JP2015162969A - Electric power system, power storage control apparatus, control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make effective use of generated electric power.SOLUTION: The electric power system includes: a power generation section that generates electric power on the basis of natural energy; and a power storage control section that stores electric power generated by the power generation section for a storage battery under a chargeable temperature environment, among a plurality of storage batteries installed at different positions from each other.

Description

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

In order to efficiently supply the power generated by the photovoltaic power generation system according to the power demand, surplus power generated when the amount of generated power exceeds the power demand is temporarily stored in the storage battery, and the stored power is There are systems that supply during times of high demand. In such a system, since it is necessary to store electric power efficiently, for example, a lithium ion battery having a relatively high energy density of electric power that can be stored is used.
A temperature range in which the storage battery can be stably used is determined, and it is necessary to use the storage battery within the temperature range. If it is used outside the temperature range where it can be used stably, there is a case where the deterioration of the electrode of the storage battery proceeds. For example, it is known that when a lithium ion battery is charged under a temperature environment lower than a temperature range in which it can be stably used, electrode deterioration proceeds.
As a related storage battery (secondary battery) charge / discharge control method, a temperature range that allows charging and a temperature range that permits discharge are specified, and the temperature range is switched between charging and discharging. (Patent Document 1). According to the technique in Patent Document 1, the lower limit temperature of the temperature range in which charging is permitted is set higher than the lower limit temperature of the temperature range in which discharging is permitted, and charging at a low temperature below the temperature range in which charging is permitted is limited.

JP 2011-155820 A

However, in the technique of Patent Document 1, since power storage (charging) to power storage is limited at low temperatures, even if there is surplus power, it may not be possible to store in the storage battery at low temperatures. Therefore, the generated power may not be used effectively.
The present invention has been made in view of the above circumstances, and provides a power system, a power storage control device, a control method, and a program that can effectively use generated power.

  According to one embodiment of the present invention, a power generation unit that generates power based on natural energy and a storage battery that is in a temperature environment that can be charged among a plurality of storage batteries that are installed at different locations are generated by the power generation unit. And a power storage control unit that stores the stored power.

  Further, according to one aspect of the present invention, in the power system, the different locations include an indoor location, and the power storage control unit stores the indoor storage battery in the rechargeable temperature environment. It is characterized by.

  Further, according to one aspect of the present invention, in the power system, the different places include a place where the power generation unit is installed and a place in the store, and the power storage control unit includes the power generation unit. When the storage battery in the place where the unit is installed is not in a temperature environment where charging is possible, the storage battery in the store stores the power generated by the power generation unit.

  One embodiment of the present invention is characterized in that, in the power system, the indoor location includes a location in a store.

  Further, according to one aspect of the present invention, in the power system, the power storage control unit may be configured to store a storage battery in the store that is in operation based on a business hours of the store, as a storage battery in the chargeable temperature environment. It is characterized by doing.

  Further, according to one aspect of the present invention, in the above power system, when there are a plurality of storage batteries in a temperature environment in which the power storage control unit can be charged, based on the storage state of each of the plurality of rechargeable storage batteries, A storage battery for storing the electric power generated by the power generation unit is selected.

  Further, according to one aspect of the present invention, in the above power system, when there are a plurality of storage batteries in a temperature environment in which the power storage control unit can be charged, the power storage control unit is located at a short distance from a place where the power generation unit is installed. The storage battery is given priority as a storage battery that stores the electric power generated by the power generation unit.

  One embodiment of the present invention includes a determination unit that determines whether each of the plurality of storage batteries is in a chargeable temperature environment in the power system, and the storage control unit includes the determination unit. The electric power generated by the power generation unit is stored in the storage battery determined to be in a temperature environment where charging is possible.

  Further, according to one aspect of the present invention, in the power system, the different locations include a location where the power generation unit is installed and an indoor location, and the storage control unit includes the determination unit When it is determined that the storage battery in the place where the power generation unit is installed is not in a temperature environment in which charging is possible and the storage battery in the indoor is in a temperature environment in which charging is possible, it is in the indoor The power generated by the power generation unit is stored in the storage battery.

  Further, according to one aspect of the present invention, in the above power system, each of the plurality of storage batteries is connected to the power generation unit via at least a distribution line, and the power storage control unit is connected via the distribution line, The electric power generated by the power generation unit is stored in any of the plurality of storage batteries.

  Further, one embodiment of the present invention is a method in which power generated by a power generation unit that generates power based on natural energy is stored in a rechargeable temperature environment among a plurality of storage batteries installed at different locations. A power storage control device comprising: a power storage control unit that stores power.

  One embodiment of the present invention is a method for controlling an electric power system, the step of generating electricity based on natural energy, and a storage battery in a rechargeable temperature environment among a plurality of storage batteries installed at different locations. On the other hand, the control method includes a step of storing electric power generated based on natural energy.

  One embodiment of the present invention includes a step of detecting, in a computer, a power generated by a power generation unit that generates power based on natural energy, and a rechargeable temperature among a plurality of storage batteries installed at different locations. A program for causing a storage battery in an environment to store power generated by the power generation unit.

  According to the present invention, the generated electric power can be used effectively.

It is a block diagram which shows an example of schematic structure of the electric power system by 1st Embodiment. It is a block diagram which shows an example of schematic structure of the electrical storage control apparatus by 1st Embodiment. It is a figure which shows an example of the temperature environment information by 1st Embodiment. It is a flowchart which shows an example of the procedure of an electrical storage control process. It is a block diagram which shows an example of schematic structure of the electrical storage control apparatus by 2nd Embodiment. It is a figure which shows an example of the installation location information by 2nd Embodiment. It is a block diagram which shows an example of schematic structure of the electrical storage control apparatus by 3rd Embodiment. It is a figure which shows an example of the installation location information by 3rd Embodiment. It is a block diagram which shows an example of schematic structure of the electric power system by 4th Embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
<First Embodiment>
Power generation facilities that generate power based on natural energy, such as solar power generation, have been installed in a wide range of areas including large-scale power generation facilities to small-scale power generation facilities. As examples of small-scale power generation, for example, in addition to commercial buildings, stores, ordinary homes, etc., installation of mobile phones at base stations is being promoted in response to power outages in the event of a disaster. In such a power generation facility, for example, in order to efficiently supply power according to power demand, surplus power generated when the amount of generated power exceeds the power demand is temporarily stored in a storage battery, and the stored power is Supply is made during times of high demand.

  By the way, as the storage battery, for example, a lithium ion battery having a relatively high energy density of electric power that can be stored may be used. However, storing the battery at a temperature lower than the rated temperature range may lead to deterioration of the electrode. For this reason, in the power generation equipment installed outdoors, the installed storage battery becomes cold depending on the region, season, weather, time, etc., and when the battery is charged under that low temperature environment, the deterioration of the storage battery electrode proceeds. Sometimes. In view of this, it is conceivable to limit charging so as not to be performed in a low temperature state. In this case, even if there is surplus power, it is impossible to store the power. For example, in cold regions, the temperature may be low even in the daytime, and even if surplus power is generated in the daytime, the power cannot be stored for use at night due to the low temperature. As a countermeasure, a heating facility is required to increase the temperature of the storage battery. In particular, when the capacity of the storage battery is large, a facility for storing the storage battery and a heating facility for increasing the temperature in the facility are required, which is not efficient in terms of power and economy.

  Therefore, in the power system according to the present embodiment, control is performed so that power is sent to and stored in the storage battery of another facility connected to the power generation facility via the distribution line. The storage battery of the other equipment in this case is a storage battery that is arranged in a temperature environment that can be charged, not in a low temperature state. For example, this storage battery is used indoors in a facility where a temperature environment that can be charged is maintained by heat from a heating facility in the store or heat released from the server, such as a store such as a convenience store or a server room. Has been placed. That is, in the electric power system according to the present embodiment, as a facility connected via the distribution line, it is possible to charge without being in a low temperature state even when the outside air temperature is low due to heat from other than the heat source intended to warm the storage battery. At least one facility in which a storage battery is installed inside a facility that can maintain a stable temperature environment is provided.

Thereby, even if the storage battery installed in the power generation facility is in a low temperature state, the power generated by the power generation facility can be stored without requiring a dedicated heating facility for increasing the temperature of the storage battery. . The stored electric power may be used in equipment having the storage battery, or may be provided to other equipment connected to the distribution line. Thereby, the utilization efficiency of the generated electric power can be improved.
Hereinafter, the power system according to the present embodiment that performs power storage control for storing the generated power in a storage battery selected according to the temperature state will be described.

FIG. 1 is a configuration diagram illustrating an example of a schematic configuration of a power system 1 according to the first embodiment of the present invention.
The power system 1 shown in this figure includes a power plant 10, a power generation facility 20, a cluster 30, a power transmission system 40, a power distribution system 50, and a power storage control device 60. Here, the term “cluster” in the present embodiment refers to one unit (for example, a facility of a customer including a power generation device, a power storage device, or a load device configured from a distributed power source using natural energy (renewable energy)). , Building, store, and equipment for each wireless base station). Here, the power system 1 includes two power generation facilities 20 (a power generation facility 20-1 and a power generation facility 20-2), three clusters 30 (a cluster 30-1, a cluster 30-2, a cluster 30-3), and However, it can be any number.

  The power plant 10 generates power based on various energies such as thermal power, hydropower, and nuclear power. The power generated by these power plants 10 is managed so that stable power is supplied to the clusters (customer facilities). The power plant 10 is connected to the power transmission system 40. The power transmission system 40 is connected to the power distribution system 50, and transmits the power generated by the power plant 10 to the power distribution system 50 via a power transmission line. The power distribution system 50 distributes the electric power transmitted from the power plant 10 via the power transmission system 40 to the power generation facility 20 and the cluster 30 via the distribution line. Here, although an example in which one power plant 10 is connected to the power transmission system 40 is shown, the number of power plants 10 may be an arbitrary number.

  The power generation facility 20 generates power based on natural energy. For example, natural energy includes sunlight, solar heat, wind power, wave power, geothermal heat, and the like. The electric power generated by the power generation facility 20 based on these natural energies varies under the influence of changes in the surrounding environment such as the weather and climate of the place where power is generated. The power generation facility 20 is connected to the power distribution system 50.

  For example, the power generation facility 20 includes a power generation device 210 (an example of a power generation unit) that generates power based on sunlight, and a power storage device 220 having a storage battery (for example, a lithium ion battery). The electric power generated by the power generation device 210 is distributed to the cluster 30 via the power distribution system 50. In addition, surplus power out of the power generated by the power generation device 210 is stored in the power storage device 220, discharged according to the power demand of the cluster 30, and distributed to the cluster 30 via the power distribution system 50. The power storage device 220 can also store power received via the power distribution system 50. Here, it is assumed that power storage devices 220 of power generation facility 20-1 and power generation device 20-2 are installed outdoors.

  The cluster 30 is a customer facility connected to the power distribution system 50. For example, the cluster 30 includes a power generation device 310 that generates power based on sunlight, a power storage device 320, and a load device 330. The power storage device 320 includes a storage battery (for example, a lithium ion battery), and the power received via the power distribution system 50 (the power generated by the power plant 10 or the power generated by the power generation facility 20) or the power generation device 310 It stores the generated power.

  The electric power stored in the power storage device 320 is supplied to the load device 330 according to the power demand of the load device 330. In addition, the power stored in the power storage device 320 is distributed to the other cluster 30 or the power generation facility 20 via the power distribution system 50 according to the power demand of the other facility. The load device 330 consumes the power received via the power distribution system 50, the power generated by the power generation device 310, or the power stored in the power storage device 320.

  Here, the cluster 30-1, the cluster 30-2, and the cluster 30-3 will be described as having the same configuration including the power generation device 310, the power storage device 320, and the load device 330. The cluster 30 including at least one of the power storage device 320 and the load device 330 may be connected to the power distribution system 50. Here, it is assumed that the cluster 30-1 and the cluster 30-2 are facilities installed outdoors, and the cluster 30-3 is a facility installed indoors (for example, in a store such as a convenience store). To do. That is, the power storage device 320 provided in each of the cluster 30-1 and the cluster 30-2 is installed outdoors, and the power storage device 320 provided in the cluster 30-3 is installed indoors (in the store). And In addition, although the electric power generating apparatus 310 of the structure with which the cluster 30-3 is provided is installed outdoors (the roof of a store, etc.), in the following, for ease of explanation, “a cluster in which storage batteries are installed indoors” “30-3” is also simply referred to as “indoor cluster 30-3”.

  The power storage control device 60 collects information from each of the power generation equipment 20 and the cluster 30 connected via the power distribution system 50. In addition, the power storage control device 60 transmits a control signal for controlling the operation of the power generation facility 20 and the cluster 30 to the power generation facility 20 and the cluster 30 based on the collected information. For example, the power storage control device 60 controls which storage battery connected to the power generated by the power generation facility 20 via the power distribution system 50 is stored. Specifically, the power storage control device 60 acquires temperature information of the environment where the storage batteries of the power generation facility 20 and the cluster 30 are installed, and the power generated by the power generation facility 20 based on the acquired temperature information. A storage battery for storing the battery is selected.

Next, the configuration of the power storage control device 60 will be described in detail with reference to FIG.
FIG. 2 is a configuration diagram illustrating an example of a schematic configuration of the power storage control device 60 according to the present embodiment. The power storage control device 60 shown in this figure includes a communication unit 610, an information collection unit 620, a temperature environment determination unit 630 (an example of a determination unit), a storage unit 640, and a power storage control unit 650.

  The communication unit 610 communicates with the power generation facility 20 (power generation facility 20-1, power generation facility 20-2) and the cluster 30 (cluster 30-1, cluster 30-2, cluster 30-3) via a communication network.

  The information collection unit 620 receives information such as the power generation state of each power generation device of the power generation facility 20 and the cluster 30, the storage state of the storage battery (for example, the remaining storage battery SOC (State of charge)), and the power consumption amount, and the communication unit 610. Get through and collect. In addition, the information collection unit 620 collects temperature information of the environment where the storage batteries included in the power storage devices (the power storage device 220 or the power storage device 320) of the power generation facility 20 and the cluster 30 are installed. This temperature information is the temperature of the storage battery or the ambient temperature (neighboring temperature) of the storage battery. For example, the temperature information is the temperature information based on the temperature detected by the temperature sensor provided in the storage battery or the temperature detected by the temperature sensor provided in the vicinity of the storage battery in each of the power generation equipment 20 and the cluster 30. is there. In addition, the information collection unit 620 supplies various information acquired from each of the power generation facility 20 and the cluster 30 to the temperature environment determination unit 630, the storage unit 640, or the power storage control unit 650.

  The temperature environment determination unit 630 determines whether or not each storage battery of the power generation facility 20 and the cluster 30 is in a chargeable temperature environment. For example, a temperature range in which charging of the storage battery is permitted is set, and a determination reference value for determining whether or not the battery is in a chargeable temperature environment is determined based on this temperature range. The temperature environment determination unit 630 determines whether each storage battery is based on the temperature information of the power generation facility 20 and the cluster 30 acquired by the information collection unit 620 and the determination reference value determined based on the temperature range in which the storage battery can be charged. It is determined whether or not the battery is in a temperature environment where charging is possible. Then, the temperature environment determination unit 630 supplies determination result information indicating the determination result to the storage unit 640 and the power storage control unit 650.

  The storage unit 640 stores information on each facility connected to the power distribution system 50, various information collected by the information collection unit 620 from each facility, information generated based on the information collected by the information collection unit 620, and the like. . For example, the storage unit 640 includes an equipment position information storage unit 641, a power state information storage unit 642, and a temperature environment information storage unit 643.

  The facility location information storage unit 641 stores facility location information indicating the location where each of the power generation facility 20 and the cluster 30 is installed. For example, the equipment location information includes information in which equipment information for identifying equipment and the equipment location information are associated with each other. The facility position information includes, for example, information indicating latitude, longitude, and altitude. The power storage control unit 650 calculates, for example, the distance between the facilities by referring to the facility position information.

  The power state information storage unit 642 stores the power state information such as the power generation state of each power generation device of the power generation facility 20 and the cluster 30, the storage state of the storage battery, and the power consumption acquired by the information collection unit 620. For example, the power state information includes information in which facility information for identifying the facility and information indicating the power generation state of the power generation device of the facility, the storage state of the storage battery, the power consumption, and the like are associated with each other. The power storage control unit 650 acquires the generated power amount, surplus power amount, remaining battery capacity SOC, and the like of the power generation device of each facility by referring to the power state information.

  The temperature environment information storage unit 643 stores temperature environment information indicating whether or not the storage batteries of the power generation facility 20 and the cluster 30 are in a chargeable temperature environment. This temperature environment information is stored or updated based on determination result information indicating a result determined by the temperature environment determination unit 630.

  FIG. 3 is a diagram illustrating an example of temperature environment information stored in the temperature environment information storage unit 643. The temperature environment information includes facility information (equipment) for identifying the facility and information indicating whether the storage battery can be charged as information (temperature environment) indicating the temperature environment in which the storage battery of the facility is installed (here) Then, “charge permission” or “charge prohibition”) is associated with the information. In the example of FIG. 3, it is shown that the storage batteries of the power generation equipment 20-1, the power generation equipment 20-2, the cluster 30-1, and the cluster 30-2 are not in a chargeable temperature environment (charging prohibited). This indicates that the storage batteries of the cluster 30-3 are in a temperature environment where charging is possible (charging permission).

  In addition, in this figure, although the example which exists in the temperature environment which can charge only the storage battery of the cluster 30-3 installed indoor (charging permission) is shown, the temperature which can be charged also in other facilities in the outdoors When it is in the environment, information indicating charging permission is associated.

  The power storage control unit 650 controls the operations of the power generation facility 20 and the cluster 30 by transmitting a control signal to the power generation facility 20 and the cluster 30 via the communication unit 610. For example, the power storage control unit 650 generates power from the power generation device 20 or the power generation device of the cluster 30 with respect to a storage battery in a temperature environment that can be charged, among storage batteries included in each facility installed in different places. Control is performed to store the generated power. Here, the different places where the storage batteries of the respective facilities are installed include indoor places. For example, in the example of the electric power system 1 shown in FIG. 1, the storage battery of the cluster 30-3 is a storage battery installed indoors. That is, the storage battery of the cluster 30-3 is a storage battery in a temperature environment where charging is possible even when the outside air is in a low temperature state.

  Specifically, the power storage control unit 650 acquires information indicating whether or not each storage battery is in a temperature environment that can be charged based on the determination result of the temperature environment determination unit 630. Then, for example, when the storage battery in the place where the power generation device 210 of the power generation facility 20-1 is installed is not in a temperature environment where charging is possible, the power storage control unit 650 is in a temperature environment where other facilities can be charged. For example, the electric power generated by the power generation device 210 of the power generation facility 20-1 is stored in (for example, the storage battery of the cluster 30-3 indoors). As described above, the power storage control unit 650 selects a storage battery to be stored based on the temperature information of each of the plurality of storage batteries installed in each facility.

  The power storage control unit 650 may acquire the result determined by the temperature environment determination unit 630 from the temperature environment determination unit 630, or the temperature environment information storage in which the result determined by the temperature environment determination unit 630 is stored. The temperature environment determination unit 630 may obtain the result determined by referring to the temperature environment information of the unit 643.

  Next, with reference to FIG. 4, the operation of the power storage control process in the power system 1 according to the present embodiment will be described. FIG. 4 is a flowchart illustrating an example of the power storage control process according to the present embodiment. Here, when surplus power is generated in the power generated by the power generation facility 20-1, the storage battery of the power generation facility 20-1 is in a low temperature state and is not in a temperature environment that can be charged. An example of a power storage control process for storing surplus power in a storage battery in a temperature environment will be described.

  First, the information collection unit 620 collects the power generation state of each power generation device of the power generation facility 20 and the cluster 30, the storage state of the storage battery, the power consumption, and the temperature information of the environment where the storage battery is installed (step S10). .

  Next, the power storage control unit 650 adds surplus power to the power generated by the power generation device based on the power generation state, power storage state, and power consumption of the power generation facility 20 and the cluster 30 collected by the information collection unit 620. It is determined whether or not there is a facility that has occurred (step S20). In step S20, when it is determined that there is no facility in which surplus power is generated (step S20: No), the power storage control unit 650 ends the process without performing power storage control.

  On the other hand, when it is determined in step S20 that there is a facility in which surplus power is generated (step S20: Yes), the temperature environment determination unit 630 is a temperature environment in which each storage battery of the power generation facility 20 and the cluster 30 can be charged. Is determined based on the temperature information of the storage battery of the power generation facility 20-1 acquired by the information collecting unit 620 and the temperature range in which charging of the storage battery is permitted. Then, based on the determination result determined by the temperature environment determination unit 630, the power storage control unit 650 is in a temperature environment where the storage battery of the facility (in this case, the power generation facility 20-1) generating surplus power can be charged. It is determined whether or not (step S30).

  When it is determined in step S30 that the storage battery of the power generation facility 20-1 is not in a chargeable temperature environment (step S30: No), the power storage control unit 650 performs charging based on the determination result of the temperature environment determination unit 630. A storage battery in a possible temperature environment is selected as a storage battery that stores electric power (surplus power) generated by the power generation facility 20-1. Here, it is determined by the temperature environment determination unit 630 that the storage battery of the cluster 30-3 in the room is in a temperature environment that can be charged, and the power storage control unit 650 converts the storage battery of the cluster 30-3 into the power generation facility 20. -1 is selected as a storage battery for storing the power (surplus power) generated (step S40).

  Next, the power storage control unit 650 stores the power generation facility 20 and the power storage device 20 so that the power (surplus power) generated by the power generation device 210 of the power generation facility 20-1 is stored in the storage battery of the selected cluster 30-3. A control signal is transmitted to each of the clusters 30 (step S50). That is, the power storage control unit 650 stores the power generated by the power generation facility 20-1 in the storage battery of the cluster 30-3 (for example, an indoor storage battery) in a chargeable temperature environment.

  On the other hand, when it determines with the storage battery of the power generation equipment 20-1 being in the temperature environment which can be charged in step S30 (step S30: Yes), with respect to the storage battery of the power generation equipment 20-1, of the power generation equipment 20-1. The electric power generated by the power generation device 210 is stored (step S60).

  Thus, in the power system 1 according to the present embodiment, the power storage control device 60 is not in a temperature environment in which the storage battery of the power generation facility 20-1 can be charged based on the temperature of the environment where the storage battery of each facility is installed. In this case, control is performed so that the electric power generated by the power generation device 210 of the power generation facility 20-1 is stored in the storage battery of the cluster 30-3 in a chargeable temperature environment via the distribution system 50. Therefore, according to this embodiment, even if the storage battery of the power generation facility 20-1 cannot be charged in a low temperature state, the power generated by the power generation facility 20-1 can be stored in the rechargeable storage battery of other facilities. Therefore, the generated power (surplus power) can be used effectively.

  In the above-described example, the case where the storage battery in the rechargeable temperature environment is the storage battery of the cluster 30-3 has been described as an example, but there may be a plurality of rechargeable storage batteries in the rechargeable temperature environment. When there are a plurality of storage batteries in a temperature environment where charging is possible, the power storage control device 60 may arbitrarily select any one of the plurality of storage batteries to store the power, or any one of the plurality of storage batteries. It may be selected and stored.

  In addition, when there are a plurality of storage batteries in a rechargeable temperature environment, the power storage control device 60 selects a storage battery to be stored based on the storage state (for example, the remaining storage battery SOC) of each of the plurality of rechargeable storage batteries. You may choose. Specifically, the power storage control device 60 refers to the power state information stored in the power state information storage unit 642 in the process of step S40 of FIG. Among them, a storage battery having a small value of the remaining battery capacity SOC may be preferentially selected as a storage battery that stores electric power (surplus power) generated by the power generation facility 20-1.

  Thereby, in the electric power system 1, when the storage battery of the power generation equipment 20-1 cannot be charged in a low temperature state, priority is given to the storage battery with a small value of the storage battery remaining capacity SOC among a plurality of rechargeable storage batteries of other facilities. Since the power (surplus power) generated by the power generation facility 20-1 can be stored, the generated power can be used effectively.

  In addition, when there are a plurality of rechargeable storage batteries in the temperature environment that can be charged, the power storage control device 60 is a distance from each power generation source (where the power generation facility 20-1 is installed) of the plurality of rechargeable storage batteries. Based on the above, a storage battery to be charged may be selected. Specifically, the power storage control device 60 refers to the facility position information stored in the facility position information storage unit 641 in the process of step S40 in FIG. A storage battery located in a short distance may be preferentially selected as a storage battery that stores electric power (surplus power) generated by the power generation facility 20-1.

  Thereby, in the electric power system 1, when the storage battery of the power generation facility 20-1 cannot be charged in a low temperature state, the power generation facility 20- is given priority over the storage battery having a short distance among the plurality of rechargeable storage batteries of other facilities. Since the power generated by 1 (surplus power) can be stored, charging loss can be suppressed and the generated power can be used effectively.

  In addition, when there are a plurality of storage batteries in a rechargeable temperature environment, the power storage control device 60 stores power based on both the storage state of each of the plurality of rechargeable storage batteries and the distance to the power generation source. You may select the storage battery to be made. For example, the power storage control device 60 may be selected as a storage battery that stores a storage battery having the shortest distance from the power generation source among storage batteries having a storage battery remaining capacity SOC smaller than a predetermined value.

  Note that the power storage control process shown in FIG. 4 may be a process excluding the processes in steps S30 and S60. That is, it connects to the power distribution system 50 containing the said storage battery, without performing the process which determines whether the storage battery of the installation (here power generation equipment 20-1) in which surplus electric power is in the temperature environment which can be charged. A storage battery that is in a temperature environment that can be charged may be selected as a storage battery that stores excess power. For example, when the storage battery of the facility in which surplus power is generated is not in a temperature environment where charging is possible, the storage battery in another rechargeable temperature environment is selected instead of the storage battery of the facility in which surplus power is generated . In addition, when the storage battery of the facility where the surplus power is generated is in a temperature environment where charging is possible, for example, if priority is given to the distance from the power generation source (the facility where surplus power is generated), the facility where the surplus power is generated Storage battery is selected.

  In the above-described example, the temperature environment determination unit 630 determines whether or not the storage battery is in a temperature environment that can be charged based on the temperature information of the storage battery acquired by the information collection unit 620. Instead of the information, whether or not the storage battery is in a chargeable temperature environment may be determined based on temperature information (temperature information) included in weather information in the vicinity of the place where the storage battery is installed. . In addition to the temperature information (temperature information) included in the weather information in the vicinity of the place where the storage battery is installed, the temperature environment determination unit 630 includes the time (season) and time, the environment where the storage battery is installed, and the like. May be determined in consideration of

  In the above-described example, the example in which the electric power generated by the power generation facility 20-1 (power generation source) is stored in the storage battery (power storage destination) of the cluster 30-3 has been described. However, the equipment is not limited to this. For example, different clusters 30 or different power generation facilities may have a relationship between a power generation source facility and a storage destination facility. In addition, when the storage battery of the power generation facility 20 is in a temperature environment where charging is possible and the storage battery of the cluster 30 is not in a temperature environment where charging is possible, the power generated by the cluster 30 is stored in the storage battery of the power generation facility 20. Also good.

<Second Embodiment>
Next, a second embodiment of the present invention will be described.
In the first embodiment described above, an example has been described in which it is determined whether or not the storage battery is in a chargeable temperature environment based on the temperature information of the storage battery, and the storage battery in the chargeable temperature environment is charged. In the present embodiment, an example will be described in which a storage battery installed indoors is stored as a storage battery in a temperature environment that can be charged based on whether or not the storage battery is installed indoors.

  The basic configuration of the power system 1 according to the present embodiment is the same as the configuration shown in FIG. Here, the configuration of the power storage control device 60A according to the present embodiment will be described with reference to FIG. FIG. 5 is a configuration diagram illustrating an example of a schematic configuration of the power storage control device 60A according to the present embodiment. In FIG. 5, the components corresponding to those in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted.

  The power storage control device 60A includes a communication unit 610, an information collection unit 620, a storage unit 640A, and a power storage control unit 650A. The storage unit 640A includes an equipment position information storage unit 641, a power state information storage unit 642, and an installation location information storage unit 644A. The storage location information storage unit 644A is replaced with the temperature environment information storage unit 643. The point provided is different from the storage unit 640 shown in FIG.

The installation location information storage unit 644A stores installation location information regarding locations where the storage batteries of the power generation equipment 20 and the cluster 30 are installed. The installation location information is stored or updated in the installation location information storage unit 644A based on an instruction from a system administrator or the like when the equipment is provided or when the equipment is changed.
FIG. 6 is a diagram illustrating an example of installation location information stored in the installation location information storage unit 644A. The installation location information is associated with facility information (equipment) for identifying the facility and information (installation location) indicating whether the installation location where the storage battery of the facility is installed is outdoor or indoor Contains information. In the example of FIG. 6, the storage battery of the power generation facility 20-1, the power generation facility 20-2, the cluster 30-1, and the cluster 30-2 are installed outdoors, and the storage battery of the cluster 30-3 is installed indoors. It shows that.

  In addition, as mentioned above, indoors here are indoors of facilities that maintain a temperature environment that can be charged without being in a low temperature state even when the outside air temperature is low, for example, in a store such as a convenience store Or in the server room.

  The power storage control unit 650A selects, from among the plurality of storage batteries, an indoor storage battery as a storage battery in a temperature environment that can be charged, and the power generation equipment 20 or the cluster 30 generates power for the selected storage battery. Control is performed to store the generated power. That is, the present embodiment is different from the first embodiment in that the storage battery is selected not to use the temperature information of the storage battery but on the condition that the storage battery is indoors.

  For example, the power storage control unit 650A refers to the installation location information stored in the installation location information storage unit 644A, and when the storage battery of the power generation facility 20-1 is not in a chargeable temperature environment, it is indoors (inside the store). The power generated by the power generation facility 20-1 is stored in a storage battery of a certain cluster 30-3.

  Next, the operation of the power storage control process according to the present embodiment will be described. The power storage control process according to the present embodiment is the same as the process described in the first embodiment except for the specific processes performed in step S30 and step S40 in the example of the power storage control process shown in FIG. For this reason, only the processing of step S30 and step S40 will be described here.

  In step S30, the power storage control unit 650 determines whether or not the storage battery of the facility (in this case, the power generation facility 20-1) in which surplus power is generated is in a chargeable temperature environment. Specifically, in the present embodiment, the power storage control unit 650 includes information indicating the annual temperature change and the daily temperature change in the area where the power generation facility 20-1 is installed, and the current time (season). Whether or not the storage battery of the power generation facility 20-1 is in a chargeable temperature environment is estimated based on the time, current weather information, the environment (indoor or outdoor) where the storage battery is installed, and the like. And based on an estimation result, the electrical storage control part 650 determines whether the storage battery of the power generation equipment 20-1 exists in the temperature environment which can be charged. For example, in the current season of the region where the power generation facility 20-1 is installed, the storage battery installed outdoors may be determined to be a storage battery that is not in a chargeable temperature environment.

  In step S30, when it is determined that the storage battery of the power generation facility 20-1 is not in a chargeable temperature environment (step S30: No), the power storage control unit 650 converts the storage battery in the chargeable temperature environment into the power generation facility 20. -1 is selected as a storage battery for storing the electric power (surplus power) generated by -1. Specifically, in the present embodiment, the power storage control unit 650 refers to the installation location information stored in the installation location information storage unit 644A, and stores the storage battery of the cluster 30-3 that is indoors (in the store), It selects as a storage battery which stores the electric power (surplus electric power) generated by the power generation equipment 20-1 (step S40).

  Thus, in this embodiment, when the storage battery of the power generation facility 20-1 is not in a temperature environment that can be charged, the power storage control device 60 uses the power generated by the power generation device 210 of the power generation facility 20-1, Control is performed so that the storage battery of the cluster 30-3 in the room is charged via the power distribution system 50. Therefore, according to this embodiment, even if the storage battery of the power generation facility 20-1 cannot be charged in a low temperature state, the power generated by the power generation facility 20-1 can be stored in the rechargeable storage battery of other facilities. Therefore, the generated power (surplus power) can be used effectively.

  In the present embodiment, as described in the first embodiment, when there are a plurality of storage batteries in a rechargeable temperature environment, the power storage control device 60 determines the power storage state of each of the plurality of rechargeable storage batteries. A storage battery to be charged may be selected based on one or both of (for example, the remaining battery capacity SOC) and the distance from each power generation source of a plurality of rechargeable storage batteries. In the present embodiment, as described in the first embodiment, the power storage control process illustrated in FIG. 4 may be a process that excludes the processes in steps S30 and S60.

<Third Embodiment>
Next, a third embodiment of the present invention will be described.
In the second embodiment described above, an example in which a storage battery installed indoors is stored as a storage battery in a temperature environment that can be charged based on whether the storage battery is installed indoors has been described.
By the way, stores such as convenience stores include stores that are open 24 hours, and stores that are open only for a predetermined time of the day. Here, as a store that is open only for a predetermined time of the day, there is a store such as a large commercial facility represented by a supermarket or a shopping mall. It is conceivable that the installation will continue in the future.

In this way, even if it is indoors, there are stores that are open only for a predetermined time unlike stores that are open 24 hours a day. There is also.
Therefore, in the present embodiment, an example will be described in which a storage battery in a temperature environment that can be charged is selected in consideration of time conditions in addition to a storage battery installed indoors.

  The basic configuration of the power system 1 according to the present embodiment is the same as the configuration shown in FIG. Here, the configuration of the power storage control device 60B according to the present embodiment will be described with reference to FIG. FIG. 7 is a configuration diagram illustrating an example of a schematic configuration of the power storage control device 60B according to the present embodiment. In FIG. 7, the components corresponding to those in FIG. 5 are denoted by the same reference numerals, and the description thereof is omitted.

The power storage control device 60B includes a communication unit 610, an information collection unit 620, a storage unit 640B, a power storage control unit 650B, and a timer unit 660.
The storage unit 640B includes an equipment location information storage unit 641, a power state information storage unit 642, and an installation location information storage unit 644B. The content of the installation location information stored in the installation location information storage unit 644B is The contents of the installation location information stored in the installation location information storage unit 644A shown in FIG.

  FIG. 8 is a diagram illustrating an example of installation location information stored in the installation location information storage unit 644B. In the installation location information shown in this figure, as in the example shown in FIG. 6, the equipment information (equipment) for identifying the equipment and the installation location where the storage battery of the equipment is installed are outdoors or indoors. Information associated with information (installation location) is included. In addition, the installation location information shown in this figure further includes information indicating the type of installation location (location type) and information indicating business hours (business hours) when the installation location is a store in the facility information. Associated. 8 is an example in which a cluster 30-4 (not shown in FIG. 1) is connected to the power distribution system 50 in addition to the cluster 30-3 as equipment installed indoors. Here, in the cluster 30-3, the “location type” is “store” and the “business hours” is “24 hours”. In the cluster 30-4, the “location type” is “store”, and the “business hours” is “10:00 to 23:00”.

  The timer unit 660 includes an oscillation circuit that oscillates the fundamental frequency signal, and a frequency divider circuit that divides the fundamental frequency signal output from the oscillation circuit into a signal having a predetermined frequency, and has a predetermined frequency for timing. A time signal is generated, and time is measured based on the generated time signal. Note that the timekeeping unit 660 may perform timekeeping based on time information acquired from a server device that provides external time information.

  The power storage control unit 650B refers to the installation location information stored in the installation location information storage unit 644B, and is in a temperature environment in which the storage battery in the operating store can be charged based on the business hours of the store. Select as storage battery. For example, in the example illustrated in FIG. 8, the power storage control unit 650 </ b> B performs control to store power in the storage battery of the cluster 30-3 from 23:00 to 10:00 the next time. On the other hand, from 10:00 to 23:00, the power storage control unit 650B performs control so that the storage battery of the cluster 30-3 or the storage battery of the cluster 30-4 is charged. For example, the power storage control unit 650B performs control so that the storage battery of the cluster 30-3 is preferentially stored between 23:00 and 10:00, and the storage battery of the cluster 30-4 is between 10:00 and 23:00. Control is performed so that power is stored with priority.

  Note that the power storage control device 60 can be charged as described in the first embodiment in the time zone when both the storage battery of the cluster 30-3 and the storage battery of the cluster 30-4 are in operation. Select a storage battery to be stored based on one or both of a storage state of each of the plurality of storage batteries (for example, storage battery remaining capacity SOC) and a distance from each power generation source of the plurality of rechargeable storage batteries. May be.

  Thus, in this embodiment, when the storage battery of the power generation facility 20-1 is not in a temperature environment that can be charged, the power storage control device 60 uses the power generated by the power generation device 210 of the power generation facility 20-1, Control is performed so that the storage battery of the cluster 30-3 in the store in business is charged via the power distribution system 50. Therefore, according to this embodiment, even if the storage battery of the power generation facility 20-1 cannot be charged in a low temperature state, the power generated by the power generation facility 20-1 can be stored in the rechargeable storage battery of other facilities. Therefore, the generated power (surplus power) can be used effectively.

<Fourth Embodiment>
Next, a fourth embodiment of the present invention will be described.
In the power system 1 according to the first to third embodiments, the configuration in which the power storage control process is performed via the power distribution system 50 between the facilities connected to the single power distribution system 50 has been described. In the present embodiment, a configuration in which the power storage control process is performed via a plurality of power distribution systems will be described.

Hereinafter, the configuration of the power system 1A according to the present embodiment will be described with reference to FIG.
FIG. 9 is a configuration diagram illustrating an example of a schematic configuration of the power system 1A according to the present embodiment. In FIG. 9, components corresponding to those in FIG. 1 are assigned the same reference numerals and explanations thereof are omitted.

  In the power system 1 </ b> A shown in this figure, in addition to the power distribution system 50, a power distribution system 51 different from the power distribution system 50 is connected to the power transmission system 40. The power transmission system 40 transmits the power generated by the power plant 10 to the power distribution system 50 and the power distribution system 51 via a power transmission line. Similar to the power distribution system 50, a plurality of facilities are connected to the power distribution system 51. For example, the power generation facility 21 and the cluster 31 (cluster 31-1, cluster 31-2) are connected to the power distribution system 51. The power distribution system 51 distributes the power transmitted from the power plant 10 via the power transmission system 40 to the power generation facility 21 and the cluster 31 via the power distribution line.

  Since the power generation equipment 21 and the cluster 31 have the same basic configuration as that of the power generation equipment 20 connected to the power distribution system 51 and the cluster 30, the description thereof is omitted. The power storage control device 61 has the same basic configuration as that of the power storage control device 60 and performs power storage control processing between the facilities connected to the power distribution system 51.

  For example, the power storage control device 61 collects information from each of the power generation equipment 21 and the cluster 31 connected via the power distribution system 51. In addition, the power storage control device 61 transmits a control signal for controlling the operation of the power generation equipment 21 and the cluster 31 to the power generation equipment 21 and the cluster 31 based on the collected information. For example, the power storage control device 61 controls which storage battery connected via the power distribution system 51 stores the power generated by the power generation facility 21. As the configuration of the power storage control device 61, any of the power storage control devices 60, 60A, and 60B in the first to third embodiments can be applied.

  In the power system 1 </ b> A according to the present embodiment, the power storage control device 60 that controls each facility connected to the power distribution system 50 and the power storage control device 61 that controls each facility connected to the power distribution system 51 are provided. Control may be performed in an interconnected manner by communicating with each other. For example, when the power storage control device 60 and the power storage control device 61 are connected and controlled, the power generated by the power generation facility 21 is transferred to the cluster 30 via the power distribution system 51, the power transmission system 40, and the power distribution system 50. The battery may be controlled so as to be stored in the -3 storage battery. In addition, the power storage control device 60 and the power storage control device 61 are connected to each other to control the power generated by the power generation facility 20 through the power distribution system 50, the power transmission system 40, and the power distribution system 51. You may control so that it may store in this storage battery. These power generation equipment and power storage equipment can be arbitrarily selected.

  As described above, in the power system 1A according to the present embodiment, the power storage control device 60 and the power storage control device 61 are connected and controlled, so that surplus power is transmitted between facilities connected to different power distribution systems. The power storage control process for storing the power is performed. Thereby, according to this embodiment, when surplus electric power arises, the storage battery which can be charged can be looked for in a wide area, and the possibility of surplus electric power loss being reduced can be reduced. For example, it is possible to store the electric power generated by the facility in the cold region by sending it to the storage battery of the facility in the warm region. Therefore, the generated electric power can be used effectively.

  As mentioned above, although embodiment of this invention was described, in the said embodiment, each part with which the electrical storage control apparatus 60 (60A, 60B, 61) is provided may be implement | achieved by dedicated hardware, It may be configured by a memory and a CPU (central processing unit), and the function may be realized by loading a program for realizing the function of each unit described above into the memory and executing it.

  For example, in the above embodiment, the power storage control device 60 (60A, 60B, 61) has a computer system therein. Then, a program for realizing the functions of the above-described units is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed, thereby executing the processing of each unit described above. You may go. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  Here, the correspondence between the present invention and the above-described embodiment will be supplementarily described. The power system in the present invention corresponds to the power system 1 shown in FIG. 1 or the power system 1A shown in FIG. The power storage control device according to the present invention includes a power storage control device 60 shown in FIGS. 1 and 2, a power storage control device 60A shown in FIG. 5, a power storage control device 60B shown in FIG. 5, or a power storage control device 60 shown in FIG. 61 corresponds. The power generation unit in the present invention corresponds to the power generation device 210 or the power generation device 310 shown in FIG. In addition, the storage battery in the present invention corresponds to the storage battery included in the power storage device 220 or the power storage device 320 illustrated in FIG. Moreover, the determination part in this invention respond | corresponds to the temperature environment determination part 630 shown in FIG. Moreover, the distribution line in this invention respond | corresponds to the distribution line with which the power distribution system 50 or the power distribution system 51 shown in FIG. 1 or FIG. 9 was equipped.

[1] In the above embodiment, the power system 1 (1A) includes a power generation unit (for example, the power generation device 210 or the power generation device 310) that generates power based on natural energy. In addition, the power system 1 (1A) has a plurality of storage batteries (for example, storage batteries included in the power storage device 220 or the power storage device 320) installed in different places, with respect to a storage battery in a rechargeable temperature environment. A power storage control unit (for example, power storage control units 650, 650A, 650B) that stores the power generated by the power generation unit is provided.

  As described above, the power system 1 (1A) stores the electric power generated based on the natural energy in a storage battery in a temperature environment where charging is possible among the plurality of storage batteries. Thereby, the electric power system 1 (1A) can store the electric power generated based on the natural energy even in a low temperature state (for example, a state where the storage battery cannot be charged in a cold region or the like). Therefore, the power system 1 (1A) can effectively use the generated power (surplus power).

[2] In the above-described embodiment, different locations include, for example, indoor locations. And the electrical storage control part (for example, electrical storage control part 650A, 650B) is good also considering the storage battery in an indoor as the storage battery in the temperature environment which can be charged.

  Thereby, the power system 1 (1A) can store the generated power in, for example, a storage battery (for example, a storage battery included in the power storage device 320 of the cluster 30-3) in an indoor chargeable environment.

[3] In the above-described embodiment, different places include a place where the power generation unit (for example, the power generation device 210 of the power generation facility 20-1) is installed and an indoor place. The power storage control unit 650 (for example, the power storage control units 650A and 650B) is a temperature at which a storage battery (for example, a storage battery included in the power storage device 220 of the power generation facility 20-1) at a place where the power generation unit is installed can be charged. When not in the environment, electric power generated by the power generation unit may be stored in an indoor storage battery (for example, a storage battery included in the power storage device 320 of the cluster 30-3).

  Thereby, even if the electric power system 1 (1A) is a case where the storage battery of the power generation equipment 20-1 cannot be charged in a low temperature state, for example, the electric power generated by the power generation equipment 20-1 is put indoors in other equipment. Since it can be stored in a certain storage battery, the generated power (surplus power) can be used effectively.

[4] In the above embodiment, the indoor location includes, for example, a location in a store. Here, the location in the store is maintained in a temperature environment that can be charged without being in a low temperature state even when the outside air temperature is low due to the heat of the heating equipment in the store. For example, a 24-hour convenience store can be used as a store.

  Thereby, the electric power system 1 (1A) can store the electric power generated by the power generation facility without requiring a dedicated heating facility for increasing the temperature of the storage battery. Therefore, the power system 1 (1A) can increase the utilization efficiency of the generated power.

  The indoor place is not limited to the place in the store, and may be in a server room, for example. Indoor locations include, for example, indoors in facilities where heat from sources other than the heat source intended to warm the storage battery maintains a temperature environment that can be charged without being cold even when the outside temperature is low. It is desirable to be.

[5] In the above embodiment, the power storage control unit (for example, the power storage control unit 650B) uses the storage battery in the operating store as a storage battery in a temperature environment where charging is possible based on the business hours of the store. Also good.
As a result, the power system 1 (1A) is not only in a storage battery installed in a 24-hour store, but also in a low-temperature state in a storage battery installed in a store that operates only for a predetermined time of the day. It can be used as a storage battery for storing electric power (surplus power) generated in the facility.

[6] In the above embodiment, the power storage control unit (for example, the power storage control unit 650, 650A, 650B), when there are a plurality of storage batteries in a rechargeable temperature environment, each of the plurality of rechargeable storage batteries A storage battery that stores the electric power generated by the power generation unit may be selected based on the storage state.

  Thereby, electric power system 1 (1A) gives priority to a storage battery with a small value of storage battery remaining capacity SOC among a plurality of rechargeable storage batteries, and stores electric power (surplus power) generated by power generation equipment 20-1. Therefore, the generated electric power can be used effectively.

[7] Further, in the above embodiment, the power storage control unit (for example, the power storage control unit 650, 650A, 650B) is connected from the place where the power generation unit is installed when there are a plurality of rechargeable storage batteries in a temperature environment that can be charged. You may give priority to the storage battery in the place where distance is near as a storage battery which stores the electric power generated by the power generation part.

  Thereby, since the electric power system 1 (1A) can store the electric power (surplus electric power) generated by the power generation facility 20-1 in preference to the storage battery having a short distance among the plurality of storage batteries, the charging loss is suppressed. Thus, the generated power can be used effectively.

[8] In the above embodiment, the power system 1 (1A) includes a determination unit (for example, the temperature environment determination unit 630) that determines whether or not each of the plurality of storage batteries is in a chargeable temperature environment. You may prepare. Then, the power storage control unit (for example, the power storage control unit 650) may store the power generated by the power generation unit in the storage battery determined to be in a temperature environment that can be charged by the temperature environment determination unit 630. .

  Thereby, electric power system 1 (1A) can store the generated electric power (surplus electric power) with respect to the storage battery in the temperature environment which can be charged based on each temperature of a plurality of storage batteries.

[9] In the above-described embodiment, different places include a place where a power generation unit (for example, the power generation device 210 of the power generation facility 20-1) is installed and an indoor place. Then, the power storage control unit 650 (for example, the power storage control unit 650) causes the determination unit (for example, the temperature environment determination unit 630) to store the storage battery (for example, the power storage of the power generation facility 20-1) at the place where the power generation unit is installed. It is determined that the storage battery included in the device 220 is not in a rechargeable temperature environment, and the storage battery (for example, the storage battery included in the power storage device 320 of the cluster 30-3) is in a rechargeable temperature environment. In this case, the power generated by the power generation unit is stored in the storage battery in the room.

  Thereby, even if the electric power system 1 (1A) is a case where the storage battery of the power generation equipment 20-1 cannot be charged in a low temperature state, for example, the power generated by the power generation equipment 20-1 can be charged to other equipment. Therefore, the generated power (surplus power) can be used effectively.

[10] In the above embodiment, each of the plurality of storage batteries is connected to the power generation unit via at least a distribution line (for example, a distribution line provided in the distribution system 50). Then, the power storage control unit (for example, power storage control units 650, 650A, 650B) stores the power generated by the power generation unit in any of the plurality of storage batteries via the power distribution system 50.

Thereby, the power system 1 (1A) can store the generated power (surplus power) in a rechargeable storage battery of another facility connected to the power distribution system 50.
In addition, the electric power system 1 (1A) uses the generated electric power (surplus power) as a rechargeable storage battery of other equipment connected to the power distribution system 51 connected to the power distribution system 50 via the power transmission system 40. It may be charged.

[11] In the above embodiment, the power system 1 is a power storage control device (for example, the power storage control device 60, 60A, 60B, or 61, hereinafter collectively referred to as the power storage control device 60 unless otherwise specified). I have. The power storage control device 60 includes, for example, a power storage control unit (for example, power storage control units 650, 650A, and 650B). As described above, the power storage control unit is generated by a power generation unit that generates power based on natural energy for a storage battery in a rechargeable temperature environment among a plurality of storage batteries installed at different locations. Electric power is stored.

  Thereby, in the power system 1 (1A), the power storage control device 60 stores the power generated based on natural energy even in a low temperature state (for example, a state where the storage battery cannot be charged in a cold region). Can be made. Therefore, the power storage control device 60 can effectively use the generated power (surplus power).

  As mentioned above, although embodiment of this invention was described, the electric power system 1 (1A) of this invention is not limited only to the above-mentioned illustration example, In the range which does not deviate from the summary of this invention, it changes variously. Of course, can be added.

  For example, the configurations described in the first to fourth embodiments can be arbitrarily combined. As an example, the configuration for determining whether or not the storage battery is in a temperature environment that can be charged based on the storage battery temperature information described in the first embodiment, and the indoor installation described in the second embodiment. It is good also as a structure which combined the structure which determines with the storage battery in the temperature environment which can charge the storage battery currently charged.

  Specifically, in the process of determining whether or not the storage battery of the facility (for example, the power generation facility 20-1) in which surplus power is generated is in a chargeable temperature environment, the storage battery is charged based on the storage battery temperature information. In the process of determining whether or not it is in a possible temperature environment and selecting a storage battery that stores surplus power, a storage battery installed indoors may be selected as a storage battery in a temperature environment that can be charged. On the contrary, in the process of determining whether or not the storage battery of the facility (for example, the power generation facility 20-1) in which the surplus power is generated is in a temperature environment that can be charged, the storage battery installed indoors In the process of determining whether or not the storage battery is in a temperature environment that can be charged based on whether or not there is, and selecting a storage battery that stores excess power, the storage battery that is in a temperature environment that can be charged based on the temperature information of the storage battery May be selected.

  In the temperature environment information shown in FIG. 3, information indicating whether charging is possible (for example, “charge permission” or “charge prohibition”) is stored based on the determination result of the temperature environment determination unit 630. However, the present invention is not limited to this. For example, information indicating a temperature state (for example, “non-low temperature state” or “low temperature state”) or information indicating a temperature (for example, “20 "Degree", "-10 degrees", etc.) may be stored. In this case, the power storage control unit 650 may determine whether or not each storage battery can be charged based on information indicating the temperature state or information indicating the temperature.

  Moreover, in the installation location information shown in FIG.6 and FIG.8, the example which stored the information which shows whether the installation location where the storage battery is installed is the outdoors or an indoor was shown as the information which shows an installation location was shown. However, the present invention is not limited to this, and for example, information indicating whether or not it is a place of a temperature environment where charging is possible, or information indicating whether or not a place where charging is possible may be stored.

  In addition, in the above description, although the storage battery which the electrical storage apparatus 220 and the electrical storage apparatus 320 have illustrated and demonstrated the lithium ion battery, another kind of storage battery may be sufficient. Note that the chargeable temperature range varies depending on the types and specifications of the storage batteries in the power storage device 220 and the power storage device 320. Therefore, the determination reference value for determining whether or not the battery is in a temperature environment where charging is possible is determined based on a temperature range that permits charging according to the type and specification of the storage battery.

  Moreover, in the above description, the inside of a convenience store, the store of a commercial facility, or the inside of a server room was illustrated and demonstrated as an indoor example, However, It is not restricted to these. For example, indoors may be in a hot bath facility, in a plant factory, in a public facility, in a play facility, or the like as long as the temperature environment where charging is possible is always or for a predetermined time.

1, 1A ... power system, 10 ... power plant, 20, 21 ... power generation equipment,
30, 31 ... cluster, 40 ... power transmission system, 50, 51 ... distribution system,
60, 61 ... power storage control device, 610 ... communication unit, 620 ... information collection unit,
630 ... temperature environment determination unit (determination unit), 640, 640A, 640B ... storage unit,
641... Equipment position information storage unit, 642... Power state information storage unit,
643 ... Temperature environment information storage unit, 644A, 644B ... Installation location information storage unit,
650, 650A, 650B ... power storage control unit,
660 ... Timekeeping section

Claims (13)

A power generation unit that generates power based on natural energy;
Among a plurality of storage batteries installed in different places, a storage control unit that stores power generated by the power generation unit for a storage battery in a temperature environment that can be charged, and
An electric power system comprising: The different places include indoor places,
The power storage control unit
The power system according to claim 1, wherein the indoor storage battery is a storage battery in the chargeable temperature environment. The different places include the place where the power generation unit is installed and the indoor place,
The power storage control unit
The electric power generated by the power generation unit is stored in the indoor storage battery when the storage battery in the place where the power generation unit is installed is not in a temperature environment where charging is possible. Power system as described in. The electric power system according to claim 2 or 3, wherein the indoor location includes a location in a store. The power storage control unit
5. The power system according to claim 4, wherein a storage battery in the store in operation is a storage battery in the rechargeable temperature environment based on business hours of the store. The power storage control unit
When there are a plurality of storage batteries in a rechargeable temperature environment, a storage battery that stores the power generated by the power generation unit is selected based on a storage state of each of the plurality of rechargeable storage batteries. Item 6. The power system according to any one of Items 1 to 5. The power storage control unit
When there are multiple storage batteries in a temperature environment that can be charged, priority is given to a storage battery that is close to the place where the power generation unit is installed as a storage battery that stores the power generated by the power generation unit. The power system according to any one of claims 1 to 6, wherein the power system is characterized. A determination unit that determines whether each of the plurality of storage batteries is in a chargeable temperature environment,
With
The power storage control unit
8. The electric power according to claim 1, wherein the electric power generated by the power generation unit is stored in a storage battery that is determined to be in a temperature environment that can be charged by the determination unit. system. The different places include a place where the power generation unit is installed and an indoor place,
The power storage control unit
When the determination unit determines that the storage battery in the place where the power generation unit is installed is not in a temperature environment in which charging is possible and determines that the storage battery in the room is in a temperature environment in which charging is possible, The electric power system according to claim 8, wherein electric power generated by the power generation unit is stored in an indoor storage battery. Each of the plurality of storage batteries is connected to the power generation unit via at least a distribution line,
The power storage control unit
The power system according to any one of claims 1 to 9, wherein the power generated by the power generation unit is stored in any of the plurality of storage batteries via the distribution line. Among a plurality of storage batteries installed in different places, a storage control unit that stores power generated by a power generation unit that generates power based on natural energy for a storage battery in a rechargeable temperature environment,
A power storage control device comprising: A control method for a power system,
Generating electricity based on natural energy;
A step of storing electric power generated based on natural energy with respect to a storage battery in a chargeable temperature environment among a plurality of storage batteries installed in different places;
The control method characterized by including. On the computer,
Detecting power generated by a power generation unit that generates power based on natural energy;
The step of storing the electric power generated by the power generation unit with respect to a storage battery in a temperature environment that can be charged, among a plurality of storage batteries installed in different places,
A program for running

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