JP7455587B2 - Environmental value management program - Google Patents

Description

The present invention relates to an environmental value management program, and particularly to an environmental value management program for controlling the operation of a fuel cell unit.

Organizations such as companies have a social responsibility regarding so-called environmental values such as CO ₂ reduction, and how organizations manage environmental values is being considered as a social issue.

In Patent Document 1, as a welfare service, utility usage fees (for example, energy such as gas and electricity) at the homes of multiple members of an organization are billed together with welfare benefits. We provide a system for efficiently billing fees.

The technology of Patent Document 1 calculates the usage amount of utilities in the homes of organization members who use utilities supplied or sold by the first organization at home, and calculates the usage amount of utilities in the homes of organization members based on the determined usage amount. Calculate the usage fee and aggregate the usage fee. Charge data representing the total usage charges of utilities in the homes of a plurality of organization members is created, and based on the charge data, bill data is created to bill the second organization for the total usage charges at once. This provides a utility usage fee billing program that can efficiently bill utility usage fees.

Japanese Patent Application Publication No. 2017-207862

The technology disclosed in Patent Document 1 streamlines the management of utility usage fees for employees belonging to a company. Here, companies use solar power generation or fuel cells attached to buildings or factories, storage batteries that store the electricity generated, and distributed energy generation equipment such as cold generation equipment (hereinafter referred to as distributed power sources). In some cases, utility costs can be reduced by using the following: Similarly, at home, utility costs may be reduced by using distributed power sources installed within the home. However, conventional technology does not provide a mechanism for accounting for the environmental value associated with these reductions in utility costs.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an environmental value management program that can account for the environmental value generated by the activities of an organization.

In order to achieve the above object, the environmental value management program of the present invention provides a first organization's computer, which includes a storage unit storing the utility usage amount related to the usage of each utility in the household, for each of the above, the computer executes a process of calculating the environmental value based on the first energy amount generated by the distributed power source, the first coefficient related to the utility, and the second coefficient related to the distributed power source. It is an environmental value management program.

According to the environmental value management program of the present invention, it is possible to record the environmental value generated by the activities of an organization or a household.

It is a diagram showing an image of environmental value management. FIG. 1 is a block diagram showing the configuration of an environmental value management system according to a first embodiment. FIG. 2 is a block diagram showing the hardware configuration of the environmental value management device. FIG. 3 is a diagram showing an example of utility usage amount, distributed power generation amount, and reverse flow power amount stored in a storage unit. It is a figure which shows an example of the allocation setting of the environmental value of each household stored in a memory|storage part. It is a figure showing an example of environmental value stored in a storage part. 2 is a flowchart showing the flow of environmental value management processing by the environmental value management device according to the first embodiment. FIG. 2 is a block diagram showing the configuration of an environmental value management system according to a second embodiment. FIG. 2 is a diagram showing an example of environmental value due to a reverse flow from businesses to households. It is a flow chart which shows the flow of environmental value management processing by an environmental value management device concerning a 2nd embodiment. FIG. 3 is a diagram illustrating an example of associating backflow environmental values from companies with households.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

First, the background and outline of the embodiments of the present invention will be explained.

The CO ₂ reduction value, ie, the environmental value, of using distributed power sources at home (for example, the use of PV (Photovoltaic)) is currently hardly utilized. On the other hand, companies are investing money and taking measures regarding environmental value.

For example, in the purchase of so-called FIT power sources, the environmental value of the purchased electricity is obtained, but on the other hand, the environmental value of the electricity consumed by households is tied to the household. Additionally, if a company owns the environmental value of an ordinary household, there is a system in which the electricity generated by household PV is used to charge an EV (Electric Vehicle) and discharge it at a store. However, with this system, the amount of discharge at the store cannot be predicted, making it difficult to judge whether the amount of discharge is sufficient for the environmental measures required by the company. In the case of a third-party ownership model, the installation company needs to conclude a power sales contract with the installation site, which is time-consuming. Additionally, if ownership is to be transferred in the case of an existing facility, a contract is also required.

On the other hand, there are services that bill companies for the use of utilities such as electricity and gas at employees' homes in one lump sum, such as for welfare benefits. Here, we would like to not only lower the unit cost of energy consumption for companies and employees, but also provide additional benefits to the companies that use our services.

Therefore, each embodiment of the present invention described below provides a mechanism for managing the environmental value generated by distributed power sources owned by a company or an employee's home. In addition, by incorporating environmental value management into the package services provided by service providers, we will provide a mechanism for accommodating environmental value to companies where employees work through environmental value management. It will also enable companies to utilize environmental value as part of their welfare services for their employees.

FIG. 1 is a diagram showing an image of environmental value management. In FIG. 1, a service provider A, a company B, and each household of an employee belonging to the company B are shown.

Service provider A is, for example, a company that owns a gas refinery, a power plant, and the like. Service provider A is a company that supplies household gas, such as city gas or LPG, and electricity as household energy. Service provider A is an example of the first organization. Note that the first organization may be a company whose main business is providing package services, or a company that provides package services on behalf of others.

Company B is a company that has employees who use energy (gas or electricity) supplied by service provider A. Employees of company B use energy provided by service provider A in their homes, either single-family homes or apartment complexes. Company B is an example of the second organization. The employee's home is an example of the homes of a plurality of organization members belonging to the second organization.

Here, the premise is the package service of Patent Document 1. Patent Document 1 discloses a package service called "Energy Welfare Pack." Furthermore, as a mechanism for package services, a mechanism for billing utility usage fees is shown. Also in this embodiment, service provider A uses the same package service and utility usage fee billing mechanism as in Patent Document 1. This embodiment is characterized in that environmental value management is incorporated into the package service. Therefore, the following explanation will focus on the point that the package service functions as an environmental value management system.

As shown in FIG. 1, the amount of grid power used in each household of employees of company B, the amount of distributed power generation by PV power generation (or the amount of demanded power), and the amount of reverse flow power are measured. Distributed power sources also include power generation using gas generators such as Ene-Farm. For gas power generation, measure the amount of gas used, the amount of gas generated (or the amount of electricity demanded), and the amount of grid power used. The environmental value generated by each household's distributed power source can be determined by the amount of power generated by the distributed power source. Additionally, in cases where a company also has distributed power sources, the environmental value generated by the company's distributed power sources can be ascertained. Note that the environmental value generated by each household's distributed power source is an example of the first environmental value generated by the household. The environmental value generated by a company's distributed power source is an example of second environmental value or third environmental value.

In a package service incorporating environmental value management, for example, the above-mentioned values for each household of each organization member and the total value for the entire household are listed. The amount to be collected from each household is listed in accordance with the coefficient (for example, unit price) of each item. The amount to be billed to companies is determined based on the total amount of grid electricity and gas usage. Add up the environmental value from PV power generation, the environmental value from Ene-Farm, etc., and notify Company B. In some cases, environmental value is converted into a different environmental value (for example, J credits) and provided.

The configuration and operation of each embodiment of the environmental value management system for managing the above-mentioned environmental values will be described below.

(First embodiment)
A first embodiment of the present invention will be described. In the first embodiment of the present invention, a case will be described using as an example a case where a system for managing environmental value generated by distributed power sources owned by employees' households is provided.

FIG. 2 is a block diagram showing the configuration of the environmental value management system 100 of the first embodiment. As shown in FIG. 2, in the environmental value management system 100 according to the first embodiment, an environmental value management device 110, a home 120, and a company 130 are connected via a network N. In the following, an example will be explained in which a company B uses a package service provided by a service provider A, and the environmental value and utility usage fees generated in each household of company B's employees are collectively managed. Company 130 corresponds to company B.

The environmental value management device 110, the household 120, and the company 130 each transmit and receive necessary data via their respective communication units (communication unit 111, communication unit 122, or communication unit 132).

After showing the hardware configuration of the environmental value management device 110, each function will be explained below.

FIG. 3 is a block diagram showing the hardware configuration of the environmental value management device 110. As shown in FIG. 3, the environmental value management device 110 includes a CPU (Central Processing Unit) 11, a ROM (Read Only Memory) 12, a RAM (Random Access Memory) 13, a storage 14, an input unit 15, a display unit 16, and a communication unit. It has an interface (I/F) 17. Each configuration is communicably connected to each other via a bus 19.

The CPU 11 is a central processing unit that executes various programs and controls various parts. That is, the CPU 11 reads a program from the ROM 12 or the storage 14 and executes the program using the RAM 13 as a work area. The CPU 11 controls each of the above components and performs various arithmetic operations according to programs stored in the ROM 12 or the storage 14. In this embodiment, the ROM 12 or the storage 14 stores an environmental value management program.

The ROM 12 stores various programs and data. The RAM 13 temporarily stores programs or data as a work area. The storage 14 is constituted by a storage device such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive), and stores various programs including an operating system and various data.

The input unit 15 includes a pointing device such as a mouse, a keyboard, a voice recognition unit, etc., and is used to perform various inputs.

The display unit 16 is, for example, a liquid crystal display, and displays various information. The display section 16 may employ a touch panel system and function as the input section 15.

The communication interface 17 is an interface for communicating with other devices such as a terminal, and uses, for example, standards such as Ethernet (registered trademark), FDDI, and Wi-Fi (registered trademark).

The above is the hardware configuration of the environmental value management device 110.

Household 120 is the home of an employee of company B who uses energy supplied by service provider A at home. The home 120 includes a home management terminal 121 for a company employee and a distributed power source 124 . The home management terminal 121 has an input/output interface (not shown) for making settings using the setting unit 123. The home management terminal 121 includes a communication section 122 and a setting section 123. In the household 120, the amount of utility usage fees, the amount of distributed power generation generated by using the distributed power source 124, and the amount of reverse flow power are measured in advance. The utility usage amount includes the above-mentioned grid power usage amount, gas usage amount, and the like. The communication unit 122 transmits the utility usage amount of the household 120 to the environmental value management device 110. Further, the communication unit 122 transmits the amount of utility usage in the household 120 and the amount of distributed power generation and reverse power generated in the household 120 to the environmental value management device 110. In the environmental value management device 110, the storage unit 116 stores the utility usage of each household, the distributed power generation amount, and the reverse flow power amount. FIG. 4 is a diagram illustrating an example of the amount of utility usage, the amount of distributed power generation, and the amount of reverse flow power stored in the storage unit 116. As shown in FIG. 4, the amount of utility usage, the amount of distributed power generation, and the amount of reverse flow power are recorded for company B for each employee ID associated with each household. As an example of the utility usage amount, the amount of electricity (referring to grid power) used (kWh) and the amount of gas used (m ³ ) are recorded. Since the calculation of the utility usage amount is similar to that of the usage calculation unit of Patent Document 1, detailed explanation will be omitted.

The setting unit 123 of the household management terminal 121 performs settings regarding the allocation of environmental values in the household 120. For example, it is possible to set whether to allocate the environmental value (first environmental value) due to the amount of power generated by the distributed power source 124 to the company B or the household 120. Settings related to the allocation of environmental values set in each household are set by the setting unit 123 of the household 120 and transmitted to the environmental value management device 110. In the environmental value management device 110, this is stored in the storage unit 116 as the environmental value allocation setting for each household. FIG. 5 is a diagram showing an example of the environmental value allocation settings for each household stored in the storage unit 116. As shown in FIG. 5, in this setting, for company B, a company or a home is assigned to each employee ID associated with each home. Note that instead of uniformly allocating companies or households, the distribution of allocations between companies and households may be determined.

The company 130 is a company B that uses a package service provided by a service provider A. In the package service, grid power is supplied to each home of the employees of the company 130. The company 130 is equipped with a company management terminal 131. The corporate management terminal 131 has an input/output interface (not shown) for setting by the setting unit 133. The setting unit 133 of the corporate management terminal 131 is a functional unit that performs various settings related to the use of the package service and views the settings. Settings related to environmental value include, for example, a discount rate for utility usage fees based on the allocation of environmental value. The details of the settings may be determined as appropriate depending on the system, so a specific explanation will be omitted.

As shown in FIG. 2, the environmental value management device 110 includes a communication section 111, a usage fee calculation section 112, a value calculation section 113, a bill creation section 114, and a storage section 116.

The usage fee calculation unit 112 calculates a provisional utility usage fee for each household associated with the employee ID. Calculation of the provisional utility usage fee is similar to the usage fee calculation unit described in Patent Document 1. The usage fee calculation unit 112 stores the usage fee based on the calculated amount of energy used by the household 120 and the provisional usage amount in the storage unit 116.

For each household associated with the employee ID, the value calculation unit 113 calculates the distributed power generation amount and reverse flow power amount of the household, the first coefficient related to the utility, and the second coefficient related to the distributed power source. Based on this, the environmental value generated by each distributed power source in the household is calculated. Note that the environmental value calculated here is an example of the first environmental value. Furthermore, the amount of power generated by the distributed power source and the amount of reverse flow power are examples of the first amount of energy.

The calculation of environmental value is based on the following formula (1).

Environmental value = Backflow electricity amount × {(CO ₂ emission coefficient of grid electricity) - (CO ₂ emission coefficient of distributed power generation)}
...(1)

Any predetermined values may be used as the CO ₂ emission coefficient of the grid power and the CO ₂ emission coefficient of the distributed power source. The CO ₂ emission coefficient of grid power is an example of a first coefficient related to utilities, and in this embodiment, it is a coefficient determined for household grid power. The CO ₂ emission coefficient of the distributed power source is an example of a second coefficient related to the distributed power source, and in this embodiment, it is a coefficient determined for the home distributed power source. Each of the coefficients may have a predetermined value, or may be changed depending on the amount of household grid power used and the amount of power generated by the distributed power source. It may also be calculated from the amount of gas used. Although the environmental value calculated by formula (1) means the amount of CO ₂ reduction, the environmental value may be calculated using other energy amounts as an index. Note that the environmental value may be calculated by replacing the reverse flow power amount with the distributed power generation amount as shown in equation (2) below.

Environmental value = Distributed power generation amount × {(CO ₂ emission coefficient of grid power) - (CO ₂ emission coefficient of distributed power generation)}
...(2)

Further, the environmental value may be calculated by combining the above equations (1) and (2) and determining design matters such as ratios.

For example, in the case of a gas generator, the CO2 emission coefficient of a distributed power source can be calculated as shown in equation (3) below.

CO2 emission coefficient of distributed power supply = ( _CO2 emission coefficient of gas x amount of gas used) / Distributed power generation amount
...(3)

FIG. 6 is a diagram showing an example of environmental values stored in the storage unit 116. As shown in FIG. 6, the environmental value is calculated, for example, for each company, each month, and each employee ID associated with each household, and is stored in the storage unit 116. Furthermore, environmental value is allocated to companies or households according to the environmental value allocation settings.

The bill creation unit 114 calculates the utility usage fee for each household associated with the employee ID by including the environmental value in the provisional utility usage fee in accordance with the environmental value assignment. For example, for a household that has assigned an environmental value to a company, the utility usage fee is calculated by subtracting a predetermined fee for the environmental value. The bill creation unit 114 creates bill data to be billed all at once to company B based on the calculated utility usage fees for each household. Utility usage charges calculated for each household of employees of company B are totaled and created as bill data. The bill creation unit 114 requests company B for the created bill data. Note that the creation of bill data, billing processing, etc. may be performed using the same method as in Patent Document 1, and the details will be omitted here.

Note that instead of deducting a predetermined fee for environmental value, the billing unit 114 may provide incentives such as points to each household according to the environmental value of the household. Furthermore, it is not necessary to provide environmental value itself to households without providing incentives such as fees or points.

Next, the operation of the environmental value management device 110 of the environmental value management system 100 according to the first embodiment will be described.

FIG. 7 is a flowchart showing the flow of environmental value management processing by the environmental value management device 110 according to the first embodiment. The environmental value management process is performed by the CPU 11 reading the environmental value management program from the ROM 12 or the storage 14, loading it onto the RAM 13, and executing it. In the environmental value management process, the CPU 11 executes the process as each part of the environmental value management device 110. Note that the storage unit 116 stores in advance the amount of utility usage, the amount of distributed power generation, and the amount of reverse flow power to be calculated. Furthermore, the storage unit 116 stores environmental value allocation settings for each household.

In step S100, the usage fee calculation unit 112 acquires the utility usage amount of each household associated with the employee ID from the storage unit 116.

In step S102, the usage fee calculation unit 112 calculates a provisional utility usage fee for each household associated with the employee ID, based on the utility usage amount of the employee ID.

In step S104, the value calculation unit 113 acquires the distributed power generation amount and the reverse power amount of each household associated with the employee ID from the storage unit 116.

In step S106, the bill creation unit 114 acquires the environmental value allocation setting for each household associated with the employee ID from the storage unit 116.

In step S108, the value calculation unit 113 calculates, for each household associated with the employee ID, the distributed power generation amount and reverse flow power amount of the household, the first coefficient related to the utility, and the first coefficient related to the distributed power source. The environmental value (first environmental value) is calculated based on at least one of the above equations (1) and (2) using the two coefficients.

In step S110, the value calculation unit 113 allocates the calculated environmental value to a company or household according to the allocation setting and stores it in the storage unit 116.

In step S112, the bill creation unit 114 calculates the utility usage fee by including the environmental value in the provisional utility usage fee for each household associated with the employee ID, according to the environmental value allocation setting.

In step S114, the bill creation unit 114 creates bill data to be collectively billed to company B based on the calculated utility usage fees for each household.

As explained above, according to the environmental value management system 100 according to the first embodiment, it is possible to account for the environmental value generated by the activities of the organization.

Furthermore, by calculating the environmental value using the amount of power generated by the distributed power sources in the home and the amount of reverse flow power, it is possible to account for the environmental value of the home or business that is generated by the use of the distributed power sources in each home of an organization member. In addition, by predetermining the environmental value allocation setting, it is possible to arbitrarily set whether the environmental value of each household of an organization member, generated through the use of distributed power sources, should be returned to the organization or retained at home.

(Second embodiment)
Next, a second embodiment of the present invention will be described. In the first embodiment, the management of the environmental value generated by the distributed power sources of each household was described, but in the second embodiment, a case will be described in which the environmental value generated by the distributed power sources of a company is managed. Note that the same parts as in the first embodiment are given the same reference numerals, and detailed explanation thereof will be omitted.

Here, we will outline the assumptions and management assumed regarding the environmental value generated by companies' distributed power sources.

In some cases, companies have distributed power sources in their buildings or factories that generate electricity using renewable energy such as sunlight or gas. However, the reality is that companies' distributed power sources cannot be used effectively when the company's power load is low. In such a case, it may be possible to utilize a self-consignment system or other means to exchange surplus electricity within the group companies, but in inter-company exchanges, since the power load patterns are similar, the power needs and distributed power sources may differ. There is a possibility that the amount of power generated by the two companies does not match. On the other hand, households have electricity needs from evening to night, which is generally different from the electricity load pattern of businesses. However, when supplying electricity to an unspecified number of households, it becomes expensive to manage the interchange of electricity. Furthermore, the environmental value created by saving energy at home is not utilized for anything other than the financial benefit of reducing utility costs.

Therefore, in the present embodiment, a system is adopted in which distributed power sources owned by a company are provided to the homes of employees of the company. Flexibility and management methods include integrated management through welfare services, etc. In this case, companies are given environmental value that contributes to reducing environmental impact through the use of distributed power sources.

As a management method, for example, a method of managing the amount of reverse power supplied to each employee's home by a company's distributed power source is used. The amount of electricity in the homes of the employees of the supplying company is measured and understood in advance for each predetermined period and time. It also measures the amount of electricity generated by the company's distributed power sources on an hourly basis. At this time, the distributed power sources are controlled so that the reverse flow power amount is less than the household power amount. At this time, if the management of the reverse power amount is to be unified, a predetermined value may be used. The predetermined value is, for example, 100W per household. Electricity shortages for households can be covered by grid electricity. Additionally, if the power is reversed to a predetermined value, there is a possibility that the company will run out of power, so it will be covered by storage batteries or other distributed power sources. Household electricity charges (grid usage, reverse flow electricity transmission costs, renewable energy surcharges, etc.) will be billed to the company in a lump sum. Additionally, utility charges for businesses or households may also be billed in one lump sum.

FIG. 8 is a block diagram showing the configuration of an environmental value management system 200 according to the second embodiment. Regarding the configuration, only the differences from the first embodiment will be described. The company 130 includes a setting section 233 and a distributed power source 234. The environmental value management device 210 includes a distributed power supply control section 217 and a value calculation section 213.

The setting unit 233 of the company 130 sets the amount of distributed power source power generated by the distributed power source 234 of the company B. The distributed power source power amount may be set arbitrarily for each date and time. The distributed power source power amount is transmitted from the communication unit 132 to the environmental value management device 210. In the environmental value management device 210, the distributed power supply power amount set for company B is stored in the storage unit 116. To set the distributed power generation amount, for example, the distributed power generation amount may be determined for each day of the week for company B.

The storage unit 116 of the environmental value management device 210 stores the estimated amount of power consumption for each time period for the homes of employees of the company. The estimated amount of power consumption may be obtained by measuring the amount of power consumed by each time period of each home of the company's employees in advance to obtain an estimated value. Further, for example, the estimated power consumption amount may be determined by the distributed power source control unit 217 by learning and estimating the amount in advance using a model using a method such as machine learning. Additionally, the model may be trained using information such as days of the week and seasons.

The distributed power source control unit 217 calculates the distributed power generation amount and reverse power generation amount for each time period based on the set distributed power source power amount and the estimated power consumption for each time period, which are stored in the storage unit 116. The power amount is calculated and the distributed power source 234 is controlled.

The value calculation unit 213 calculates the value of the company based on the above equation (1) using the amount of reverse flow electricity from the company to the home, the first coefficient related to the utility, and the second coefficient related to the distributed power source. Calculate the environmental value attributed to distributed power sources. Note that the environmental value calculated here is an example of the second environmental value. Note that, similarly to the first embodiment, the first environmental value is also calculated.

The amount of reverse flow power from a company to a home is an example of the second reverse flow power amount. In this embodiment, the reverse power amount is the reverse flow power amount from a company to a home. In this embodiment, the first coefficient related to the utility is a coefficient determined for the company's grid power. In this embodiment, the second coefficient related to distributed power sources is a coefficient determined for corporate distributed power sources. The value calculation unit 213 stores the calculated environmental value generated by the company's distributed power source in the storage unit 116 in association with the company. FIG. 9 is a diagram showing an example of environmental value due to reverse flow from businesses to households. As shown in FIG. 9, for example, the environmental value due to the reverse flow from businesses to households on a monthly basis is stored.

Next, the operation of the environmental value management device 210 of the environmental value management system 200 according to the second embodiment will be described.

FIG. 10 is a flowchart showing the flow of environmental value management processing by the environmental value management device 210 according to the second embodiment. In the second embodiment, the distributed power source control unit 210 calculates the distributed power generation amount and the reverse power amount for each time period in advance, and controls the distributed power source 234.

In step S200, the value calculation unit 213 acquires the amount of reverse power from the company to the home from the storage unit 116.

In step S202, the value calculation unit 113 calculates, for each household associated with the employee ID, the amount of reverse power to the household, the first coefficient related to the utility, and the second coefficient related to the distributed power source. The environmental value (second environmental value) is calculated based on the formula (1) used above.

In step S204, the value calculation unit 113 stores the environmental value calculated in step S202 in the storage unit 116 by associating the environmental value with the company.

As explained above, according to the environmental value management system 200 according to the second embodiment, it is possible to account for the environmental value generated by the activities of the organization.

(Modified example)
Modifications of each embodiment will be described.

For example, in each embodiment, a case has been described in which provisional usage fees and billing data are created, but the present invention is not limited to this, and only environmental value may be calculated and stored.

Furthermore, for example, environmental value is not limited to being allocated to businesses or households according to allocation settings determined for each household, but may be set in advance to be uniformly allocated to businesses or households. You can leave it there.

Furthermore, for example, a management system may be used in which service provider A trades only environmental value generated by company B or households without supplying utilities such as electricity and gas to households.

Furthermore, for example, in the second embodiment, the environmental value (first environmental value) that is said to be generated by the distributed power sources of households and the environmental value (second environmental value) that is said to be generated by the distributed power sources of companies are calculated. I explained the case. However, the present invention is not limited to this, and only the second environmental value may be calculated without calculating the first environmental value.

Furthermore, for example, in the second embodiment, a case has been described in which the environmental value (second environmental value) that is said to have been generated by a company's distributed power source is associated with a company, assuming that it is due to a reverse flow from the company to the home. However, it is not limited to this. For example, households use electricity that is reversed from businesses. Therefore, it can also be seen as environmental value generated in households that have been reversed by companies. In this case, the environmental value may be associated with a home. In this way, it is assumed that environmental value is generated by the amount of reverse flow electricity generated by a company, and the environmental value is associated with the household. In this case, the storage unit 118 stores in advance settings regarding the allocation of the second environmental value for each household. When assigning the second environmental value to company B for each household according to the settings, company B and the second environmental value are stored in association with each other. Furthermore, when assigning the second environmental value to a household, the household and the second environmental value are stored in the storage unit 118 in association with each other. In this way, the allocation for the second environmental value may be set. In such a case, when allocating the second environmental value to a household, the proportion of the total environmental value of the company in the second embodiment above that corresponds to the amount of backflow electricity each household uses from the company is calculated. It can be assigned as a secondary environmental value. FIG. 11 is a diagram illustrating an example of associating backflow environmental value from companies with households. As shown in FIG. 11, the amount of reverse flow power to each household may be added and managed. In this way, the environmental value that is said to have been generated by each household is calculated using the company's reverse flow power amount as the reverse flow power amount, and the home and the environmental value are associated and stored in the storage unit 116. It's okay.

Note that the present invention is not limited to the environmental value related to the amount of electricity generated by the distributed power source described above. For example, any environmental value that can be imparted by other energy generation targets may be used, such as environmental value related to the calorific value of cold and hot heat (air conditioning, hot and cold water, etc.), and environmental value related to the production and use of agricultural products. The other energy generation target is an example of a predetermined energy generation target other than the distributed power source. Further, the amount of energy generated from the other energy generation target is an example of the second amount of energy.

Note that the present invention is not limited to the embodiments described above, and various modifications and applications are possible without departing from the gist of the present invention.

100, 200 Environmental value management system 110, 210 Environmental value management device 111, 122, 132 Communication section 112 Usage fee calculation section 113, 213 Value calculation section 114 Bill creation section 116 Storage section 120 Home 121 Home management terminal 123, 133, 233 Setting units 124, 234 Distributed power supply 130 Company 131 Corporate management terminal 217 Distributed power supply control unit

Claims (9)

A computer of a first organization that includes a storage unit that stores utility usage amounts related to the usage of utilities in each household;
For each of the households, for the first energy amount, based on the first energy amount generated by the distributed power source, the first coefficient related to the utility, and the second coefficient related to the distributed power source, Calculating the environmental value by a calculation process of multiplying the value obtained by subtracting the second coefficient from the first coefficient ,
The home is a home of a plurality of organization members belonging to the second organization,
Settings for allocation and distribution of the environmental value set for each household by each predetermined management terminal corresponding to each of the households, to a second organization or household for each ID associated with the household. allocating the environmental value to a second organization or household according to settings regarding allocation and distribution of the environmental value;
An environmental value management program that causes the computer to execute processing. Regarding the environmental value, the first energy amount generated by a distributed power source installed in at least one of each of the second organization and the home, a first coefficient related to the utility, and a first coefficient related to the distributed power source 2. The environmental value management program according to claim 1, which causes the computer to calculate the environmental value generated in each of the second organization or the household by the calculation process based on the second coefficient. calculating a provisional utility usage fee for each of the households according to the amount of utility usage;
Claim: The computer is configured to calculate a utility usage fee by including the environmental value in the provisional utility usage fee, and to create billing data for billing the second organization at once for the utility usage fees of each of the households. The environmental value management program described in 2. Replacing the first energy amount with a second energy amount generated from a predetermined energy generation target other than a distributed power source,
in calculating the environmental value, causing the computer to use the second energy amount generated from the predetermined energy generating object to calculate the environmental value generated by the energy generating object through the calculation process ; The environmental value management program according to claim 2 or 3, wherein the environmental value management program is stored in the storage unit as the environmental value generated by the energy generating object. In the case where the distributed power source is installed in each of the homes,
The first amount of energy is the amount of distributed power generated by the distributed power source of each of the homes, or the amount of reverse power generated by the distributed power sources of each of the homes that is reversed to the second organization. As the tidal power amount,
In calculating the environmental value , the computer uses the first amount of energy, which is at least one of the distributed power generation amount and the first reverse power amount, to calculate the amount of energy that is said to be generated by each of the households. 4. The environmental value management program according to claim 2, wherein the environmental value management program causes the computer to calculate the first environmental value by the calculation process and store it in the storage unit as the first environmental value generated by the household. The storage unit stores in advance settings regarding allocation of the first environmental value for each of the households,
When allocating the first environmental value to the second organization for each of the households according to the settings, the computer stores the second organization and the first environmental value in association with each other; 6. The environmental value management program according to claim 5, wherein when allocating one environmental value to the household, the household and the first environmental value are stored in association with each other in the storage unit . When the distributed power source is installed in the second organization,
to the computer;
Calculate a second reverse power amount that is a reverse flow power amount flowing backward from the distributed power source of the second organization to each of the homes;
In the calculation of the environmental value, a second environmental value generated by the distributed power source of the second organization is calculated by the calculation process using the second reverse flow power amount as the reverse flow power amount, The environmental value management program according to any one of claims 2 to 6, wherein the environmental value management program is stored in the storage unit as the second environmental value generated by a second organization. The storage unit stores in advance settings regarding allocation of the second environmental value for each of the households,
When allocating the second environmental value to the second organization for each of the households according to the settings, the computer stores the second organization and the second environmental value in association with each other; 8. The environmental value management program according to claim 7, wherein when assigning the second environmental value to the household, the household and the second environmental value are stored in the storage unit in association with each other . The environmental value management program according to any one of claims 1 to 8 , which causes the computer to give an incentive to each of the households according to the environmental value.