JP2024036275A - Management device, management method and management program - Google Patents

Abstract

[Issue] Make it easier to achieve GHG emissions targets. The present management device is a management device for managing GHG emissions, and includes an emission calculation unit 132 that calculates the GHG emissions, a setting unit 131 that sets a target value of the GHG emissions, The required reduction amount calculation unit 133 calculates the required reduction amount of GHG emissions necessary to achieve the target value of GHG emissions. [Selection diagram] Figure 1

Description

The present disclosure relates to a management device, a management method, and a management program for managing GHG (Greenhouse Gas) emissions.

In recent years, the problem of climate change has arisen due to large amounts of GHG such as carbon dioxide being emitted. To solve this problem, it is necessary to reduce GHG emissions. Patent Document 1 discloses a technique for calculating the amount of carbon dioxide emitted when a communication network is operated.

Japanese Patent Application Publication No. 2013-164646

A management device according to an embodiment of the present disclosure is a management device for managing GHG emissions, and includes an acquisition unit that acquires the GHG emissions, and a setting unit that sets a target value for the GHG emissions. , a required reduction amount calculation unit that calculates a required reduction amount of the GHG emissions necessary to achieve the target value.

In addition, when the target value of GHG emissions is the target value of the GHG emissions beyond the present, the required reduction amount calculation unit offsets the required reduction amount by at least one of the required reduction amount and the required activity reduction amount. It may be calculated as one.

Further, the required reduction amount calculation unit may calculate the required reduction amount as an offset required amount when the target value of the GHG emission amount is a past or present target value of the GHG emission amount.

Furthermore, the apparatus may further include a display section that displays the calculation result of the required reduction amount calculation section.

The invention may further include a scenario registration unit in which scenarios including predictions for future climate change are registered, and the setting unit may set the target value based on the scenario registered in the scenario registration unit. .

Further, a plurality of the scenarios are registered in the scenario registration unit, and the setting unit selects one or more of the scenarios related to the organization from among the plurality of scenarios, and selects the selected scenario. One or more of the target values may be set based on the following.

Further, a plurality of the scenarios may be registered in the scenario registration section, and the setting section may cause the display section to display the target value for the organization for each of the plurality of scenarios.

Also, a first selection and proposal unit that proposes and selects investment destinations that can reduce GHG emissions, and a second selection and proposal unit that selects and proposes business partners that can trade environmental value in order to achieve the required reduction amount. , and a third selection unit that selects a business partner on the supply chain in order to achieve the required reduction amount.

Furthermore, the apparatus may further include a carbon price calculation unit that calculates a carbon price for the GHG emissions.

Further, a management method according to another embodiment of the present disclosure is a management method for managing GHG emissions, which includes a step in which a server device sets a target value for the GHG emissions; and calculating a required reduction amount of the GHG emissions necessary to achieve the target value.

Further, a management program according to another embodiment of the present disclosure causes a computer to execute the management method.

FIG. 1 is a block diagram showing the configuration of a management system according to a first embodiment. FIG. 2 is a conceptual diagram showing an example of an investment destination DB according to the first embodiment. 1 is a flowchart showing the overall operation of the management system according to the first embodiment. 7 is a flowchart showing the operation of the first process of the management system according to the first embodiment. The conceptual diagram which shows an example of supply chain customer DB based on the modification of 1st Embodiment. FIG. 7 is a conceptual diagram showing an example of a customer DB according to a second embodiment. 7 is a flowchart showing the operation of the management system according to the second embodiment.

Hereinafter, embodiments of the present disclosure will be described in detail based on the drawings. The following description of preferred embodiments is merely exemplary in nature and is not intended to limit the invention, its applications, or its uses.

A management device, a management method, and a management program according to the present disclosure are realized as part or all of the management system according to the present embodiment.

Further, the management system according to the present embodiment is used by various organizations such as companies, groups, and local governments to achieve various GHG emission reduction targets for each organization, product, project, etc.

(First embodiment)
FIG. 1 is a block diagram showing the configuration of a management system according to the first embodiment. As shown in FIG. 1, the management system includes a server device 1. As shown in FIG. The server device 1 is configured to be able to communicate with the operating terminal 2 via the communication network N.

The operation terminal 2 (reception section) is a PC, a smartphone, or the like, and is a terminal operated by a user (an employee of an organization, a user, etc.). The operation terminal 2 includes a display section 21 and an operation section 22. The display unit 21 is composed of a monitor or the like, and displays images to the user in accordance with instructions from the control unit of the operating terminal 2. The operation unit 22 includes input devices such as a keyboard and a mouse, and accepts operations from the user. Furthermore, a management program is installed in the storage section of the operation terminal 2 in advance. The control section of the operating terminal 2 operates each section of the operating terminal 2 according to the management program.

As will be described in detail later, the operating terminal 2 receives an operation from the user for setting a target value of GHG emissions. Specifically, the operating terminal 2 accepts a scenario selection from the user in order to set a target value for GHG emissions. Note that the target value of GHG emissions can be set without receiving a scenario selection from the user.

As mentioned above, in recent years, large amounts of GHG such as carbon dioxide have been emitted, resulting in the problem of climate change. In order to take measures to prevent, mitigate, and adapt to climate change, governments and international organizations are requesting organizations (users) to reduce their GHG emissions. For example, SBTi (Science-Based Targets Initiative), CDP (Cisco Discovery Protocol), RE100, TCFD are used as frameworks for reducing GHG emissions, calculating and reporting GHG emissions, and disclosing climate change-related information. (Task Force on Climate-related Financial Disclosures), GHG Protocol, etc. In these efforts, GHG emissions targets are set for organizational units, product units, project units, etc., as well as various standards and rules, etc., to minimize the effects of climate change. In this embodiment, it is assumed that the organization sets a target value for GHG emissions according to a TCFD scenario analysis. TCFD scenario analysis envisions and analyzes scenarios of how climate change and long-term policy trends to respond to it will change the business environment, and how such changes will impact an organization's business strategy. The purpose of this study is to consider whether it will have a significant impact. For example, scenarios used for TCFD scenario analysis include a plurality of scenarios (2°C increase scenario, 4°C increase scenario, etc.) depending on the predicted increase in average temperature. In a TCFD scenario analysis, an organization sets goals and indicators for climate-related risks and opportunities in each of these multiple scenarios. Note that the target value of GHG emissions can be set without receiving a scenario selection from the user. In the present embodiment, the operation terminal 2 receives a selection from the user regarding which scenario among the TCFD scenario analyzes to follow to set the target value of GHG emissions.

The operation terminal 2 transmits information indicating the operation input received from the user through the operation unit 22 to the server device 1 .

(About the configuration of server device 1)
As shown in FIG. 1, the server device 1 includes a communication section 11, a storage section 12, and a control section 13.

The communication unit 11 is composed of, for example, an electric circuit, and communicates with the operation terminal 2 via the communication network N.

The storage unit 12 includes ROM (Read Only Memory), RAM (Random Access Memory), HD
It is a storage medium composed of a D (Hard Disk Drive), an SSD (Solid State Drive), and the like. The storage unit 12 stores various programs executed by the control unit 13.

Furthermore, the storage unit 12 (scenario registration unit) includes various databases. Specifically, the storage unit 12 stores a scenario DB and an investment destination DB.

The scenario DB is a scenario showing predictions for future climate change, and is a database used by the user to select a scenario for use in TCFD scenario analysis and the like. Specifically, multiple scenarios used in TCFD scenario analysis (transition scenarios such as IEA NZE 2050, IEA B2DS, IEA 2DS, IEA 450, IEA SDS, IEA APS, IEA STEPS, IEA CPS, and RCP 1.9, RCP 2.6 , RCP 3.4, RCP 4.5, RCP 6.0, RCP 7.0, RCP 8.5, etc. (hereinafter referred to as "2℃ increase scenario, 4℃ increase scenario" etc. for convenience) are stored (registered).

The investment destination DB is a database used by the user to select an investment destination (see FIG. 2). Specifically, the investee DB contains the investee name (investment target), asset class, value indicating the user's contribution in each asset class such as investment price, and the denominator used to calculate the GHG emissions of each asset class. , the amount of GHG emissions, the amount of GHG emissions in Scope 3 Category 15 of the GHG Protocol, etc. The investee name (investment target) is data indicating the name of an organization (company name or project name) in which the organization can invest. The asset class is data indicating to which class the corresponding investment target falls, among the asset classes defined in PCAF, which will be described later. For example, in FIG. 2, investment price (A) is data indicating the price when investing in the corresponding investment target. The denominator (B) is data indicating corporate value such as the market capitalization of the investment target. Emission amount (C) is data indicating the GHG emission amount of the corresponding investment target. Emissions in Scope 3 Category 15 of the GHG Protocol are data indicating the amount of GHG emissions when the investment price is invested in the corresponding investment target. Note that the emissions in Scope 3 Category 15 of the GHG Protocol are calculated by A×C÷B.

Scope 3 Category 15 "Investments" of the GHG Protocol stipulates that companies should calculate and report their contribution to the GHG emissions of investees. The standards for calculating GHG emissions from investments mainly for financial institutions are established by the Partnership for Carbon Accounting Financials (PCAF). The standard stipulates the calculation of GHG emissions for six asset classes: listed stocks and corporate bonds, business loans and unlisted stocks, project finance, commercial real estate, mortgage loans, and auto loans. Although this embodiment mainly assumes investment in projects, investment in other asset classes may also be used. Therefore, for example, by changing the investment destination from the current investment destination to an investment destination with low GHG emissions, the investment source's Scope 3 Category 15 GHG emissions will also be reduced.

The control unit 13 is composed of, for example, a microcomputer including a CPU (Central Processing Unit), a semiconductor memory, and the like. The control unit 13 controls each unit of the server device 1 by executing programs stored in the storage unit 12 and the like.

The control unit 13 also includes a setting unit 131 , an emissions calculation unit 132 , a required reduction amount calculation unit 133 , a selection unit 134 , and a carbon price calculation unit 135 .

The setting unit 131 sets a target value for GHG emissions. In the first embodiment, the setting unit 131 receives a scenario selection from the user using the operating terminal 2. Then, the setting unit 131 determines the future (for example, one year, two years, five years, 10 years, 30 years, etc., or 2025, 2030, 2040, etc.) based on the scenario received from the user. Set targets for GHG emissions by 2050, etc.). That is, the setting unit 131 sets the target value of GHG emissions from now on based on the scenario received from the user. Specifically, we aim to reduce GHG emissions by 40% from the base year (for example, 2015) in 2030, and to achieve net zero GHG emissions (the total of the organization's GHG emissions and GHG removals are zero) in 2040. There are things like doing.

The emissions calculation unit 132 (acquisition unit) calculates the GHG emissions. For example, the emissions calculation unit 132 calculates various GHG emissions for each organization, product, project, etc. based on power generation equipment owned by the organization, production volume of products, and the like. The targets for calculating GHG emissions (organizational scope and activity scope) may be set in advance through master registration or the like. Then, for each GHG emission source included in the organizational scope and activity scope, we will accept input of direct measurement results of GHG emissions, and numerical values (activity amount, emission coefficient, various quantities) used to calculate each GHG emission amount. The GHG emissions of each organization may be calculated from the data input through the input reception process (e.g.), and the GHG emissions of the organization may be calculated as the total. Further, the GHG emissions may include the GHG emissions calculated for each product or service (product unit) handled by the organization, or the GHG emissions calculated for each project. Note that an organization's GHG emissions include Scope 3 Category 15 GHG emissions (GHG emissions from investments) and GHG emissions from other companies in the supply chain.

The required reduction amount calculation unit 133 calculates the required reduction amount of GHG emissions necessary to achieve the target value of GHG emissions set by the setting unit 131. Specifically, the required reduction amount calculation unit 133 calculates the amount of GHG emissions by subtracting the GHG emissions of the organization calculated by the emission amount calculation unit 132 from the target value of GHG emissions set by the setting unit 131. Calculate the required amount of reduction. Note that the required reduction amount calculated by the required reduction amount calculation unit 133 of the first embodiment corresponds to the required activity reduction amount.

The required activity reduction amount is the amount of GHG emissions that should be reduced when GHG emissions are directly measured in activities that emit GHG, and the amount of GHG emissions that should be reduced when the amount of GHG emissions is calculated indirectly by the amount of activity x emission coefficient, etc. It may be expressed as the amount of activity to be reduced or the emission factor to be reduced. For example, if the amount of electricity used in the calculation is 1000 kWh, the required amount of activity reduction may be expressed as the amount necessary for reduction of 200 kWh out of the 1000 kWh of electricity used. Further, the required amount of activity reduction may be expressed as another amount of activity that replaces the amount of activity used for calculation. For example, if the amount of electricity used in the calculation is 1000 kWh, the required amount of activity reduction may be expressed as 200 kWh of renewable energy that does not emit GHG out of the 1000 kWh of electricity used. Further, the required amount of activity reduction may be expressed as a recommendation for a substitute for the amount of activity used for calculation. For example, if the amount of electricity used in the calculation is 1000 kWh due to the use of device A, the required amount of activity reduction may be expressed as a usage recommendation for device B, which uses less electricity than device A. Furthermore, the required amount of activity reduction is the amount by which the emission factor should be reduced by multiplying the electricity consumption of 1000 kWh used for calculation (for example, 0.0003 t-CO2/kWh reduced from the initial 0.0008 t-CO2/kWh). CO2/kWh).

The selection unit 134 selects an investment destination corresponding to the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133 from among the investment destinations included in the investment destination DB. Specifically, the required reduction amount calculation unit 133 reads the investment destination DB and selects the investment destination corresponding to the required reduction amount of GHG emissions. For example, assume that a user (organization) has invested in a specific investment target I (company or project) in advance. In this case, the user's GHG emissions will include the GHG emissions from the investment in investment object I as scope 3 category 15. At this time, the selection unit 134 selects an investment destination whose GHG emissions are smaller than investment target I from among the investment destinations registered in the investment destination DB. For example, if the GHG emissions from the investment of investment target I are 1000 tons and the reduction activity amount of the organization is 500 tons, the selection unit 134 selects investment targets with GHG emissions of 500 tons or less in scope 3 category 15 from the investment destination database. Select (investment destination). Thereby, the selection unit 134 achieves the required amount of reduction for the organization (user). Further, the selection unit 134 may select a plurality of investment destinations. At this time, if the total value of the GHG reduction amount exceeds the required reduction amount of GHG emissions, the plurality of investment destinations may be selected. That is, the selection unit 134 may select one or more investment destinations. Further, the selection unit 134 may accept changes regarding each investment target. For example, for the above investment target I, a reduction in the investment price that is sufficient to achieve the required amount of reduction may be accepted. The selection and change acceptance described above by the selection unit 134 may be performed by receiving a selection instruction from the user. In addition, the selection and change acceptance described above by the selection unit 134 are based on rules predetermined to achieve the required reduction amount (for example, the investment destination with the lowest investment price among the investment destinations whose GHG reduction amount exceeds the required reduction amount, etc.) This may be done automatically based on the Note that the selection unit 134 in the first embodiment corresponds to a first selection unit.

In the first embodiment, as described above, the investment destination DB stores data indicating investment destinations that can reduce GHG emissions. That is, the selection unit 134 selects an investment destination from the investment destination DB and accepts changes to the investment details so as to achieve the target value of GHG emissions.

The carbon price calculation unit 135 calculates the carbon price by pricing the GHG emissions of the organization. A carbon price can be a carbon tax imposed by the national or local government on companies, organizations, or other organizations, or it can be an internal carbon tax that companies, organizations, or other organizations voluntarily set on GHG emissions. It may be. In addition, carbon prices may be set as the price of emission allowances to be purchased for GHG emissions that exceed the upper limit (cap) set for the organization in emissions trading, or may be set as the price of emission allowances to be purchased for GHG emissions that exceed the upper limit (cap) set by the organization in emissions trading. The price may be in line with the pricing scheme for GHG emissions. Here, the pricing may be any method that calculates the carbon price, but for example, it may be an amount per metric ton of GHG emissions (for example, 10,000 yen per metric ton), It may be an average, maximum value, minimum value, median value, or other statistical amount of prices shown in market transactions, bilateral transactions, etc. regarding GHG emissions. The carbon price calculation unit 135 calculates a carbon price from the organization's GHG emissions calculated by the emissions calculation unit 132, according to one or more combinations of the above-described pricing determined in advance. This allows organizations to easily calculate carbon prices and understand the cost impact of GHG emissions. Additionally, as mentioned above, organizations can reduce their GHG emissions by investing in investees. The carbon price calculation unit 135 calculates a carbon price when an organization reduces GHG emissions by investing in an investment destination. That is, the carbon price calculation unit 135 calculates a carbon price regarding the investment by assigning a predetermined price to the GHG emission reduction amount by the investment destination selected by the selection unit 134. Note that the carbon price calculation unit 135 of the first embodiment corresponds to a first carbon price calculation unit. Furthermore, if the carbon price changes from year to year, the carbon price calculation unit 135 calculates the carbon price according to the year in which the investment is made. Note that the carbon tax may be a tax imposed on the carbon content of fossil fuels such as coal and oil.

(About the operation of the management system)
3 and 4 are flowcharts showing the operation of the management creation system according to the first embodiment. Specifically, FIG. 3 shows the overall operation of the management system, and FIG. 4 shows the operation of the management system in the first process (step S21) of FIG. 3.

When the operation terminal 2 receives an instruction to set a GHG emission reduction target from the user via the operation unit 22, it requests the server device 1 for a scenario DB. When the server device 1 receives a request for the scenario DB from the operating terminal 2, it transmits the data included in the scenario DB to the operating terminal 2. When the operating terminal 2 receives the data from the server device 1, it displays a list of scenarios (2°C increase scenario, 4°C increase scenario, etc.) included in the scenario DB on the display unit 21. The list of scenarios includes specific conditions when you select the scenario, such as less than 1.5 degrees, 1.5 degrees or more and less than 2 degrees, 2 degrees or more and less than 3 degrees, 3 degrees or more and less than 4 degrees, and 4 degrees or more. The information may be categorized and displayed according to how many times the global temperature rises per year. In addition, the list of scenarios may display at the top the scenarios that are selected the most based on the type of industry, topography and weather of the location of the head office/factory, and other classifications. When the operation terminal 2 receives the selection of a scenario from the user via the operation unit 22, the operation terminal 2 transmits data indicating the selected scenario to the server device 1.

When the setting unit 131 of the server device 1 receives data indicating the scenario selected by the user from the operating terminal 2 (step S1), it executes the first process (step S21).

In step S21, the setting unit 131 first sets a target value for future GHG emissions (step S2). The emissions calculation unit 132 of the server device 1 calculates the GHG emissions (step S3). For example, the emissions calculation unit 132 calculates the GHG emissions based on the power generation equipment owned by the organization, the production volume of products, and the like.

The required reduction amount calculation unit 133 of the server device 1 calculates the required reduction amount of GHG emissions necessary to achieve the reduction target set by the setting unit 131 (step S4). Specifically, the required reduction amount calculation unit 133 calculates the required reduction amount of GHG emissions by subtracting the GHG emissions calculated by the emission amount calculation unit 132 from the target value of GHG emissions set by the setting unit 131. Calculate the amount.

The selection unit 134 of the server device 1 reads the investment destination DB (step S5). Then, the selection unit 134 selects an investment destination corresponding to the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133 from among the investment destinations included in the investment destination DB (step S6). The selection unit 134 transmits data indicating the selected investment destination to the operation terminal 2, and receives permission from the user to determine the investment destination (step S7).

The carbon price calculation unit 135 of the server device 1 calculates the carbon price for the reduction in GHG emissions when the organization invests in the investee (step S8). The carbon price calculation unit 135 transmits data indicating the calculated carbon price to the operating terminal 2, and causes the display unit 21 to display the data.

With the above configuration, the management device according to the first embodiment includes the emission calculation unit 132 (acquisition unit) that calculates (acquires) the GHG emissions, the setting unit 131 that sets the target value of the GHG emissions, and the GHG The required reduction amount calculation unit 133 calculates the required reduction amount of GHG emissions necessary to achieve the target value of emissions. That is, based on the GHG emissions calculated by the emissions calculation unit 132 and the target value of GHG emissions set by the setting unit 131, the required reduction amount calculation unit 133 calculates the amount necessary to achieve the target value of GHG emissions. In order to calculate the required reduction amount of GHG emissions, the user (organization) can know the required reduction amount of GHG emissions necessary to achieve the GHG emission target. This makes it easier for users to achieve their GHG emissions goals.

The setting unit 131 also sets a target value for future GHG emissions. The selection unit 134 selects an investment destination so as to achieve a target value of GHG emissions. This makes it easier for users to achieve their GHG emissions goals.

(Modified example)
In the embodiment described above, the selection unit 134 achieved the GHG emissions target by changing (selecting) the investment destination, but in this modification, the selection unit 134 achieves the GHG emissions target by changing (selecting) the investment destination. GHG emissions targets may be achieved by changing (selecting) supply chain suppliers).

For example, the supply chain business partner DB shown in FIG. 5 is stored in the storage unit 12 together with or in place of the investee DB. The supply chain business partner DB is a database used by the user to select a supply chain business partner. Specifically, in the supply chain supplier database, the supply chain supplier name is associated with the transaction object, the amount of activity related to the transaction, the GHG emission coefficient according to the activity of the transaction, the amount of GHG emissions, the transaction price, etc. There is. The supply chain supplier name is data indicating the organization name (company name or project name) with which the organization can do business. Transaction targets include product names, parts names, material names, service names, and other data indicating activities that are transaction targets that can be traded by the organization. The amount of activity is data indicating the amount of activity related to transactions with the corresponding supply chain business partner. The emission factor is a GHG emission factor according to the activities of the corresponding supply chain business partner. The amount of emissions is the amount of GHG emissions generated by the corresponding transaction. For example, the amount of emissions is determined by the amount of activity x the emission coefficient. The transaction price is the transaction price per unit of the transaction target. Although not shown in this figure, the quantity of the transaction object, the amount of activity per unit of the transaction object, the emission coefficient per unit of the transaction object, the emission amount per unit of the transaction object, etc. may be included.

According to the GHG protocol, when an organization (user) trades (for example, purchases) a product, the GHG emissions generated from the manufacturing, transportation, etc. of the traded object are included in the organization's GHG emissions. Become. For this reason, for example, an organization may change its current supply chain suppliers to supply chain suppliers that can manufacture and transport the products with lower GHG emissions. By changing to , it becomes possible to reduce an organization's GHG emissions. Furthermore, an organization can reduce GHG emissions by reducing the amount of transactions (amount of activity) even with the same supply chain business partner. In addition, an organization can set a lower emission factor for the same supply chain supplier (for example, by setting a lower emission factor for the supplier through its own efforts) ), it becomes possible to reduce GHG emissions. In this embodiment, it is possible to reduce GHG emissions related to these supply chain business partners.

Here, in the above embodiment, the selection unit 134 selects an investment destination corresponding to the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133 from among the investment destinations included in the investment destination DB. In this modification, the selection unit 134 selects a supply chain business partner corresponding to the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133 from among the supply chain business partners included in the supply chain business partner DB. Select and accept changes to transaction details. For example, assume that a user (organization) has traded a transaction object (screws, etc.) from a specific supply chain business partner S (company or project) in advance. In this case, according to the Scope 1 to Scope 3 regulations, the user's GHG emissions include GHG emissions from transactions of transaction objects (screws, etc.) with supply chain business partners S (companies and projects). At this time, the selection unit 134 selects, from among the supply chain business partners registered in the supply chain business partner DB, a supply chain business partner that can transact the transaction object with lower GHG emissions than supply chain business partner S. It's fine. For example, if the GHG emissions of a transaction target of supply chain supplier S is 100 kg and the required reduction amount is 50 kg, the selection unit 134 selects GHG emissions from the same transaction target as the relevant transaction target from the supply chain supplier DB. You may select supply chain suppliers whose emissions are 50 kg or less. Thereby, the selection unit 134 achieves the required amount of reduction for the organization (user). At this time, the selection unit 134 selects the plurality of supply chain suppliers if the total value of their GHG reduction amount exceeds the required reduction amount of GHG emissions by selecting the plurality of supply chain suppliers. You may. That is, the selection unit 134 may select one or more supply chain suppliers. Note that the selection section 134 of this modification corresponds to a third selection section.

According to this modification, the selection unit 134 selects (changes) a business partner on the supply chain in order to achieve the required reduction amount. This makes it possible to achieve GHG emissions reduction targets by changing suppliers in the supply chain. In addition, if data on GHG emissions not only for direct supply chain business partners but also for each supply chain business partner is available, it is possible to understand changes in GHG emissions when supply chain business partners change. be able to.

(Second embodiment)
The management system according to the first embodiment manages GHG emission reduction targets beyond the present. In contrast, the management system according to the second embodiment manages the user's current or past GHG emission reduction goals.

The management system according to the second embodiment has the same configuration as the management system according to the first embodiment (see FIG. 1), but the data stored in the storage unit 12, the setting unit 131 of the control unit 13, and the reduction The functions of the required amount calculation unit 133, selection unit 134, and carbon price calculation unit 135 are partially different. Note that the carbon price calculation unit 135 of the second embodiment corresponds to a second carbon price calculation unit.

Specifically, in the second embodiment, the storage unit 12 stores a business partner DB instead of the investee DB.

The business partner DB is a database used by the organization to select business partners with environmental value (see FIG. 6). Specifically, in the business partner DB, a business partner name is associated with a GHG emission reduction method, a GHG reduction amount, and a transaction price. The business partner name is data indicating the name of an organization (company name or project name) that owns the environmental value that can be traded by the user. The GHG emission reduction method is data indicating the GHG emission reduction method of the corresponding business partner. Methods for reducing GHG emissions include reducing an organization's GHG emissions by trading environmental value (offsets such as J-Credit and environmental certificates), building power generation facilities using natural energy, and planting trees. These include ways to reduce an organization's GHG emissions by investing in negative emissions technologies (technologies that directly reduce carbon) and long-term projects to develop those technologies, and reducing one's own activity and/or emission factors. . The GHG reduction amount is data indicating the amount of GHG emissions reduced by the GHG reduction method. The transaction price is the price when transacting with the corresponding business partner.

In efforts to reduce GHG emissions such as through CDP, when an organization purchases environmental value, it is considered that the organization's GHG emissions have been reduced. In addition, by doing business with business partners that construct power generation facilities using natural energy, we will reduce the GHG emissions of the organization in an additional manner. The second embodiment aims at achieving a GHG emission reduction target by a user (organization) doing business with a business partner.

The setting unit 131 sets a GHG emission reduction target for the user. In the second embodiment, the setting unit 131 receives a scenario selection from the user using the operating terminal 2. Then, the setting unit 131 sets a target value of GHG emissions for the current year or the past year (such as one year ago) based on the scenario received from the user. That is, the setting unit 131 sets the target value of the GHG emissions of the organization for the current year or the past year (eg, one year ago) based on the scenario received from the user. Specifically, a target value for the GHG emissions of the organization may be set in the past and stored in a target value storage unit (not shown), and the target value may be read and set. In addition, the goal is to reduce GHG emissions by 40% from the base year (for example, 2015) in 2030, and to achieve net zero GHG emissions (the total of the organization's GHG emissions and GHG removal amount is zero) in 2040. You can set a target and allocate a reduction target to each fiscal year in the case of a uniform reduction by the relevant year. That is, in the second embodiment as well, similarly to the first embodiment, the setting unit 131 may set a target value for the future GHG emissions of the organization. Further, the setting unit 131 may set the target value of GHG emissions for the current year or the past year (such as one year ago) by accepting input from the user, etc., without being based on the scenario. Further, the setting unit 131 may set the target value by reading the target value of GHG emissions set in the past for the current year or the past year (such as one year ago).

The required reduction amount calculation unit 133 calculates the required reduction amount of GHG emissions necessary to achieve the target value of GHG emissions set by the setting unit 131. Specifically, the required reduction amount calculation unit 13
3 calculates the required reduction amount of GHG emissions by subtracting the GHG emissions of the organization calculated by the emissions calculation unit 132 from the target value of GHG emissions set by the setting unit 131. Note that the required reduction amount calculated by the required reduction amount calculation unit 133 of the second embodiment corresponds to the required offset reduction amount.

The selection unit 134 selects a business partner corresponding to the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133 from among the business partners included in the business partner DB. Specifically, the required reduction amount calculation unit 133 reads the GHG reduction amount of each customer (see FIG. 6) from the customer database, and selects the customer corresponding to the required reduction amount of GHG emissions. For example, the selection unit 134 selects a business partner whose GHG reduction amount exceeds the required reduction amount of GHG emissions from among the business partners registered in the business partner DB. For example, in FIG. 6, when the required reduction amount is 20 tons, the selection unit 134 selects Company H as a business partner. At this time, the selection unit 134 may select a plurality of business partners if the total value of their GHG reduction amount exceeds the required reduction amount of GHG emissions. . That is, the selection unit 134 may select one or more business partners. Note that the selection unit 134 in the second embodiment corresponds to a second selection unit.

In the second embodiment, an organization can offset or reduce GHG emissions in the future by trading (obtaining) environmental values with business partners registered in a business partner DB. As described above, the business partner DB stores data indicating business partners with which an organization can offset or reduce GHG emissions by doing business with. That is, the selection unit 134 selects a business partner from the business partner DB so as to achieve the target value of GHG emissions.

The carbon price calculation unit 135 calculates a carbon price for reducing GHG emissions when an organization conducts business with a business partner. As mentioned above, organizations can offset or reduce their GHG emissions by doing business with business partners. Therefore, the carbon price calculation unit 135 calculates the carbon price when the organization offsets or reduces GHG emissions by doing business with business partners. Note that the carbon price calculation unit 135 of the second embodiment corresponds to a second carbon price calculation unit.

(About the operation of the management system)
FIG. 7 is a flowchart showing the operation of the management creation system according to the second embodiment. FIG. 7 shows the operation of the management system according to the second embodiment. In FIG. 7, compared to FIGS. 3 and 4, steps S12 and S15 to S18 are executed instead of steps S2 and S5 to S8.

When the setting unit 131 of the server device 1 receives data indicating the scenario selected by the user from the operating terminal 2 (step S1), it sets a target value for the GHG emissions of the organization for the current year or the past year (step S1). S12). After that, step S3. S4 is executed. Note that, in step S1, the setting unit 131 of the server device 1 does not necessarily need to select a scenario, and may directly receive input of a target value of GHG emissions for the current year or past year from the user.

The selection unit 134 of the server device 1 reads the customer DB (step S15). Then, the selection unit 134 selects a business partner corresponding to the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133 from among the business partners included in the business partner DB (step S16). The selection unit 134 transmits data indicating the selected business partner to the operation terminal 2, and receives permission from the user to determine the business partner (step S17).

The carbon price calculation unit 135 of the server device 1 calculates a carbon price based on the amount of reduction in GHG emissions due to transactions with business partners (step S18). The carbon price calculation unit 135 transmits data indicating the calculated carbon price to the operating terminal 2, and causes the display unit 21 to display the data.

With the above configuration, the management device according to the second embodiment includes the emission calculation unit 132 (acquisition unit) that calculates (acquires) the GHG emissions, the setting unit 131 that sets the target value of the GHG emissions, and the GHG The required reduction amount calculation unit 133 calculates the required reduction amount of GHG emissions necessary to achieve the target value of emissions. That is, based on the GHG emissions calculated by the emissions calculation unit 132 and the target value of GHG emissions set by the setting unit 131, the required reduction amount calculation unit 133 calculates the amount necessary to achieve the target value of GHG emissions. In order to calculate the required reduction amount of GHG emissions, the user (organization) can know the required reduction amount of GHG emissions necessary to achieve the GHG emission target. This makes it easier for users to achieve their GHG emissions goals.

Further, the setting unit 131 sets a current or past target value of GHG emissions of the organization. The selection unit 134 selects business partners so as to achieve the target value of GHG emissions. This makes it easier for users to achieve their organization's GHG emissions goals.

Note that in step S16 of the present embodiment, when selecting a business partner from the business partner DB, the selection unit 134 may preferentially select a business partner with a low amount of activity from the business partner DB. As a result, it is possible to obtain transaction objects (products, etc.) that have been manufactured using a method with low GHG emissions.

Further, in step S16 of the present embodiment, when selecting a business partner from the business partner DB, the selection unit 134 may preferentially select a business partner with a small emission coefficient from the business partner DB. In addition to being determined through actual measurements, emission factors are determined as general emission factors for each activity based on statistical data such as input-output tables. Generally, calculating emission factors through actual measurements is complicated, so companies and projects use alternative values such as input-output tables, but these alternative values do not reflect the GHG reduction efforts of companies and projects in their activities. . Therefore, when selecting a business partner from the business partner DB, the selection unit 134 preferentially selects a business partner with a lower emission coefficient from the business partner DB for the same activity, thereby indirectly It is possible to measure the emission factors of business partners and increase their motivation to reduce GHG emissions.

(Other embodiments)
As described above, the embodiments have been described as examples of the technology disclosed in this application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments in which changes, replacements, additions, omissions, etc. are made as appropriate.

The tissue in the above embodiments may be any tissue. For example, an organization may be a country, local government, company, association, or other group. In addition, the organization is a business that provides services such as electricity, gas, water, communication lines, insurance, banking, web shopping, teaching of knowledge such as education, advertising, logistics, leasing, retail, and product sales such as product sales. It may be a person. Further, the organization may be a person engaged in business such as manufacturing, real estate, retail, finance, etc.

Further, in the first embodiment, a customer DB may be configured in the storage unit 12. In this case, the selection unit 134 may select a business partner from the business partner DB so as to achieve the target value of GHG emissions. Further, the selection unit 134 may select one or more business partners and one or more investment targets from the business partner DB and the investment target DB so as to achieve the target value of GHG emissions.

Further, in each of the above embodiments, the selection unit 134 selects the investee (business partner) in step S7 (S17), but the selection unit 134 selects the investee (business partner) based on the user operation.
You may also select Supplier). For example, the selection unit 134 may display the data stored in the investee DB (client DB) on the display unit 21 of the operating terminal 2, and may accept the selection of the investee (client) from the user. In this case, the display unit 21 may display the target value of GHG emissions set by the setting unit 131 and the required reduction amount of GHG emissions calculated by the required reduction amount calculation unit 133. Further, the carbon price calculation unit 135 displays on the display unit 21 the calculation result of the carbon price to be reduced by making an investment contract (transaction contract) with the investee (business partner). may be displayed.

Further, in each of the embodiments described above, the setting unit 131 sets the target value of the GHG emissions of the organization based on the scenario used for the TCFD scenario analysis, but the setting unit 131 is not limited to this. For example, the setting unit 131 may set the target value of the organization's GHG emissions in accordance with the standards and rules defined in the GHG emissions initiatives such as SBTi, CDP, RE100, TCFD, and GHG protocols mentioned above. good. For example, the setting unit 131 selects SBTi, and according to the target year such as 5 to 15 years from now and the setting of standards such as "standard well below 2 degrees Celsius" or "keep below 1.5 degrees Celsius", A goal may be set to reduce an organization's GHG emissions by 2.5% each year or by 4.2% each year. The setting unit 131 may determine which approach standards and rules should be followed based on the user's selection. Further, the setting unit 131 may accept different target settings for a plurality of periods with respect to the target value of the GHG emissions of the organization set arbitrarily by the above-mentioned standards or rules or by the user. For example, the setting unit 131 may accept the target value of the organization's GHG emissions as a reduction of 3% per year compared to last year until 2030, and a reduction of 4% per year compared to last year until 2040.

Further, the setting unit 131 may set a target value for GHG emissions in other units instead of or in addition to the target value for the organization's GHG emissions. For example, the setting unit 131 may set a target value of GHG emissions for each product (including service). Further, the setting unit 131 may set a target value of GHG emissions for each base linked to the organization. In this embodiment, numerical values and the like expressed in tissue units in each of the above-described embodiments may be expressed in other units.

Further, the setting unit 131 may calculate the target value of the GHG emissions of the organization for each scenario stored in the scenario DB, and display the calculation result on the display unit 21. For example, in TCFD scenario analysis, it is necessary to evaluate the importance of each risk (transition risk, physical risk, etc.), and based on this evaluation, the target value of GHG emissions for each scenario is set. . For this reason, the setting unit 131 may receive an evaluation of the importance of this risk from the user, calculate a target value of the organization's GHG emissions in each scenario, and display this result on the display unit 21.

Further, in the first embodiment, the selection unit 134 may preferentially select an investee (business partner) whose emission coefficient is calculated by the company from the investee DB (business partner). . GHG emissions are generally determined based on activity amount x emission coefficient. Although a general value can be used for this emission factor, it is also possible to calculate it by the investee (business partner) itself. Calculating emission factors by the investee (business partner) itself is time-consuming and costly, so it can be said that such investees are highly conscious of trying to further reduce GHG emissions through investment. For this reason, the selection unit 134 may preferentially select an investee (business partner) whose emission coefficient is calculated by the company from the investee DB (business partner).

Further, in the first embodiment described above, the selection unit 134 may select an investment destination for achieving the target value based on past GHG emission reduction results of the investment destination. For example, the selection unit 134 may preferentially select an investee that has a track record of achieving GHG reduction amount or power generation amount registered in the investee database in the past, or may prioritize an investee that has a high achievement record. You may also select

Further, the emission amount calculation unit 132 may be provided outside the server device 1. Furthermore, various databases stored in the storage unit 12 may be provided externally.

Furthermore, in each of the embodiments described above, the carbon price calculation unit 135 calculates the carbon price after step S7 (or step S17), but the present invention is not limited to this. For example, the carbon price calculation unit 135 may calculate the carbon price after the required reduction amount calculation unit 133 calculates the required reduction amount. In this case, the carbon price calculation unit 135 calculates the carbon price of the organization when the required reduction amount is calculated.

Furthermore, in each of the above embodiments, when selecting an investee (a business partner or a business partner in a supply chain), the selection unit 134 selects a contract between the organization and the investee (a business partner or a business partner in a supply chain). The user and the investee (business partner or business partner on the supply chain) may be notified of the establishment of the investment contract.

Moreover, a management program for realizing the functions according to the embodiment described above is installed in each of the server device 1 and the operation terminal 2. The server device 1 and the operation terminal 2 implement various functions according to the above embodiment by executing a management program.

In addition, the management system in the second embodiment not only offsets, but also generates energy (in-house), saves energy, collects energy (purchasing power supplies, discharging from storage batteries, surplus from cogeneration system), and then offsets. This may be displayed on the display unit 21. This may indicate that the reduction is not greenwashing, where the reduction was done through offsets alone.

The management system according to the present embodiment is useful because it calculates the amount of reduction in GHG emissions necessary to achieve the target value of GHG emissions of an organization.

1 Server device 12 Storage unit (scenario registration unit)
13 Control unit 131 Setting unit 132 Emission amount calculation unit (acquisition unit)
133 Required reduction amount calculation unit 134 Selection unit (first selection unit, second selection unit)
135 Carbon price calculation unit 2 Operation terminal 21 Display unit 22 Operation unit

Claims (9)

A management device for managing GHG emissions,
an acquisition unit that acquires the GHG emissions;
a setting unit that sets the target value of the GHG emissions;
A management device comprising: a required reduction amount calculation unit that calculates a required reduction amount of the GHG emissions necessary to achieve the target value. When the target value of the GHG emissions is a target value of the GHG emissions beyond the present, the required reduction amount calculation unit sets the required reduction amount as at least one of the required offset reduction amount and the required activity reduction amount. The management device according to claim 1, which calculates. The required reduction amount calculation unit calculates the required reduction amount as an offset required amount when the target value of the GHG emissions is a past or present target value of the GHG emissions. Management device. The management device according to claim 1, further comprising a display unit that displays the calculation result of the required reduction amount calculation unit. It further includes a scenario registration section in which scenarios including predictions for future climate change are registered.
The management device according to claim 1, wherein the setting unit sets the target value based on the scenario registered in the scenario registration unit. a first selection and proposal unit that proposes and selects investment destinations that can reduce GHG emissions; a second selection and proposal unit that selects and proposes business partners that can trade environmental value in order to achieve the required reduction amount; The management device according to claim 1, further comprising at least one of a third selection unit that selects a business partner on a supply chain in order to achieve the required reduction amount. The management device according to claim 1, further comprising a carbon price calculation unit that calculates a carbon price for the GHG emissions. A management method for managing GHG emissions, the method comprising:
The server device is
setting a target value for the GHG emissions;
A management method comprising: acquiring the GHG emissions amount; and calculating a required reduction amount of the GHG emissions necessary to achieve the target value. to the computer,
A management program for executing the management method according to claim 8.