JP2018137863A - Area-based storage battery sharing system - Google Patents

Abstract

PURPOSE: To provide an area-based storage battery sharing system which allows sharing of a storage battery by a plurality of user facilities which are closer to one another in an area having a certain size.CONSTITUTION: The system comprises: inverters set in power facilities (user facilities) set for respective users; solar battery modules set inside the respective user facilities; one or more shared storage batteries which are set inside or outside of each of the user facilities and are connected with the inverter via a DC/DC converter; a DC bus via which the shared storage batteries set for the respective user facilities or outside the user facilities are connected to one another or to the corresponding DC/DC converters; and a control device that controls charging or discharging, etc. between the shared storage batteries and the inverters or solar battery modules of the corresponding user facilities.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a storage battery area sharing system in which grid-connected power use facilities provided for each user can cooperate with each other in a certain area.

  Conventionally, for each user, a solar power generation system that can supply the generated power from the solar cell module to the load and sell the surplus power to the power system, and use the electric power by storing nighttime power with a low electricity bill There is known a grid-connected power usage facility combined with a power storage system that discharges in the daytime (see Patent Document 1). In such a grid-connected power usage facility, for example, as shown in FIG. 4, a storage battery (506) is connected to a grid-connected bidirectional AC / DC converter via a bidirectional DC / DC converter (505). The solar cell module (7) is also connected to the grid interconnection bidirectional AC / DC converter (inverter. 502). In such a grid-connected power usage facility, the power generated by the solar cell module (7) can be charged to the storage battery (506) via the bidirectional DC / DC converter (505). In addition, it is possible to charge the storage battery (506) by converting the power from the power system (1) into a direct current by a system interconnection bidirectional AC / DC converter (inverter 502). (506) or DC power from the solar cell module (7) is converted to AC by a system interconnection bidirectional AC / DC converter (inverter. 502) and output to the load (3) or to the power system (1). It is also possible to output (reverse power flow / power sales).

JP 2002-369406 A

  Incidentally, in recent years, as power conditioners with storage batteries are increasingly installed, the use of storage batteries for the purpose of saving power costs and for emergency power supply is increasing in each home. And generally, utilization of a storage battery is dependent on a user's power consumption and the capacity | capacitance of a storage battery. If a storage battery having a larger capacity can be installed, the effect of saving electricity costs and the utility as an emergency power source can be increased.

  However, at present, since storage batteries are still expensive, it is costly for each house (each user) to purchase and install a storage battery having sufficient capacity for saving electricity costs and using it as an emergency power source. It ’s difficult. From such a current situation, a device for effectively utilizing the capacity of an expensive storage battery is desired. On the other hand, the amount of power used varies from door to door, and the amount of power used varies greatly depending on the time zone even when viewed from the door. From this point of view, if there are various users and time zones that use a lot of power and users and time zones that do not use much power, it would be expensive if multiple users could use the storage battery jointly. It is possible to increase opportunities to effectively utilize the capacity of the storage battery without wasting it.

  The present invention has been made paying attention to such problems of the prior art, and each of a plurality of user facilities (system interconnection type) existing close to each other in an area having a certain size. Provide a storage battery area sharing system that allows multiple users to share (joint use) expensive storage batteries, such as power storage facilities) each storing power in a shared storage battery or using power from a shared storage battery. For the purpose. In particular, an object of the present invention is to provide a storage battery area sharing system capable of recording and managing the amount of power charged in the shared storage battery for each user facility. It is another object of the present invention to provide a storage battery area sharing system that allows each user facility to use power from the shared storage battery only within the range of the amount of power that is charged to the shared storage battery. . Furthermore, an object of the present invention is to provide a storage battery area sharing system in which each user facility can individually charge a shared storage battery within a range in which the shared storage battery can be charged.

  A storage battery area sharing system according to the present invention for solving the above-described problems is an inverter installed in each power facility (hereinafter referred to as “user facility”) installed for each user. An inverter connected to a load in the power system and each user facility, and a solar cell module installed inside each user facility, the inverter being connected to the first DC / DC converter Connected to each other, and one or a plurality of door-to-door storage batteries installed inside each user equipment, via the inverter or the solar cell module and a second DC / DC converter. Connected door-to-door storage batteries and one or a plurality of shared storage batteries installed inside or outside each of the user facilities, the inverter Is a shared storage battery connected through the third DC / DC converter installed for each of the user storage equipment and each user equipment, and a DC bus arranged outside each of the user equipment, DC bus for connecting a plurality of shared storage batteries to each other, operations of loads, inverters, first and second DC / DC converters, and solar cell modules arranged in each user facility, and each use An inverter, a solar cell module, or a door-to-door storage battery in each user facility of the shared storage battery based on detection data of each operation of the third DC / DC converter and the shared storage battery disposed inside or outside the user facility And a central control device that controls charging or discharging between them.

  Moreover, the storage battery area sharing system according to the present invention is an inverter installed in each power facility (hereinafter referred to as “user facility”) installed for each user, and includes an electric power system and each user. An inverter connected to a load in the facility, and a solar cell module installed in each user facility, the solar cell module being connected to the inverter via a first DC / DC converter; One or a plurality of door-to-door storage batteries installed inside each user facility, the door-to-door storage batteries connected to the inverter or the solar cell module via a second DC / DC converter, and One or a plurality of shared storage batteries installed outside the user equipment, installed for each of the inverter or the individual storage battery and each user equipment A shared storage battery connected via a third DC / DC converter and a DC bus described later, and a DC bus arranged outside the user equipment, wherein the shared storage battery is connected to each of the third DCs. DC bus connected to the DC / DC converter, loads, inverters, first and second DC / DC converters, and solar cell modules arranged in the user equipment, operations of the user equipment Based on the detection data of the operation of the third DC / DC converter arranged inside or outside and the operation of the shared storage battery arranged outside each user equipment, the inside of each user equipment of the common storage battery A central control device that controls charging or discharging between the inverter, the solar cell module, or the door-to-door storage battery.

  Further, in the storage battery area sharing system according to the present invention, the central control device acquires detection data of each operation of the third DC / DC converter arranged for each user facility, and uses these detection data as the detection data. Based on how much electric power from each user equipment is charged in the shared storage battery, and how much electric power discharged from the shared storage battery is used for each user equipment. It may be obtained separately and recorded.

  Further, in the storage battery area sharing system according to the present invention, the central control unit is configured to use each user facility based on each data indicating how much electric power from each user facility is charged in the shared storage battery. The third DC / DC converter is controlled so as to enable discharge from the shared storage battery to each of the user facilities within the range of the amount of power charged to the shared storage battery. May be.

  Further, in the storage battery area sharing system according to the present invention, the central control device acquires detection data of the remaining amount of storage of the shared storage battery, and the shared storage battery is within a range in which the shared storage battery can be charged based on the remaining storage power data. The third DC / DC converter may be controlled so as to enable charging from each user facility.

  According to the present invention, one or a plurality of shared storage batteries installed inside or outside each user facility are connected to a DC bus arranged outside each user facility and inside or outside each user facility. Via an arranged third DC / DC converter, an inverter in each user facility (an inverter connected to a power system and a load in each user facility, a bidirectional AC / DC for system interconnection) Connected to a DC converter), each user facility of a plurality of users (customers) belonging to a certain area can store power in the shared storage battery or the shared storage battery. A plurality of users can share (joint use) expensive storage batteries, such as using electric power from

  In the present invention, the central control unit acquires detection data of each operation of the third DC / DC converter arranged for each user facility, and uses each of the use based on the detection data. So as to obtain and record for each user facility how much power from the user facility is charged in the shared storage battery and how much power discharged from the shared storage battery is used for each user facility. When this is done, independent power management for each user facility and shared use of the shared storage battery can both be properly achieved.

  Further, in the present invention, the central control device, from each user facility to the shared storage battery, based on each data indicating how much power from each user facility is charged to the shared storage battery, respectively. When each of the third DC / DC converters is controlled so as to enable discharge from the shared storage battery to each of the user facilities within the range of the charged electric energy, the shared storage battery Shared use of each user equipment fairly (that is, each user equipment uses the discharge power from the shared storage battery only within the amount of power charged to the shared storage battery by each user equipment. Can be done fairly).

  Further, in the present invention, the central control device acquires detection data of the remaining amount of charge of the shared storage battery, and based on the remaining charge amount data, each user equipment within a range in which the shared storage battery can be charged. When each of the third DC / DC converters is controlled so as to be able to be charged from the battery, in the shared use of the shared storage battery, within the range of electric energy that the shared storage battery can charge, It becomes possible to charge the shared storage battery with electric power from each user facility.

It is the schematic which shows notionally an example of the storage battery area sharing system which concerns on this invention. It is a schematic block diagram which shows the storage battery area sharing system by Embodiment 1 of this invention. It is a schematic block diagram which shows the storage battery area sharing system by Embodiment 2 of this invention. It is a schematic block diagram which shows the grid connection type electric power usage equipment (user equipment) which combined the conventional photovoltaic power generation system and the electrical storage system.

  FIG. 1 is a schematic conceptual diagram showing an example of a storage battery area sharing system according to the present invention. As shown in FIG. 1, in the present invention, for example, a shared storage battery (shared auxiliary storage battery) is arranged in each door (customer) having a load or the like connected to the system line, or connected to the system line, respectively. A shared storage battery (shared auxiliary storage battery) is arranged separately from each door (customer) having a load, etc., the shared storage batteries are connected to each other by a DC bus, and the shared storage battery is connected to each door (for example, each door has its own Storage battery) and a specific load line so that a plurality of users can share (joint use) an expensive storage battery.

[First Embodiment]
Hereinafter, Embodiment 1 of the present invention will be described with reference to FIG. FIG. 2 is a schematic block diagram showing a storage battery area sharing system according to Embodiment 1 of the present invention. In FIG. 2, 1 is a power system to which power from the commercial AC power supply 2 is supplied, and 3 is a power facility (user facility) on each user (user) side that can receive power from the power system 1. .

  Each user facility 3 is equipped with a device as shown in the frame of reference numeral 3 in FIG. That is, in the frame of reference numeral 3 in FIG. 2, 4 is a load such as a home appliance provided in each user equipment 3 and is connected to the power system 1 through the AC wiring 5 and the switchboard (not shown). The load 6 is a solar cell module provided in each user facility 3, and 7 is an inverter connected to the solar cell module 6 through a DC / DC converter 8 and a DC wiring 9. The inverter 7 is connected to the load 4 and the power system 1. Further, the inverter 7 is usually disposed in a power conditioner having a role of converting and adjusting DC power from the solar cell module 6 to AC and supplying it to a load.

  In FIG. 2, reference numeral 10 denotes a door-to-door storage battery that is used inside each user equipment 3 and is connected to the inverter 7 through a DC / DC converter 11 and a DC wiring 9. Reference numeral 12 denotes a door to control various devices in each user facility 3, that is, the solar cell module 6 and the DC / DC converter 8, the inverter 7, the door-to-door storage battery 10 and the DC / DC converter 11, and the load 4. It is a control device. The door-to-door control device 12 includes the amount of generated power at each time of the solar cell module 6 in each user facility 3, voltage / current data indicating the operation at each time of the DC / DC converters 8 and 11, Detection of voltage / current data indicating operation at each time, storage / charge / discharge amount of each storage battery 10 at each time, and voltage / current data indicating power consumption of the load 4 at each time Data is acquired and the devices are controlled based on the data.

  In FIG. 2, reference numeral 13 denotes a DC / DC converter 8 for the solar cell module 6 and a DC / DC converter 11 for the individual storage battery 10 in each user facility 3 via the DC wiring 15 and the DC / DC converter 14. The shared storage battery 16 connected to the inverter 7 (DC wiring 9) is connected to the DC / DC converter 14 arranged for each user facility 3 (not all user facilities 3). It is a DC bus that connects the connected shared storage batteries 13 to each other. The DC / DC converter 14 and the shared storage battery 13 are accommodated in a casing 18 separate from the casing, for example, in a place adjacent to the casing of a power conditioner (not shown) including the inverter 7 and the like. Has been installed. In FIG. 2, reference numeral 17 denotes a central controller that controls operations such as charging / discharging by the DC / DC converter 14 and the shared storage battery 13.

  Next, the operation of the first embodiment will be described. In the first embodiment, the electric power generated by the solar cell module 6 is converted into an alternating current by the inverter 7 after being converted into a voltage by the DC / DC converter 8, and most of the power is supplied through a distribution board (not shown). Although used in the load 4, other surplus power is reversely flowed (sold) into the power system 1. Further, a part of the electric power generated by the solar cell module 6 may be converted into a voltage by the DC / DC converter 8 and then further converted into a voltage by the DC / DC converter 11 to be charged to the individual storage battery 10. .

  In addition, a part of the electric power generated by the solar cell module 6 is charged into the door-to-door storage battery 10 by voltage conversion by the DC / DC converter 11, and inexpensive night AC power from the power system 1 is supplied to the inverter 7 ( DC conversion is performed by the DC / DC converter 11 and the battery is charged.

  Each of the above operations is performed under the control of the door-to-door control device 12. That is, each voltage sensor and current sensor for detecting each operation | movement of the said distribution board (illustration omitted), the load 4, the inverter 7, each DC / DC converter 8,11, the solar cell module 6, and the door-to-door storage battery 10. Detection data from various sensors such as (not shown) is sent to the door-to-door control device 12 as needed. Based on the detection data sent from these various sensors, for example, the door-to-door control device 12 causes the load 4 to use the power from the solar cell module 6 in a clear daytime and the surplus power is the power grid. 1 is caused to reversely flow (sell power) or be charged in the door-to-door storage battery 10, and in the nighttime, the load 4 can be used with the electric power from the door-to-door storage battery 10 and / or the inexpensive nighttime electric power from the power system 1. The above-mentioned devices are controlled so as to achieve optimal power use and power storage, such as charging the night-time storage battery 10 with the nighttime power when the remaining power is low.

  Moreover, in this Embodiment 1, as above-mentioned, the shared storage battery 13 is installed in the outer side of each said user equipment 3, and this each shared storage battery 13 is the DC / DC converter 8 for solar cell modules 6, and a door-to-door storage battery. The DC wiring 9 between the DC / DC converter 11 for 10 and the inverter 7 is connected via the DC / DC converter 14 and the DC wiring 15, respectively. In addition, each shared storage battery 13 installed outside each user facility 3 is connected to each other by a DC bus 16.

  In the first embodiment, operations such as charging / discharging of the shared storage battery 13 are always managed and controlled by a central control device 17 installed in a remote management center or the like. That is, in the first embodiment, detection data such as voltage and current for each time of each device in each user facility 3 is sent to the central control device 17 via the door-to-door control device 12 as needed. . Also, the voltage / voltage data for each time indicating the operation of the DC / DC converter 14 and the detection data from various sensors for detecting the remaining power storage data for each time of the shared storage battery 13 are always centrally controlled. Sent to device 17.

  The central control unit 17 controls the DC / DC converter 14 for a part of the electric power generated by the solar cell module 6 in each user facility 3 based on the detection data from the various sensors, and the shared storage battery. 13 (a plurality of shared storage batteries 13 connected to each other by the DC bus 16) is charged. Further, the central control device 17 controls the DC / DC converter 11 with a part of the electric power stored in the individual storage battery 10 in each user facility 3 based on the detection data from the various sensors. Then, the DC / DC converter 14 is controlled to charge the shared storage battery 13 with the discharged power.

  The central control unit 17 controls the inverter 7 by controlling the DC / DC converter 14 to discharge the electric power stored in the shared storage battery 13 based on the detection data from the various sensors. The discharged power is AC converted and supplied to the load 4 for use, or the DC / DC converter 11 is controlled to charge the discharged storage battery 10 with the discharged power.

  In the present embodiment, the central control device 17 obtains detection data such as voltage / current for each time indicating the operation of each DC / DC converter 14 installed for each user facility 3, How much electric power is charged in the shared storage battery 13 from each user equipment 3 (the solar cell module 6 and the door-to-door storage battery 10 inside the user equipment 3), and how much power is supplied from the shared storage battery 13 to each user equipment 3 It can be ascertained whether or not the internal load 4 and the door-to-door storage battery 10 are discharged and supplied.

  In the first embodiment, the central controller 17 determines how much electric power is charged in the shared storage battery 13 from each user facility 3 grasped as described above, and how much from the shared storage battery 13. On the basis of data indicating whether or not the electric power of each user equipment 3 is discharged and supplied to each user equipment 3, the amount of electric power discharged and supplied from the shared storage battery 13 to each user equipment 3 is determined up to that time. The DC / DC converter 14 is controlled so as to be suppressed within the range of each electric energy charged in the shared storage battery 13.

  In the first embodiment, the central control device 17 acquires detection data of the remaining amount of charge of the shared storage battery 13 as needed. Then, the central control device 17 is configured to charge each DC / DC so as to enable charging from each user facility 3 within a range in which the shared storage battery 13 can be charged based on the acquired remaining power storage data. The DC converter 14 is controlled.

  As described above, in the first embodiment, each shared storage battery 13 (connected to each other by the DC bus 16) installed outside each user facility 3 is connected to each user facility 3. Since it is connected to the inverter 7, the individual storage battery 10 and the solar cell module 6 in each user facility through a DC / DC converter 14 or the like disposed outside the vehicle, the area has a certain size. Each of a plurality of users belonging can share the shared storage battery by charging the shared storage battery with electric power or using the electric power from the shared storage battery.

  Moreover, in this Embodiment 1, the said central control apparatus 17 acquires the detection data of each operation | movement of the DC / DC converter 14 arrange | positioned for every said user equipment 3, Based on these detection data, Ascertain and record how much power from each user facility 3 is charged in the shared storage battery 13 and how much power discharged from the shared storage battery 13 is used in each user facility 3. Therefore, independent power management for each user facility 3 and shared use of the shared storage battery can be easily made compatible.

  Moreover, in this Embodiment 1, the said central control apparatus 17 is based on each data which shows how much the electric power from each said user equipment 3 was charged to the said common storage battery 13, Each said user equipment 3 Each of the DC / DC converters 14 is controlled so as to enable discharge from the shared storage battery 13 to each of the user equipments 3 within a range of each amount of power charged in the shared storage battery 13. Therefore, the shared use of the shared storage battery 13 is performed fairly among the user facilities 3 (that is, each user facility 3 has a range of electric energy charged by the user storage 3 to the shared storage battery 13, respectively). The discharge power from the shared storage battery 13 can be used only in a fair manner).

  Furthermore, in the first embodiment, the central control device 17 acquires detection data of the remaining amount of charge of the shared storage battery 13 and, based on the remaining charge amount data, is within a range where the shared storage battery 13 can be charged. Since each DC / DC converter 14 is controlled so that charging from each user facility 3 is possible, the amount of power that can be charged by the shared storage battery 13 in the shared use of the shared storage battery 13 Within this range, it becomes possible to charge the shared storage battery 13 with electric power from each of the user facilities 3.

[Second Embodiment]
Next, a storage battery area sharing system according to Embodiment 2 of the present invention will be described with reference to FIG. In FIG. 3, the same reference numerals are given to portions common to FIG. 2. Since the basic configuration of the second embodiment is the same as that of the first embodiment, the following description will focus on different parts.

  In the second embodiment, the shared storage battery 13 (see FIG. 2) is installed corresponding to each user equipment 3 as in the first embodiment (for example, the same as the case where each user equipment 3 is arranged). Is installed in association with each of the plurality of user equipments 3 so that one or a plurality of shared storage batteries 21 can be collectively handled with respect to the plurality of user equipments 3. (For example, it is installed in a site different from the site where each user equipment 3 is arranged). The shared storage battery 21 is connected to the inverter 7 in each user facility 3, the DC / DC converter 8 for the solar battery module 6, the DC / DC converter 11 for the door-to-door storage battery 10, the DC / DC converter 22 and the DC wiring 15. Connected. The operation of the central controller 17 is substantially the same as in the first embodiment.

  As described above, in the second embodiment, one or a plurality of shared storage batteries 21 are installed in association with a plurality of user equipments 3 so that the plurality of user equipments 3 can be collectively handled. Although the shared storage battery 13 is different from the first embodiment in which each user facility 3 is associated with each other, the other basic configuration is the same as that of the first embodiment. Therefore, also according to the second embodiment, the same effect as that of the first embodiment can be obtained.

  While the embodiments of the present invention have been described above, the present invention is not limited to those described as the first and second embodiments, and various modifications and changes can be made. For example, in the first embodiment, the DC / DC converter 14 and the shared storage battery 13 that are installed for each user equipment 3 are arranged in a casing 18 that is installed outside the user equipment 3 instead of inside the user equipment 3. However, in the present invention, the DC / DC converter 14 and the shared storage battery 13 may be arranged inside the user equipment 3, respectively.

DESCRIPTION OF SYMBOLS 1 Electric power system 2 Commercial AC power source 3 User equipment 4 Load 5 AC wiring 6 Solar cell module 7 Inverter 8, 11, 14, 22 DC / DC converter 9, 15 DC wiring 10 Door-to-door storage battery 12 Door-to-door control device 13, 21 Shared storage battery 16 DC bus 17 Central control unit 18 Case

Claims (5)

An inverter installed in each power facility installed for each user (hereinafter referred to as “user facility”), connected to a power system and a load in each user facility;
A solar cell module installed inside each user facility, the solar cell module connected to the inverter via a first DC / DC converter,
One or a plurality of door-to-door storage batteries installed inside each user facility, the door-to-door storage batteries connected to the inverter or the solar battery module via a second DC / DC converter,
One or a plurality of shared storage batteries installed inside or outside each user facility, wherein the inverter or the individual storage battery and a third DC / DC converter installed for each user facility A shared storage battery connected via
A DC bus arranged outside each of the user facilities, the DC bus connecting the plurality of shared storage batteries to each other;
Each operation of the load, the inverter, the first and second DC / DC converters, and the solar cell module arranged inside each user equipment, and the third arranged inside or outside each user equipment Central control for controlling charging or discharging between the shared storage battery, an inverter in each user facility, a solar battery module or a door-to-door storage battery based on detection data of each operation of the DC / DC converter and the shared storage battery Equipment,
Storage battery area sharing system equipped with. An inverter installed in each power facility installed for each user (hereinafter referred to as “user facility”), connected to a power system and a load in each user facility;
A solar cell module installed inside each user facility, the solar cell module connected to the inverter via a first DC / DC converter,
One or a plurality of door-to-door storage batteries installed inside each user facility, the door-to-door storage batteries connected to the inverter or the solar battery module via a second DC / DC converter,
One or a plurality of shared storage batteries installed outside the user equipment, the inverter or the door-to-door storage battery, a third DC / DC converter installed for each user equipment, and a DC bus described later A shared storage battery connected via
A DC bus arranged outside the user equipment, the DC bus connecting the shared storage battery to each of the third DC / DC converters;
Each operation of the load, the inverter, the first and second DC / DC converters, and the solar cell module arranged inside each user equipment, and a third arranged inside or outside each user equipment Based on the detection data of the operation of the DC / DC converter and the operation of the shared storage battery arranged outside each user facility, the shared storage battery, the inverter in each user facility, the solar cell module or the individual storage battery, A central controller for controlling charging or discharging between
Storage battery area sharing system equipped with.   The central control unit obtains detection data of each operation of the third DC / DC converter arranged for each user facility, and based on these detection data, power from each user facility is obtained. The amount of charging of the shared storage battery and the amount of electric power discharged from the shared storage battery are used for each user facility and recorded for each user facility. 2. Storage battery community sharing system according to 2.   The central control unit is configured such that each amount of electric power charged to each shared storage battery from each user facility is based on each data indicating how much electric power from each user facility is charged to each shared storage battery. The storage battery area according to claim 1 or 2, wherein each of the third DC / DC converters is controlled so as to enable discharge from the shared storage battery to each of the user facilities within the range of Shared system. The central control device acquires detection data of the remaining amount of charge of the shared storage battery, and based on the remaining charge amount data, charging from each user facility is possible within a range where the shared storage battery can be charged. The storage battery area sharing system according to claim 1 or 2, which controls each of the third DC / DC converters.