JP2018046711A - Storage battery for communication device, storage battery system, storage battery management server, storage battery communication control program, and storage battery management program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication device for storage battery capable of reducing delay time of communication information while preventing increase of load in information processing.SOLUTION: A communication device 5 for storage battery executes: a series of first communication processing to transmit a piece of first communication information from plural types of information to a storage battery management server 2 at every first time T; and a series of second communication processing to transmit a piece of second communication information from plural types of information to the storage battery management server 2 at every second time Tsorter than the first time T. The data amount of the first communication information is larger than the data amount of the second communication information.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a storage battery communication device that relays information communicated between a storage battery system and a storage battery management server.

  Conventionally, a technique has been proposed in which the storage battery management server determines the frequency of collecting information from the storage battery system in accordance with the state of the storage battery system (see Patent Document 1). According to this prior art, for example, the frequency at which the storage battery management server collects information from the storage battery system depending on whether the storage battery is in a charging state, a discharging state, or a standby state. Can be changed.

JP 2014-103717 A

  A conventional storage battery system or a storage battery communication device that relays information communicated between the storage battery system and the storage battery management server is usually sent to the storage battery management server at a predetermined interval, for example, once every 30 minutes. , Send communication information. Since this communication information includes, for example, all information related to the storage battery, the data amount as a whole is considerably large. Further, the storage battery management server transmits the communication information to the storage battery system in response to the reception of the communication information transmitted from the storage battery system. That is, the storage battery management server also transmits communication information to the storage battery system only once every 30 minutes. Since this communication information includes all information related to storage battery management such as 24-hour charging and discharging schedule information of the storage battery system 6 in addition to demand response command information, the data amount as a whole is considerably large. Therefore, both the storage battery system and the storage battery management server require time for processing communication information and a large capacity memory for storing a lot of communication information.

  On the other hand, the storage battery management server transmits demand response command information to the storage battery system or the storage battery communication device according to, for example, the demand amount and supply amount of the grid power. If this demand response command information is transmitted at an interval of, for example, once every 30 minutes as described above, the delay time of demand response is long, and it may not be possible to respond immediately to the demand or supply of system power. . Therefore, there is a desire to make the transmission interval of demand response command information considerably shorter than once every 30 minutes. However, if the communication interval between the storage battery management server and the storage battery communication device is shortened, the amount of communication information that must be processed by both the storage battery management server and the storage battery communication device becomes extremely large. In this case, both the storage battery management server and the storage battery communication device must greatly improve the processing capacity, the memory capacity, and the like.

  As can be seen from the above, there is a desire to reduce the delay time of communication information, for example, the delay time of demand response command information, while suppressing an increase in the processing load of the communication information of the storage battery communication device and the storage battery management server. There is.

  The present invention has been made in view of such problems of the prior art. The objective of this invention is providing the communication apparatus for storage batteries, a storage battery system, and a storage battery management server which can shorten the delay time of communication information, suppressing the increase in the burden of a process of communication information.

  Another object of the present invention is to provide a storage battery communication control program used for the above-described storage battery communication device or storage battery system and a storage battery management program used for the above storage battery management server.

  In order to solve the above-mentioned problem, the storage battery communication device according to the first aspect of the present invention provides a storage battery management server that manages the storage battery system from a storage battery system that includes a storage battery and a control unit that controls the storage battery. A storage battery communication device that transmits information related to a storage battery, the memory storing a plurality of types of information related to the storage battery acquired from the control unit, and the plurality of types of information stored in the memory to the storage battery management server A first communication process for transmitting first communication information of the plurality of types of information to the storage battery management server at every first time; Performing a second communication process of transmitting second communication information of the plurality of types of information to the storage battery management server every second time shorter than the first time; Data of serial first communication information is greater than the data amount of the second communication information.

  A storage battery system according to a second aspect of the present invention is a storage battery system including a storage battery, a control unit that controls the storage battery, and a communication unit that transmits information related to the storage battery to a storage battery management server. The unit includes a memory that stores a plurality of types of information about the storage battery acquired from the control unit, and a transmission unit that transmits the plurality of types of information stored in the memory to the storage battery management server, The transmission unit transmits a first communication information of the plurality of types of information to the storage battery management server for each first time, and a second shorter than the first time. A second communication process for transmitting second communication information of the plurality of types of information to the storage battery management server every time, and a data amount of the first communication information is determined by the second communication information. Communication Greater than the amount of data broadcast.

  A storage battery management server according to a third aspect of the present invention is a storage battery management server that manages a storage battery system, a memory that stores a plurality of types of information related to storage battery management that is transmitted to the storage battery system, and a storage in the memory A transmission unit that transmits the plurality of types of information to the storage battery system, and the transmission unit transmits third communication information of the plurality of types of information to the storage battery system every third time. 4th communication which transmits 4th communication information of the said multiple types of information to the said storage battery management server for every 4th time shorter than said 3rd time and 3rd communication processing to transmit to The data amount of the third communication information is larger than the data amount of the fourth communication information.

  A storage battery communication control program according to a fourth aspect of the present invention is a storage battery communication that relays communication between the storage battery system and the storage battery management server so as to transmit information on the storage battery to a storage battery management server that manages the storage battery. A storage battery communication control program for operating a device or a computer incorporated in the storage battery system, the computer storing a plurality of types of information related to the storage battery, and the plurality of types stored in the memory The transmission unit transmits the first communication information of the plurality of types of information to the storage battery management server every first time. For each of the first communication process and the second time shorter than the first time, The second communication information running, and a second communication processing to be transmitted to the battery management server, the data quantity of the first communication information is greater than the data amount of the second communication information.

  A storage battery management program according to a fifth aspect of the present invention is a storage battery management program for operating a computer incorporated in a storage battery management server that manages a storage battery system, and the computer is transmitted to the storage battery system. A memory that stores a plurality of types of information related to storage battery management, and a transmission unit that transmits the plurality of types of information stored in the memory to the storage battery system, wherein the transmission unit is configured every third time. The third communication process of transmitting the third communication information of the plurality of types of information to the storage battery system, and the fourth time shorter than the third time, of the plurality of types of information The fourth communication information is transmitted to the storage battery management server, and the data amount of the third communication information is the fourth communication information. Larger than the data amount of communication information.

  According to each of the storage battery communication device, the storage battery system, the storage battery communication control program, the storage battery management server, and the storage battery management program of the present invention, it is possible to shorten the delay time of communication information while suppressing an increase in information processing burden. Can do.

It is a schematic diagram for demonstrating the whole structure of the communication system of Embodiment 1 of this invention. It is a block diagram for demonstrating the function of the communication apparatus for storage batteries of Embodiment 1 of this invention, and a storage battery management server. It is a sequence diagram for demonstrating the communication aspect between the communication apparatus for storage batteries of Embodiment 1 of this invention, and a storage battery management server. It is a figure for demonstrating the 1st communication information and the 2nd communication information which the communication apparatus for storage batteries of Embodiment 1 of this invention transmits. It is a figure for demonstrating the 3rd communication information and 4th communication information which the storage battery management server of Embodiment 1 of this invention transmits. It is a flowchart for demonstrating the storage battery communication process which the storage battery communication control program of the communication apparatus for storage batteries of Embodiment 1 of this invention performs. It is a flowchart for demonstrating the server communication process which the storage battery management program of the storage battery management server of Embodiment 1 of this invention performs. It is a sequence diagram for demonstrating the communication aspect between the communication apparatus for storage batteries of the modification of Embodiment 1 of this invention, and a storage battery management server. It is a schematic diagram for demonstrating the storage battery system of Embodiment 2 of this invention. It is a schematic diagram for demonstrating the storage battery system of Embodiment 3 of this invention.

  Hereinafter, a storage battery communication device, a storage battery system, a storage battery communication control program used therefor, a storage battery management server, and a storage battery management program used therefor will be described with reference to the drawings. In the description of the embodiments and the drawings, the same reference numerals are assigned to the same parts. The description of the same part given the same reference numeral is not repeated in the following embodiments unless otherwise required. In the comparison of the drawings between the first embodiment and the subsequent embodiments, the same parts to which the same reference numerals are attached have the same structure and function unless otherwise specified.

(Embodiment 1)
First, the overall configuration of the communication system according to the first embodiment will be described with reference to FIG.

  As shown in FIG. 1, in the communication system of the present embodiment, the facilities of the electric power company are connected to the Internet as an example of the electric information communication network 3. The power company facilities include a power company server 1 and a storage battery management server 2. In the communication system of the present embodiment, a large number of storage battery systems 6 are connected to the electrical information communication network 3 via storage battery communication devices 5 and routers 4. In the present embodiment, the storage battery management server 2 and the storage battery communication device 5 can communicate via the Internet, which is the electrical information communication network 3. However, the storage battery management server 2 and the storage battery communication device 5 may be communicably connected via a dedicated line without going through the Internet.

  The storage battery management server 2 receives information on storage batteries from each of a large number of storage battery systems 6, for example, information such as the remaining capacity of the storage battery, the total charge amount of the storage battery, and the total discharge amount of the storage battery. Thereby, the storage battery management server 2 manages the operation and state of the storage battery system 6 by transmitting and receiving information to and from the storage battery system 6. On the other hand, the electric power company server 1 acquires information related to the storage battery from the storage battery management server 2 and also acquires information such as customer information and power charges from other devices. Thereby, in addition to the information regarding many storage batteries which the storage battery management server 2 manages, the electric power company server 1 manages the information regarding customer information, an electric power charge, etc.

  The storage battery management server 2 transmits information related to storage battery management, such as demand response command information requesting charging or demand response command information requesting discharging, to the storage battery communication device 5. The storage battery communication device 5 receives information related to storage battery management from the storage battery management server 2 and transmits it to the storage battery system 6. In addition, the storage battery communication device 5 receives information about the storage battery from the storage battery system 6 and transmits information about the storage battery to the storage battery management server 2.

  On the other hand, an electric power system 7 that supplies electric power transmitted from a power company power plant to each building 100 passes through an electric power meter 8 installed outside each building 100 to a distribution board 9 in the building 100. Electrically connected. Various electrical devices such as the air conditioner 10 installed in the building 100 and the storage battery communication device 5 are electrically connected to the distribution board 9 and installed outside the building 100. The storage battery system 6 is electrically connected. Therefore, electric power is supplied from the electric power system 7 to the air conditioner 10, the storage battery communication device 5, and the storage battery system 6 via the power meter 8 and the distribution board 9.

  Further, the storage battery system 6 includes a storage battery 6 </ b> A that can be charged or discharged with respect to the power system 7 via the power meter 8 and the distribution board 9. The storage battery system 6 includes a power converter 6B that outputs the DC power of the storage battery 6A to the power system 7 as AC power and inputs the AC power of the power system 7 to the storage battery 6A as DC power. The storage battery system 6 includes a control unit 6C that controls the power conversion unit 6B to switch the storage battery 6A to any one of charging, discharging, and standby states.

  Next, the communication mode between the storage battery communication device 5 of this embodiment and the storage battery management server 2 will be described with reference to FIG.

The storage battery communication device 5 of the present embodiment includes a timer 5T that measures time. The timer 5T includes timers 5T ₁ and 5T _2, which will be described later in detail. The storage battery communication device 5 transmits information about the storage battery from the storage battery system 6 to the storage battery management server 2 each time the timers 5T ₁ and 5T ₂ each time. The storage battery communication device 5 includes a memory 5M that temporarily stores a plurality of types of information related to the storage battery. Further, the storage battery communication device 5 includes a transmission unit 5C that transmits a plurality of types of information stored in the memory 5M to the storage battery management server 2. The transmitting unit 5C also functions as a receiving unit that receives demand response command information and the like from the storage battery management server 2. The storage battery communication device 5 includes a storage battery communication control program 5 </ b> P that executes processing for controlling communication with the storage battery management server 2. The storage battery communication control program 5P can be read by a computer, can be recorded on a recording medium 5R as an external device of the storage battery communication device 5, and is installed in the storage battery communication device 5 from the recording medium 5R.

  The storage battery management server 2 of the present embodiment includes a timer 2T that measures time. The storage battery management server 2 receives a plurality of types of information related to the storage battery from the storage battery system 6. The storage battery management server 2 includes a memory 2M that temporarily stores a plurality of types of information related to storage batteries and a plurality of types of information related to storage battery management. The storage battery management server 2 includes a transmission unit 2C that transmits a plurality of types of information stored in the memory 2M to the storage battery management server 2. The transmitting unit 2C also functions as a receiving unit that receives information about the storage battery from the storage battery communication device 5. The storage battery management server 2 has a built-in storage battery management program 2 </ b> P that executes processing for controlling communication with the storage battery communication device 5. The storage battery management program 2P can be read by a computer, can be recorded on a recording medium 2R as an external device of the storage battery management server 2, and is installed from the recording medium 2R to the storage battery management server 2. The storage battery management server 2 further includes a database 2D that stores information transmitted from the storage battery communication device 5 and information transmitted to the storage battery communication device 5.

  Next, the communication mode between the storage battery communication device 5 and the storage battery management server 2 will be described with reference to FIG.

As illustrated in FIG. 3, the transmission unit 5C of the storage battery communication device 5 includes first communication information (a relatively thick arrow in FIG. 3) among a plurality of types of information for each first time T ₁ . Is transmitted to the storage battery management server 2. First time _{T 1,} for example, to 30 minutes. Transmitting portion 5C of the storage battery for communication equipment 5, every _two shorter second time T than the first time T _1, a relatively thin arrows in the second communication information (Figure 3 among a plurality of types of information ) Is transmitted to the storage battery management server 2. Second time _{T 2} are, for example, to 1 minute. However, in the present embodiment, in the second time T within ₂ including the first communication information is time zone is sent, the second communication information has not been sent.

The data amount of the first communication information is larger than the data amount of the second communication information. Accordingly, the first communication information relatively large amount of data is transmitted to the battery management server 2 each time the relatively long first time T ₁ is passed. Further, the second communication information relatively small amount of data is transmitted to the battery management server 2 for every relatively short second time T _2. According to this, the burden of processing the communication information of the storage battery management server 2 can be reduced by using, as the first communication information, information that does not cause a problem even if transmitted at a long interval. Moreover, by generating the information that needs to be transmitted at short intervals as the second communication information, it is possible to prevent the storage battery management server 2 from generating a time zone in which necessary data regarding the storage battery is insufficient.

2 C of transmission parts of the storage battery management server 2 perform the 3rd communication process which transmits the 3rd communication information of multiple types of information to the storage battery system 6 triggered by having received the 1st communication information. . Spacing the third communication information is transmitted from the transmitting unit 2C is thought to often become comparable first time T ₁ and, depending on the degree of congestion of communication traffic, the first time T It is possible that the time is slightly different from ₁ . 2 C of transmission parts of the storage battery management server 2 perform the 4th communication process which transmits the 4th communication information of multiple types of information to the storage battery management server 2 triggered by having received the 2nd communication information. To do. Interval fourth communication information is transmitted from the transmitting unit 2C is thought to often becomes the same extent as T ₂ second time, according to the degree of congestion of communication traffic, a second time T It may be a little different from ₂ . Note that the storage battery communication device 5 and the storage battery management server 2 may transmit communication information independently of each other.

  The data amount of the third communication information is larger than the data amount of the fourth communication information. Therefore, normally, the third communication information having a relatively large amount of data is transmitted to the storage battery system 6 every time a relatively long time elapses. In general, the fourth communication information with a relatively small amount of data is transmitted to the storage battery management server 2 every relatively short time. According to this, the information which does not cause a problem even if transmitted at a long interval is set as the third communication information, so that the burden of processing the communication information of the storage battery management server 2 can be reduced. Further, by making the information that needs to be transmitted at short intervals as the fourth communication information, it is possible to prevent occurrence of a time zone in which necessary data related to storage battery management, for example, demand response command information is insufficient in the storage battery system 6. be able to.

Although not depicted in FIG. 3, the storage battery communication device 5 acquires information on the storage battery from the storage battery system 6 every predetermined time, for example, every minute. The interval at which the storage battery communication device 5 acquires information about the storage battery from the storage battery system 6 includes an interval (T ₂ ) including the time period during which the storage battery communication device 5 transmits the second communication information to the storage battery management server 2. Or shorter than that.

  Next, details of the first communication information and the second communication information will be described with reference to FIG. As described in FIG. 4, both the first communication information and the second communication information are information transmitted from the storage battery system 6 to the storage battery management server 2 and are information related to the storage battery.

  As shown in FIG. 4, the first communication information includes, for example, information on an event such as failure or restart of the storage battery 6A, information on the total charge amount of the storage battery 6A, and information on the total discharge amount of the storage battery 6A. It is out. Therefore, the first communication information is information that needs to grasp a certain amount of change when a relatively long time has passed. Therefore, it is possible to reduce the burden of processing communication information of the storage battery communication device 5.

  The information on the total charge amount and the information on the total discharge amount of the storage battery system 6 can be used for predicting the life of the storage battery system 6. Since life prediction does not require frequent data collection, the storage battery communication device 5 transmits the storage battery management server 2 to the storage battery management server 2 at relatively long intervals. Thereby, the increase in the processing load of the communication information of both the storage battery communication device 5 and the storage battery management server 2 can be suppressed.

  The second communication information includes information on the remaining capacity of the storage battery 6A, information indicating whether the storage battery 6A is in a charged state, a discharged state, or a standby state, information on the temperature of the storage battery 6A, and the like. Yes. That is, the first communication information is information that is preferably grasped when a relatively short time has elapsed. For this reason, the storage battery communication device 5 can transmit to the storage battery management server 2 information that the storage battery management server 2 preferably knows as much as possible without any time lag at relatively short intervals.

  Next, details of the third communication information and the fourth communication information will be described with reference to FIG. As described in FIG. 5, the third communication information and the fourth communication information are both information transmitted from the storage battery management server 2 to the storage battery system 6 and information regarding storage battery management.

As shown in FIG. 5, in the present embodiment, the third communication information includes demand response command information. The fourth communication information also includes demand response command information. Therefore, approximately every second time near the time T _2, is always demand response command information is sent from the battery management server 2 to the storage battery system 6. That is, the demand response command information is transmitted at relatively short intervals. Therefore, it is possible to respond more quickly to the demand and supply of power. The third communication information includes information that can specify the charging and discharging schedule of the storage battery 6A. Since the charging and discharging schedule of the storage battery 6A has a large amount of information, it is transmitted at relatively long intervals, thereby burdening the processing of the communication information of both the storage battery management server 2 and the storage battery communication device 5 with each other. Can be reduced.

  The storage battery communication process executed by the storage battery communication control program 5P of the storage battery communication device 5 will be described with reference to FIG.

As shown in FIG. 6, in the storage battery communication process, first, in step S1, a timer 5T is started. At this time, both the timer 5T ₁ timed to the first time T ₁ (for example, 30 minutes) and the timer 5T ₂ timed to the second time T ₂ (for example, 1 minute) are started. .

Next, in step S2, whether the timer 5T ₁ had finished counting the T ₁ first time is determined. In step S2, if the timer 5T ₁ has already finished counting the T ₁ first time, in step S3, processing for transmitting the first communication information (see FIG. 4) it is executed. Thereafter, in step S4, the third communication information is received. Next, the process which transmits 3rd communication information to the storage battery system 6 is performed in step S5. In step S6, after the timer 5T ₁ and timer 5T ₂ is both reset, the process of step S2 is executed again.

In step S2, the timer 5T ₁ is when no finished yet measures the T ₁ first time, in step S7, whether the timer 5T ₂ had finished counting the T ₂ second time is determined The In step S7, when the timer 5T ₂ is already finished counting the T ₂ second time, in step S8, the process of transmitting the second communication information (see FIG. 4) is executed.

Thereafter, in step S9, the storage battery communication device 5 receives the fourth communication information. Then, the process which transmits 4th communication information to the storage battery system 6 is performed in step S10. Next, in step S11, the timer 5T ₂ is after being reset, the process of step S2 is executed again. In step S7, the timer 5T ₂ is when not yet counting the second time T ₂ are, immediately step S2 is executed again.

  The server communication process which the storage battery management program 2P of the storage battery management server 2 performs is demonstrated using FIG.

  As shown in FIG. 7, in the server communication process, first, in step S111, the storage battery management server 2 determines whether or not the information transmitted from the storage battery communication device 5 has been acquired. If information is not acquired in step S111, the storage battery management server 2 waits until information is acquired.

  If information is acquired in step S111, the storage battery management server 2 stores the information in the memory 2M, and the process of step S112 is executed. In step S12, it is determined whether or not the information acquired in step S111 is second communication information. When it is determined in step S112 that the information acquired in step S111 is the second communication information, a process of transmitting the fourth communication information (see FIG. 5) to the storage battery communication device 5 in step S113. Executed. Thereafter, in step S114, the second communication information is stored in the database 2D. Next, in step S115, the information acquired in step S111 stored in the memory 2M is deleted, and then the process of step S111 is executed again.

  On the other hand, if it is determined in step S112 that the information acquired in step S112 is not the second communication information, it is determined in step S116 whether or not the information acquired in step S111 is the first communication information. Is done. If it is determined in step S116 that the information acquired in step S111 is the first communication information, a process of transmitting the third communication information (see FIG. 5) is executed in step S117. Thereafter, in step S118, the first communication information is stored in the database 2D. Thereafter, the information acquired in step S119 stored in the memory 2M in step S119 is deleted, and the process in step S111 is executed again. If it is determined in step S116 that the information acquired in step S111 is not the first communication information, the information acquired in step S111 stored in the memory 2M is deleted in step S119, and the information in step S111 is deleted. The process is executed again.

  Next, modifications 1 to 4 of the storage battery communication device, the storage battery system, the storage battery communication control program, the storage battery management server, and the storage battery management program according to the above-described embodiment will be described.

(Modification 1)
In the present embodiment, the communication device 5 for the storage battery, by timer 5T ₂ finishes counting the T ₂ second time, when transmitting the first communication information, the second communication information Do not send. However, the storage battery communication device 5 may transmit the first communication information and the second communication information in a superimposed manner at the same time.

(Modification 2)
In the present embodiment, an example in which the client request model, that is, the storage battery communication device 5 starts communication with the storage battery management server 2 is shown. However, if communication with the storage battery management server 2 is established in advance in the storage battery communication device 5, communication may be started from the storage battery management server 2 to the storage battery communication device 5.

For example, as shown in FIG. 8, in the second modification, the storage battery management server 2 stores the storage battery every time a _third time T _{3 in} which the third communication information with a relatively large amount of data passes is relatively long. May be transmitted to the communication device 5 for use. May also be transmitted every fourth communication information relatively small amount of data is relatively short fourth time T ₄ from the battery management server 2 to the storage battery for the communication device 5. In this case, the data amount of the third communication information is larger than the data amount of the fourth communication information. According to this, the information which does not cause a problem even if transmitted at a long interval is set as the third communication information, so that the burden of processing the communication information of the storage battery management server 2 can be reduced. Further, by making the information that needs to be transmitted at short intervals as the fourth communication information, it is possible to prevent occurrence of a time zone in which necessary data related to storage battery management, for example, demand response command information is insufficient in the storage battery system 6. be able to.

 In the case of the second modification, the storage battery communication device 5 transmits the first communication information to the storage battery management server 2 in response to the reception of the third communication information. In addition, the storage battery communication device 5 transmits the second communication information to the storage battery management server 2 in response to the reception of the fourth communication information. However, the storage battery communication device 5 and the storage battery management server 2 may transmit communication information independently of each other.

(Modification 3)
In Embodiment 1 and Modifications 1 and 2, the first time T ₁ and the third time T ₃ are both 30 minutes. Time T ₄ of the second time T ₂ and the fourth are both assumed to be 1 minute. However, the first time T ₁ , the second time T ₂ , the third time T ₃ , and the fourth time T ₄ are not particularly limited to the above time. Second time T ₂ is shorter than the first time T1, the fourth time T ₄ is is shorter than the third time T _3, each time, may be any time. That is, the first time T ₁ and the third time T ₃ may be the same, but may be different. The second time T ₂ and the fourth time T _4, may be identical or different.

In the present embodiment, the information on the first time T ₁ , the second time T ₂ , the third time T ₃ , and the fourth time T ₄ is received from the storage battery management server 2 at the time of initial setting. Shall be sent to. However, the information of the first time T ₁ , the second time T ₂ , the third time T ₃ , and the fourth time T ₄ is stored in the storage battery system 6 immediately before being shipped from the factory or the like. It may be.

(Embodiment 2)
The storage battery system of Embodiment 2 is demonstrated using FIG. The present embodiment is almost the same as the first embodiment. As shown in FIG. 9, the present embodiment differs from the above-described embodiment shown in FIG. 1 only in that the storage battery communication device 5 is built in the storage battery system 6 as a communication unit.

  In general, the storage battery system 6 is often installed outside the building 100 because the space occupancy is large. On the other hand, the storage battery communication device (communication unit) 5 is often installed in the building 100 because it is not preferable to be exposed to rain and sunlight. However, the storage battery communication device (communication unit) 5 is installed in the storage battery system 6 installed outside the building 100 if windproof processing, waterproof processing, and weather resistance processing that can withstand rain wind and sunlight are applied. It may be built in. In this case, the storage battery communication device 5 in the storage battery system 6 is actually communicating with the storage battery management server 2, but it can be said that the storage battery system 6 is communicating with the storage battery management server 2. Even when the storage battery system 6 is installed in the building 100, the storage battery communication device (communication unit) 5 may be built in the storage battery system 6.

  Note that the storage battery communication device (communication unit) 5 in the storage battery system 6 of the present embodiment can also be controlled by the storage battery communication control program 5P described in the first embodiment.

(Embodiment 3)
The storage battery system of Embodiment 3 will be described using FIG. The present embodiment is almost the same as the first embodiment. As shown in FIG. 10, the present embodiment is the same as that shown in FIG. 1 only in that the storage battery communication device 5 is replaced with a communication unit 5A integrated with the control unit 6C of the storage battery system 6. This is different from the embodiment. That is, in the present embodiment, the communication unit 5 </ b> A is incorporated in the control unit 6 </ b> C of the storage battery system 6. From the viewpoint of miniaturization of the storage battery system 6, as shown in FIG. 10, the communication unit 5A having the same configuration as the storage battery communication device 5 and performing the same function as the storage battery communication device 5 is used. 6 is preferably integrated with the control unit 6C.

  Note that the communication unit 5A in the storage battery system 6 of the present embodiment can also be controlled by the storage battery communication control program 5P described in the first embodiment. However, the storage battery communication control program 5P of the present embodiment is a part of a program executed in the control unit 6C that controls the storage battery 6A.

(Characteristic configuration and effects obtained thereby)
Hereinafter, characteristic configurations and effects of the storage battery communication device, the storage battery system, the storage battery communication control program used for them, and the storage battery management server and the storage battery management program used therefor will be described collectively.

(1) As shown in FIGS. 1 and 2, the storage battery communication device 5 includes a storage battery management server 2 that manages the storage battery system 6 from the storage battery system 6 that includes the storage battery 6A and a control unit 6C that controls the storage battery 6A. The information regarding a storage battery is transmitted to. The storage battery communication device 5 includes a memory 5M that stores a plurality of types of information related to the storage battery acquired from the control unit 6C, and a transmission unit 5C that transmits a plurality of types of information stored in the memory 5M to the storage battery management server 2. It has. As illustrated in FIG. 3, the transmission unit 5 </ b> C executes a first communication process of transmitting the first communication information of the plurality of types of information to the storage battery management server 2 for each first time T _1. . As shown in FIG. 3, the transmission unit 5 </ b> C transmits the second communication information of the plurality of types of information to the storage battery management server 2 for each second time T ₂ that is shorter than the first time T _1. The second communication process is executed. The data amount of the first communication information is larger than the data amount of the second communication information. According to this, the delay time of communication information can be shortened, suppressing the increase in the burden of processing communication information.

  (2) As shown in FIG. 4, the first communication information includes at least one of information on failure or restart of the storage battery 6A, information on the total charge amount of the storage battery 6A, and information on the total discharge amount of the storage battery 6A. Any one of them may be included. According to this, an increase in the burden of processing communication information can be suppressed.

  (3) As shown in FIG. 4, the second communication information may include at least one of the following information. The information includes information on the remaining capacity of the storage battery 6A, information indicating whether the storage battery 6A is in a charged state, a discharged state, or a standby state, and information on the temperature of the storage battery 6A. According to this, the delay time of communication information can be shortened.

(4) As shown in FIG. 2, FIG. 9, and FIG. 10, the storage battery system 6 of the embodiment is connected to the storage battery 6A, the control unit 6C that controls the storage battery 6A, and the storage battery management server 2 that manages information related to the storage battery. And a communication unit 5A for transmission. The communication unit 5A shown in FIG. 10 may be the storage battery communication device 5 shown in FIG. The communication unit 5A includes a memory 5M that stores a plurality of types of information related to the storage battery acquired from the control unit 6C, and a transmission unit 5C that transmits the plurality of types of information stored in the memory 5M to the storage battery management server 2. ing. As illustrated in FIG. 3, the transmission unit 5 </ b> C executes a first communication process of transmitting the first communication information of the plurality of types of information to the storage battery management server 2 for each first time T _1. . As shown in FIG. 3, the transmission unit 5 </ b> C transmits the second communication information of the plurality of types of information to the storage battery management server 2 for each second time T ₂ that is shorter than the first time T _1. The second communication process is executed. The data amount of the first communication information is larger than the data amount of the second communication information. According to this, the delay time of communication information can be shortened, suppressing the increase in the burden of processing communication information.

(5) The storage battery management server 2 according to the embodiment is for managing the storage battery system 6 as shown in FIG. As shown in FIG. 2, the storage battery management server 2 stores a plurality of types of information related to storage battery management transmitted to the storage battery system 6 and a plurality of types of information stored in the memory 2M to the storage battery system. 2C for transmitting. Transmitting unit 2C, as shown in FIG. 8, each third time T _3, it executes the third communication process of transmitting the third communication information among the plurality of types of information to the storage battery system 6. As illustrated in FIG. 8, the transmission unit 2 </ b> C transmits the fourth communication information of the plurality of types of information to the storage battery management server 2 at every fourth time T ₄ shorter than the third time T _3. The fourth communication process is executed. The data amount of the third communication information is larger than the data amount of the fourth communication information. According to this, the delay time of communication information can be shortened, suppressing the increase in the burden of processing communication information.

  (6) As shown in FIG. 5, the third communication information may include information that can specify the charging and discharging schedules of the storage battery system 6. According to this, an increase in the burden of processing communication information can be suppressed.

  (7) The storage battery system 6 may be configured such that it can be charged from the power system 7 to the storage battery system 6 and discharged from the storage battery system 6 to the power system 7. The storage battery management server 2 may be capable of transmitting each of demand response command information for requesting charging from the power system 7 to the storage battery system 6 and demand response command information for requesting discharge from the storage battery system 6 to the power system 7. As shown in FIG. 5, the fourth communication information may include demand response command information. According to this, the delay time of demand response command information can be shortened. Therefore, it is possible to quickly respond to the demand or supply of power.

  (8) The storage battery communication control program 5P of the embodiment is for operating a storage battery communication device 5 that relays communication between the storage battery system 6 and the storage battery management server 2 or a computer incorporated in the storage battery system 6. . By executing the storage battery communication control program 5P, information about the storage battery is transmitted to the storage battery management server 2 that manages the storage battery system 6. Therefore, the storage battery communication control program 5P causes the computer to function as the memory 5M and the transmission unit 5C described above. According to this, the delay time of communication information can be shortened, suppressing the increase in the burden of processing communication information.

  (9) The storage battery management program 2P of the embodiment is for operating a computer incorporated in the storage battery management server 2 that manages the storage battery system 6, as shown in FIG. The storage battery management program 2P causes the computer to function as the memory 2M and the transmission unit 2C described above. According to this, the delay time of communication information can be shortened, suppressing the increase in the burden of processing communication information.

2 storage battery management server 2C transmission unit 2M memory 2P storage battery management program 5 storage battery communication device 5C transmission unit 5M memory 5P storage battery communication control program 6 storage battery system 6A storage battery 6C control unit 7 power system

Claims (9)

A storage battery communication device that transmits information related to the storage battery from a storage battery system including a storage battery and a control unit that controls the storage battery to a storage battery management server that manages the storage battery system,
A memory for storing a plurality of types of information related to the storage battery obtained from the control unit;
A transmission unit that transmits the plurality of types of information stored in the memory to the storage battery management server,
The transmitter is
A first communication process for transmitting the first communication information of the plurality of types of information to the storage battery management server for each first time;
Performing a second communication process of transmitting second communication information of the plurality of types of information to the storage battery management server every second time shorter than the first time;
The storage battery communication device, wherein the data amount of the first communication information is larger than the data amount of the second communication information.   The first communication information includes at least one of information on a failure or restart of the storage battery, information on a total charge amount of the storage battery, and information on a total discharge amount of the storage battery. A communication device for a storage battery as described in 1.   The second communication information includes information on the remaining capacity of the storage battery, information indicating whether the storage battery is in a charged state, a discharged state, or a standby state, and information on the temperature of the storage battery. The communication apparatus for storage batteries according to claim 1 or 2, comprising at least one of them. A storage battery system comprising a storage battery, a control unit that controls the storage battery, and a communication unit that transmits information to the storage battery management server that manages information related to the storage battery,
The communication unit is
A memory for storing a plurality of types of information related to the storage battery obtained from the control unit;
A transmission unit that transmits the plurality of types of information stored in the memory to the storage battery management server,
The transmitter is
A first communication process for transmitting the first communication information of the plurality of types of information to the storage battery management server for each first time;
Performing a second communication process of transmitting second communication information of the plurality of types of information to the storage battery management server every second time shorter than the first time;
The storage battery system, wherein the data amount of the first communication information is larger than the data amount of the second communication information. A storage battery management server for managing a storage battery system,
A memory for storing a plurality of types of information related to storage battery management transmitted to the storage battery system;
A transmission unit that transmits the plurality of types of information stored in the memory to the storage battery system,
The transmitter is
A third communication process for transmitting third communication information of the plurality of types of information to the storage battery system every third time;
Performing a fourth communication process of transmitting the fourth communication information of the plurality of types of information to the storage battery management server every fourth time shorter than the third time;
The storage battery management server, wherein the data amount of the third communication information is larger than the data amount of the fourth communication information.   The storage battery management server according to claim 5, wherein the third communication information includes information capable of specifying a charging and discharging schedule of the storage battery system. The storage battery system is configured to be able to charge from the power system to the storage battery system and to be discharged from the storage battery system to the power system,
The storage battery management server can transmit each of demand response command information for requesting charging from the power system to the storage battery system and demand response command information for requesting discharge from the storage battery system to the power system,
The storage battery management server according to claim 5 or 6, wherein the fourth communication information includes the demand response command information. A storage battery communication device that relays communication between the storage battery system and the storage battery management server or a computer incorporated in the storage battery system so as to transmit information about the storage battery to a storage battery management server that manages the storage battery system A storage battery communication control program,
Causing the computer to function as a memory that stores a plurality of types of information related to the storage battery, and a transmission unit that transmits the plurality of types of information stored in the memory to the storage battery management server,
The transmitter is
A first communication process for transmitting the first communication information of the plurality of types of information to the storage battery management server for each first time;
Performing a second communication process of transmitting second communication information of the plurality of types of information to the storage battery management server every second time shorter than the first time;
The storage battery communication control program, wherein the data amount of the first communication information is larger than the data amount of the second communication information. A storage battery management program for operating a computer incorporated in a storage battery management server for managing a storage battery system,
The computer functions as a memory that stores a plurality of types of information related to storage battery management transmitted to the storage battery system, and a transmission unit that transmits the plurality of types of information stored in the memory to the storage battery system,
The transmitter is
A third communication process for transmitting third communication information of the plurality of types of information to the storage battery system every third time;
Performing a fourth communication process of transmitting the fourth communication information of the plurality of types of information to the storage battery management server every fourth time shorter than the third time;
The storage battery management program, wherein the data amount of the third communication information is larger than the data amount of the fourth communication information.

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