JP2001183186A - Method and system for calculation of discharge amount of carbon dioxide - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method in which the amount of carbon dioxide discharged by every entrepreneur is calculated easily without any time-lag. SOLUTION: Data on an energy consumption amount in one or a plurality of entrepreneurs is transmitted to a remote server via a communication line. The server calculates the real-time discharge amount of the carbon dioxide corresponding to the energy consumption amount of every entrepreneur. The server is provided in advance with a computing equation which computes the discharge amount of the carbon dioxide with reference to the energy consumption amount regarding a plurality of kinds of energies. Thereby, the discharge amount of the carbon dioxide regarding every entrepreneur can be calculated easily.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for calculating the amount of carbon dioxide emitted by a business using a computer system, and more particularly to a method for calculating a reliable amount of carbon dioxide emitted in real time. And its system.

[0002]

2. Description of the Related Art In order to prevent global warming, the Kyoto Protocol adopted by the Third Conference of the Parties to the United Nations Framework Convention on Climate Change (COP3) has been ratified in the near future, and developed countries are obliged to achieve their carbon dioxide reduction targets. Will occur. At that time, each country is assigned an annual carbon dioxide emission to the business operator, and the business operator is required to regularly report the carbon dioxide emission to the government or similar organizations.

At present, there is a method of calculating the amount of carbon dioxide emission based on the consumption of gas, electricity, petroleum and the like. The energy consumption of gas, electricity, petroleum, and the like can be determined based on a slip or the like issued separately by each energy company.

[0004]

However, the reason for each business operator to calculate the carbon dioxide emission amount by summing up the slips of each energy consumption sent from each energy supply company once a month is as follows. This is a laborious and time-consuming task and requires some expertise. Depending on the familiarity of each business operator with the necessary expertise for calculating carbon dioxide emissions, the calculated carbon dioxide emissions may be different, which is a major problem,
The self-reporting method has a problem that the reliability is low and the calculated carbon dioxide emission is not guaranteed.

[0005] In addition, since the slips sent from the respective energy supply companies are monthly, a time lag of one month or more occurs in obtaining the carbon dioxide emission data.
Therefore, there is a problem that it is not possible to satisfy the needs of the business operator who wants to manage the carbon dioxide emission timely.

[0006] Further, conventional gas meters and electric meters are not installed individually for each device, and cannot calculate the carbon dioxide emission amount for each device. Therefore, there is a problem in that it is difficult to conduct business analysis from the viewpoint of carbon dioxide emission such as which of the devices used by the company is greatly involved in carbon dioxide emission.

[0007] Therefore, an object of the present invention is to allow a third party having specialized knowledge not less than a predetermined standard to easily calculate the amount of carbon dioxide emitted by each business without a time lag, and to calculate the amount of carbon dioxide. It is to provide a method for guaranteeing.

Another object of the present invention is to provide a method for calculating the total amount of carbon dioxide emitted by a business operator and the carbon dioxide emission amount of each device used by the business operator in real time.

It is a further object of the present invention to provide a method for calculating the amount of carbon dioxide emitted by a business based on a business plan.

[0010]

In order to achieve the above object, according to the present invention, data of energy consumption of each business is stored in a remote place via a communication line with a technical knowledge above a predetermined standard. By transmitting the information to a server managed by a third party, the server calculates the real-time carbon dioxide emission corresponding to the energy usage of each business operator. The server has, in advance, an arithmetic expression for calculating the carbon dioxide emission amount with respect to the energy usage amount for a plurality of energy types. This makes it possible to easily calculate the carbon dioxide emission amount for each company, even if the types of energy used by each company differ.

[0011] In response to a browsing request from a customer (a business or a person permitted to browse the data output site), the calculated carbon dioxide emission is output to a data output site on the Internet. Therefore, the customer can obtain the carbon dioxide emission amount without a time lag.

Further, according to the present invention, a plurality of businesses registered as customers in a server are classified according to predetermined conditions, and the total carbon dioxide emissions of the plurality of classified businesses are easily and in real time obtained. Can be. That is, it is possible to total the carbon dioxide emission data according to various classification conditions, and it is possible to provide statistical data and various information according to customer needs.

[0013] Preferably, the method for calculating carbon dioxide emission according to the present invention, which achieves the above object, comprises a method for calculating the amount of carbon dioxide emitted by one or a plurality of businesses implementing a business involving carbon dioxide emission. In the calculation method, a step of measuring the amount of use of at least one energy related to the carbon dioxide emission of one or a plurality of businesses or an amount corresponding thereto, and the server uses the communication amount or the amount corresponding to the amount of use via a communication line. And the server calculates a carbon dioxide emission based on the used amount or the amount corresponding to the used amount.

[0014]

Embodiments of the present invention will be described below. However, the technical scope of the present invention is not limited to the present embodiment. In the embodiment of the present invention, gas is described as an example of energy for discharging carbon dioxide, but the present invention is not limited to this, and other energy (electricity, petroleum, coal, etc.) may be used. Is also applicable.

FIG. 1 is an overall configuration diagram of a system for implementing a method for calculating carbon dioxide emission according to an embodiment of the present invention. In FIG. 1, a server 10 is connected to a terminal 100 of each of operators 1, 2,.
-1, 100-2,... Measuring instrument 200-
1, 200-2,... (A gas meter when energy is gas) measures the amount of gas used. For example, the measuring device 200 is provided for each type of gas used by the business operator. For example, when a business uses both city gas and propane gas, a gas meter corresponding to city gas and a gas meter corresponding to propane gas are provided. Since the amount of carbon dioxide emitted varies depending on the type of gas, it is possible to calculate the amount of carbon dioxide emissions for each type of gas and add them together to obtain the total amount of carbon dioxide emitted by the business. it can. The measuring device 200 may be provided for each device owned by the business operator and measure the amount of gas used for each device. In this case, the business operator can acquire the carbon dioxide emission amount for each device in addition to the total amount of carbon dioxide emitted by the business operator. When the measuring device 200 is installed for each device, the measuring device 200
Instead of measuring the gas usage itself, the usage time and operating load of the device may be measured. If the gas usage per unit operating time at the unit operating load is known,
The actual gas usage can be determined from the usage time and operating load of the device.

Each terminal 100 of each business operator is connected to a measuring instrument 200 in each business operator, and the gas consumption measured by each measuring instrument 200 (or the measuring equipment installed for each apparatus is used time and operating load). When measuring the operating time and operating load,
Hereinafter, the amount is simply summarized as gas usage) is periodically transmitted to the server via the communication line. Or, the measuring instrument 200
Each may have a communication function and may directly transmit gas usage data to the server 10. Further, the terminal 100 connects to the Internet via a communication line. Server 10
Provides a data output site 10A described later on the Internet, and allows the terminal 100 to browse the data output site 10A.

FIG. 2 is a block diagram of the server 10. In FIG. 2, the control unit 11 and the arithmetic processing unit 12
It is composed of CPU. The control unit 11 performs control of each unit, data transfer, various arithmetic processing instructions, temporary storage of data, and the like. The arithmetic processing unit 12 performs arithmetic processing on the data transferred from each unit. The input / output control unit 13 controls data input from the connected terminal 100 via a communication line. For example, measurement data from the measuring device 200 is transmitted from the terminal 100 via the communication line to the input control unit 1.
3 is input. Further, the input / output control unit 13 controls data output to the data output site 10A. The following programs and files are stored in a predetermined storage device in the server 10.

The main program 15 is executed by the control unit 11. The main program 15 is a program for recording data before the arithmetic processing, a program for arithmetically processing the data and converting it into carbon dioxide emission, a program for recording and displaying the calculated carbon dioxide emission, and simulating and predicting the carbon dioxide emission. It has a program, a program for searching for information, a program for totalizing information, a program for outputting information, and a program for guaranteeing carbon dioxide emission, which will be described later.

The calculation file 16 contains calculation coefficients and calculation formulas necessary to calculate stoichiometrically reasonable carbon dioxide emissions for each compound or composition for various gas compositions or compositions. The information of is stored. For example, the amount of carbon dioxide emitted when methane gas Xm ³ is used by combustion is calculated stoichiometrically as X × 1.0 from CH ₄ + 2O ₂ → CO ₂ + 2H ₂ O, and is calculated as Xm ³ . That is, in the case of methane gas, information of an arithmetic coefficient of 1.0 and an arithmetic expression of X × 1.0 is stored. Further, the amount of carbon dioxide emitted when the propane bath Ym ³ is used by combustion is calculated stoichiometrically as Y × 3.0 from C ₃ H ₈ + 5O ₂ → 3CO ₂ + 4H ₂ O, and is calculated as 3Ym ³ Is done. That is, in the case of propane gas, the calculation coefficient 3.
0, information of an arithmetic expression Y × 3.0 are stored.

Further, the calculation file stores all types of gas for each device and gas consumption speed (gas usage amount per unit usage time at a unit operation load) when the device is used. For example, information is stored such that the energy used by a certain device is city gas, and operating the device for one hour consumes Am ^{3 of} city gas.

The customer file 17 has a customer registration file, a measuring instrument file, an energy file, a device file, a carbon dioxide file, a business file, and the like for each customer.

FIG. 3 is a diagram showing a configuration example of the customer file 17. FIG. 3 illustrates the customer file 17 for the company 1 (FIG. 3A) and the company 2 (FIG. 3B). In addition, the business 1 is a gas meter (a measuring
0) is installed for each device, and the company 2 installs a gas meter for each type of gas.

In the customer registration file 171, in addition to the name, address, business type, and the like of each business, an ID and a password necessary for each business to access the data output site 10A are registered. The instrument file 172 contains
The energy type (here, gas type) or device name corresponding to the measuring instrument ID is registered. The device name is registered for the company 1, and the gas type is registered for the company 2.

The energy file 173 stores the types of energy used by each company and their respective composition data. For example, in the energy file corresponding to the company 1, gas is registered as an energy type, and gas types A, B, and C and their compositions a, b, and c are stored. For example, the composition a of gas A
Is 80% methane, 15% propane and 5% butane. When other energy, for example, petroleum is used, its type (light oil, heavy oil, gasoline, etc.) and its composition are stored.

The device file 174 stores the device used by each business operator (customer) and the gas type (energy type in a broader concept) of each device. FIG. 3 (b)
Then, since the company 2 does not install a gas meter for each device, there is no device file 174 in the customer file of the company 2. On the other hand, since the company 1 installs a gas meter for each device, as shown in FIG. 3A, the customer file of the company 1 has a device file 174, in which a gas file corresponding to each device is stored. The species has been registered.

The business file 175 stores information on the amount of carbon dioxide emission set or assigned by each company, a business plan of each company, and the like. The business plan related to the amount of carbon dioxide emission is, for example, information on a use plan of the device. The use plan of the device is a plan relating to changes in the number, type, performance, operation load, operation rate, operation time, energy used, and the like of the device. Information stored in these business files 175 is, for example,
The operator can easily change the data at the data output site 10A from the terminal of the operator via the Internet.

The carbon dioxide file 176 stores the carbon dioxide emission amount calculated as needed by the arithmetic processing.
Furthermore, the total amount and cumulative amount of carbon dioxide emissions for each business period for each predetermined period, the total amount of carbon dioxide emissions for each business site for each predetermined period and their cumulative amount, The total amount and cumulative amount of carbon dioxide emissions for each type of gas for each predetermined period, the total amount and cumulative amount of carbon dioxide emissions for each device of each company for each predetermined period, and the carbon dioxide emissions that are allocated in advance Is calculated, and the calculated data is stored in the carbon dioxide file 176.

FIG. 4 is a flowchart of a method for calculating carbon dioxide emission according to the embodiment of the present invention. The person who implements the method for calculating carbon dioxide emissions is, for example, a third party that provides a service for calculating carbon dioxide emissions on behalf of a company that emits carbon dioxide. In advance, information about the customer who provides the service is stored in the server 10.
Is registered in the customer file 17 described above. The information to be registered differs depending on the customer and the contents of service to the customer.

For example, if the customer is a business operator that emits carbon dioxide, information corresponding to each of the above-described files is required. However, a company that does not install a gas meter for each device does not need to register information on the device file. Further, when it is not necessary to predict the carbon dioxide emission amount, information (business plan) on the business file may not be registered.

The gas usage data from the gas meters installed in each business is attached to the business ID and the gas meter ID and transmitted to the server 10 via a communication line. The control unit 11 of the server 10 receives the data from the terminal (Step S11). When receiving the data, the control unit 11
First, the company is specified with reference to the customer registration file 171 of the customer file. Next, the control unit 11 searches the measuring instrument file 172 in the customer file of the specified business operator. For a company that installs a gas meter for each gas type (for example, the company 2 in FIG. 3B), by searching the measuring instrument file 172, the gas type (generally, the energy type) is searched. Specified. Also,
A company that installs a gas meter for each device (for example, FIG. 3
(A) For the operator 1), the measuring instrument file 172
The device is specified by searching for. In this case, by further searching the device file 174, the gas type corresponding to the specified device is specified. After specifying the gas type, the arithmetic processing unit 12 refers to the energy file 173 and specifies the composition of the gas type.

As described above, upon obtaining the gas composition, the arithmetic processing section 12 obtains the corresponding arithmetic expression stored in the arithmetic file 16 (step S12). Then, a carbon dioxide emission amount corresponding to the gas usage amount is calculated using the arithmetic expression (step S13). Further, a total amount of the calculated carbon dioxide emission amount for each predetermined period and an accumulated amount thereof are calculated. Preferably, the total amount and the cumulative amount are calculated for all the energy used by the business operator, and the total amount and the cumulative amount of the carbon dioxide emission amount for each energy and for each device may be calculated for each predetermined period. .

The data on the calculated carbon dioxide emission amount, the total amount and the cumulative amount are stored in the carbon dioxide file 176 of the customer file of each business (step S14).

FIG. 5 is a flowchart of an output process of the calculated carbon dioxide emission data. First, the customer
A request for browsing the amount of carbon dioxide emission is made from the data output site 10A (step S21).

The browsing request processing will be described in more detail. The customer first connects the terminal 100 to the Internet, and inputs an ID and a password, so that the server 1
0 accesses the data output site 10A provided by the user.
Then, the startup screen shown in FIG. 6 is displayed. The customer inputs his / her ID and password on the screen shown in FIG. In addition, the customer who requests browsing may be a browsing applicant other than the business operator that emits carbon dioxide (for example, a local government that is in a position to supervise the business or an investment company that finances the business). . Such a customer need only register information on the customer registration file in the customer file. Further, for such a customer, the range of the business that can be browsed (business name, region, industry, investment target, etc.) is registered.

The server 10 searches the customer registration file of the customer file, checks the entered ID and password,
If the ID and the password are correct, the screen shown in FIG. 7 is displayed. FIG. 7 shows an output content designation screen. In FIG.
The customer selects either “individual” or “total”.
"Individual" is selected when it is desired to view the carbon dioxide emission data for each business operator. When "individual" is selected, the business name is displayed in a pull-down menu, and the customer selects one of them. “Aggregation” is selected when it is desired to view the carbon dioxide emission data of the entire plurality of businesses classified according to predetermined conditions such as regions and industries. When “total” is selected, predetermined conditions (including a condition of selecting all businesses) are displayed in a pull-down menu, and the customer selects one of them.

FIG. 8 is an example of the next output content designation screen when one operator is selected by "individual". The customer specifies the type of carbon dioxide emission to be acquired on the screen of FIG. "Whole" corresponds to the amount of carbon dioxide emitted by the entire business. "By business" shows the business establishments (business establishment A, business establishment B, factory A, etc.) of one business establishment, and carbon dioxide emissions limited to the use of energy of the business establishment selected by one business establishment. Corresponding to When "By energy" is selected, the type of energy (gas, electricity, petroleum, coal, etc.) used by the operator is displayed in a pull-down display, and carbon dioxide emissions limited to the use of the selected energy by one operator are displayed. You can know the quantity. Further, when "by device" is selected, a device name or a device number is displayed in a pull-down display, so that the amount of carbon dioxide emission limited to use of the selected device by one company can be known. The customer selects the type of carbon dioxide emission desired.

FIG. 9 shows an example of a next output content designation screen when "by area" is selected by "totaling". The customer specifies an area range on the screen of FIG. For example,
When you select a region, the name of the region (Hokkaido, Tohoku region, Kanto region, etc.) is displayed in a pull-down menu. When the prefecture is selected, the name of the prefecture is displayed in a pull-down menu. Furthermore, when the municipalities are selected, the names of municipalities nationwide are displayed in a pull-down menu. The customer specifies the desired area. When the desired area is designated, all the businesses or establishments having addresses in the designated area are selected, and the total amount of carbon dioxide emissions emitted by the selected business or establishment is output. .

FIG. 10 is a screen next to FIG. 8 or FIG. In the screen of FIG. 10, the customer specifies display contents. First, the customer specifies the period for which he wants to obtain carbon dioxide emissions. “Current year” and “arbitrary designation” are set as the “period” menu. When "current year" is selected, the total amount of carbon dioxide emission from the beginning of the current year to the present, monthly, weekly, or daily and the cumulative amount thereof are displayed.
It is also possible to select “arbitrary designation” and input an arbitrary period. Further, the customer can select either a “numerical table” or a “graph” as a display format of the carbon dioxide emission.

Furthermore, when "this year" is selected in the period, the predicted amount of future carbon dioxide emission in this year can be displayed. The forecast amount is obtained based on the change over time of the carbon dioxide emission amount up to the present in the current fiscal year. More preferably, in addition to aging,
The business plan stored in the business file is considered. For example, according to a business plan, it is predicted that when an additional device is added in the future, a larger amount of carbon dioxide will be emitted. Further, according to the business plan, when the operation rate or the operation load of the device is reduced in the future, it is predicted that the carbon dioxide emission will be further reduced. Further, for example, if a business plan changes the energy used by the device from propane to methane, it is expected that carbon dioxide emissions will be lower. Therefore, in such a case, the predicted amount of carbon dioxide emission obtained from the change over time is corrected based on the type of the device to be added, the timing of addition, the number of added devices or the operation rate, the operating load, the change in the energy used, and the like. .

When all the designations have been completed, the customer returns to FIG.
Click “OK”. Thus, the designated browsing request is sent to the control unit 11 and the arithmetic processing unit 12 of the server 10.

The arithmetic processing unit 12 of the server 10
Upon receiving a browsing request specifying the output contents “this year”, “total amount of carbon dioxide emissions”, etc., from the carbon dioxide file in the customer file 17 of the business entity requested to browse, the The total amount and the accumulated amount are read (step S22). If the display in the graph format is specified, the arithmetic processing unit 11 processes the read data into, for example, a monthly graph and outputs the processed data to the data output site 10A (step S23).

FIG. 11 is a diagram showing a screen example of the data output site 10A. In FIG. 11, the data output site 10 </ b> A displays, in the form of a graph, the changes over time in the total amount of carbon dioxide emissions per month (bar graph) and the accumulated amount per month (line graph) in the current year. Also, when "Predicted display" is specified at the time of the browsing request, as shown in the figure, the predicted amount of future carbon dioxide emissions in the current year and the remaining amount (or excess Amount) and output. The predicted amount is indicated by a dotted line in FIG.

As described above, according to the present embodiment, by transmitting data on the amount of energy used by the business operator to server 10 via the communication line, the server can realize real-time dioxide emission corresponding to the amount of energy used. Calculate carbon emissions. Then, in response to a browsing request from a customer (a business or a person permitted to browse the data output site),
The calculated carbon dioxide emission is output to a data output site on the Internet. Therefore, the customer can obtain the carbon dioxide emission amount without a time lag.

Further, according to the present embodiment, a plurality of businesses registered as customers in the server are classified according to predetermined conditions, and the carbon dioxide emissions of all the classified businesses are easily and in real time acquired. can do. That is,
It is possible to total the carbon dioxide emission data according to various classification conditions, and to provide statistical data and various information according to customer needs.

In this embodiment, gas has been described as an example of energy for discharging carbon dioxide. However, this embodiment is similarly applicable to other energies (coal, oil, electricity, etc.). is there. That is, a measuring instrument for measuring the usage of coal, oil, electricity, etc. is installed, and the usage of each is transmitted to the server 10 in real time. The server 10 stores in a calculation file a calculation formula for converting each used energy into a carbon dioxide emission amount,
Calculate carbon dioxide emissions.

Note that carbon dioxide is emitted by the use of electric energy when electric energy generated by using fossil fuel is used.

In this way, the usage amount of all energy that emits carbon dioxide by use is measured. The carbon dioxide emission is calculated as the sum of the carbon dioxide emissions calculated for each energy, and more specifically, for each device.

Further, a third party who provides a service for calculating the carbon dioxide emission according to the above-described embodiment may perform a guarantee operation on the calculated carbon dioxide emission data. This third party may be, for example, an administrative or private institution, and may provide assurance on the carbon dioxide emissions that the operator reports to the administration. For example,
By selecting a predetermined menu on the data output site 10A, the customer may be able to download an electronic document in a predetermined format to which the carbon dioxide emission data has been input. The electronic document is assured by being stamped with an electronic seal or an electronic signature.

[0049] Contrary to the emission of carbon dioxide due to the use of energy, when a business implements a business of recovering carbon dioxide in the atmosphere, a negative carbon dioxide emission may be counted. For example, when a business implements a business such as tree planting, the amount of carbon dioxide recovered from the atmosphere by the business is defined as a negative carbon dioxide emission, and the carbon dioxide emission calculated by the above-described embodiment is used. Can be combined with quantity. For projects such as afforestation, continuous monitoring using a measuring instrument is not possible.For example, by registering in a project file, a certain amount of negative carbon dioxide emissions are recorded regularly from the time it is implemented. You.

The scope of protection of the present invention is not limited to the above embodiments, but extends to the inventions described in the claims and their equivalents.

[0051]

As described above, according to the present invention, the amount of carbon dioxide emitted by the business can be easily calculated in real time. It is also possible to predict a future change in carbon dioxide emission based on the calculated carbon dioxide emission, and to provide a guarantee service for the calculated carbon dioxide emission. Then, by totalizing the carbon dioxide emission data of a plurality of businesses according to various classification conditions, it is possible to provide statistical data and various information according to customer needs.

According to the present invention, the business can be analyzed from the viewpoint of the carbon dioxide emission, and the reduction of the carbon dioxide emission can be promoted.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a system for implementing a carbon dioxide emission calculation method according to an embodiment of the present invention.

FIG. 2 is a block diagram of a server 10;

FIG. 3 is a diagram showing a configuration example of a customer file 17;

FIG. 4 is a flowchart of a carbon dioxide emission amount calculation method according to the embodiment of the present invention.

FIG. 5 is a flowchart of an output process of calculated carbon dioxide emission data.

FIG. 6 is a screen example of a data output site.

FIG. 7 is a screen example of a data output site.

FIG. 8 is a screen example of a data output site.

FIG. 9 is a screen example of a data output site.

FIG. 10 is a screen example of a data output site.

FIG. 11 is a screen example of a data output site.

[Explanation of symbols]

 Reference Signs List 10 server 11 control unit 12 operation processing unit 15 main program 16 operation file 17 customer file 100 terminal 200 measuring instrument 10A data output site

Claims (15)

[Claims] 1. A carbon dioxide emission calculating method for calculating an amount of carbon dioxide emitted by one or a plurality of businesses that carry out a business involving carbon dioxide emission, comprising: Measuring the amount of use of at least one related energy or the amount corresponding thereto; the step of periodically transmitting the amount of use or the amount corresponding thereto to a server via a communication line; and Or a step of calculating the amount of carbon dioxide emission based on the amount corresponding thereto. 2. The carbon dioxide emission calculation method according to claim 1, wherein the amount corresponding to the amount of energy used is a use time and an operation load of at least one device that uses energy. 3. The method according to claim 1, wherein when one company uses a plurality of energies related to carbon dioxide emission, the amount of energy consumption or the amount corresponding thereto is measured for each type of energy. To calculate carbon dioxide emissions. 4. The carbon dioxide emission according to claim 1, wherein when one business has a plurality of devices that use energy, the amount of energy consumption or the amount corresponding thereto is measured for each device. Amount calculation method. 5. The carbon dioxide according to claim 1, wherein a total amount or a cumulative amount of the calculated carbon dioxide emissions for each predetermined period is calculated for each business entity. Emission calculation method. 6. The method according to claim 5, wherein a current remaining amount or an excess amount with respect to the predetermined carbon dioxide emission amount is calculated based on a difference between the cumulative amount of the carbon dioxide emission amount and a predetermined carbon dioxide emission amount. A method for calculating carbon dioxide emissions. 7. The method according to claim 5, wherein, based on a temporal change of the cumulative amount of the carbon dioxide emission,
A method for calculating a carbon dioxide emission amount, wherein a predicted amount of a future carbon dioxide emission amount is calculated. 8. The method according to claim 5, wherein a predicted amount of future carbon dioxide emission is calculated based on a change over time of the cumulative amount of carbon dioxide emission and a change in the use condition of the apparatus. How to calculate carbon emissions. 9. The apparatus according to claim 8, wherein the use status is a quantity, a performance, a type, an operation load,
At least one of operation rate, operation time, and energy used
A method for calculating carbon dioxide emissions. 10. The method according to claim 7, wherein a future remaining amount or an excess amount with respect to the predetermined carbon dioxide emission amount is calculated based on a difference between the predicted amount and a predetermined carbon dioxide emission amount. Calculation method of carbon dioxide emission. 11. The carbon dioxide emission according to claim 5, wherein a total amount or a total amount of the total amount for each of the predetermined periods for the business operator selected from the plurality of business operators according to predetermined conditions is calculated. Amount calculation method. 12. The method according to claim 1, further comprising a step of outputting the calculated amount data to the one or more businesses and other registered people. Calculation method of carbon dioxide emission. 13. The carbon dioxide emission amount calculation method according to claim 12, wherein the calculated amount data is provided with an electronic seal stamp or an electronic signature data for giving a guarantee to the calculated amount data. 14. The method according to claim 1, wherein the energy is at least one of gas, oil, coal, and electricity. 15. A carbon dioxide emission calculation system for calculating an amount of carbon dioxide emitted by one or a plurality of businesses that carry out a business involving carbon dioxide emission, wherein: A measuring device for measuring the amount of use of at least one related energy or an amount corresponding thereto, and a server connected to the measuring device via a communication line, wherein the measuring device periodically uses the amount of use or the amount corresponding thereto. Is transmitted to the server, and the server calculates the carbon dioxide emission based on the used amount or the amount corresponding thereto.