JP2003091618A - Greenhouse effect gas emission index converting system and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a greenhouse effect gas emission index converting system and a greenhouse effect gas emission index converting method capable of performing the conversion of the emission index of the greenhouse effect gas on the basis of the input information by using a predetermined conversion formula. SOLUTION: This greenhouse effect gas emission index converting system has an information input part 9 for getting the conversion formula 10a for conversion into the emission index M of the greenhouse effect gas, and each constant GWP, Ci, Bi, etc., through the Internet 6, an input part 8 for inputting various datum Q, C, FC, h, P, a, d for calculating the emission index M of the greenhouse effect gas, an operation processing part 10 for converting the data from the input part 8 in accordance with the converting information obtained from the information input part 9, and calculating the emission index M of the greenhouse effect gas, and an information output part 11 for outputting the calculated emission index M to the Internet 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention regulates greenhouse gas emission rights based on a single emission index and trades these emission rights based on a single emission index in order to prevent global warming. The present invention relates to a greenhouse gas emission index conversion system and a greenhouse gas emission index conversion method.

[0002]

2. Description of the Related Art CO ₂ , CH ₄ , N ₂ O, HFC, PFC, SF ₆ which are conventionally defined as greenhouse gases.
It is feared that global warming will progress due to factory exhaust gas, etc., and the framework of emission rights for greenhouse gases has been agreed between countries. However, at present, the means for each country to properly exercise its greenhouse gas emission rights,
And the means and penalties for controlling this greenhouse gas emission are under deliberation.

In other words, there is no means for calculating the greenhouse gas emission index effective for the greenhouse gas emission allowance in each region and company, the regulation of the emission amount has not been decided, and the greenhouse gas emission is increasing. There is concern about the large impact on the global environment due to the emission of carbon dioxide. For this reason, it is being considered to establish some kind of regulatory measures after defining the greenhouse gas emission allowance in each region and each company, and various calculation methods for calculating the greenhouse gas emission index for that are considered. There is.

Generally, as a calculation method of a greenhouse gas emission index, carbon amount conversion is performed based on aggregate information of various research institutions and various industrial associations. For example, in the semiconductor industry, carbon equivalent value MMTCE ( Million Metric Ton Ca
The following formula (1) has been proposed and adopted as rbon Equivalent). MMTCE = 12/44 Σ {(Pi x 0.9) x (1-C) x (1-A x F) x GWPi} Equation (1) where Pi is the purchase amount, C is the consumption rate in the process, and A
Is the reduction efficiency by the abatement device, F is the decomposition rate of the abatement device, GW
Pi is the global warming potential 100-year value.

Here, the purchase amount Pi indicates the amount of greenhouse gas purchased by each company, and the reduction efficiency A indicates the efficiency guaranteed by the manufacturer of the abatement device attached to the process. F is an intergovernmental panel on climate change (hereinafter referred to as IPCC: Intergovernm
ental Panel on Climate Change)).

[0006] By limiting the greenhouse gas emission index calculated using the conversion formula such as the above formula (1), for example, within the prescribed range assigned to each company, the total amount of greenhouse gas in each company is reduced. It is believed that emissions can be capped. In other words, by determining the greenhouse gas emission index, each company voluntarily determines whether or not the total emission falls within the emission allowance, and in the future, companies that do not have sufficient emission Consideration is being given to making it possible to purchase from companies that have left over.

[0007]

However, although the consumption rate C by the process and the decomposition rate F of the abatement device vary greatly depending on the state of the process, the consumption rate C is always constant in the equation (1). It has a value. Similarly,
Although the reduction of the decomposition rate F of the abatement device is calculated as a constant reduction efficiency A, it is inevitable that a variation actually occurs. For this reason, even if accurate input is made, the greenhouse gas emission index obtained by the above equation (1) may be different from the actual value.

[0008] Therefore, the formula used for calculating the greenhouse gas emission index includes IPCC for calculating a fair value.
A number of conversion formulas (Tier1, Tier2A, Tier2) defined by (Intergovernmental Panel on Climate Change)
B, Tier2C, etc.) are considered. However, in this case, it is difficult to determine which conversion formula should be used as the basis for trading emission credits, and it may not be possible to negotiate when conducting emissions trading. Conceivable.

Further, each constant used in the conversion formula defined by the IPCC (for example, consumption rate C in the process, reduction efficiency A by the abatement device, decomposition rate F of the abatement device,
The global warming potential (GWPi, etc.) and the conversion formula itself are fluid, as they are updated from time to time with the progress of measuring instruments and the efficiency of production lines. Therefore, it was necessary to recalculate the greenhouse gas emission index because these conversion formulas and constants were reviewed.

The present invention has been made in consideration of such circumstances, and an object thereof is to convert a greenhouse gas emission index based on input information using a predetermined conversion formula. To provide a greenhouse gas emission index conversion system and a greenhouse gas emission index conversion method.

[0011]

The present invention comprises means for solving the above-mentioned problems as follows. That is, the greenhouse gas emission index conversion system of the present invention includes an information input unit that captures conversion information for converting into a greenhouse gas emission index through a network, and various types for calculating a greenhouse gas emission index. An input unit for inputting data, an arithmetic processing unit for converting the data from this input unit according to the conversion information obtained from the information input unit to calculate a greenhouse gas emission index, and the calculated emission index It is characterized by having an information output section for outputting to a network.

In the greenhouse gas emission index conversion system, the conversion information for converting the greenhouse gas emission index into the greenhouse gas emission index is fetched through the information input unit and the network, so that the conversion information can always be the latest version. At the same time, it is possible to unify the method of converting into a greenhouse gas emission index as a whole. Therefore, it is possible to regulate the amount of greenhouse gas emissions in each country, region, or company and trade the emission credits based on the greenhouse gas emission index calculated by the unified conversion method. And

Among various data input through the input unit, for example, the number of used greenhouse gas cylinders, the residual gas ratio of the return cylinders, the gas consumption rate, the type of process, the abatement device The decomposition rate can be entered using a keyboard or the like. In addition, by installing an analyzer and a flow meter that can measure the concentration and flow rate of the gas discharged through the flue, etc., these measured values are used as various data to measure greenhouse gas emission indicators. It is also possible to convert from the total amount of effect gas emissions.

When the conversion information has a conversion formula for calculating a greenhouse gas emission index, which is set by a monitoring organization that monitors the greenhouse gas emission amount, the contents of calculation by the calculation processing unit using various data. Can be easily changed, and when the conversion formula for calculating the greenhouse gas emission index is reviewed by the IPCC or the like, it can be calculated using the revised conversion formula.

Note that the calculation contents can be supplied by various methods, but can also be supplied by a calculation program which is created based on a conversion formula published by IPCC or the like and which can be executed by the calculation processing section. In addition, a conversion formula for converting various input data into a greenhouse gas emission index is represented according to a predetermined form such as a matrix operation,
It is also possible to supply the calculation contents in the form of a matrix.

Each greenhouse gas emission index conversion system
If you store multiple calculation programs that are supplied as conversion formulas, you can switch between the conversion formulas according to the situation and use them to facilitate smooth trading of emission credits. it can.

When the conversion information has respective constants used in the conversion formula for calculating the greenhouse gas emission index, which is set by the monitoring organization for monitoring the greenhouse gas emission amount, the greenhouse gas is calculated by IPCC or the like. When the constants of the conversion formula for converting into the emission index of are reviewed, this can be promptly dealt with.

The greenhouse gas emission index conversion method of the present invention incorporates conversion information for converting into a greenhouse gas emission index through an information input unit connected to a network, and at the same time, calculates a greenhouse gas emission index. Data for conversion is input through the input unit, and using this input data, it is converted into a greenhouse gas emission index according to the conversion information obtained from the information input unit, and the converted emission index is calculated. It is characterized in that the data is output via an information output unit connected to the network.

[0019]

FIG. 1 is a diagram showing an example of a greenhouse gas emission credit conversion system 1 according to the present invention. In FIG. 1, 2 is a greenhouse gas emission index converter installed in a factory or the like that emits greenhouse gases, 3 is an exhaust flow path for exhaust gas such as a flue of a factory, and 4 is attached to this exhaust flow path 3. The gas flow meter 5 is a gas analyzer for analyzing the concentration of the gas flowing through the exhaust flow path 3, 6 is the Internet, which is an example of a network, and 7 is a greenhouse gas emission index converter 2 via the Internet 6. This is an example of a connected transaction market, and in this example, it also functions as a conversion information supply terminal 7 described later.

The greenhouse gas emission index converter 2 is
An input unit 8 for inputting various data required for conversion into a greenhouse gas emission index, and an information input unit for inputting conversion information for conversion into a greenhouse gas emission index via the Internet 6. 9, an arithmetic processing unit 10 for converting various data obtained through the input unit 8 using the conversion information obtained through the information input unit 9, and a greenhouse effect gas obtained by the arithmetic processing unit 10. And an information output unit 11 for outputting the emission index of No. 1 to the Internet 6.

Reference numeral 12 is, for example, the purchase weight F of greenhouse gas.
C, greenhouse gas emission index conversion that inputs the ratio h of unused gas, process type P, plant-specific abatement device decomposition rate a, abatement device decomposition rate d for each abatement method, etc. A keyboard of the device 2, 13 is a display portion of the greenhouse gas emission index converter 2, and 14 is a monitoring body for monitoring the emission amount of greenhouse gas such as IPCC.

The exhaust flow path 3 is a portion through which all the gas exhausted from, for example, a semiconductor manufacturing process passes, and some of the gas exhausted from the organization such as a factory is exhausted.
In the case of exhausting through the exhaust gas, it is necessary to provide a pair of gas flow meters 4 and gas analyzers 5 in each exhaust pipe 3.

Various types of gas flow meters 4 can be used, but ultrasonic type, Doppler type, Karman vortex type and the like can be used.

The gas analyzer 5 is an exhaust gas flowing in the exhaust flow path 3.
Each concentration of greenhouse gas contained in gas G is rear
Can be measured in real time, preferably FTIR
(Fourier transform infrared gas analyzer). In addition,
Gas chromatography, mass spectrometer, etc.
Sometimes used. The component to be measured is, for example,
CO₂, CH_Four, N₂O, HFC, PFC, SF₆Such
In the following explanation, the concentration of each greenhouse gas is
(C_CO2, C_CH4, C_N2O, C_HFC, C_PFC, C _SF6)
Express.

It should be noted that the present invention does not limit the type of greenhouse effect gas or the type of gas analyzer 5. That is, all kinds of greenhouse effect gases may be measured, and the concentration of each greenhouse effect gas may be measured using different gas analyzers 5, respectively.

The input section 8 is, for example, the gas flow meter 4
And a signal input section 8 for inputting a measured value by FTIR5
It has an A and a key input section 8B for inputting various data by the keyboard 12. Then, the arithmetic processing unit 10 inputs various data C _CO2 ..., FC, from the input unit 8.
It has various conversion formulas 10a, ... Which calculate the greenhouse gas emission index using h, P, a, d.

The conversion formulas 10a, ... Are conversion formulas defined by a monitoring organization that monitors the emission amount of greenhouse gases such as IPCC. For example, the conversion programs 10A, 10B, which can be executed by the arithmetic processing unit 10, It is stored in the form of ... In the following description of the present example, as an example of conversion information, the greenhouse gas emission index conversion formula 10a,
Conversion programs 10A, 10 for performing calculations based on
B will be illustrated and described, but the present invention is not limited to the conversion information being the conversion programs 10A, 10B ,. That is, various modifications are possible, for example, storing a calculation matrix when the greenhouse gas emission index conversion formulas 10a, ... Are expressed by matrix calculation as conversion information.

The conversion information supply terminal 7 side communicates with the IPCC 14 via the Internet 6, for example,
The latest conversion formula 10a for calculating the greenhouse gas emission index determined by the PCC 14 and the value of each coefficient used in this conversion formula 10a, are browsed. And
The calculation processing unit 10 calculates the greenhouse gas emission index based on the conversion formula 10a, ... Revised by the IPCC 14.
Conversion programs 10A and 10 that can be executed by
B, ... are created, and the conversion programs 10A, 10B,
Is delivered to each greenhouse gas emission index converter 2 via the Internet 6 or the like.

Therefore, each greenhouse gas emission index converter 2 uses a common conversion formula by executing a designated program among the conversion programs 10A, 10B, ... Received from the conversion information supply terminal 7. A greenhouse gas emission index (for example, carbon equivalent value) M can be calculated, and this can be displayed on the display unit 13. Further, each greenhouse effect gas emission index converter 2 outputs the greenhouse effect gas emission index M via the information output unit 11, thereby trading the greenhouse effect gas emission right with other greenhouse effect gas emission index converters. It is also possible. At this time, the trading market 7 can also act as an intermediary.

With the configuration of this example, the conversion formulas 10a, ... For calculating the greenhouse gas emission index can be changed all at once by a command from the conversion information supply terminal 7. , Using the adjusted conversion formula,
The overall greenhouse gas emission index can be calculated very easily. That is, the conversion formula of the greenhouse effect gas emission index determined by the IPCC 14 or the like can be easily used for guidance for reducing the amount of greenhouse effect gas emission, greenhouse gas emission rights trading, and the like.

It should be noted that, in the case of trading of greenhouse gas emission rights, when there is an agreement between the parties involved in the trading, calculation was made using a conversion formula different from the conversion formula of the greenhouse gas emission index established by IPCC14 or the like. It goes without saying that you can trade emissions credits. Further, the distribution of the conversion programs 10A, 10B ... and the designation of the conversion formula used for calculating the greenhouse gas emission index are not limited to being performed from the conversion information supply terminal 7 such as a trading market.
IPCC14, JEITA (Japan Electronics and Information Technology I)
ndustries Association), a government agency (Ministry of Economy, Trade and Industry), etc.

On the other hand, as conversion formulas for calculating the greenhouse gas emission index, several conversion formulas have been proposed at present, for example. That is, the conversion formula for calculating an approximate value of total greenhouse gas emissions (greenhouse gas emission index) called “Tier 1” by the IPCC 14 is expressed by the following formula (2) when expressed by carbon equivalent value (MMTCE). )
It is defined as. MMTCE = 12/44 Σ {(1-h) × FCi × (1-Ci) × GWPi + (1-h) × Bi × FCi × GWP _CF4 }… Equation (2) where FCi is the i-th purchased gas Weight, GWP _FCi is the 100-year value of the global warming potential GWP of the i-th gas, h is the ratio of the residual gas in the return cylinder, Ci is the default value of the gas consumption rate, and Bi is the production rate of CF ₄ gas, which is a by-product. Default value of GWP _FCi is 1 of global warming potential GWP of CF ₄ gas
It is the year 00 value. In addition, global warming potential GWP of 100
The year value is one of the conversion information defined in the IPCC 14, and is currently defined as shown in Table 1 below as an example. The value of the global warming potential GWP is kept updated by the latest value being delivered from the conversion information supply terminal 7 when a change occurs.

[0033]

[Table 1]

Further, according to IPCC14, "Tier2
The conversion formula for calculating the approximate value of the total amount of greenhouse gas emissions called “B” and “Tier 2C” (greenhouse gas emission index) is expressed in terms of carbon equivalent value (MMTCE) as shown in the following formula (3). Has been defined. MMTCE = 12/44 Σ {(1-h) × FCi × (1-Ci) × (1-a _i d _i ) × GWPi + (1-h) × Bi × FCi × (1-a _i d _CF4 ) GWP _CF4 } Equation (3) where a _i is the decomposition rate of the abatement device unique to the i-th gas plant, d _i is the abatement device decomposition rate, and d _CF4 is the abatement device CF ₄ decomposition. The rate and others are the same as in the equation (2).

In the case of Tier2C, the default value B
i and Ci are constant values regardless of plant type, and Ti
In the case of er2B, the default value Bi, C is used depending on whether the plant is dry etching or CVD.
The value of i is different.

The conversion formula for calculating the approximate value of the total amount of greenhouse gas emissions called "Tier 2A" (greenhouse gas emission index) is the carbon equivalent value (MMTCE) shown in the following formula (4). It is defined as. Where p is the number of processes or types of processes, FCi, p is the weight of the i-th purchased gas in process p, Ci, p is the default value of the consumption rate of the i-th gas in process p,
a _ip is the decomposition rate of the abatement device unique to the company or plant of the i-th gas in process p, _dij is the decomposition rate for each abatement method, and Bi, p is the production rate of CF ₄ gas generated in process p. , D
_CF4j is the decomposition rate of CF _{4 in} the abatement system, and others are expressed by the formula (2),
Same as (3).

The conversion formulas shown in the formulas (2) to (4) are calculated mainly by using various data (FC, h, P, a, d) etc. inputted through the keyboard 12. However, the gas consumption rate C in equations (2) and (3)
i and the CF ₄ gas production rate Bi are the information input unit 9
Are constants (default values) used in the conversion formulas 10a, ... Therefore, these constants Ci, Bi
Can be adjusted at any time according to the judgment of the IPCC 14, but by using the greenhouse gas emission index conversion system 1 of the present invention, this can be promptly dealt with. Needless to say, these constants Ci and Bi and the conversion formulas 10a, ... May be input from the keyboard 12. On the other hand, the gas consumption rate Ci, p and the CF ₄ gas production rate Bi, p in the equation (4) are obtained from the values measured by the gas analyzer 5.

In addition, the greenhouse gas emission index conversion system of this example is
The stem 1 has a gas flow meter 4 and a gas component in the exhaust passage 3.
Since an analyzer 5 is provided, it can be obtained from these measuring instruments 4 and 5.
By multiplying the measured values Q and C thus obtained,
Greenhouse gas CO₂, CH_Four, N₂O, HFC, PF
C, SF₆Emissions Q_i(Q_CO2, Q_CH4, Q_N2O, Q
_HFC, Q_PFC, Q_SF6) Is also possible. formula
(5) shows this relationship.   Q_i= C_i× Q ... Formula (5) However, i is a greenhouse gas CO₂, CH_Four, N₂O, HF
C, PFC, SF₆Indicates the type of.

Further, each greenhouse gas CO
₂, CH_Four, N₂O, HFC, PFC, SF₆Emissions
Is multiplied by the global warming potential GWP to calculate the sum
And, as shown in equation (6), CO₂Converted greenhouse effect
Instantaneous value Q of total gas emissions _totalCan ask
It   Q_total= Σ (C_i× Q × GWP_i) ... Formula (6) However, i is a greenhouse gas CO₂, CH_Four, N₂O, HF
C, PFC, SF₆Indicates the type of.

Then, the calculation processing unit 2 causes the instantaneous value Q of the discharge amount to
_As shown in equation (7), total greenhouse gas emissions (carbon equivalent value:
MMTCE) can be obtained. MMTCE = ∫Q _total ... Formula (7)

That is, since the greenhouse gas emission index conversion system 1 of the present invention has the gas flow meter 4, the gas analyzer 5 and the signal input section 8A for inputting the measurement signals C, Q ... By using the total amount of greenhouse gas emissions of the above as a greenhouse gas emission index, the greenhouse gas emission index can be made more accurate and can be made a fairer index.

When the greenhouse gas emission index is calculated by the calculation shown in the above equations (5) to (7),
Since it is not necessary to input the numerical data using the keyboard 12, not only the troublesome input work is eliminated,
It is possible to detect the deterioration of the efficiency of the abatement system and the occurrence of abnormalities in the plant at an early stage and take appropriate measures. Above all,
The FTIR illustrated as an example of the gas analyzer 5 can freely set the measurement components. Therefore, a new gas designated as a greenhouse gas by the IPCC 14 or the like is input as a part of the conversion information and used. It is also possible to convert the greenhouse gas emission index.

In each of the conversion formulas described above, an example in which the greenhouse gas emission index M is expressed by carbon equivalent value (MMTCE) is shown, and the degree of the greenhouse effect is appropriately calculated using a one-dimensional numerical value. Is expressed in. However, the present invention does not limit this point. That is, the greenhouse gas emission index M may be an index that represents the total emission amount of each greenhouse gas.

In any of the above cases, the feature of the greenhouse gas emission index conversion system 1 of the present invention is that the greenhouse gas emission index M as shown in the above equations (2) to (7) is used. Network 6 to calculate conversion formula (conversion information)
Each greenhouse gas emission index converter 2
Is to calculate greenhouse gas emission rights based on a single emission index.

Further, when each greenhouse gas emission index converter 2 stores a plurality of conversion programs 10A, 10B ... As in this example, when each company agrees with each other, the general trading market It is also possible to trade the emission credits by using a greenhouse gas emission index calculated according to another conversion formula different from the conversion formula defined by 7 or IPCC14.

In addition, by using the greenhouse gas emission index conversion system 1 of the present invention, the trading market 7 and I
It is also possible to set the amount R of carbon dioxide per unit amount of carbon dioxide used in the greenhouse gas emission trading (that is, the converted value of the emission index and the transaction amount) by the PCC 14 or the like. That is, as shown in the following formula (8), the greenhouse gas emission index P (a transaction value) can be calculated by multiplying the greenhouse gas emission index M by the conversion value R. P = M × R ... Formula (8)

That is, the conversion result information obtained by conversion by the arithmetic processing unit 10 using the conversion formula and output through the Internet 6 is the greenhouse gas emission index M (especially carbon equivalent value MMTCE). Not only it can be represented by the transaction amount, the total amount of each greenhouse gas, the total amount of CO ₂ , and the like.

When trading with countries with different currencies, by considering the exchange rate as the conversion value R, greenhouse gas emission rights can be traded between different countries. .

In addition, the information output unit 11 is the Internet 6
Emission index M of greenhouse gas to the trading market 7 via
By outputting, the trading market 7 can confirm how much greenhouse gas is emitted in each factory. In other words, the trading market 7 adjusts so that the greenhouse gas can be kept within a predetermined range for the entire region, while companies with excessive greenhouse gas emissions have a sufficient amount of greenhouse gas emissions. Greenhouse gas emission rights can be purchased from companies.

The present invention does not limit that the greenhouse gas emission index M from each company is output only to the trading market 7. That is, it is also possible to output the greenhouse gas emission index M or the like to a governmental organization (Ministry of Economy, Trade and Industry) or JEITA corporation.

FIG. 2 shows another example of the greenhouse gas emission index conversion system of the present invention. In FIG. 2, members given the same reference numerals as those in FIG. 1 are the same or equivalent members, and thus detailed description thereof will be omitted.

In FIG. 2, 10 'is an arithmetic processing unit installed in each company, 3a and 3b are exhaust passages managed by the arithmetic processing unit 10', 4a and 4b are exhaust passages 3a and 3b.
Gas flowmeters 5a and 5b provided in the respective units, gas analyzers 8a and 8b, input units for inputting measured values Qa, Ca, Qb and Cb by the respective measuring instruments 4a, 4b, 5a and 5b,
Reference numerals 12a and 12b are keyboards, and 14a and 14b are input / output units that connect the signal input units 8a and 8b to the arithmetic processing unit 2a via the Internet 6. And 15, 16
Is a measurement unit provided in each of the exhaust flow paths 3a and 3b.

Reference numeral 17 is an input / output unit (information input unit and information output unit) on the side of the arithmetic processing unit 10 ', and 18 is a display unit for displaying the greenhouse gas emission amount calculated by the arithmetic processing unit 10'. is there.

That is, by configuring as in this example, the arithmetic processing unit 10 'attaches the measurement units 15 and 16 to the plurality of exhaust flow paths 3a and 3b owned by each company respectively, and connects them to the network 6. Using arithmetic processing unit 1
By connecting to 0 ', a greenhouse gas emission credit conversion system 1'can be formed.

Therefore, each company has an exhaust flow path 3a, 3b.
By appropriately attaching the measuring units 15, 16 ... According to the number of ..., the emission index M of all greenhouse gases emitted by this company can be easily confirmed in real time. In other words, it is possible to accurately understand how much emission is being carried out for the allocated emission allowance, purchase the emission credit from the company with surplus, and sell the surplus to other companies. it can. Further, since the measuring units 15, 16 ... Have a simple structure, it is possible to suppress the manufacturing cost thereof as much as possible.

Further, like the present example, the arithmetic processing unit 10 'can be formed by using a desired conversion function formed on the network 6, and the configuration thereof is not limited. In the case of the present example, an example in which a server or the like is arranged for each company and the arithmetic processing unit 10 ′ is formed using this server is shown, but it may be executed by another computer on the network 6. For example, the trading market 7 is each measurement unit 1
When monitoring the measured values by 5, 16
It is also possible to monitor whether each company is operating properly in terms of the global environment.

In any case, each arithmetic processing unit 10 '
Since the conversion process to the greenhouse gas emission index is performed using the conversion formula 10a that conforms to the standard set by the PCC14 organization and a constant (conversion information), a greenhouse gas is generated using a single conversion formula common to all. The effect gas emission index can be calculated, and fair emission rights can be traded.

In addition, the greenhouse gas emission index conversion can be performed in a hierarchical structure. That is, for example, the total emission indicators aggregated for each company are summarized for each region to calculate the total amount of greenhouse gas emissions in each region, or the total emission indicators aggregated in each region are used for each country. It is also possible to confirm the total amount of greenhouse gases emitted in each country by collecting in. Further, trading of greenhouse gases may be carried out not only between companies but also between countries or between municipalities.

In the above example, the Internet 6 which is generally popular is used as an example of the network 6, but the present invention is not limited to this. That is, it goes without saying that security may be improved by using a limited communication network such as an intranet instead of the Internet.

[0060]

As described above, by using the greenhouse gas emission index conversion system and the greenhouse gas emission index conversion method of the present invention, the greenhouse gas emission amount is converted into a common single transaction index. In addition to the above, it is possible to convert the greenhouse gas emission index using the latest conversion formula and conversion coefficient.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a greenhouse gas emission credit conversion system of the present invention.

FIG. 2 is a diagram showing another example of the greenhouse gas emission credit conversion system.

[Explanation of symbols] 1,1 '... Greenhouse gas emission credit conversion system, 4, 4
a, 4b ... Flowmeter, 5, 5a, 5b ... Gas analyzer, 6 ...
Network, 8, 8a, 8b ... Input unit, 9, 17 ... Information input unit, 10, 10 '... Arithmetic processing unit, 10a ... Conversion formula (conversion information), 10A, 10B, ... Conversion program (conversion information), 11 , 17 ... Information output unit, 14 ... Monitoring agency for monitoring greenhouse gas emissions, C, Q, FC, h,
P, a, d ... Various data, Bi, Bi, p, Ci, Ci, p ... Constant (conversion information), GWP ... Global warming potential (conversion information),
M: Greenhouse gas emission index.

Claims (6)

[Claims] 1. An information input unit for taking in conversion information for converting into a greenhouse gas emission index through a network, and an input unit for inputting various data for calculating a greenhouse gas emission index. An arithmetic processing unit for converting the data from this input unit according to the conversion information obtained from the information input unit to calculate a greenhouse gas emission index, and an information output unit for outputting the calculated emission index to the network A greenhouse gas emission index conversion system comprising: 2. The greenhouse gas emission index conversion system according to claim 1, wherein the conversion information includes a conversion formula for calculating a greenhouse gas emission index determined by a monitoring organization that monitors a greenhouse gas emission amount. . 3. The greenhouse according to claim 1, wherein the conversion information has respective constants used in a conversion formula for calculating a greenhouse gas emission index, which is set by a monitoring organization that monitors the greenhouse gas emission amount. Effect gas emission index conversion system. 4. The conversion information for converting into a greenhouse gas emission index is taken in through an information input unit connected to a network, and the data for converting into a greenhouse gas emission index is input through an input unit. Input, and using this input data, it is converted into a greenhouse gas emission index according to the conversion information obtained from the information input unit, and the converted emission index is output via the information output unit connected to the network. A method for converting greenhouse gas emission indicators, which is characterized in that 5. The greenhouse according to claim 4, wherein a conversion formula determined by a monitoring organization that monitors greenhouse gas emissions through the network is imported, and the conversion is performed using the imported conversion formula. Effect gas emission rights exercise conversion method. 6. The constants of a conversion formula defined by a monitoring organization that monitors greenhouse gas emissions through the network are taken in, and the conversion is performed using the constants of the conversion formula taken in. The method for exercising greenhouse gas emission credits according to item 4 or 5.