JP2019071778A - Power control system, power control method, power control unit, and power storage device - Google Patents

Abstract

To utilize a power generated in a power generation facility effectively as much as possible in a condition to purchase all the generated power.SOLUTION: A power control system comprises: a power control unit (2) that interconnects to a power generation facility in a condition to purchase all generated power; and a power storage device (3) that is used while connected to the power control unit. The power control unit includes a first interconnection relay (25) for connecting to the system, an autonomous output relay (26) for connecting to the power storage device, and a first control unit (23) that, when detecting that abnormality occurs in the system interconnected to the power control unit, performs control to open the first interconnection relay and close the opened autonomous output relay. The power storage device (3) includes a second interconnection relay (34) for connecting to the system, an autonomous input relay (32) for connecting to the power control unit, and a second control unit (31) that, when the power storage device detects that abnormality occurs in the system interconnected to the power storage device or acquires a connection request based on the occurrence of abnormality from the power control unit, performs control to close the autonomous input relay.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a power control system, a power control method, a power control device, and a power storage device.

  BACKGROUND Conventionally, there is known a solar power generation system that stores energy generated by a solar cell in a storage unit when a voltage of a power system exceeds a predetermined value (for example, Patent Document 1).

Unexamined-Japanese-Patent No. 6-133472

  By the way, as a system which sells the electric power which generate | occur | produced (sells electricity), two systems from which power sale conditions etc. differ, such as surplus purchase and whole quantity purchase, are known. Surplus purchase is a system based on the premise that, among the electric power generated by the power generation facility, the surplus that is not used in the home or the like is sold to a general electric utility company or the like. On the other hand, total purchase is a system based on the premise that all electricity generated is sold to general electric utilities and the like. As described above, although there are a plurality of systems having different selling conditions at present, the method described in Patent Document 1 is assumed only in the case of surplus purchase.

  An object of the present invention made in view of such circumstances is an electric power control system, an electric power control method, an electric power control device, and an electric storage device capable of effectively utilizing electric power generated by a power generation facility as much as possible. It is to provide.

In order to solve the above-mentioned subject, a power control system concerning the present invention,
A power control system comprising: a power control device for grid interconnection of a power generation facility under the condition of whole quantity purchase; and a power storage device used in connection with the power control device, wherein the power control device is connected to the grid The first interconnection relay is opened when it is detected that an abnormality has occurred in a system in which the own device is interconnected, and a stand-alone output relay for connection to the power storage device, and the first interconnection relay for opening the first interconnection relay. And a first control unit that performs control to close the open self-standing output relay, and the storage device includes a second interconnected relay for connecting to a grid and an independent stand for connecting to the power control device. Control that closes the self-supporting input relay when the own device detects that the abnormality has occurred in the input relay and the system in which the own device is linked, or when the connection request based on the occurrence of the abnormality is acquired from the power control device Do And a control unit.

Further, in the power control system according to the present invention,
It is preferable that the said abnormality is a power failure of a system.

Further, in the power control system according to the present invention,
It is preferable that the generated power of the power generation facility can be supplied as charging power to the power storage device by closing the stand-alone output relay.

Further, in the power control system according to the present invention,
Preferably, the power control device outputs a connection request to the power storage device when the independent output relay is closed.

Further, in the power control system according to the present invention,
It is preferable that the power storage device closes the self-sustaining input relay after opening the second interconnection relay when detecting that the abnormality has occurred in the system connected by the power control device.

Further, in the power control system according to the present invention,
It is preferable that the power storage device can be supplied with generated power of the power generation facility as charging power by closing the stand-alone input relay.

Further, in the power control system according to the present invention,
When closing the self-supporting input relay, the power storage device preferably acquires a connection request from the power control device.

Moreover, in order to solve the above-mentioned subject, the power control method concerning the present invention is:
A power control method in a power control system, comprising: a power control device for grid-connecting a power generation facility under the condition of whole quantity purchase; and a power storage device used by connecting to the power control device, wherein the power control device The power control device supplies power from the power generation facility to the power storage device after a first step in which the power control device is disconnected from the power system when an abnormality occurs in the system, and after the first step. And second step of controlling to enable.

Further, in order to solve the above problems, a power control apparatus according to the present invention is:
A power control device that interconnects a power generation facility under the condition of whole quantity purchase and is a first interconnection relay for connecting to a grid, a self-supporting output relay for connecting to a power storage device, and an interconnection of the own device And a first control unit that performs control to open the first interconnecting relay and close the open self-standing output relay.

Moreover, in order to solve the above-mentioned subject, the electricity storage device concerning the present invention is:
A power storage device used by connecting a power generation facility with a power control device that interconnects power generation equipment under the condition of whole quantity purchase, for connecting a second interconnecting relay for connecting with a system and the power control device Control of closing the self-supporting input relay upon detection of occurrence of a malfunction in the self-supporting input relay of the invention and the system to which the self-device is linked, or when acquiring a connection request based on the occurrence of the malfunction from the power control device. And a second control unit to perform.

  According to the power control system, the power control method, the power control device, and the power storage device according to the present invention, it is possible to effectively use the power generated by the power generation facility as much as possible under the condition of purchasing all of the power.

It is a functional block diagram in the case of surplus purchase of the power control system concerning one embodiment of the present invention. It is a functional block diagram in the case of whole quantity purchase of the power control system concerning one embodiment of the present invention. It is a figure which shows the mode of the electric power control system when 1st abnormality generate | occur | produces in FIG. It is a figure which shows the mode of the electric power control system when 1st abnormality generate | occur | produces in FIG. It is a figure which shows the mode of the electric power control system when 2nd abnormality generate | occur | produces in FIG. It is a figure which shows the mode of the electric power control system when 2nd abnormality generate | occur | produces in FIG. It is a figure which shows the operation | movement flow of a power control system when a 1st abnormality generate | occur | produces. (A) is a diagram showing an operation flow of the power control device when the second abnormality occurs, and (b) is a diagram showing an operation flow of the power storage device when the second abnormality occurs .

  Hereinafter, an embodiment of the present invention will be described based on the drawings. Although each function of the power generation facility 1, the power control device 2 and the power storage device 3 according to one embodiment of the present invention is described, it should be noted that it is not intended to exclude other functions included in them.

[System configuration]
FIG. 1 is a functional block diagram in the case of surplus purchase of a power control system according to an embodiment of the present invention. The power control system includes a power generation facility 1, a power control device 2, a power storage device 3, a load 4 and a load 5. In the power control system of FIG. 1, the power control device 2 and the power storage device 3 are connected to the same system (commercial power system) in order to perform surplus sale of the power generated by the power generation facility 1. In FIG. 1, the control line and the information transfer line are indicated by broken lines, and the power lines are indicated by solid lines.

  The power generation facility 1 is, for example, a PV (photovoltaic: solar cell) panel, and converts the energy of sunlight into a direct current. In the power generation facility 1, for example, power generation units having photoelectric conversion cells are connected in a matrix and output a predetermined direct current (for example, 10 A). The power generation facility 1 is capable of photoelectric conversion such as a silicon-based polycrystalline solar cell, a silicon-based single crystal solar cell, or a thin-film solar cell such as CIGS (Copper Indium Gallium DiSelenide), and the type is not limited. Further, the power generation facility 1 is not limited to the facility using solar power generation, but may be a facility using a fuel cell, wind power generation, thermal power generation or the like.

  The power control device 2 includes a DC / DC converter 21, an inverter 22, a first control unit 23, a storage unit 24, a first interconnection relay 25, a self-supporting output relay 26, and a sensor 27.

  The DC / DC converter 21 boosts / lowers the voltage of the DC power generated by the power generation facility 1. As shown in FIG. 1, the DC / DC converter 21 is connected to the output end of the power generation facility 1.

  The inverter 22 is connected to the output terminal of the DC / DC converter 21, converts the DC power output from the DC / DC converter 21 into AC power, and outputs the AC power.

  The first control unit 23 is a processor such as a CPU (Central Processing Unit) that controls various operations of the power control device 2. The first control unit 23 acquires information such as the voltage of the system from the sensor 27 and detects whether or not an abnormality such as a voltage increase or a power failure has occurred in the system to which the power control device 2 is connected. it can. The sensor 27 is connected to, for example, the output end of the first interconnection relay 25. In addition, the first control unit 23 controls the opening and closing of the first interconnection relay 25 and the independent output relay 26 in accordance with the occurring abnormality and the grid interconnection condition of the power control device 2. Details will be described later. Furthermore, the first control unit 23 can communicate with the power storage device 3 in a wired or wireless manner, and can output a connection request to the power storage device 3 when closing the isolated output relay 26.

  The storage unit 24 stores whether the grid connection condition is total purchase or surplus purchase. The grid connection condition is set, for example, by the user when the power control device 2 is installed. A functional block diagram of the power control system in the case of full quantity purchase is shown in FIG.

  FIG. 2 shows the power control system in the case of whole quantity purchase, in which case the power control device 2 and the storage device 3 are connected to different systems. In this case, when the power control device 2 and / or the power storage device 3 are connected to the grid, connecting the power control device 2 and the power storage device 3 violates the definition.

  When power control device 2 and power storage device 3 are connected to the same system (that is, in the case of surplus purchase), even if power control device 2 and power storage device 3 are connected, there is no violation of the regulation.

  It returns to the explanation of FIG. The first interconnection relay 25 is a switch connected between the inverter 22 and the system, for switching connection (interconnection) and disconnection (disconnection) between the system and the power control device 2. When the first interconnection relay 25 is closed, the system and the power control device 2 are connected, and when the first interconnection relay 25 is open, the system and the power control device 2 are disconnected.

  The stand-alone output relay 26 is a switch connected between the inverter 22 and the storage device 3 for switching connection and disconnection between the power control device 2 and the storage device 3. When self-sustaining output relay 26 is closed, power control device 2 and power storage device 3 can be connected, and when self-sustaining output relay 26 is open, power control device 2 and power storage device 3 are disconnected. Although details will be described later, it is possible to supply the generated power of the power generation facility 1 to the storage device 3 as charging power by closing the stand-alone output relay 26.

  The storage device 3 includes a second control unit 31, a self-supporting input relay 32, a PCS (Power Conditioning System) 33, a second interconnection relay 34, a storage battery 35, and a sensor 36. The storage device 3 is a device for storing (charging) the electricity generated by the power generation facility 1. The power storage device 3 can store the electricity generated by the power generation facility 1 even when there is an abnormality such as a power failure of the system and a voltage increase of the system.

  The second control unit 31 is a processor such as a CPU that controls various operations of the power storage device 3. The second control unit 31 can use the information notified from the sensor 36 to detect whether a power failure has occurred in the system to which the power storage device 3 is connected. Further, the second control unit 31 controls the opening and closing of the second interconnection relay 34 and the self-supporting input relay 32 according to the occurring abnormality and the grid interconnection condition of the power control device 2. Details will be described later. Furthermore, the second control unit 31 can communicate with the power control device 2 by wire or wirelessly and can obtain a connection request from the power control device 2 when closing the isolated input relay 32.

  The self-supporting input relay 32 is a switch connected between the power control device 2 and the PCS 33 for switching connection and disconnection between the power control device 2 and the storage device 3. When self-sustaining input relay 32 is closed, power control device 2 and power storage device 3 can be connected, and when self-sustaining input relay 32 is opened, power control device 2 and power storage device 3 are separated.

  The PCS 33 is a PCS including an inverter, an AC / DC converter, a bidirectional DC / DC converter, and the like. The PCS 33 outputs the power converted to direct current to the storage battery 35 to charge the storage battery 35. Further, the PCS 33 converts DC power acquired from the storage battery 35 into AC power and outputs the AC power to the load 4.

  The second interconnection relay 34 is a switch connected between the system and the PCS 33 for switching connection (interconnection) and disconnection (disconnection) between the system and the power storage device 3. When the second interconnection relay 34 is closed, the system and the storage device 3 are connected, and when the second interconnection relay 34 is open, the system and the storage device 3 are disconnected.

  The load 4 and the load 5 are power loads that consume power, and are, for example, various electric products such as an air conditioner, a microwave, a refrigerator, a television, a HEMS (Home Energy Management System), and a router used in a home. Moreover, load 4 and load 5 are machines such as an air conditioner or a lighting fixture used in a commerce and industrial facility, lighting equipment and the like. The number of loads 4 and 5 is not limited. By means of the distribution board, it is possible to divide the power into a plurality of stems and supply it to a plurality of loads.

  Hereinafter, power control processing performed by the power control system according to an embodiment of the present invention will be described. In the following description, as an example, the first abnormality is described as a system voltage increase exceeding a threshold (for example, 107 V), and the second abnormality is described as a system power failure. Further, in the case where the system interconnection condition is the whole amount purchase, that is, even when the power control device 2 and the storage device 3 are connected to different systems, the same abnormality occurs in each system.

[Power control processing at the time of the first abnormality occurrence]
Based on the information notified from the sensor 27, the first control unit 23 reports that the system voltage increase (first abnormality) has occurred in the system connected (interconnected) with the own device (power control device 2). When it is detected, the first interconnection relay 25 is opened. Further, the first control unit 23 refers to the storage unit 24 to acquire the grid interconnection condition of the own device (power control device 2).

  When the grid connection condition is surplus purchase (shown in FIG. 3), the first control unit 23 closes the stand-alone output relay 26. On the other hand, when the grid connection condition is the whole amount purchase (shown in FIG. 4), the first control unit 23 opens the stand-alone output relay 26.

  In addition, when the first control unit 23 detects that the system voltage increase (first abnormality) has occurred, it outputs a connection request to the storage device 3, and thereafter the storage device 3 generates the power generated by the power generation facility 1. It may be supplied to the In this case, the first control unit 23 may cause the power generated by the power generation facility 1 to flow only when permission for the connection request is obtained from the power storage device 3.

  When the second control unit 31 acquires a connection request from the power control device 2 due to the occurrence of a system voltage rise, the second control unit 31 detects that the system voltage rise has occurred based on the connection request. The second control unit 31 confirms the grid interconnection condition of the power control device 2 by communication with the power control device 2.

  When the grid connection condition of the power control device 2 is surplus purchase (shown in FIG. 3), the second control unit 31 closes the stand-alone input relay 32 and outputs permission for the connection request to the first control unit 23. Do. At this time, the second interconnection relay 34 is closed. Then, when obtaining permission for the connection request from the storage device 3, the first control unit 23 supplies the power generated by the power generation facility 1 to the storage device 3, and the storage battery 35 is charged.

  On the other hand, when the grid connection condition is the whole amount purchase (shown in FIG. 4), the second control unit 31 opens the self-standing input relay 32. In this case, the second control unit 31 does not output permission for the connection request to the first control unit 23 or outputs failure. At this time, the second interconnection relay 34 is closed.

  By the way, as a method for the second control unit 31 to detect the occurrence of the system voltage increase (first abnormality), a connection request is output by communication from the first control unit 23 to the second control unit 31 for detection. I explained how to do it. However, in addition to this, the second control unit 31 may directly detect the occurrence of the system voltage increase (first abnormality) by the sensor 36 of the power storage device 3 itself.

[Power control processing at the time of the second abnormality occurrence]
For example, the first control unit 23 generates a power failure (second abnormality) in a system connected (interconnected) with its own apparatus (power control apparatus 2) based on information such as a voltage notified from the sensor 27. When it is detected, the first interconnection relay 25 is opened regardless of the grid interconnection condition of the power control device 2. The first control unit 23 then closes the independent output relay 26. The case where the grid connection condition is surplus purchase is shown in FIG. 5, and the case where the grid connection condition is total purchase is shown in FIG.

  On the other hand, when the second control unit 31 detects that a power failure (second abnormality) has occurred based on the information notified from the sensor 36, the second control unit 31 does not depend on the grid interconnection condition of the power control device 2. The system relay 34 is opened, and the stand-alone input relay 32 is closed. At this time, the electric power generated by the power generation facility 1 flows to the storage device 3 and the storage battery 35 is charged.

[Operation flow]
FIG. 7 is a diagram showing an operation flow of the power control system according to an embodiment of the present invention when a system voltage rise (first abnormality) occurs.

  The power control device 2 detects that the system voltage rise (first abnormality) has occurred based on the information notified from the sensor 27 (step S1). After the detection, the power control unit 2 opens the first interconnection relay 25 (step S2). The power control apparatus 2 refers to the storage unit 24 to acquire the grid connection condition (step S3), and determines whether the grid connection condition is surplus purchase or total purchase (step S4).

  If the grid connection condition is surplus purchase, the power control device 2 closes the stand-alone output relay 26 (step S5). On the other hand, when the grid connection condition is the whole amount purchase, the power control unit 2 opens the stand-alone output relay 26 (step S6). The power control device 2 outputs a connection request to the storage device 3 at an arbitrary time point after detecting that the first abnormality has occurred (step S7).

  When the power storage device 3 detects that the system voltage rise (first abnormality) has occurred, for example, based on the connection request (step S8), the power storage device 3 queries the power control device 2 for grid interconnection conditions of the power control device 2 ( Step S9). When the storage device 3 acquires the grid connection condition from the power control device 2 (step S10), the storage device 3 determines whether the grid connection condition is surplus purchase or whole purchase (step S11). When the grid connection condition is surplus purchase, the storage device 3 closes the stand-alone input relay 32 (step S12), and when the grid connection condition is all purchase, the storage device 3 opens the stand-alone input relay 32 (step S13).

  As described above, the storage device 3 (second control unit 31) not only detects the occurrence of the first abnormality based on the connection request acquired from the power control device 2, but also detects the sensor 36 of the storage device 3 itself. It may be detected directly by

  FIG. 8A is a diagram showing an operation flow of the power control apparatus 2 according to an embodiment of the present invention when a power failure (second abnormality) occurs. Since the power control device 2 and the storage device 3 do not necessarily need to communicate, the operation flow of the power control device 2 and the operation flow of the storage device 3 will be described separately.

  The power control device 2 detects that a power failure (second abnormality) has occurred based on the information notified from the sensor 27 (step S21). Next, the power control device 2 opens the first interconnection relay 25 (step S22), and then closes the isolated input relay 32 (step S23).

  FIG. 8B is a diagram showing an operation flow in the case where a power failure (second abnormality) occurs by the power storage device 3 according to an embodiment of the present invention. The power storage device 3 detects that a power failure (second abnormality) has occurred based on the information notified from the sensor 36 (step S31). Next, the storage device 3 opens the second interconnection relay 34 (step S32), and closes the self-supporting input relay 32 (step S33).

  According to the present embodiment, it is possible to effectively use the power generated by the power generation facility as much as possible according to the conditions of surplus purchase or whole quantity purchase.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various changes and modifications based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, functions included in each member, each part, each step, and the like can be rearranged so as not to be logically contradictory. Further, when the present invention is embodied as a method invention, it is possible to combine or divide a plurality of parts and steps into one.

  Further, when the first control unit 23 and the second control unit 31 according to the present invention are configured by a computer, a program describing processing contents for realizing each function is stored in a storage unit inside or outside the computer. This can be realized by reading and executing this program by a central processing unit (CPU) of the computer. Moreover, such a program can be distributed by selling, transferring, lending, etc. of portable recording media such as DVD or CD-ROM, for example, and also storing such a program in, for example, a storage unit of a server on a network. The program can be distributed by transferring the program from the server to another computer via a network. In addition, a computer that executes such a program can temporarily store, for example, a program recorded on a portable recording medium or a program transferred from a server in its own storage unit. Further, as another embodiment of this program, the computer may read the program directly from the portable recording medium and execute processing according to the program, and further, when the program is transferred from the server to the computer Alternatively, processing according to the received program may be performed sequentially.

REFERENCE SIGNS LIST 1 power generation facility 2 power control device 21 DC / DC converter 22 inverter 23 first control unit 24 storage unit 25 first interconnection relay 26 independent output relay 27 sensor 3 storage device 31 second control unit 32 independent input relay 33 PCS
34 second interconnection relay 35 storage battery 36 sensor 4, 5 load

Claims (10)

An electric power control system comprising: an electric power control device for grid-connecting a power generation facility under the condition of whole quantity purchase; and a power storage device used in connection with the electric power control device,
The power control device
A first interconnection relay for connecting to the grid,
An independent output relay for connecting to the power storage device;
And a first control unit configured to open the first interconnection relay and close the self-sustaining output relay that has been opened when it detects that an abnormality has occurred in a system in which the own device is interconnected,
The storage device is
A second interconnection relay for connecting to the grid,
An independent input relay for connecting to the power control device;
The second device performs control to close the stand-alone input relay when the own device detects that the anomaly has occurred in the system to which the own device is linked, or when a connection request based on the occurrence of the anomaly is acquired from the power control device Power control system comprising: In the power control system according to claim 1,
The power control system, wherein the abnormality is a power failure of a system. The power control system according to claim 1 or 2
A power control system characterized in that the generated power of the power generation facility can be supplied as charging power to the power storage device by closing the stand-alone output relay. In the power control system according to claim 3,
A power control system, wherein the power control device outputs a connection request to the power storage device when the independent output relay is closed. The power control system according to any one of claims 1 to 4.
The power storage system, when detecting that the abnormality has occurred in a system connected by the power control apparatus, closes the second self-connected relay and then closes the self-supporting input relay. The power control system according to any one of claims 1 to 5.
A power control system characterized in that the storage device can be supplied with generated power of the power generation facility as charging power by closing the self-sustaining input relay. In the power control system according to claim 6,
A power control system, wherein the power storage device acquires a connection request from the power control device when the independent input relay is closed. A power control method in a power control system, comprising: a power control device that grid-links a power generation facility under the condition of whole quantity purchase; and a power storage device used by connecting to the power control device,
A first step of disconnecting the power control apparatus from the system when an abnormality occurs in a system to which the power control apparatus is connected;
After the first step, a second step of controlling the power control device to supply power from the power generation facility to the power storage device;
A power control method characterized by comprising: It is a power control system that interconnects the power generation equipment under the condition of the total purchase,
A first interconnection relay for connecting to the grid,
A stand-alone output relay for connecting to a storage device,
A power control apparatus comprising: a first control unit that opens the first interconnection relay and performs control to close the self-sustaining output relay that has been opened when it detects that an abnormality has occurred in a system in which the own device is interconnected . A power storage device that is used by connecting a power generation facility with a power control device that interconnects power generation equipment under the condition of total quantity purchasing,
A second interconnection relay for connecting to the grid,
An independent input relay for connecting to the power control device;
A second control unit that performs control to close the self-supporting input relay when it detects that an abnormality has occurred in a system to which the own device is linked, or when a connection request based on the occurrence of the abnormality is acquired from the power control device Power storage device comprising

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