of child cluster units 200 or the like (second cluster unit) that receive supply of commercial power via In the power interchange system 1, each of the parent cluster unit 100 and the child cluster unit 200 includes a power generation device and a load device or a power storage device and a load device, and the parent cluster unit 100 and the child cluster units 200 and 300, etc. In addition, the power is exchanged with AC power and the power is exchanged with DC power.
In the power accommodation system having such a configuration (for example, the power accommodation system 1), a parent cluster unit 100 (first cluster unit) that receives power from the commercial power system, a plurality of child cluster units 200, etc. (second cluster unit) Are connected in common by the primary side AC bus 31 and the primary side DC bus 32. Then, AC power interchange and DC power interchange are performed between the parent cluster unit 100 and the child cluster unit 200 and the like.
Thereby, the utilization efficiency of electric power can be improved among a plurality of clusters (customers).

(2) In the above-described embodiment, the power accommodation system (for example, the power accommodation system 1) is configured such that the parent cluster unit 100 (first cluster unit) and the child cluster unit 200 (second cluster unit) are The main cluster unit 100 (first cluster unit) and the child cluster unit are connected by a primary side AC bus 31 serving as an AC power supply path and also connected by a primary side DC bus 32 serving as a DC power supply path. The AC power is interchanged via the primary side AC bus 31 and the DC power is interchanged via the primary side DC bus 32 between 200 and the like (second cluster unit).
Accordingly, in the power accommodation system (for example, the power accommodation system 1), the parent cluster unit 100 (first cluster unit), the child cluster unit 200, and the like (the first cluster unit) are connected via the primary side AC bus 31 and the primary side DC bus 32 (first cluster unit). AC power and DC power can be interchanged between the two cluster units) and between the plurality of child cluster units 200 and 300 (second cluster unit).

(3) In the above embodiment, the power accommodation system (for example, the power accommodation system 1) is provided between the parent cluster unit 100 (first cluster unit) and the child cluster unit 200 (second cluster unit), and When accommodating power between the plurality of child cluster units 200 and 300, etc., a mode in which only AC power is accommodated, a mode in which only DC power is accommodated, and a mode in which both AC power and DC power are accommodated And can be selected.
Thereby, in the power accommodation system (for example, the power accommodation system 1), between the parent cluster unit 100 (first cluster unit) and the child cluster unit 200 and the like (second cluster unit), and a plurality of child cluster units 200 and Whether to exchange AC power or DC power according to the power supply / demand status in the parent cluster unit 100 and the child cluster unit 200, etc. Alternatively, it is possible to select whether to exchange both AC power and DC power.

  (4) In the above-described embodiment, the power interchange system (for example, the power interchange system 1) is configured such that the parent cluster unit 100 (first cluster unit), the child cluster unit 200 and the like (second cluster unit) Bidirectional AC / DC converter (for example, bidirectional AC / DC converter 121) that performs bidirectional power conversion between the DC power and DC power, and bidirectional DC that performs bidirectional power conversion between DC power and DC power A conversion unit (for example, a bidirectional DC conversion unit 131). For example, in the parent cluster unit 100, the bidirectional AC / DC conversion unit 121 converts the AC power supplied from the primary AC bus 31 into DC power distributed to the power supply path inside the cluster unit, and the converted DC power Supply power to the DC load device 144 and store the converted DC power in the power storage device 145, and AC power to accommodate the DC power supplied from the power generation device 142 or the power storage device 145 included in the own cluster unit. An operation mode for converting and supplying the AC power to the primary AC bus 31. Further, the bidirectional DC converter 131 converts the DC power supplied from the primary side DC bus 32 bus into DC power distributed to the feeding path inside the cluster unit, and the converted DC power is supplied to the DC load device 144. In addition to supplying the converted DC power to the power storage device 145, the DC power supplied from the power generation device 142 and the power storage device 145 is converted into DC power to be interchanged, and the DC power is converted into the primary DC bus 32. And an operation mode to be supplied to the bus.

In the case of a power accommodation system having such a configuration (for example, the power accommodation system 1), for example, bidirectional AC / DC conversion is performed in the conversion device A120 and the conversion device D130 of the parent cluster unit 100 (first cluster unit) shown in FIG. The unit 121 includes an AC / DC converter and a DC / AC converter (inverter). The bidirectional AC / DC converter 121 converts AC power input from the transformer 102 into DC power along the direction indicated by the broken line b, and supplies the DC power to the distribution board 162 via the power supply path 172 inside the cluster unit. Can be output.
In addition, the bidirectional AC / DC converter 121 converts the DC power supplied from the power generation device 142 and the power storage device 145 along the direction indicated by the broken line c into AC power that can be accommodated in the primary AC bus 31, and the AC power Can be output to the primary AC bus 31. In addition, the bidirectional AC / DC converter 121 converts AC power input from the primary AC bus 31 via the distribution board 161 into DC power along the direction indicated by the broken line d, so that the internal power of the cluster unit is increased. The power can be output toward the distribution board 162 via the power supply path 172. The same applies to the child cluster unit 200 and the like (second cluster unit).

  Further, as shown in FIG. 3B, the bidirectional DC converter (bidirectional DC / DC converter) 131 is supplied from the power generator 142 and the power storage device 145 along the direction indicated by the broken line e, for example. The direct current power can be converted into direct current power that can be accommodated in the primary side DC bus 32, and this direct current power can be supplied to the primary side DC bus 32. In addition, the bidirectional DC converter 131 inputs DC power from the primary side DC bus 32 along the direction indicated by the broken line f, and converts this DC power into DC power distributed to the power supply path inside the cluster unit. The DC power can be output to the distribution board 162 via the power supply path 173. The same applies to the child cluster unit 200 and the like (second cluster unit).

  (5) In the above embodiment, the parent cluster unit 100 (first cluster unit) converts the power supplied from the power generation device 141 (first power generation device) into AC power and communicates with the connected power supply path. Including a PCSAC 150 (first power conditioner) to be connected, a power supply path for supplying power to the primary AC bus 31 and a power supply path for supplying power to the commercial power system 2 at the connection destination of the PCSAC150, A switching unit 160 (first switching unit) that switches between a power supply path that supplies power to the power supply 31 and a power supply path that supplies power to the commercial power system 2, and the switching unit 160 changes from the PCSAC 150 to the primary AC bus 31. When power is supplied, the connection destination of the PCSAC 150 is a power supply path for supplying power to the primary AC bus 31.

  In the parent cluster unit 100 (first cluster unit) having such a configuration, for example, as shown in the conversion device A 120 in FIG. 3, the common contact point c and the contact point b of the switching unit 160 are made conductive, thereby generating the power generation device 141. The PCSAC 150 (first power conditioner) can be connected to the power supply path 174 toward the primary AC bus 31, and AC interchange can be performed from the PCSAC 150 toward the AC bus 31. In addition, by connecting the common contact c and the contact a of the switching unit 160, power can be supplied from the PCSAC 150 to the commercial power system 2.

  (6) In the embodiment described above, the parent cluster unit 100 (first cluster unit) converts the power supplied from the power generation device 142 (second power generation device) into DC power and connects to the connected power supply path. Including a PCSDC 150A (second power conditioner) to be connected, a power supply path for supplying power to the primary DC bus 32 at a connection destination of the PCSDC 150A, and a power supply path for distributing direct current power within the own cluster unit. A switching unit 160A (second switching unit) that switches between a power supply path that supplies power to the DC bus 32 and a power supply path that distributes DC power inside the own cluster unit, and the switching unit 160A is connected to the primary side from the PCSDC 150A. When supplying power to the DC bus 32, the connection destination of the PCSDC 150 </ b> A is set as a power supply path for supplying power to the primary side DC bus 32.

  In the parent cluster unit 100 (first cluster unit) having such a configuration, for example, as shown in the parent cluster unit 100A of FIG. 5, the common contact c and the contact a of the switching unit 160A are made conductive, thereby causing the PCSDC 150A ( A second power conditioner) can be directly connected to the primary DC bus 32 to allow direct current interchange from the PCSDC 150A toward the primary DC bus 32.

  (7) In the above embodiment, for example, the child cluster unit 200 (second cluster unit) converts the power supplied from the power generation device 241 (third power generation device) into AC power and connects to the power supply path of the connection destination. A PCSAC 250 (third power conditioner) to be connected to the PCSAC 250, a power supply path for supplying power to the primary AC bus 31 at a connection destination of the PCSAC 250, and a power supply path for distributing AC power to the inside of the own cluster unit, A switching unit 260 (third switching unit) that switches between a power supply path that supplies power to the primary AC bus 31 and a power supply path that distributes AC power within the own cluster unit. When power is supplied to the primary side AC bus 31, the connection destination of the PCSAC 250 is set as a power supply path for supplying power to the primary side AC bus 31.

In the child cluster unit having such a configuration, for example, as shown in the converter B220 in FIG. 4, the PCSAC 250 of the power generator 241 is connected to the AC bus 31 by conducting the common contact c and the contact a of the switching unit 260. Direct connection is made, and AC interchange is performed from the PCSAC 250 toward the primary AC bus 31. That is, AC interchange is performed from the PCSAC 250 to the primary AC bus 31 along the path indicated by the broken line A1.
As a result, when AC interchange is performed from the child cluster unit 200 to the primary AC bus 31, power is directly supplied to the primary AC bus 31 via the switching unit 260 without passing through the conversion device B 220. Can do.

  (8) In the above embodiment, for example, the child cluster unit 200A (FIG. 9) converts the power supplied from the power generation device 242 (fourth power generation device) into DC power and connects to the power supply path of the connection destination. Including a PCSDC 250A (fourth power conditioner) to be connected, a power supply path for supplying power to the primary DC bus 32 at a connection destination of the PCSDC 250A, and a power supply path for distributing DC power to the inside of the own cluster unit. A switching unit 260A (fourth switching unit) that switches between a power supply path that supplies power to the side DC bus 32 and a power supply path that distributes DC power to the inside of the own cluster unit, and the switching unit 260A is primary from the PCSDC 250A. When supplying power to the side DC bus 32, the connection destination of the PCSDC 250 </ b> A is a power supply path for supplying power to the primary side DC bus 32.

In the child cluster part (second cluster part) having such a configuration, for example, as shown in the child cluster part 200A of FIG. 9, the PCSDC 250A is made primary by conducting the common contact c and the contact a of the switching part 260A. Direct connection to the side DC bus 32 and direct current interchange from the PCSDC 250 </ b> A toward the primary side DC bus 32 can be performed. That is, DC interchange can be performed directly from the PCSAC 250A to the primary DC bus 32 along the path indicated by the broken line A2.
Thereby, when DC interchange is performed from the child cluster unit 200 to the primary side DC bus 32, power is directly supplied from the power generator 242 to the primary side DC bus 32 via the switching unit 260A without passing through the conversion device B220. Can be accommodated.

  (9) Further, in the above embodiment, the power accommodation system (for example, the power accommodation system 1) is configured such that the primary cluster AC (primary cluster unit) in the parent cluster unit 100 (first cluster unit), the child cluster unit 200, and the like (second cluster unit). AC interchange via bus 31, DC interchange via primary DC bus 32, or AC interchange via primary AC bus 31 and DC interchange via primary DC bus 32 When performing conversion between AC power and DC power in a bidirectional AC / DC converter (for example, the bidirectional AC / DC converter 121), the supply direction of the DC power is determined. Determined by.

  For example, as shown in the parent cluster unit 100 (first cluster unit) shown in FIG. 6, the AC power output from the power conditioner (PCSAC) 150 is large, and the direction from the bidirectional AC / DC conversion unit 121 to the distribution board 162 is large. When the current Idc flows through the parent cluster unit 100, the parent cluster unit 100 performs AC interchange with the child cluster unit 200 and the like (second cluster unit) through the primary AC bus 31. In addition, when the DC power output from the PCSDC 150A is large and the current Idc flows from the distribution board 162 in the direction of the bidirectional AC / DC converter 121, the parent cluster unit 100 has a primary side with respect to the child cluster unit 200 and the like. DC exchange is performed via the DC bus 32. The same applies to the child cluster unit 200 and the like.

  Thereby, when the AC power output from the power conditioner (PCSAC) 150 is large, AC interchange can be performed using the AC power output from the PCSAC 150. When the DC power output from the PCSDC 150A is large, DC interchange can be performed using the DC power output from the PCSDC 150A. For this reason, it becomes easy to determine whether to perform AC accommodation or DC accommodation, and the power accommodation control can be simplified.

(10) In the above embodiment, the parent cluster unit 100 (first cluster unit), the child cluster unit 200, etc. (second cluster unit) perform AC interchange via the primary side AC bus 31 or the primary side. The parent cluster unit selects whether to perform direct current interchange through the DC bus 32, or to perform both alternating current interchange through the primary side AC bus 31 and direct current interchange through the primary side DC bus 32. It implements according to the storage battery remaining capacity of the electrical storage apparatus with which the cluster part which is a supply source among 100 (1st cluster part), child cluster part 200 grade | etc., (2nd cluster part).
In the case of the power accommodation system having such a configuration (for example, the power accommodation system 1), for example, in the parent cluster unit 100, the first stage of performing the AC accommodation mode according to the remaining battery capacity SOC of the power storage device 145; The power accommodation process is performed in two stages, that is, the second stage in which both the AC accommodation mode and the DC accommodation mode are executed.
Thereby, for example, when the power storage device 145 becomes nearly fully charged, the AC interchange mode can perform AC interchange with another cluster unit, and the power storage device 145 may be overcharged. By performing DC accommodation together with AC accommodation, it is possible to increase the amount of power accommodated to other cluster units and avoid overcharging of the power storage device 145.

As mentioned above, although embodiment of this invention was described, the electric power interchange system 1 and the electric power interchange system 1A of this invention are not limited only to the above-mentioned illustration example, The range which does not deviate from the summary of this invention. Of course, various changes can be made.
For example, the power storage device 145 of the parent cluster unit 100 may be provided independently of the parent cluster unit 100 unit. The same applies to the power storage devices of the child cluster unit 200, the child cluster unit 300, and the child cluster unit 400.

In the power accommodation system 1 (1A) according to the above-described embodiment, the so-called “soft start” control is performed so that the interchanged power is gradually fed at the start of feeding the electricity to be accommodated via the primary DC bus 32. May be performed. For example, a cluster unit that provides power to other cluster units is controlled so as to gradually increase the power supply voltage at a predetermined time at the start of power supply so that the rise of the voltage of the primary DC bus 32 becomes gentle. May be. Further, the cluster unit that accommodates power may be controlled to intermittently supply power at a predetermined time at the start of power supply. Note that the cluster unit that accommodates power may be controlled so as to limit the current value to be fed during a predetermined time at the start of feeding.
In this way, by performing the soft start control, it is possible to suppress the occurrence of an inrush current at the start of power supply that causes a voltage drop of the power supply voltage or power supply stop.

1, 1A ... Power interchange system, 2 ... Commercial power system,
11 ... Energy management device (EMS), 12 ... Communication network,
31 ... Primary side AC bus, 32 ... Primary side DC bus,
100, 100A ... parent cluster part (first cluster part), 102 ... transformer,
200, 200A, 300 ... child cluster part (second cluster part),
110, 210, 310, 410 ... control unit,
121, 221... Bidirectional AC / DC converter
131, 223 ... Bidirectional DC converter,
141 ... power generation device (first power generation device), 142 ... power generation device (second power generation device),
241 ... Power generation device (third power generation device),
242 ... Power generation device (fourth power generation device),
143, 243, 343, 443 ... AC load device,
144, 244, 344, 444 ... DC load device,
145, 245, 345, 445 ... power storage device,
150 ... power conditioner (first power conditioner),
150A ... Power conditioner (second power conditioner),
250 ... power conditioner (third power conditioner),
250A ... power conditioner (fourth power conditioner),
160 ... switching unit (first switching unit), 160A ... switching unit (second switching unit),
260 ... switching unit (third switching unit),
260A ... switching unit (fourth switching unit),
161,261,361,461 ... distribution panel,
162, 262, 362, 462 ... distribution board

Claims (11)

A first cluster unit that serves as a power reception point of the commercial power system and receives supply of commercial power from the commercial power system; and one or a plurality of second cluster units that receive supply of the commercial power via the first cluster unit; A power interchange system comprising:
Each of the first cluster unit and the second cluster unit includes a power generation device and a load device, or a power storage device and the load device,
Between the first cluster part and the second cluster part, and between the plurality of second cluster parts,
A power interchange system characterized in that power is interchanged with AC power and power is interchanged with DC power. The first cluster unit and the second cluster unit are connected by an AC bus serving as an AC power feeding path and also connected by a DC bus serving as a DC power feeding path,
The AC power is interchanged between the first cluster unit and the second cluster unit via the AC bus, and the DC power is interchanged via the DC bus. Power interchange system. When accommodating power between the first cluster unit and the second cluster unit and between the plurality of second cluster units,
3. A mode in which only AC power is accommodated, a mode in which only DC power is accommodated, and a mode in which both AC power and DC power are accommodated are selectable. The power interchange system described in 1. The first cluster part and the second cluster part are:
A bidirectional AC / DC converter that performs bidirectional power conversion between AC power and DC power;
A bidirectional DC converter that performs bidirectional power conversion between DC power and DC power;
With
The bidirectional AC / DC converter is
The AC power supplied from the AC bus is converted into DC power distributed to a power supply path inside the cluster unit, and the converted DC power is supplied to a DC load device, and the converted DC power is supplied to the power storage device. Operation mode to store,
An operation mode for converting the DC power supplied from the power generation device or the power storage device included in the own cluster unit into the AC power to be accommodated, and supplying the AC power to the AC bus;
With
The bidirectional DC converter is
The DC power supplied from the DC bus is converted into DC power distributed to the power supply path inside the cluster unit, the converted DC power is supplied to the DC load device, and the converted DC power is supplied to the power storage device. Operation mode to store,
An operation mode for converting DC power supplied from the power generation device and the power storage device into the flexible DC power, and supplying the DC power to the DC bus;
The power interchange system according to claim 2 or 3, further comprising: The first cluster unit includes:
A first power conditioner that converts electric power supplied from the first power generator into AC power and that is linked to a power supply path of a connection destination;
The connection destination of the first power conditioner includes a power supply path for supplying power to the AC bus and a power supply path for supplying power to the commercial power system, and the power supply path for supplying power to the AC bus and the commercial power supply A first switching unit that switches between a power supply path that supplies power to the power system;
With
The first switching unit includes:
When power is supplied from the first power conditioner to the AC bus,
The power interchange system according to claim 4, wherein the connection destination of the first power conditioner is a power supply path that supplies power to the AC bus. The first cluster unit includes:
A second power conditioner that converts electric power supplied from the second power generator into direct-current power and that is linked to the power supply path of the connection destination;
A power supply path for supplying power to the DC bus; and a power supply path for supplying power to the DC bus and a power supply path for distributing DC power inside the own cluster unit at a connection destination of the second power conditioner; A second switching unit that switches between a power supply path for distributing DC power within the own cluster unit;
With
The second switching unit is
When power is supplied to the DC bus from the second power conditioner,
The power interchange system according to claim 5, wherein a connection destination of the second power conditioner is a power supply path for supplying power to the DC bus. The second cluster part is
A third power conditioner that converts the power supplied from the third power generation device into AC power and that is linked to the power supply path of the connection destination;
A power supply path for supplying power to the AC bus, including a power supply path for supplying power to the AC bus and a power supply path for distributing AC power inside the own cluster unit at a connection destination of the third power conditioner; A third switching unit for switching between a power feeding path for distributing AC power inside the own cluster unit;
With
The third switching unit is
When supplying power to the AC bus from the third power conditioner,
The power interchange system according to claim 6, wherein a connection destination of the third power conditioner is a power supply path that supplies power to the AC bus. The second cluster part is
A fourth power conditioner that converts the power supplied from the fourth power generation device into direct current power and that is linked to the connected power supply path;
A power supply path for supplying power to the DC bus, including a power supply path for supplying power to the DC bus at a connection destination of the fourth power conditioner and a power supply path for distributing DC power inside the own cluster unit And a fourth switching unit that switches between the power feeding path for distributing DC power to the inside of the own cluster unit,
With
The fourth switching unit is
When supplying power to the DC bus from the fourth power conditioner,
The power interchange system according to claim 7, wherein a connection destination of the fourth power conditioner is a power supply path for supplying power to the DC bus. In the first cluster part and the second cluster part,
AC interchange via the AC bus, DC interchange via the DC bus, or both AC interchange via the AC bus and DC power via the DC bus When deciding
9. The conversion according to claim 4, wherein when the bidirectional AC / DC conversion unit performs conversion between AC power and DC power, the DC power supply direction is determined. Power interchange system. The first cluster part and the second cluster part are:
AC interchange via the AC bus, DC interchange via the DC bus, or both AC interchange via the AC bus and DC interchange via the DC bus The choice of
It implements according to the storage battery remaining capacity of the power storage device with which the cluster part which corresponds to the supply source among the first cluster part and the second cluster part is provided. The described power interchange system. A first cluster unit that serves as a power reception point of the commercial power system and receives supply of commercial power from the commercial power system; and one or a plurality of second cluster units that receive supply of the commercial power via the first cluster unit; Each of the first cluster unit and the second cluster unit includes a power generation device and a load device, or a power storage device and the load device, and each of the power generation device, the power storage device, and the load device. A power interchange method in a power interchange system comprising any or all of them,
In the first cluster unit and the second cluster unit, and between the plurality of second cluster units, power is exchanged by AC power, and power is exchanged by DC power. Power interchange method to do.

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