JP7628838B2 - Power Management Device - Google Patents

Description

The present invention relates to a power management apparatus .

As a result of the need to dramatically reduce greenhouse gas emissions that cause climate change, major companies have been stepping up efforts to strengthen environmental management for the sustainable development of both society and their own companies. For example, the number of companies participating in the international corporate alliance "RE100," which aims to use renewable energy (hereafter referred to as "renewable energy") for all the electricity used in business activities, has been increasing year by year, with 288 companies participating worldwide, including 50 companies in Japan (as of February 2021).
Participating companies are required to declare plans and goals to cover their business operations with 100% renewable energy, which indicates a sharp rise in the need to increase the renewable energy utilization rate. In order for companies to increase their renewable energy utilization rate, they need to procure electricity that has been proven to have environmental value as it is derived from renewable energy.

Possible methods of procuring renewable energy power include (a) setting up a renewable energy power plant on one's own premises and consuming it, (b) setting up an off-site renewable energy power plant in-house and self-consigning it, and (c) procuring it from a retail electricity supplier. In addition, a method of proving the environmental value of renewable energy power could be, for example, power source tracking using blockchain.
Since it is possible to prove the environmental value of renewable energy electricity supplied on one's own premises or from external sources, it is possible to achieve reliable management of renewable energy utilization rates without losing environmental value.
An example of a public technology related to power source tracking is an energy trading system in which a power facility or a power generation facility having surplus power directly trades with an energy storage facility (see Patent Document 1).

JP 2019-153275 A

However, power source tracking has the problem that tracking is difficult when a storage device such as a storage battery is present in the grid. For example, when a storage battery connected to both a solar power generation device and a commercial grid is charged and then power is output from the storage battery, it is not possible to determine whether the power is purchased power or solar power. This makes power source tracking difficult, and makes it difficult to prove the usage of renewable energy power.

The present invention has been made in view of the above circumstances, and has an object to provide a power management device that enables power supply tracking even in a system that includes a power storage device.

In order to solve the above-mentioned problems, one aspect of the present invention is a power management device connected to a blockchain to which multiple nodes are connected, and a power storage device of a consumer facility having the power storage device capable of charging purchased power and power based on renewable energy, the power management device having a power information acquisition unit that acquires a measurement result of measuring the power generated by the renewable energy and a measurement result of measuring the power output from the power storage device, a tracking information generation unit that generates tracking information based on the measurement result obtained by the power information acquisition unit when discharging from the power storage device, the tracking information generation unit generating tracking information including, among the charging rates of the power storage device, the charging rate at the power storage device that is charged from renewable energy and the charging rate that is charged from purchased power, and, among the output power from the power storage device, the output power that is derived from renewable energy and the output power that is derived from purchased power, and a registration request unit that transmits the generated tracking information to a first node of the multiple nodes and requests registration in a distributed ledger.

One aspect of the present invention is a power management device connected to a blockchain to which multiple nodes are connected, and to a power storage device of a consumer facility having the power storage device capable of charging purchased power and power based on renewable energy, the power management device having a power information acquisition unit that acquires measurement results of the power generated by the renewable energy and the power output from the power storage device, a tracking information generation unit that, when charging the power storage device, generates tracking information representing the charging rate of the power storage device that is charged from renewable energy and the charging rate that is charged from purchased power based on the measurement results obtained by the power information acquisition unit, and a registration request unit that transmits the generated tracking information to a first node of the multiple nodes and requests registration in a distributed ledger.

One aspect of the present invention is a power management method executed in a power management device connected to a blockchain to which multiple nodes are connected and to a power storage device of a consumer facility having the power storage device capable of charging purchased power and power based on renewable energy, in which a power information acquisition unit of the power management device acquires a measurement result of measuring the power generated by the renewable energy and a measurement result of measuring the power output from the power storage device, and a tracking information generation unit of the power management device generates tracking information based on the measurement result obtained by the power information acquisition unit when discharging from the power storage device, the tracking information including the charging rate of the power storage device, which is the charging rate at the power storage device that is charged from renewable energy and the charging rate that is charged from purchased power, and the output power from the power storage device, which is the output power that is derived from renewable energy and the output power that is derived from purchased power, based on the measurement result obtained by the power information acquisition unit, and a registration request unit of the power management device transmits the generated tracking information to a first node of the multiple nodes and requests registration in a distributed ledger.

One aspect of the present invention is a power management method executed in a power management device connected to a blockchain to which multiple nodes are connected and to a power storage device of a consumer facility having the power storage device capable of charging purchased power and power based on renewable energy, in which a power information acquisition unit of the power management device acquires a measurement result of measuring the power generated by the renewable energy and a measurement result of measuring the power output from the power storage device, and a tracking information generation unit of the power management device generates tracking information representing the charging rate of the power storage device that is charged due to renewable energy and the charging rate that is charged due to purchased power based on the measurement result obtained by the power information acquisition unit when charging the power storage device, and a registration request unit of the power management device transmits the generated tracking information to a first node of the multiple nodes and requests registration in a distributed ledger.

As described above, this invention makes it possible to perform power source tracking even in systems that have a power storage device.

1 is a schematic block diagram showing a configuration of a power supply tracking system 1 according to an embodiment of the present invention. 2 is a schematic block diagram illustrating the function of a power management device 231. FIG. 11 is a flowchart illustrating the operation of a power management device 231. FIG. 1 is a diagram illustrating the origin of a storage battery. FIG. 1 is a diagram illustrating the origin of a storage battery. FIG. 11 is a schematic block diagram showing the configuration of a power source tracking system 1 according to another embodiment. FIG. 2 is a schematic block diagram illustrating the function of a power management device 231A. FIG. 13 is a diagram for explaining the case where the present invention is applied to power source tracking in electricity retailing. FIG. 1 is a schematic block diagram showing a configuration of a power source tracking system 1B. FIG. 13 is a diagram illustrating an example of a calculation result of a power management device 231B. FIG. 13 is a diagram illustrating an example of a calculation result of a power management device 231B.

Hereinafter, a power supply tracking system 1 according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic block diagram showing the configuration of a power supply tracking system 1 according to an embodiment of the present invention.
The power source tracking system 1 includes a blockchain platform 10, a consumer facility 20, a commercial power source 30, and a network 40.
The blockchain platform 10 and the customer facility 20 are communicatively connected via a network 40. The customer facility 20 and the commercial power source 30 are connected via a power line.

<Blockchain Platform 10>
The blockchain platform 10 includes multiple nodes 101 (node 101a, node 101b, node 101c, node 101d, node 101e, and node 101f; hereinafter, when no particular identification is required, these will be simply referred to as nodes 101) that are communicatively connected via a network 102.
Each of the multiple nodes 101 is composed of a computer. Each node 101 has a distributed ledger format in which data indicating the power usage status is transmitted from a computer in a customer facility connected to the node itself at regular intervals, a hash value of the data is calculated, and the hash value is transmitted to other nodes. By using such blockchain technology, the power usage status in each customer facility is stored so as not to be tampered with.

In the consumer facility 20, a power meter 201, a load 202, a measuring device 203, a PV (Photovoltaic) panel 211, a PCS (Power Conditioning Subsystem) 212, a storage battery 221, and a power management device 231 are connected via a cable 241. The cable 241 may include a power line and a communication line.

<Commercial power supply 30>
The commercial power source 30 supplies electric power generated in a power generation facility of an electric power company.
The commercial power source 30 is an example of a source of purchased power.

<Power meter 201>
The power meter 201 is connected to the commercial power source 30 via a cable 241, measures the power supplied from the commercial power source 30 to the load or the storage battery 221, and transmits the measurement result to the power management device 231 via the cable 241. The power meter 201 may transmit the measurement result to the power management device 231 wirelessly.

<Load 202>
The load 202 operates by being supplied with at least one of power supplied from the commercial power source 30 , power supplied from the storage battery 221 , and power supplied from the PV panel 211 via the PCS 212 .

<Measuring device 203>
The measurement device 203 measures the power supplied to the load, and outputs the measurement result to the power management device 231 .

<PV Panel 211>
The PV panel 211 is a solar power generation device that outputs renewable energy obtained by converting sunlight into electric power using a solar cell to the storage battery 221 or the load 202 via the PCS 212 .
The PV panel 211 may be a facility installed on the same premises as the load 202, an off-site facility owned by the company, or a facility owned by a renewable energy provider.

<PCS212>
The PCS 212 converts DC power (renewable energy) supplied from the PV panel 211 into AC power and supplies it to a load or the storage battery 221. Here, the PCS 212 may supply AC power to the storage battery 221, or may supply AC power to the storage battery 221.
The PCS 212 also has a controller that measures the power obtained from the PV panel 211 and transmits the measurement results to the power management device 231 .

<Storage battery 221>
The storage battery 221 accumulates power supplied from at least one of the power generated by the PV panel 211 and the power supplied from the commercial power source 30 , and supplies the accumulated power to the load 202 .
A controller is provided in the storage battery 221. This controller has a function of measuring the output power output from the storage battery and transmitting the measurement result to the power management device 231, a function of measuring the charging power for charging the storage battery with power supplied from outside (renewable energy or commercial power source) and transmitting the measurement result to the power management device 231, and a function of measuring the SOC of the storage battery 221 and transmitting the measurement result to the power management device 231.

This storage battery 221 is an example of a power storage device, and other power storage devices may be used as long as they are capable of storing electric power. Examples of other power storage devices include a hydrogen system that stores hydrogen obtained by electrolysis of water and outputs it using a fuel cell during power generation, a flywheel that converts electric energy into the physical energy of rotational motion, stores the converted energy, and converts the physical energy of rotational motion into electric energy during power generation and outputs the converted energy, and a pumped-storage power generation device that uses electric power to pump water to the top and generates power by supplying water from the top during power generation.
In addition, the storage battery 221 can be charged by the power supplied from the PV panel 211, and thus stores renewable energy and supplies it to the load 202 at a timing when it is necessary to discharge it. As a result, in the customer facility 20, the renewable energy supplied from the PV panel 211 can be used within the customer facility 20 (e.g., the load 202) by first charging the storage battery 221 and then discharging it.
In addition, in the consumer facility 20, it is also possible to supply the renewable energy supplied from the PV panel 211 to the load 202 without charging the storage battery 221.

<<Power management device 231>>
The power management device 231 has the function of determining the origin (whether it is renewable energy or a commercial power source) of the electricity used within the consumer facility 20 (e.g., the load 202), and based on this determination result, has the function of adding power tracking information to the charging and discharging power of the storage battery 221 and transmitting it to the blockchain platform 10.
By transmitting the power used in the customer facility 20 from the power management device 231 to the blockchain platform 10, it is possible to notify the blockchain platform 10 of how much of the power used in the customer facility 20 has been covered by power derived from renewable energy. Based on this notification, the blockchain platform 10 electronically stores this in a distributed ledger, making it possible to use it to prove the environmental value of renewable energy.

FIG. 2 is a schematic block diagram illustrating the functionality of the power management unit 231.
The power management device 231 includes a power information acquisition unit 2311, a tracking information generation unit 2312, a registration request unit 2313, and a storage unit 2314. The power information acquisition unit 2311, the tracking information generation unit 2312, and the registration request unit 2313 may be configured by a processing unit such as a CPU (Central Processing Unit) or a dedicated electronic circuit.

The power information acquisition unit 2311 acquires the purchased power [kW] at time n, the load power [kW] at time n, the PV power [kW] at time n, the storage battery output (positive discharge) [kW] at time n, and the measured SOC value [%] at time n. These variables are as shown in the following (1).

The power information acquisition unit 2311 acquires the purchased power [kW] at time n from the power meter 201, the load power [kW] at time n from the measuring device 203, the PV power [kW] at time n from the controller of the PCS 212, and the storage battery output (positive discharge) [kW] at time n and the SOC measurement value [%] at time n from the controller provided in the storage battery 221.

When storing power in the power storage device or discharging power from the power storage device to the outside, the tracking information generating unit 2312 generates tracking information including the charging rate of the power storage device derived from renewable energy and the charging rate of the power storage device derived from purchased power, based on data obtained from the power information acquiring unit 2311. For example, by using information included in this tracking information, it is possible to know that the current charging rate of the power storage device is 80%, and that, of the charging rate A%, the charging rate of the power storage device derived from renewable energy is A1%, and the charging rate of the power storage device derived from purchased power is A2% (charging rate A=A1+A2).
In addition, when discharging electricity from the storage device, the tracking information generation unit 2312 generates tracking information based on the data obtained from the power information acquisition unit 2311, which includes, among the charging rates of the storage device, the charging rate at the storage device that is charged from renewable energy and the charging rate that is charged from purchased electricity, and also includes, among the output power from the storage device, the output power that is charged from renewable energy and the output power that is charged from purchased electricity.

The registration request unit 2313 transmits the generated tracking information to a first node among the multiple nodes and requests registration in the distributed ledger.
The first node to which the tracking information is transmitted may be any node constituting the blockchain platform 10. In this embodiment, a case where the first node is the node 101e will be described.

The storage unit 2314 stores various types of information, for example, the storage unit 2314 stores the rated capacity _{W_BAT} of the storage battery.
Furthermore, the storage unit 2314 stores the tracking information transmitted from the power management device 231 to the first node.
The storage unit 2314 is configured by a storage medium, for example, a hard disk drive (HDD), a flash memory, an electrically erasable programmable read only memory (EEPROM), a random access read/write memory (RAM), a read only memory (ROM), or any combination of these storage media. For example, a non-volatile memory can be used for this storage unit 2314.

Next, the operation of the above-mentioned power management device 231 will be described using the flowchart of Fig. 3. The power management device 231 executes the process shown in this flowchart every time the timing for transmitting tracking information to a node arrives. For example, the power management device 231 sequentially transmits tracking information at a timing that matches the time interval for generating blocks in the blockchain platform 10.
The power information acquisition unit 2311 of the power management device 231 acquires the purchased power [kW] at time n, the load power [kW] at time n, the PV power [kW] at time n, the storage battery output (positive: discharge, negative: charge) [kW] at time n, and the measured SOC value [%] at time n (step S101). The measured SOC value is a value obtained by measuring the SOC (State Of Charge) and is a measurement result obtained by measuring the charging rate.

Next, the tracking information generating unit 2312 determines whether the storage battery is charging or discharging by determining whether the storage battery output at time n is less than 0 (step S102). For example, if the storage battery output at time n is less than 0, the tracking information generating unit 2312 determines that the storage battery is in a charging state at time n, and if the storage battery output at time n is 0 or greater, the tracking information generating unit 2312 determines that the storage battery is in a discharging state.
When the tracking information generation unit 2312 determines that the operating state of the storage battery 221 is charging, it calculates the SOC value of the portion of the SOC of the storage battery 221 that has been charged due to renewable energy and the SOC value of the portion that has been charged due to purchased electricity (electricity supplied from the commercial power source 30) (step S103).
Here, the tracking information generating unit 2312 calculates the amount of charge by different calculation methods depending on whether the charging power currently being charged to the storage battery 221 is derived entirely from renewable energy or whether at least a portion of the charging power is derived from purchased power. When the charging power being charged to the storage battery 221 is entirely from renewable energy, this refers to when all the charging power for charging the storage battery 221 is power generated in the PV panel 211 and supplied via the PCS 212. In other words, this can also be said to be when the storage battery 221 is being charged without being supplied from the commercial power source 30.

<When all energy comes from renewable sources>
Whether the charging power for charging the storage battery 221 is entirely generated and supplied by the PV panel 211 or whether at least a portion of the charging power is derived from purchased power can be determined, for example, using the following equation (2) or equation (5).
The tracking information generation unit 2312 uses the data obtained from the power information acquisition unit 2311 and determines that all charging is derived from renewable energy if the following equation (2) is satisfied.

Here, the storage priority X of PV power is any number between 0 and 1. For example, if all the power (PV power) supplied from the PV panel 211 is stored and the surplus is used for the load, X=1 is used; if half of the PV power is stored as much as possible, X=0.5 is used; and if as much of the PV power is directly used for the load as much as possible and the surplus is stored, X=0 is used. The larger the storage priority X of the PV power, the higher the priority of the power being stored in the storage battery 221.

By using this formula (2), the tracking information generating unit 2312 obtains a value obtained by dividing the product of the difference between the measured SOC value obtained at the previous time and the measured SOC value obtained at the current time and the rated capacity of the storage battery by the measurement time increment, and compares this value with the product of the storage priority of the PV power and the power generated by the PV panel at time n. If the product is greater, it can be determined that all of the charging power for charging the storage battery 221 is power generated and supplied by the PV panel 211. For example, if the power from the PV panel supplied to the storage side in accordance with the storage priority is greater than the increased SOC at a certain time, it can be determined that all of the power is generated and supplied by the PV panel 211.

また、トラッキング情報生成部２３１２は、買電電力に由来する充電率を次の（４）式に基づいて求める。

If it is determined that all of the electricity is generated and supplied by the PV panel 211, the tracking information generation unit 2312 calculates the charging rate derived from renewable energy based on the following equation (3).

In addition, the tracking information generating unit 2312 calculates the charging rate derived from the purchased power based on the following equation (4).

The initial value of the charging rate derived from renewable energy and the initial value of the charging rate derived from purchased power may be set so that the storage battery 221 is fully charged only from purchased power or only from renewable energy, and a value corresponding to this state is set as the initial value. Also, the SOC of the storage battery 221 may be set to 0 (%), and a value corresponding to this state may be set as the initial value.

<When at least a portion of the electricity comes from purchased electricity>
The tracking information generation unit 2312 uses the data obtained from the power information acquisition unit 2311, and if the following equation (5) is satisfied, determines that at least a portion of the charging is derived from purchased power.

By using this formula (5), the tracking information generating unit 2312 obtains a value obtained by dividing the product of the difference between the measured SOC value obtained at the previous time and the measured SOC value obtained at the current time and the rated capacity of the storage battery by the measurement time increment, and compares this value with the product of the storage priority of the PV power and the power generated by the PV panel at time n. If this value is equal to or greater than this product, it can be determined that the charging power for charging the storage battery 221 is at least partially derived from purchased power. For example, if the increased SOC at a certain time is equal to or greater than the power from the PV panel supplied to the storage side according to the storage priority, it is determined that at least a portion of the charging power is derived from purchased power.

また、トラッキング情報生成部２３１２は、買電電力に由来する充電率を次の（７）式に基づいて求める。

If it is determined that at least a portion of the power is derived from purchased power, the tracking information generation unit 2312 calculates the charging rate derived from renewable energy based on the following equation (6).

In addition, the tracking information generating unit 2312 calculates the charging rate derived from the purchased power based on the following equation (7).

When the tracking information generation unit 2312 determines the SOC based on renewable energy and the SOC derived from purchased electricity, the registration request unit 2313 transmits information including the determined SOC based on renewable energy and the SOC derived from purchased electricity as tracking information to the first node along with an instruction requesting that the first node register the information in the distributed ledger (step S105).
Here, the registration request unit 2313 may transmit information including the purchased power at time n at the consumer facility 20, the load power at time n, the solar power generation output (PV power) at time n, the charging and discharging power (output power) of the storage battery, and the SOC value of the storage battery (PV-derived SOC, purchased power-derived SOC) as tracking information to the first node together with a request for registration in the distributed ledger.

In step S102, if the tracking information generating unit 2312 determines that the operating state of the storage battery 221 is discharging, it obtains the value of the SOC derived from renewable energy or purchased power and the value of the output power at time n.
Here, the tracking information generation unit 2312 calculates the renewable energy at time n based on the following equation (8).

In addition, the tracking information generating unit 2312 calculates the value of the SOC derived from purchased electricity based on the following formula (9).

Moreover, the tracking information generating unit 2312 calculates the output power based on the following equation (10).

Moreover, the tracking information generating unit 2312 calculates the output power based on the following equation (11).

When the tracking information generating unit 2312 calculates the SOC derived from renewable energy, the SOC derived from purchased power, the output power derived from renewable energy, and the output power derived from purchased power, the registration requesting unit 2313 transmits these as tracking information to the first node together with a command requesting that they be registered in the distributed ledger (step S105). Here, the tracking information generating unit 2312 may transmit information indicating that the storage battery 221 is in a discharging state, the SOC derived from renewable energy, and the SOC derived from purchased power as tracking information.
Here, the registration request unit 2313 may transmit information including the purchased power at time n at the consumer facility 20, the load power at time n, the solar power generation output (PV power) at time n, the charging and discharging power (output power) of the storage battery, and the SOC value of the storage battery (PV-derived SOC, purchased power-derived SOC) as tracking information to the first node together with a request for registration in the distributed ledger.

According to the above-described embodiment, the SOC of the storage battery 221 is calculated as the SOC derived from renewable energy and the SOC derived from purchased power, and is transmitted to the blockchain platform 10 as tracking information. This tracking information is transmitted each time a timing corresponding to the time interval for generating blocks in the blockchain platform 10 arrives. This makes it possible to know whether the power at the time when the SOC of the storage battery increases or decreases (during charging and discharging) is derived from renewable energy or purchased power, and in the case where the managed consumer facility includes a power storage device, it becomes possible to know to what extent the power output from the power storage device is derived from renewable energy. Furthermore, by managing the tracking information on the blockchain platform 10, it becomes possible to store and manage the tracking information as ledger information, making it possible to prove environmental value.

In addition, since blockchain technology is used, tracking information is less likely to be tampered with.
Furthermore, according to the above-described embodiment, it is also possible to manage, as tracking information, a case in which the amount of stored electricity is reduced due to self-discharge in the electricity storage device or a case in which a charge/discharge loss occurs.
In the above-described embodiment, if the consumer facility is a system that does not have a power storage device, the power management device 231 may transmit the origin of the power supplied to the load from the solar power generation output and purchased power to the node as tracking information, and have it written on the blockchain.

In the embodiment described above, as shown in FIG. 4A, even if the power when the SOC of the storage battery increases or decreases (when charging or discharging) includes power derived from renewable energy (PV) or power derived from purchased power, it is possible to determine whether the power is derived from renewable energy (PV) or power derived from purchased power. This has described a case where environmental value can be illuminated even in a system including a storage battery.

Next, as another embodiment, as shown in FIG. 4B , a case will be described in which it is possible to prove environmental value even in the case of a system that includes a storage battery by managing which of multiple types of power sources (including commercial grids, renewable energy (PV-derived, wind power generation), generators, etc.) the power comes from when the SOC of the storage battery increases or decreases (when charging or discharging).
That is, in addition to commercial grids and PV power generation, wind power generation, generators, etc. may also be used as power sources. When a storage battery is charged in a system in which a variety of power sources are combined in this way, if it is not possible to identify which power source the charged storage amount comes from among purchased power, PV, wind power generation, and generators, power source tracking becomes difficult. Therefore, when multiple types of power sources are used in a system having an energy storage device such as a storage battery, a system that enables power source tracking is required.

5 is a schematic block diagram showing the configuration of a power supply tracking system 1 according to another embodiment. In this other embodiment, the same functions as those in the power supply tracking system 1 shown in FIG. 1 are denoted by the same reference numerals, and only the different parts will be described.
In the power source tracking system 1 shown in FIG. 1, the commercial power source 30, the storage battery 221, and the PV panel 211 are connected to the cable 241, and the storage battery 221 can be charged from the commercial power source 30 and the PV panel 211. However, in this other embodiment, in addition to the commercial power source 30, the storage battery 221, and the PV panel 211, other power sources such as a wind power generation device 222 and a generator 225 are connected to the cable 241, and the storage battery 221 can be charged from the commercial power source 30, the PV panel 211, the wind power generation device 222, and the generator 225.

The wind power generation device 222 receives wind power to rotate a windmill, and converts the motive power into electric power using a generator to obtain renewable energy, which is output to the storage battery 221 or the load 202. The measurement device 223 measures the electric power generated by the wind power generation device 222, and outputs the measurement result to the power management device 231A.
The generator 225 outputs the electric power obtained by generating electricity to the storage battery 221 or the load 202. The measurement device 226 measures the electric power generated by the generator 225, and outputs the measurement result to the power management device 231A.

Here, the power sources that can be charged into the storage battery 221 are described as being a commercial power source 30, a PV panel 211, a wind power generation device 222, and a generator 225, but are not limited to these, and the storage battery 221 can be charged from the first through mth power sources m, which can include purchased power, power based on renewable energy, and power obtained from a generator.
For example, the power source for charging the storage battery 221 may be electricity based on a plurality of renewable energies. In this case, the power source may be, for example, the PV panel 211 and the wind power generation device 222.
Also, for example, the power source that charges the storage battery 221 may be power based on one or more renewable energies and power other than one or more renewable energies. In this case, the power based on renewable energy may be a plurality of power sources (the PV panel 211 and the wind power generation device 222), and the power other than the power based on renewable energy may be a single power source (for example, the commercial power source 30). Also, for example, the power based on renewable energy may be a single power source (the PV panel 211), and the power other than the power based on renewable energy may be a plurality of power sources (the commercial power source 30 and two or more generators 225, etc.). Also, for example, the power based on renewable energy may be a plurality of power sources (the plurality of PV panels 211 and the wind power generation device 222), and the power other than the power based on renewable energy may be a plurality of power sources (the commercial power source 30, the plurality of generators 225).
Furthermore, for example, the power source that charges the storage battery 221 may be power other than the power based on the multiple renewable energies. In this case, the power other than the power based on the multiple renewable energies may be the commercial power source 30 and the generator 225.

FIG. 6 is a schematic block diagram illustrating the function of the power management device 231A.
The power management device 231A includes a power information acquisition unit 2311A, a tracking information generation unit 2312A, a registration request unit 2313, and a storage unit 2314. The power information acquisition unit 2311A, the tracking information generation unit 2312A, and the registration request unit 2313 may be configured by a processing unit such as a CPU (Central Processing Unit) or a dedicated electronic circuit. The registration request unit 2313 and the storage unit 2314 have the same functions as the registration request unit 2313 and the storage unit 2314 shown in FIG.

The power information acquisition unit 2311A acquires the battery charge/discharge power amount (positive discharge) [kWh] from time n-1 to n, the battery charge/discharge power amount (positive discharge) [kWh] from power source m from time n-1 to n, the battery SOC value (measured value) [%] at time n, the battery SOC value (calculated value) [%] from power source m at time n, and the SOC measurement value [%] at time n. These variables are as shown in the following (12).

Here, the power information acquisition unit 2311A can obtain the storage battery charge/discharge power amount (positive discharge) [kWh] from time n-1 to time n based on the following formula (13).

In addition, the power information acquisition unit 2311A can calculate the storage battery SOC value (measured value) [%] at time n from the following formula (14).

The power information acquisition unit 2311A obtains the power supplied from the power source m to the storage battery 221 from a measurement device provided on the power source m when the storage battery 221 is being charged, for the amount of battery charge/discharge power (positive discharge) [kWh] derived from the power source m at times n-1 to n. For example, in this example, the power source m is four (m=4), namely, the commercial power source 30, the PV panel 211, the wind power generation device 222, and the generator 225. The power supplied from the commercial power source 30 to the storage battery 221 is obtained from the measurement value of the power meter 201. The power supplied from the PV panel 211 to the storage battery 221 is obtained from the measurement value of the PCS 212. The power supplied from the wind power generation device 222 to the storage battery 221 is obtained from the measurement value of the measurement device 223. The power supplied from the generator 225 to the storage battery 221 is obtained from the measurement value of the measurement device 226.

The power information acquisition unit 2311A obtains the battery SOC value (calculated value) [%] derived from the power source m at time n based on the following formula (15) when the storage battery 221 is being charged. Also, the power information acquisition unit 2311A can obtain the battery SOC value (calculated value) [%] derived from the power source m at time n based on the following formula (15) when the storage battery 221 is being discharged.

Here, the power information acquisition unit 2311A calculates the battery charge/discharge power amount (positive discharge) [kWh] from the power source m at times n-1 to n when the storage battery 221 is discharging based on the following formula (16).

The power information acquisition unit 2311A can also calculate the average instantaneous power of each power source m from time n-1 to n by dividing the battery charge/discharge power amount (positive discharge) [kWh] from the power source m at time n, which is obtained by the above formula (16), by Δt.

このように、電力情報取得部２３１１Ａは、充電及び放電を行っていない状態において、ＳＯＣが変動したことを検出した場合には、このような補正を行うことで、蓄電池２２１が自己放電等により蓄電量が減少した場合や充放電ロスが生じた場合であっても対応可能となる。 Here, in the case of the storage battery 221, when self-discharge or an error in measuring the SOC occurs, the SOC fluctuates even though the storage battery 221 is not being charged or discharged. In this case, the power information acquisition unit 2311A can make a correction based on the following formula (17).

In this way, when the power information acquisition unit 2311A detects that the SOC has fluctuated when neither charging nor discharging is taking place, it performs such a correction, making it possible to respond even when the amount of stored electricity in the storage battery 221 has decreased due to self-discharging, etc., or when charging/discharging losses have occurred.

When charging power to the storage device and discharging power from the storage device to the outside at time n, the tracking information generation unit 2312A calculates the amount of power output from each of the power sources m, the amount of charging and discharging power of the storage device, and the SOC value of the storage battery based on the data obtained from the power information acquisition unit 2311A, and generates tracking information including the amount of power output from each of the power sources m, the amount of charging and discharging power of the storage device, and the SOC value of the storage battery.
This allows the origin of multiple power sources m to be added to the SOC of the power storage device. For example, by using the information included in this tracking information, it is possible to grasp that the current charging rate of the power storage device is 80%, and of the charging rate A%, the charging rate in the power storage device originating from the PV panel 211 is A1%, the charging rate originating from the wind power generation device 222 is A2%, the charging rate originating from the commercial power source 30 is A3%, and the charging rate originating from the generator 225 is A4% (charging rate A=A1+A2+A3+A4). Such tracking information is transmitted every time the timing for transmitting a block to the blockchain platform arrives.

In the above-mentioned power source tracking system 1A, FIG. 7 has been described as an example of power source tracking within a building, but as shown in FIG. 7, it can also be applied to power source tracking for retail electricity. In this case, it is possible to know from which power source m the retailed electricity comes and to what extent.

According to the other embodiments described above, even in a system including an energy storage device, tracking of each of the multiple power sources m becomes possible, making it possible to certify the environmental value of renewable energy.

Next, another embodiment will be described.
In the power source tracking system 1A of FIG. 5, when controlling charging and discharging of a power storage device, the power storage device is charged from an arbitrary power source based on rules set by a retailer, and when discharging from the power storage device, the power storage device is discharged evenly according to the immediately preceding charging state (the ratio of each power source to the total remaining charge). There are other ways of discharging besides evenly discharging. For example, a user may want to preferentially use a specific power source among multiple power sources when charging and discharging. In such a case, by adopting the following configuration, tracking information can be generated even when multiple power storage devices are charged or discharged according to the priority order.

FIG. 8 is a schematic block diagram showing the configuration of a power source tracking system 1B according to another embodiment.
In this figure, in the power source tracking system 1B, a plurality of power sources, a load, and a storage battery are connected to a cable 241B. Although not shown in this figure, the power source tracking system 1B is provided with a power meter, a measuring device, a blockchain platform, a node, and the like in the same manner as in Figures 1 and 5.
The power supplied from each of the multiple power sources to the storage battery 221 is measured by a measuring device, and the measurement results are output to the power management device 231B, in the same manner as in the power source tracking system 1A shown in Fig. 5. This allows the power management device 231B to grasp the power supplied from each power source to the storage battery 221.

Here, the multiple power sources are connected to four power sources, namely, power source 1, power source 2, power source 3, and power source 4, and different types of power sources are used for each of the power sources. For example, a commercial power source, a PV panel, a wind power generation device, a generator, etc. can be used.
The storage battery 221 can be charged using power supplied from the power source 1, the power source 2, the power source 3, and the power source 4 during charging, and supplies power to the load 202B during discharging.
The load 202B operates using power supplied from any one of power source 1, power source 2, power source 3, power source 4, and storage battery 221.

Power management device 231B has the functions of power management device 231 or power management device 231A, and can calculate the amount of charge or discharge from each power source in storage battery 221 when charging or discharging is performed according to the priority order set for multiple power sources.

Definition of variables and constants
Here, each variable is as shown in (18) below.

Definition of variables and constants
The power management device 231B first
ΔC=C ^t -C ^t-Δt
Here, ^Ct is obtained by measuring the remaining capacity of the storage battery 221 using a controller provided in the storage battery 221.
When ΔC is obtained, the power management device 231B performs a calculation according to the obtained value of ΔC.

<When ΔC = 0>
When ΔC=0, this corresponds to a case where there is no change in the remaining charge of the storage battery 221.
In this case, the power management device 231B calculates the remaining battery capacity from the power source n at time t based on the following equation (19).

<When ΔC>0>
When ΔC>0, this corresponds to a case where the remaining charge of the storage battery 221 has increased.
In this case, the power management device 231B determines the charging priority order for the power received from power source 1, power source 2, power source 3, and power source 4. For example, the order of priority may be power source 4, power source 3, power source 2, and power source 1, with power source 4 being given the highest priority. These priorities may be stored in advance in a storage unit of the power management device 231B, and the priorities may be determined based on the priorities that have been read out.
For example, if the order of priority is power supply 4, power supply 3, power supply 2, and power supply 1, then the order can be expressed in terms of variables as shown in (20) below.

Once the priority order has been determined, the power management device 231B performs the following calculations based on the determined priority order.

The tracking information generating unit of the power management device 231B subtracts the capacity when the storage battery is charged with power supplied from the power source with the highest priority from the change in the total remaining capacity of the storage battery 221. Next, the tracking information generating unit subtracts the capacity when the storage battery is charged with power obtained from the power source with the next highest priority from the change in the total remaining capacity after subtraction. This calculation is repeated in order until the power source with the lowest priority is reached. The power supplied from the power source to the storage battery can be obtained from a measuring device.
When the power management device 231B completes the calculation for each power source according to the priority order, ΔC = 0. However, there may be cases where ΔC > 0 due to a loss of received power data, etc. In this case, the power management device 231B allocates the remaining battery capacity from a pre-specified power source (for example, a commercial power source).
This makes it possible to determine how much of the power that has been charged into the storage battery 221 and from which power source.

The tracking information generation unit of the power management device 231B can obtain information indicating how much power was supplied from each power source by calculating the charging power derived from each power source based on the ΔC obtained in this manner.
When charging power to the storage battery 221 at time t, the tracking information generation unit uses this to calculate the amount of power output from each of the power sources n, the amount of power charged and discharged from the storage device, and the SOC value of the storage battery based on the data obtained from the power information acquisition unit, and generates tracking information including the amount of power output from each of the power sources n, the amount of power charged and discharged from the storage battery 221, and the SOC value of the storage battery.
This allows multiple power source origins to be assigned to the SOC of the storage battery 221. Such tracking information is transmitted every time the timing for transmitting a block to the blockchain platform arrives.

<When ΔC<0>
When ΔC<0, this corresponds to a case where the remaining charge of the storage battery 221 has decreased.
In this case, the power management device 231B determines the discharge priority order for the remaining battery powers from power source 1, power source 2, power source 3, and power source 4.
For example, the order of priority may be power source 1, power source 2, power source 3, and power source 4, with the highest priority being given to discharging power charged by power source 1. These priorities may be stored in advance in a storage unit of the power management device 231B, and the priorities may be determined based on the priorities that have been read out.
For example, if the order of priority is power supply 1, power supply 2, power supply 3, and power supply 4, then the order can be expressed using the variables as shown in (22) below.

Once the priority order has been determined, the power management device 231B performs the following calculations based on the determined priority order.

The tracking information generating unit of the power management device 231B subtracts the capacity discharged to the load from the capacity charged from the power source with the highest priority from the change in the total remaining capacity of the storage battery 221, and subtracts the capacity discharged to the load from the capacity charged from the power source with the next highest priority from the change in the total remaining capacity after subtraction, and performs this calculation in order until the power source with the lowest priority is reached. Here, when switching from charging to discharging, the remaining battery capacity from the power source n at time t may be the value calculated immediately before switching from charging to discharging using the above formula (21) during charging.
When the power management device 231B completes the calculation for each power source in accordance with the priority order, ΔC=0 (always 0 due to the calculation specifications).
This makes it possible to determine from which power source the remaining battery power of the power discharged from the storage battery 221 to the load is derived.

The tracking information generation unit of the power management device 231B can obtain information indicating from which power source the charging power was discharged (supplied to the load) by calculating the discharge power originating from each power source based on the ΔC obtained in this manner.
The tracking information generation unit uses this to calculate, when discharging from the storage battery 221 at time t, the amount of power output from each of the power sources n, the amount of charge and discharge power of the storage device (discharge power indicating which power source the charging power originated from which the discharge was made), and the SOC value of the storage battery, and generates tracking information including the amount of power output from each of the power sources n, the amount of charge and discharge power of the storage battery 221 (discharge power indicating which power source the charging power originated from which the discharge was made), and the SOC value of the storage battery.
This allows multiple power source origins to be assigned to the SOC of the storage battery 221. Such tracking information is transmitted every time the timing for transmitting a block to the blockchain platform arrives.

9 and 10 are diagrams showing examples of calculation results of the power management device 231B in this embodiment. Fig. 9 shows the time series of power transition, and Fig. 10 shows the time series of the remaining battery charge. The conditions are charging at 180 kW from 7:00 to 14:00, and discharging at 50 kW from 19:00 to 23:30.
The charging priority order is power source 4 > power source 3 > power source 2 > power source 1 (power source 4 has the highest priority), and the discharging priority order is power source 1 > power source 2 > power source 3 > power source 4 (power source 1 has the highest priority).
10, it can be seen that the remaining battery power increases in the order of c4, c3, and c2 during charging, and that the remaining battery power is consumed first in the order of c1, c2 during discharging.

The power management device 231 in the above-mentioned embodiment may be realized by a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read into a computer system and executed to realize the function. The term "computer system" here includes hardware such as an OS and peripheral devices. The term "computer-readable recording medium" refers to portable media such as flexible disks, optical magnetic disks, ROMs, and CD-ROMs, and storage devices such as hard disks built into a computer system. The term "computer-readable recording medium" may also include a medium that dynamically holds a program for a short period of time, such as a communication line when a program is transmitted via a network such as the Internet or a communication line such as a telephone line, and a medium that holds a program for a certain period of time, such as a volatile memory inside a computer system that is a server or client in such a case. The above-mentioned program may be a program for realizing part of the above-mentioned function, or may be a program that can realize the above-mentioned function in combination with a program already recorded in the computer system, or may be a program that is realized using a programmable logic device such as an FPGA (Field Programmable Gate Array).

The above describes an embodiment of the present invention in detail with reference to the drawings, but the specific configuration is not limited to this embodiment, and includes designs that do not deviate from the gist of the present invention.

1, 1A, 1B...power source tracking system, 10...blockchain platform, 20...customer facility, 30...commercial power source, 40...network, 101, 101a, 101b, 101c, 101d, 101e, 101f...node, 102...network, 201...power meter, 202...load, 203, 223, 226...measuring device, 211...PV panel, 221...storage battery, 222...wind power generation device, 225...generator, 231, 231A, 231B...power management device, 241...cable, 2311, 2311A...power information acquisition unit, 2312, 2312A...tracking information generation unit, 2313...registration request unit, 2314...storage unit

Claims (8)

A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
When the power storage device is charged, the tracking information generation unit
When all energy used to charge the storage device is renewable,
The charging rate derived from renewable energy is calculated based on the following formula (1):
The charging rate derived from the purchased power is calculated based on the following formula (2):
When charging the power storage device with at least purchased power,
The charging rate derived from renewable energy is calculated based on the following formula (3):
The charging rate derived from purchased power is calculated based on the following formula (4).
Power management device.

A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
When discharging from the power storage device, the tracking information generation unit
The charging rate derived from renewable energy is calculated based on the following formula (5):
The charging rate derived from purchased power is calculated based on the following formula (6).
Power management device.

A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
When discharging from the power storage device, the tracking information generation unit
Regarding the output power from the power storage device,
The output power derived from renewable energy is calculated based on the following formula (7):
The output power derived from the purchased power is calculated based on the following formula (8).
Power management device.

A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
the power storage device is capable of being charged from first to m-th power sources m, which may include the purchased power, the power based on the renewable energy, and power obtained from a generator;
When the power storage device is charged, the tracking information generation unit
The charging rate from the power source m at time n is calculated based on the following formula (9).
Power management device.

A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
the power storage device is capable of being charged from first to m-th power sources m, which may include the purchased power, the power based on the renewable energy, and power obtained from a generator;
When discharging from the power storage device, the tracking information generation unit
The charging rate and discharge power from the power source m at time n are calculated based on the following formula (10).
Power management device.

A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
The power storage device can be charged from a plurality of power sources that may include the purchased power, the power based on the renewable energy, and the power obtained from a generator, and the power storage device is charged in an order of priority with respect to which power source the charging is to be performed from;
When the power storage device is charged, the tracking information generation unit
From the change in the total remaining charge of the storage battery, subtract the capacity when the storage battery is charged with power supplied from the power source with the highest priority, and from the change in the total remaining charge after subtraction, subtract the capacity when the storage battery is charged with power obtained from the power source with the next highest priority. This calculation is repeated in order until the power source with the lowest priority is reached.
Generate tracking information based on the results of the calculations.
Power management device. A power management device connected to a blockchain to which a plurality of nodes are connected and to a power storage device of a consumer facility having the power storage device capable of storing purchased power and power based on renewable energy,
a power information acquisition unit that acquires a measurement result of the power generated by the renewable energy and a measurement result of the power output from the power storage device;
When charging the power storage device, based on the measurement result obtained by the power information acquisition unit,
The charging rate of the power storage device is:
A charging rate at which the storage device is charged using renewable energy; and
The charging rate derived from purchased electricity,
A tracking information generating unit that generates tracking information representing the
a registration request unit that transmits the generated tracking information to a first node among the plurality of nodes and requests registration in a distributed ledger;
having
The power storage device is capable of being charged from a plurality of power sources that may include the purchased power, the power based on the renewable energy, and the power obtained from a generator, and the power storage device is configured to discharge the power from a power source in an order of priority;
When charging from the power storage device, the tracking information generation unit
From the change in the total remaining capacity of the storage battery, subtract the capacity discharged to the load from the storage battery capacity charged from the power source with the highest priority, and from the change in the total remaining capacity after subtraction, subtract the capacity discharged to the load from the storage battery capacity charged from the power source with the next highest priority, and repeat this calculation in order until the power source with the lowest priority is reached;
Generate tracking information based on the results of the calculations.
Power management device. 6. The power management device according to claim 4, wherein when the storage device is not being discharged or charged and there is a fluctuation in the charging rate of the storage device, the charging rate is corrected based on the following formula ( 11 ):

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