JP2004126843A - System and method for calculating amount of carbon-dioxide emission in water treatment facility - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a carbon-dioxide emission calculating system and method capable of easily and reliably calculating the amount of carbon-dioxide emission in the construction stage of water treatment facilities. <P>SOLUTION: An input part 32 inputs the amount of consumption of prescribed construction materials and construction energy used for the construction of the water treatment facilities. A first storage part 31d stores preliminarily the emission original unit of carbon-dioxide corresponding to the individual construction materials and/or construction energy. Then, a CPU 31a calculates the amount of the carbon-dioxide emission in the construction stage of the water treatment facilities on the basis of: the consumption of the individual construction materials and construction energy inputted by the input part 32; and the emission original unit of the carbon-dioxide corresponding to the individual construction materials and construction energy stored in the storage part 31d. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a system and a method for calculating carbon dioxide emissions in various water treatment facilities.
[0002]
[Prior art]
Since the "International Conference on Environment and Development (Earth Summit)" held in Rio de Janeiro, Brazil in 1992, the spirit of global environmental conservation has been increasing internationally, and global warming and air and water quality caused by greenhouse gases are now increasing. Environmental problems, such as pollution, have become a common issue for humankind.
[0003]
At the so-called COP3, “The 3rd Conference of the Parties to the Framework Convention on Wakeup and Fluctuations” held in Kyoto in December 1997, as one of the concrete initiatives for environmental protection, greenhouse gases such as carbon dioxide were released in 1990. It was determined that the average annual reduction from 2008 to 2012 was 6%.
[0004]
In response, energy saving systems such as cogeneration systems and heat storage / power storage systems have been used in various water treatment facilities, and reductions in carbon dioxide emissions have been promoted. In order to reduce carbon dioxide emissions efficiently and effectively, it is important to first understand carbon dioxide emissions, but conventional carbon dioxide emissions are calculated only during the operation stage. Was.
[0005]
[Problems to be solved by the invention]
However, many construction materials and energy are input to water treatment facilities, and the construction stage emits a large amount of carbon dioxide. The calculation has a problem that the actual state of environmental load in the water treatment facility cannot be correctly evaluated.
[0006]
The present invention has been made in view of the above-described problems, and can easily and reliably determine the amount of carbon dioxide emitted during the construction stage of a water treatment facility. It is an object of the present invention to provide a carbon dioxide emission calculation system and method that can be evaluated.
[0007]
[Means for Solving the Problems]
The present invention is a carbon dioxide emission calculation system for calculating carbon dioxide emissions in a water treatment facility, in order to achieve the above object,
An input unit for inputting a usage amount of construction materials and / or construction energy used for construction of the water treatment facility, and a first unit for storing in advance a unit of emission of carbon dioxide corresponding to the construction materials and / or construction energy. Storage unit, the usage amount of the construction material and / or construction energy input by the input unit, and the emission of carbon dioxide corresponding to the construction material and / or construction energy stored in the first storage unit A first calculation unit for calculating the amount of carbon dioxide emitted during the construction stage of the water treatment facility based on the basic unit.
[0008]
Note that the construction energy refers to fuel, electric power, and the like consumed by various machines such as civil engineering and construction machines used in the construction of the water treatment facility. Further, the unit of carbon dioxide emission refers to the amount of carbon dioxide emitted per predetermined unit amount of construction material or construction energy.
[0009]
According to this, the amount of carbon dioxide emitted during the construction stage of the water treatment facility can be easily and reliably obtained, and the actual environmental load of the water treatment facility can be correctly evaluated.
[0010]
Further, a measuring unit for measuring the consumption and / or generation amount of the operating energy consumed and / or generated in the operation stage of the water treatment facility, and the emission unit of carbon dioxide corresponding to the operating energy are stored in advance. A second storage unit, based on the consumption and / or generation amount of the driving energy measured by the measurement unit, and a carbon dioxide emission intensity corresponding to the driving energy stored in the second storage unit. And a second calculator for calculating the amount of carbon dioxide emitted during the operation stage of the water treatment facility. The operating energy refers to gas, electric power, heat, or the like consumed or generated during operation of the water treatment facility.
[0011]
According to this, the emission amount of carbon dioxide in the operation stage of the water treatment facility can be easily and reliably obtained.
[0012]
In addition, an input unit for inputting a used amount of materials and / or waste energy used for disposal of the water treatment facility, and an emission unit of carbon dioxide corresponding to the materials and / or waste energy are stored in advance. A third storage unit, a usage amount of the material and / or waste energy input by the input unit, and emission of carbon dioxide corresponding to the material and / or waste energy stored in the third storage unit Preferably, a third calculation unit for calculating the amount of carbon dioxide emitted at the disposal stage of the water treatment facility based on the basic unit is provided. In addition, the waste energy refers to gas or electric power consumed in various machines such as civil engineering and construction machines used when disposing of a water treatment facility.
[0013]
According to this, the emission amount of carbon dioxide in the disposal stage of the water treatment facility can be easily and reliably obtained.
[0014]
Further, it is preferable that the consumption and / or generation amount of the driving energy measured by the measurement unit is transmitted to the second calculation unit via a network.
[0015]
According to this, the consumption and / or generation of operating energy is collected using a network such as the Internet, so that it is possible to centrally manage the carbon dioxide emission in the operation stage of the water treatment facility. it can.
[0016]
Further, the present invention is a carbon dioxide emission calculation method for calculating the carbon dioxide emission in a water treatment facility by a computer system,
The construction material and / or construction energy used for the construction of the water treatment facility is input by the input unit, and the emission unit of carbon dioxide corresponding to the construction material and / or construction energy is stored in the first storage unit in advance. Based on the used amount of the construction material and / or the construction energy input by the input unit and the emission unit of carbon dioxide corresponding to the construction material and / or the construction energy stored in the storage unit. It is characterized in that the amount of carbon dioxide emission in the construction stage of the water treatment facility is calculated by the first calculation unit.
[0017]
According to this, the amount of carbon dioxide emitted during the construction stage of the water treatment facility can be easily and reliably obtained, and the actual environmental load of the water treatment facility can be correctly evaluated.
[0018]
Furthermore, the consumption and / or generation amount of the operating energy consumed and / or generated in the operation stage of the water treatment facility is measured by the measuring unit, and the emission unit of carbon dioxide corresponding to the operating energy is calculated as the second unit. It is stored in advance in a storage unit, and is based on the consumption and / or generation amount of the operation energy measured by the measurement unit and the carbon dioxide emission intensity corresponding to the operation energy stored in the second storage unit. Preferably, the amount of carbon dioxide emission in the operation stage of the water treatment facility is calculated by the second calculation unit.
[0019]
According to this, the emission amount of carbon dioxide in the operation stage of the water treatment facility can be easily and reliably obtained.
[0020]
Further, the amount of material and / or waste energy used for disposal of the water treatment facility is input by the input unit, and the unit of emission of carbon dioxide corresponding to the material and / or waste energy is stored in the third storage unit. Unit and the amount of use of the material and / or waste energy input by the input unit and the emission source of carbon dioxide corresponding to the material and / or waste energy stored in the third storage unit It is preferable that the amount of carbon dioxide emitted in the disposal stage of the water treatment facility is calculated by the third calculation unit based on the unit.
[0021]
According to this, the emission amount of carbon dioxide at the disposal stage of the water treatment facility can be easily and reliably obtained.
[0022]
Further, the computer program according to the present invention is a program for calculating a carbon dioxide emission amount in a water treatment facility,
The computer stores in advance an input unit for inputting a usage amount of construction materials and / or construction energy used for the construction of the water treatment facility, and an emission unit of carbon dioxide corresponding to the construction materials and / or construction energy. A first storage unit, a usage amount of the construction material and / or construction energy input by the input unit, and a carbon dioxide emission intensity corresponding to the construction material and / or construction energy stored in the storage unit Based on the above, it functions as a first calculation unit that calculates the amount of carbon dioxide emitted during the construction stage of the water treatment facility.
[0023]
According to this, by downloading this program to the computer, the carbon dioxide emission amount calculation system can be realized simply and reliably.
[0024]
Further, the computer-readable recording medium according to the present invention is a computer-readable recording medium in which a program for calculating the amount of carbon dioxide emission in a water treatment facility is recorded,
The computer stores in advance an input unit for inputting a usage amount of construction materials and / or construction energy used for the construction of the water treatment facility, and an emission unit of carbon dioxide corresponding to the construction materials and / or construction energy. A first storage unit, a usage amount of the construction material and / or construction energy input by the input unit, and a carbon dioxide emission intensity corresponding to the construction material and / or construction energy stored in the storage unit Based on the above, a program for functioning as a first calculation unit for calculating the amount of carbon dioxide emitted during the construction stage of the water treatment facility is recorded.
[0025]
According to this, by installing the program recorded on the recording medium into the computer, the carbon dioxide emission calculation system can be realized simply and reliably.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
[Embodiment 1]
Next, an embodiment of the present invention will be described.
[0027]
FIG. 1 is a schematic configuration diagram of a carbon dioxide emission amount calculation system according to this embodiment.
[0028]
In FIG. 1, (1) is a cogeneration system (hereinafter, referred to as a cogeneration) provided in a water treatment facility (M), (2) is a measuring instrument provided in the cogeneration (1), and (3) is a measuring instrument ( A personal computer (hereinafter referred to as a personal computer) connected to 2) via a dedicated line (4).
[0029]
The cogeneration (1) uses kerosene, heavy oil, city gas, or the like as a fuel to generate electricity using a diesel engine generator or a gas turbine generator, and at the same time, recovers waste heat or cooling water of the engine or turbine. , And is used for cooling and heating, hot water supply, and the like of a building provided with a water treatment facility (M). The cogeneration (1) includes various modes such as a gas engine cogeneration (1), a gas turbine cogeneration (1), and a fuel cell cogeneration (1). In this embodiment, the gas engine cogeneration (1) is used.
[0030]
The measuring device (2) includes a gas meter (2a) for measuring the amount of gas input to the cogeneration (1), a power meter (2b) for measuring the amount of power generated from the cogeneration (1), and a cogeneration (1). )) And a calorie meter (2c) for measuring the amount of heat generated from the calorimeter. Then, the gas amount, the electric power amount, and the heat amount measured by the measuring device (2) are transmitted to the personal computer (3) continuously or periodically via the dedicated line (4) or wirelessly. It has become.
[0031]
The personal computer (3) includes a personal computer (31), an input unit (32) including a keyboard and a mouse, and an output unit (33) including a display and a speaker.
[0032]
FIG. 2 is a diagram showing a hardware configuration of the personal computer (3).
[0033]
In FIG. 2, (31a) is a central processing unit (hereinafter, referred to as CPU) for controlling various parts, displaying various screens, transferring data, performing various calculations, and the like, and (31b) is for performing various processes. (31c) is a RAM for appropriately storing data and programs required when the CPU (31a) executes various processes, and (31d) is a CO2 emission unit shown in FIG. A storage unit for storing a reference table; (31e) a drive for executing reading and writing of a program from a recording medium such as a CD-ROM; and (31f) a communication unit for communicating with the measuring unit (2) of the cogeneration system (1) , (31g) are input / output interfaces for controlling input / output of each unit, and include the CPU (31a), ROM (31b), RAM (31c), and input / output interface. 31 g) are connected via a bus (31h), respectively.
[0034]
The CPU (31a) calculates a carbon dioxide emission amount in the construction stage of the water treatment facility (M) according to a program stored in the ROM (31b) (hereinafter, a construction stage CO2 emission calculation function (A )) And a function of calculating the amount of carbon dioxide emission in the operation stage of the water treatment facility (M) (hereinafter, referred to as an operation stage CO2 emission calculation function (B)).
[0035]
The construction stage CO2 emission calculation function (A) further includes a function of calculating the amount of carbon dioxide emitted from the construction material (hereinafter referred to as a construction material CO2 emission calculation function (A1)), and (Hereinafter referred to as a construction process CO2 emission calculation function (A2)).
[0036]
The above-mentioned construction material CO2 emission calculating function (A1) is used to calculate the amount of carbon dioxide emitted from each construction material used for the construction of the water treatment facility (M), such as concrete, reinforcing steel, steel plates, steel pipe, cast iron, and vinyl chloride. Is a function for calculating Specifically, this function (A1) is to multiply the amount of use of each construction material by the unit of emission of carbon dioxide of the corresponding construction material (see FIG. 3), thereby obtaining the carbon dioxide associated with each construction material. Calculate the amount of emissions.
[0037]
For example, the carbon dioxide emissions of concrete used to construct the water treatment facility (M) are:
Carbon dioxide emissions from concrete (kg · C)
= Concrete usage (m ³ ) × Intensity unit (62.97 kg · C / m) ³ )… [1]
Is calculated by In addition, the amount of carbon dioxide emitted from each construction material is calculated, for example, as shown in FIG.
[0038]
In addition, the usage amount of each construction material is acquired by the CPU (31a) by being input from the input unit (32) by the operator. Further, the emission unit of carbon dioxide of each construction material is obtained by the CPU (31a) from the CO2 emission unit reference table shown in FIG. 3 stored in the storage unit (31d).
[0039]
The construction process CO2 emission calculation function (A2) is used for construction energy (light oil, electric power, etc.) of civil engineering and construction machinery used in each construction process such as excavation, backfill, residual soil disposal, material transportation, pile driving, and sheet pile. ) Is a function for calculating the carbon dioxide emission. Specifically, this function (A2) is to multiply the amount of construction energy used in each construction process, such as civil engineering and construction machinery, by the carbon dioxide emission intensity (see FIG. 3) corresponding to each construction energy. By doing so, the amount of carbon dioxide emissions related to each construction process is calculated. The amount of carbon dioxide emitted in each of these construction steps is calculated, for example, as shown in FIG.
[0040]
The amount of construction energy used for the civil engineering and construction machines used in each construction process is acquired by the CPU (31a) by being input from the input unit (32) by the operator. Further, the emission unit of carbon dioxide of each energy is obtained by the CPU (31a) from the CO2 emission unit reference table shown in FIG. 3 stored in the storage unit (31d).
[0041]
On the other hand, the operation stage CO2 emission calculation function (B) is a function of calculating the carbon dioxide emission amount for each operation energy (gas, electric power, heat) consumed or generated in the operation stage of the water treatment facility (M). It is. More specifically, this function (B) includes the gas amount, electric amount, and heat amount transmitted from the gas meter (2a), the power meter (2b), and the calorimeter (2c) via a dedicated line or wireless. Is a function of calculating the carbon dioxide emission amount in the operation stage by multiplying the carbon dioxide emission intensity (see FIG. 3) corresponding to the gas, electric power and heat.
[0042]
For example, as shown in FIG. ³ When a city gas (13A: equivalent to 11000 kcal) is input, the cogeneration (1) generates electric power equivalent to 3850 kcal (4.447455 kwh) at a conversion efficiency of 35% and heat equivalent to 4950 kcal at a conversion efficiency of 45%. At this time, gas 1Nm ³ Since the carbon dioxide emission per unit (carbon equivalent) is 0.639 kg · C, the carbon dioxide emission of the input gas (carbon equivalent) is 0.639 kg · C / Nm ³ × 1Nm ³ = 0.639 kg · C. In addition, the amount of carbon dioxide emission (carbon equivalent) per 1 kWh of power generated by thermal power generation is 0.1047 kg · C, so the amount of carbon dioxide emission (carbon equivalent) when the generated electric power is obtained from a power company as before is 0.1047 kg · C. 1047 kg · C / kwh × 4.447455 kwh = 0.468 kg · C. When a gas corresponding to the generated heat is obtained from a gas company, the carbon dioxide emission (carbon equivalent) is 0.639 kg · C / Nm. ³ X 4950 kcal / 11000 kcal = 0.288 kg · C. Therefore, by using the cogeneration (1), compared with the conventional use of electric power and gas, (0.468 kg · C + 0.288 kg · C) −0.639 kg · C = 0.117 kg · C of carbon dioxide Emissions (carbon equivalent) can be reduced. Note that, in this example, the amount of carbon dioxide emitted is converted into carbon.
[0043]
In the water treatment facility (M), it is preferable to recycle the hot waste water. For example, normally, the energy required to raise 10 t of water or well water from 15 ° C. to 40 ° C. is 1 cal / ° C. · g × (40−15) ° C. × 10 t = 250 Mkcal, which is reduced to the required temperature with city gas. To do this, 250Mkcal / 11Mkcal = 22.72Nm ³ City gas is required. On the other hand, when hot waste water (for example, 30 ° C.) is used for recycling 10 tons, the required energy is 1 cal / ° C. · g × (40−30) ° C. × 10 t = 100 Mkcal. , 100Mkcal / 11Mkcal = 9.09Nm ³ City gas is required. Therefore, the use of hot wastewater is 22.72 Nm compared to the case where it is not used. ³ -9.09Nm ³ = 13.63 Nm ³ City gas can be saved. This is 0.639kg · C / Nm ³ X 13.63 Nm ³ = 8.71 kg of carbon dioxide emissions (carbon equivalent) will be reduced.
[0044]
The emission unit of carbon dioxide corresponding to the gas, electric power and heat is obtained by the CPU (31a) from the CO2 emission unit reference table shown in FIG. 3 stored in the storage unit (31d). You.
[0045]
FIG. 7 is a flowchart showing a method for calculating the amount of carbon dioxide emitted from the construction material. In the following description and drawings, “step” is abbreviated as “S”.
[0046]
First, the operator inputs from the input unit (32) the amount of each construction material used in the water treatment facility (M), such as concrete, reinforcing steel, steel plates, steel pipe, cast iron, and vinyl chloride (S1). .
[0047]
Then, the CPU (31a) refers to the CO2 emission intensity reference table shown in FIG. 3 stored in the storage unit (31d), and acquires the input emission intensity of carbon dioxide of each construction material ( S2).
[0048]
Then, the CPU (31a) multiplies the amount of use of each construction material input from the input unit (31d) by a unit of emission of carbon dioxide of each corresponding construction material, thereby obtaining a value related to each construction material. Calculate carbon dioxide emissions (S3)
Then, the CPU (31a) outputs the calculated amount of carbon dioxide emission related to each construction material to an output unit (33) such as a display in a predetermined format for use by the user (S4).
[0049]
According to this, it is possible to easily and reliably obtain the amount of carbon dioxide emitted from each construction material used for the construction of the water treatment facility (M).
[0050]
FIG. 8 is a flowchart showing a method for calculating the amount of carbon dioxide emitted in the construction process.
[0051]
First, the operator inputs, from the input unit (32), construction energy (light oil, electric power, etc.) of civil engineering and construction machinery used in each construction process such as excavation, backfilling, disposal of remaining soil, material transport, pile driving, sheet pile, and the like. ) Is used (S11).
[0052]
Then, the CPU (31a) refers to the CO2 emission intensity reference table shown in FIG. 3 stored in the storage unit (31d), and acquires the carbon dioxide emission intensity of each input construction energy ( S12).
[0053]
Then, the CPU (31a) multiplies the amount of use of each construction energy input from the input unit (31d) by a unit of emission of carbon dioxide of each corresponding construction energy, thereby controlling each construction process. The amount of carbon dioxide emission is calculated (S13).
[0054]
Then, the CPU (31a) outputs the calculated emission amount of carbon dioxide related to each construction process to an output unit (33) such as a display in a predetermined format, and provides it to the user for viewing (S14).
[0055]
According to this, it is possible to easily and reliably calculate the amount of carbon dioxide emitted in each construction process of the water treatment facility (M), and to calculate the amount of carbon dioxide emitted in each construction process described above. Thus, the amount of carbon dioxide emitted during the construction stage of the water treatment facility (M) can be easily and reliably calculated.
[0056]
FIG. 9 is a flowchart illustrating a method of calculating the amount of carbon dioxide emission in the operation stage.
[0057]
First, each measuring instrument (2) of the gas meter (2a), the power meter (2b), and the calorimeter (2c) respectively measures the amount of gas input, the amount of generated power and the amount of heat in the cogeneration (1). It measures (S21).
[0058]
Then, each measuring device (2) transmits the measured gas amount, electric power amount, and heat amount to the personal computer (3) via the dedicated line (4) (S22).
[0059]
In the personal computer (3), the CPU (31a) receives the gas amount, the electric power amount, and the heat amount transmitted from each measuring instrument (2) (S23).
[0060]
Then, the CPU (31a) refers to the CO2 emission intensity reference table stored in the storage unit (31d), and acquires the carbon dioxide emission intensity corresponding to gas, electric power, and heat (S24). .
[0061]
The CPU (31a) multiplies the transmitted gas amount, electric amount, and heat amount by the emission unit of carbon dioxide corresponding to the gas, electricity, and heat, thereby obtaining carbon dioxide in the operation stage. Is calculated (S25).
[0062]
Then, the CPU (31a) outputs the calculated carbon dioxide emission amount at the operation stage to an output unit (33) such as a display in a predetermined format, and provides the output to the user (S26).
[0063]
According to this, it is possible to easily and reliably calculate the amount of carbon dioxide emitted during the operation stage of the water treatment facility (M), and to calculate the amount of carbon dioxide emitted during the construction stage of the water treatment facility (M) described above. At the same time, it is possible to correctly evaluate the actual state of the environmental load in the water treatment facility (M).
[0064]
Therefore, based on the carbon dioxide emissions calculated as described above, the life cycle stage with a high environmental load and room for improvement is grasped, and materials, processes and technologies with a smaller environmental load will be adopted. By doing so, development that reduces the environmental burden over the entire life cycle can be performed. And by performing energy saving and resource saving by such development, it becomes possible to improve cost efficiency and energy efficiency of the water treatment facility as a result.
[0065]
In addition, by evaluating the environmental load obtained based on the carbon dioxide emissions calculated as described above in the life cycle, and presenting the obtained quantitative environmental information to general consumers and the like, It can be used to promote environmental initiatives.
[0066]
Further, it is possible to realize a business style in which environmental information of a water treatment facility is directly presented to a customer, and a water treatment facility that is more environmentally friendly than an existing water treatment facility is preferentially sold. In other words, a water treatment facility that saves energy and resources at the time of use has the effect of reducing running costs weekly, monthly, or annually, and can present attractive information to purchasers. It becomes.
[0067]
In this embodiment, the invention is applied to the water treatment facility (M) provided with the cogeneration (1), but may be applied to a water treatment facility (M) not provided with the cogeneration (1). However, also in this case, it is preferable to calculate the carbon dioxide emission in the operation stage based on energy such as gas, electric power, or heat consumed and / or generated in the water treatment facility (M).
[0068]
Further, the method of calculating the carbon dioxide emission amount in the construction stage is not limited to the above method, and may be another method. For example, all the equipment and materials used in the water treatment facility (M) are picked up, the materials and the like are manufactured from the raw materials, and the carbon dioxide emitted at each stage until the facility is constructed is sequentially accumulated. There is a method (stacking method). In addition, there is a method (industry-related analysis method) of calculating the amount of carbon dioxide emitted from construction materials using an input-output table (a table showing the flow of goods and the like between industries).
[0069]
In addition, although the emission amount of carbon dioxide relating to both the construction material and the construction energy is calculated, the emission amount of only one of the carbon dioxide may be calculated.
[0070]
In addition, although the emission unit of carbon dioxide corresponding to the construction material, the construction energy, and the operation energy is stored in the single storage unit (31d), it is assumed that each unit is stored in a separate storage unit. Is also good.
[0071]
Further, the construction stage CO2 emission calculation function (A) and the operation stage CO2 emission calculation function (B) are executed by the CPU (31a), which is a single arithmetic unit. It may be executed.
[0072]
In addition, although both the consumed energy (gas amount) and the generated amount (power amount and heat amount) of the operating energy are measured, at least one of the operating energy may be measured.
[0073]
In addition, although the amount of carbon dioxide emission in the construction stage and the operation stage of the water treatment facility is calculated, the amount of carbon dioxide emission in the disposal stage may be further calculated. The emission amount of carbon dioxide in the disposal stage is obtained in the same manner as the emission amount of carbon dioxide in the construction stage described above. That is, the system in this case further includes an input unit for inputting the amount of material and / or waste energy used for disposal of the water treatment facility, and emission of carbon dioxide corresponding to the material and / or waste energy. A storage unit that stores the basic unit in advance, the usage amount of the material and / or waste energy input by the input unit, and the emission of carbon dioxide corresponding to the material and / or waste energy stored in the storage unit A calculation unit for calculating the amount of carbon dioxide emitted at the disposal stage of the water treatment facility based on the basic unit. According to this, the emission amount of carbon dioxide in the disposal stage of the water treatment facility can be easily and reliably obtained.
[0074]
Further, the carbon dioxide emission calculated as described above may be used for banking in carbon dioxide emission trading. This banking means that if the amount of carbon dioxide allowances held at the end of the commitment period exceeds the amount of carbon dioxide It means that it can be used or sold during the promised period.
[0075]
In addition, the carbon dioxide emissions calculated as described above are also converted to an auction (open bidding or auction), a cap and trade (an emission allowance is set, and a set , Emissions trading that permits the transfer or acquisition of a portion of emission allowances), grandfathering (grants are issued based on the actual amount of emissions, etc. in the past specified year or period of the subject of emission allowances) Determining the amount of allowances), subtraction (subtracting the amount of emissions that exceeded the amount of allowances held during a certain commitment period plus a penalty amount from the amount to be issued in the next term) , Tracking (grasping of holding / moving of emission allowances), baseline and credit (compared to the case where there is no business with a carbon dioxide emission reduction project, etc. Certified emissions reductions as a credit, a system to deal with this credit), matching and invalidation of the amount of such discharge and matching (allowances), may be used for such monitoring (grasp of the amount of discharge, etc.).
[Embodiment 2]
Next, another embodiment of the present invention will be described.
[0076]
FIG. 10 is a schematic configuration diagram of a carbon dioxide emission amount calculation system according to this embodiment.
[0077]
In FIG. 10, (1) is a cogeneration provided in each water treatment facility (M), and (5) is connected to each measuring instrument (2) of each cogeneration (1) via a network (NW) such as the Internet. The server computer (hereinafter referred to as a server) (6) is a personal computer connected to the server (5) via a dedicated line (7) or wirelessly.
[0078]
In this embodiment, the server (5) includes a CPU (31a), a ROM (31b), a RAM (31c), a storage unit (31d), and a communication unit (31f) in the personal computer (3) of the first embodiment. The same function is provided.
[0079]
The personal computer (6) functions as an input unit (32) and an output unit (33) in the personal computer (3) of the first embodiment.
[0080]
In the personal computer (6), the amount of each construction material and each construction energy used is input from a keyboard or the like provided on the personal computer (6), and the inputted amount of each construction material and each construction energy is input to a dedicated line (7). ) To the server (5).
[0081]
The server (5) performs the construction stage CO2 emission calculating function on the basis of the amount of construction materials and construction energy transmitted from the personal computer (1) via the dedicated line (7) or wirelessly. (A) (the construction material CO2 emission calculation function (A1) and the construction process CO2 emission calculation function (A2)) are executed to calculate the carbon dioxide emission in the construction stage of the water treatment facility (M).
[0082]
On the other hand, each measuring instrument (2) provided in each cogeneration (1) transmits the measured gas amount, electric power amount, and heat amount to the server (5) via a network (NW).
[0083]
Then, the server (5) performs the operation stage CO2 emission based on the gas amount, the electric power amount, and the heat amount transmitted from each measuring instrument (2) of each cogeneration (1) via the network (NW). The amount calculation function (B) is executed to calculate the amount of carbon dioxide emission in the operation stage of the water treatment facility (M).
[0084]
The emission amount of carbon dioxide calculated by the server (5) is transmitted to the personal computer (6) as necessary, and output to a display or the like of the personal computer (6).
[0085]
According to this, the gas amount, the heat amount, and the electric energy measured by the measuring device (2) of the cogeneration (1) of each water treatment facility (M) are collected using the network, so that the water treatment facility (M) It is possible to centrally manage the amount of carbon dioxide emitted during the operation stage.
[0086]
In any of the above embodiments, the calculated information on the carbon dioxide emission reduction amount and the accumulated amount may be provided to a user of the system via a network.
[0087]
In addition, a trading site for trading carbon dioxide emission credits corresponding to the amount of carbon dioxide emission reduction is provided on the Internet, and the purchase and sale of carbon dioxide emission credits by users of the system are brokered through the trading site. It may be something.
[0088]
Further, the personal computer (3) or the server (5) calculates only the carbon dioxide emission reduction amount by the cogeneration (1). However, the running cost reduction amount by the cogeneration (1) may be calculated. Information on the running cost reduction amount and the accumulated amount may be provided to a user of the system via a network (NW).
[0089]
The CPU (31a) executes the functions (A) and (B) in accordance with a program stored in the ROM (31b). The program is executed by a personal computer (3) via a network (NW). Alternatively, the program may be downloaded to the server (5), or a program recorded on a recording medium such as a CD-ROM as shown in FIG. 2 may be installed on the personal computer (3) or the server (5). It may be something. According to this, it is possible to sell evaluation software that can easily calculate the amount of carbon dioxide emitted from the above-described water treatment facility, and a collection of basic data such as raw materials used for the calculation as a product.
[0090]
【The invention's effect】
According to the first aspect of the present invention, the amount of carbon dioxide emitted during the construction stage of the water treatment facility can be easily and reliably obtained, and the actual state of the environmental load in the water treatment facility can be correctly evaluated. .
[0091]
According to the second aspect of the present invention, the amount of carbon dioxide emitted during the operation stage of the water treatment facility can be easily and reliably obtained.
[0092]
According to the third aspect of the present invention, the amount of carbon dioxide emitted at the disposal stage of the water treatment facility can be easily and reliably obtained.
[0093]
According to the invention according to claim 4, since the consumption and / or generation amount of the operation energy is collected using a network such as the Internet, the amount of carbon dioxide emission in the operation stage of the water treatment facility is extremely concentrated. Can be managed.
[0094]
According to the invention according to claim 5, it is possible to easily and reliably obtain the amount of carbon dioxide emitted during the construction stage of the water treatment facility, and it is possible to correctly evaluate the actual state of the environmental load in the water treatment facility. .
[0095]
According to the invention according to claim 6, the amount of carbon dioxide emitted during the operation stage of the water treatment facility can be easily and reliably obtained.
[0096]
According to the seventh aspect of the present invention, it is possible to easily and reliably obtain the amount of carbon dioxide emitted at the disposal stage of the water treatment facility.
[0097]
According to the invention of claim 8, by downloading this program to a computer, the carbon dioxide emission calculation system can be realized simply and reliably.
[0098]
According to the ninth aspect of the present invention, by installing the program recorded on the recording medium into a computer, the carbon dioxide emission calculating system can be realized simply and reliably.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a carbon dioxide emission amount calculation system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a hardware configuration of the personal computer in FIG. 1;
FIG. 3 CO ² It is a figure showing an emission unit reference table.
FIG. 4 is a diagram showing an example of the amount of carbon dioxide emitted from construction materials.
FIG. 5 is a diagram showing an example of carbon dioxide emissions related to a construction process.
FIG. 6 is a diagram showing a state of consumption and generation of gas, electric power, and heat in the cogeneration.
FIG. 7 is a flowchart showing a method for calculating the amount of carbon dioxide emitted from construction materials.
FIG. 8 is a flowchart showing a method for calculating the amount of carbon dioxide emitted in the construction process.
FIG. 9 is a flowchart showing a method for calculating a carbon dioxide emission amount in an operation stage.
FIG. 10 is a schematic configuration diagram of a carbon dioxide emission amount calculation system according to another embodiment of the present invention.
[Explanation of symbols]
1 ... Cogeneration
2 ・ ・ ・ Measuring instrument
3 ... PC
31 ・ ・ ・ PC body
32 ・ ・ ・ Input unit
33 ··· Output section

Claims (9)

A carbon dioxide emission calculation system for calculating carbon dioxide emission in a water treatment facility,
An input unit for inputting the amount of construction materials and / or construction energy used for the construction of the water treatment facility;
A first storage unit that stores in advance a unit of emission of carbon dioxide corresponding to the construction material and / or construction energy;
Based on the used amount of the construction material and / or the construction energy input by the input unit and the emission unit of carbon dioxide corresponding to the construction material and / or the construction energy stored in the first storage unit. A first calculation unit for calculating the amount of carbon dioxide emitted during the construction stage of the water treatment facility;
A carbon dioxide emission calculation system, comprising: Further, a measuring unit for measuring the consumption and / or generation amount of the operating energy consumed and / or generated in the operation stage of the water treatment facility,
A second storage unit that stores in advance an emission unit of carbon dioxide corresponding to the operating energy;
The operation of the water treatment facility based on the consumption and / or generation of the operating energy measured by the measuring unit and the carbon dioxide emission intensity corresponding to the operating energy stored in the second storage unit A second calculator for calculating the amount of carbon dioxide emitted in the stage,
The carbon dioxide emission calculation system according to claim 1, further comprising: An input unit for inputting the amount of materials and / or waste energy used for disposal of the water treatment facility;
A third storage unit that stores in advance a unit of emission of carbon dioxide corresponding to the material and / or waste energy;
On the basis of the used amount of the material and / or waste energy input by the input unit and the emission unit of carbon dioxide corresponding to the material and / or waste energy stored in the third storage unit, A third calculation unit for calculating the amount of carbon dioxide emitted at the disposal stage of the water treatment facility;
The carbon dioxide emission calculation system according to claim 1 or 2, further comprising: 4. The carbon dioxide according to claim 2, wherein the consumption and / or generation amount of the driving energy measured by the measurement unit is transmitted to the second calculation unit via a network. 5. Emission calculation system. A method for calculating carbon dioxide emissions in a water treatment facility by calculating a carbon dioxide emissions by a computer system,
Construction materials and / or construction energy used for the construction of the water treatment facility are input by the input unit,
Pre-store a carbon dioxide emission unit corresponding to the construction material and / or construction energy in a first storage unit;
Water based on the usage of the construction material and / or construction energy input by the input unit and the carbon dioxide emission intensity corresponding to the construction material and / or construction energy stored in the storage unit; A carbon dioxide emission calculation method, wherein a carbon dioxide emission amount in a construction stage of a treatment facility is calculated by a first calculation unit. Further, the consumption and / or generation amount of the operating energy consumed and / or generated in the operation stage of the water treatment facility is measured by the measuring unit, and the emission unit of carbon dioxide corresponding to the operating energy is stored in the second storage unit. In advance,
The operation of the water treatment facility based on the consumption and / or generation of the operating energy measured by the measuring unit and the carbon dioxide emission intensity corresponding to the operating energy stored in the second storage unit The carbon dioxide emission calculation method according to claim 5, wherein the carbon dioxide emission in the step is calculated by the second calculation unit. Further, the amount of materials and / or waste energy used for disposal of the water treatment facility is input by the input unit,
A third storage unit stores in advance a unit of emission of carbon dioxide corresponding to the material and / or waste energy,
On the basis of the used amount of the material and / or waste energy input by the input unit and the emission unit of carbon dioxide corresponding to the material and / or waste energy stored in the third storage unit, The carbon dioxide emission calculation method according to claim 5 or 6, wherein the amount of carbon dioxide emission at the disposal stage of the water treatment facility is calculated by the third calculation unit. A program for calculating carbon dioxide emissions in a water treatment facility,
The computer stores in advance an input unit for inputting a usage amount of construction materials and / or construction energy used for the construction of the water treatment facility, and an emission unit of carbon dioxide corresponding to the construction materials and / or construction energy. A first storage unit, a usage amount of the construction material and / or construction energy input by the input unit, and a carbon dioxide emission intensity corresponding to the construction material and / or construction energy stored in the storage unit A program for functioning as a first calculation unit for calculating the amount of carbon dioxide emitted during the construction stage of the water treatment facility based on the above. A computer-readable recording medium recorded with a program for calculating the amount of carbon dioxide emission in the water treatment facility,
The computer stores in advance an input unit for inputting a usage amount of construction materials and / or construction energy used for the construction of the water treatment facility, and a carbon dioxide emission unit corresponding to the construction materials and / or construction energy. A first storage unit, a usage amount of the construction material and / or construction energy input by the input unit, and a carbon dioxide emission intensity corresponding to the construction material and / or construction energy stored in the storage unit A computer-readable recording medium in which a program for functioning as a first arithmetic unit for calculating the amount of carbon dioxide emitted during the construction stage of the water treatment facility is recorded.

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