JP6312230B1 - Method and apparatus for predicting and calculating greenhouse gas emissions - Google Patents

Abstract

The present invention provides a method for predicting and calculating greenhouse gas emissions that can be used to estimate the future when an energy-saving member is attached to an air-conditioning facility, and to estimate the carbon offset and credit transfer from the following year. A method for predicting and calculating greenhouse gas emissions includes a subtraction step S1 for subtracting the effect of energy-saving members from the annual CO2 emissions from the air conditioning equipment, and air to the CO2 emissions of the air conditioning equipment after the subtraction. Total amount calculation step S2 for calculating the total emission amount in the operator by adding the annual CO2 emission amount by facilities other than the harmonized facility, and a reduction essential amount calculation step for calculating the reduction essential amount by multiplying the total emission amount by a predetermined ratio S3, a determination step S4 for determining whether or not crediting is possible from the amount of effect by the energy saving member and the amount of reduction required, and a credit distribution step S5 for distributing credits to the annual CO2 emissions from the next year when crediting is possible It comprises. [Selection] Figure 4

Description

  The present invention relates to a method for predicting and calculating greenhouse gas emissions when an energy-saving member is attached to an air conditioning facility, and an apparatus for predicting and calculating greenhouse gas emissions.

  Conventionally, a step of transmitting data on the power usage measured by the device-specific ID and the power consumption measuring device from the electric product to the power usage meter via the home power supply line, and power supply in the home by the power usage meter Storing the data received via the line in the data storage unit, and using the power usage meter, the device unique ID and the power usage data stored in the data storage unit using the external communication function The device unique ID and the power usage amount data received by the server via the external device, the device unique ID and the power usage amount data registered in the database, and registered in the database. Using the data on power consumption, calculate the carbon dioxide emission reduction amount and register it in the database An information processing method for specifying the elementary emission reductions are known (e.g., Patent Document 1).

JP 2005-339187 A (particularly paragraphs 0010 to 0013)

However, the above-described conventional information processing method has a configuration that specifies how much reduction is actually obtained using data, and thus has a problem that it is difficult to make a prospect in the future.
And there was a problem that it was difficult to make a carbon offset after the following year and to make a credit transfer.

  Therefore, the present invention solves the problems of the prior art as described above, that is, the purpose of the present invention is to make a future prospect when an energy-saving member is attached to the air conditioning equipment, and the following year or later. Is to provide a method and apparatus for predicting and calculating greenhouse gas emissions that can be used to predict carbon offsets and credit transfers.

The invention according to claim 1 includes a subtracting step of subtracting the effect of the energy saving member from the annual CO ₂ emission amount by the air conditioning equipment, and the CO ₂ emission amount of the air conditioning equipment after the subtraction, other than the air conditioning equipment. A total amount calculation step of calculating the total emission amount in the operator by adding the annual CO ₂ emission amount by the facility; a reduction essential amount calculation step of calculating a reduction essential amount by multiplying the total emission amount by a predetermined ratio; A determination step for determining whether or not crediting is possible based on the amount of the effect by the energy saving member and the amount of reduction required, and a credit distribution step for distributing credit to the annual CO ₂ emission amount from the following year when the crediting is possible By doing so, the above-described problems are solved.

In the invention according to claim 2, in addition to the configuration of the greenhouse gas emission prediction calculation method according to claim 1, the energy saving member is formed in a sheet shape having a hole penetrating in the front and back direction of the sheet. And ceramics that emit far-infrared rays, and the ceramics contain SiO ₂ , Fe ₂ O ₃ , Al ₂ O ₃ , MgO, and CaO. Is a further solution.

The invention according to claim 3 is an apparatus that includes an input unit and a control unit, and predicts and calculates a greenhouse gas emission amount, and the control is performed based on a numerical value input through the input unit. The subtracting step of subtracting the effect of the energy saving member from the annual CO ₂ emission amount by the air conditioning equipment, and the annual CO ₂ emission by equipment other than the air conditioning equipment to the CO ₂ emission amount of the air conditioning equipment after the subtraction A total amount calculating step of calculating the total emission amount in the operator by adding the amount, a reduction essential amount calculating step of calculating a reduction essential amount by multiplying the total emission amount by a predetermined ratio, and an effect amount by the energy saving member A determination step for determining whether or not crediting is possible based on an amount and a reduction required amount, and a credit for distributing the credit to annual CO ₂ emissions from the next year when crediting is possible. The above-described problem is solved by executing the digit distribution step.

  The method for predicting and calculating the greenhouse gas emission amount of the present invention can not only calculate and calculate the greenhouse gas emission amount, but also has the following specific effects.

According to the method for predicting and calculating greenhouse gas emissions according to the first aspect of the present invention, since the amount of CO ₂ emission subtraction due to the use of energy-saving members and the possibility of crediting can be known, , You can make a credit transfer.

According to the method for predicting and calculating the greenhouse gas emission amount of the invention according to claim 2, in addition to the effect of the invention according to claim 1, the energy saving member is attached to the air conditioner so that the hole of the energy saving member is obtained. Since the far-infrared rays are irradiated to the molecules contained in the air passing through the air, the vibrations of the molecules become active, and the molecules are easily exchanged heat, so the heat exchange efficiency in the air conditioning equipment is improved, and the air conditioning equipment Power consumption, that is, CO2 emission can be reduced.
That is, by using a predetermined energy-saving member, it is possible to secure an effective estimated amount of CO ₂ emission subtraction, and to clearly establish the carbon offset and credit transfer prospects for the following year.

According to the apparatus for predicting and calculating the greenhouse gas emission amount of the invention according to claim 3, as with the effect of the invention according to claim 1, the estimated amount of CO ₂ emission subtraction by using the energy saving member, Since it is possible to determine whether credits can be credited, carbon offsets for the following year and credit transfer can be expected.

Schematic which shows the air conditioning equipment using the energy saving member which is an Example of this invention. The perspective view which shows the energy saving member which is an Example of this invention. It shows the change before and after the CO ₂ emissions installation of energy-saving member according to an embodiment of the present invention. The chart figure which shows the prediction calculation method of the greenhouse gas emission which is the Example of this invention.

The method for predicting and calculating the greenhouse gas emission amount of the present invention includes a subtraction step for subtracting the effect due to the energy saving member from the annual CO ₂ emission amount by the air conditioning equipment, and the CO ₂ emission amount of the air conditioning equipment after the subtraction. Total amount calculation step of calculating the total emission amount by the operator by adding the annual CO ₂ emission amount by facilities other than the harmonized facility, and a reduction essential amount calculation step of calculating the reduction required amount by multiplying the total emission amount by a predetermined ratio And a determination step for determining whether or not crediting is possible from the amount of effect by the energy-saving member and the amount of reduction required, and a credit distribution step for distributing credits to the annual CO ₂ emissions from the next year when crediting is possible If it can be equipped with a carbon offset for the following year or a credit transfer, The specific embodiment may be anything.
The apparatus for predicting and calculating greenhouse gas emissions according to the present invention is a computer including an input unit such as a keyboard and a control unit that performs arithmetic processing, and calculates a numerical value input through the input unit. based on the control unit, and a subtraction step of subtracting the effects caused by energy conservation member per year CO ₂ emissions HVAC, annual by equipment other than the HVAC in CO ₂ emissions HVAC after subtracting The total amount calculation step for calculating the total emission amount by the operator by adding the CO ₂ emission amount, the reduction required amount calculation step for calculating the reduction required amount by multiplying the total emission amount by a predetermined ratio, and the effect by the energy saving member A step to determine whether or not crediting is possible from the amount of emissions and the amount of reduction required, and if crediting is possible, credit the annual CO ₂ emissions from the following year As long as it is possible to estimate the carbon offset and credit transfer from the following year by executing the credit distribution step for distributing the credit, any specific embodiment may be used. .

For example, the energy saving member may be any member as long as it is attached to the air conditioning equipment and reduces the CO ₂ emission amount of the air conditioning equipment.

Below, the calculation method of the prediction of the greenhouse gas emission which is an Example of this invention is demonstrated based on FIG. 1 thru | or FIG.
Here, FIG. 1 is a schematic view showing an air-conditioning facility AC using an energy-saving member ES that is an embodiment of the present invention, and FIG. 2 is a perspective view showing an energy-saving member ES that is an embodiment of the present invention. FIG. 3 is a diagram showing a change in CO ₂ emission before and after installation of the energy saving member ES which is an embodiment of the present invention, and FIG. 4 is a prediction of greenhouse gas emission which is an embodiment of the present invention. It is a chart figure which shows the calculation method.

As shown in FIG. 1, an air conditioning facility AC that is a part of a method for predicting and calculating greenhouse gas emissions according to an embodiment of the present invention is of a type that is suspended from a ceiling as an example. A port AC1, an exhaust port AC2, and an intake cover AC3 are provided.
Among these, the intake port AC1 is configured to take in air.
Further, the exhaust port AC2 is configured to exchange the exhausted air in the internal heat exchanger and exhaust it.
Further, the intake cover AC3 is provided so as to allow air to pass therethrough and cover the intake port AC1 in a swingable manner.
As an example, the energy saving member ES is attached to the inside of the intake cover AC3.

As shown in FIG. 2, the energy saving member ES is formed in a sheet shape having a plurality of holes ES1 penetrating in the sheet front and back direction, and contains first ceramics that radiates far infrared rays.
Specifically, as an example, the energy saving member ES is molded by adding first ceramics to an elastic body or plastic such as polyethylene or resin as a base.
As an example, the dimension of the energy saving member ES is 37 to 40 cm in the longitudinal direction, 17 to 20 cm in the lateral direction, and 1 to 5 mm in the thickness direction.
Moreover, the area ratio which the hole ES1 occupies with respect to the whole energy-saving member ES is 45 to 55%.

The first ceramic contains SiO ₂ , Fe ₂ O ₃ , Al ₂ O ₃ , MgO, and CaO.
Here, the hole ES1 of the energy saving member ES is formed in a perfect circle shape as an example, but may be any shape such as a triangle, a quadrangle, an ellipse, etc. as long as air can pass through the hole ES1 and enter the intake port AC1. Any number is acceptable.
Thereby, far-infrared rays are irradiated to the molecules contained in the air passing through the hole ES1 of the energy saving member ES, the vibration of the molecules becomes active, and the molecules are easily exchanged.
As a result, the heat exchange efficiency in the air conditioning facility AC is improved, and the power consumption amount of the air conditioning facility AC, that is, the CO2 emission amount can be reduced.

Furthermore, the energy saving member ES contains elbaite tourmaline as the second ceramic.
Thereby, a very small amount of negative ions is generated.
As a result, air can be heat exchanged more easily.

In addition, it is desirable that the ratio of the content by weight of the second ceramic to the content by weight of the first ceramic is about 1 to 14 (0.069 to 0.074).
This is because the emissivity at which the first ceramic emits far-infrared rays at room temperature is high, and the second ceramic generates a small amount of negative ions.
Moreover, although the elbow tourmaline is used as the second ceramic, a shawl tourmaline or a drab tourmaline may be used instead of the elbow tourmaline.
Further, the energy saving member ES may include the second ceramics instead of the first ceramics.
This is because even in this case, heat is easily exchanged by the negative ions generated.

When the energy saving member ES contains the first ceramic and the second ceramic, the heat exchange efficiency in the air-conditioning equipment AC is improved as described above.
In particular, it is preferable that the first ceramic and the second ceramic are coated on the elastic body of the base of the energy saving member ES or the surface of the plastic.
By attaching the energy-saving member ES to the air conditioning equipment AC, depending on the detailed conditions, as shown in FIG. 3, as an example, the CO ₂ emission amount of the air conditioning equipment AC before installation is reduced after the installation. The CO ₂ emissions of the air conditioning equipment AC are reduced by about 13% to about 87%.

Then, the prediction calculation method of the greenhouse gas emission which is an Example of this invention is demonstrated.
For the calculation, a computer that is an example of an apparatus is used.
The computer includes a keyboard that is an example of an input unit and a control unit that executes computation.
As shown in FIG. 4, in step S < _b > 1, as a subtraction step, the control unit calculates a difference in CO ₂ emission amount before and after attachment of the energy saving member ES to the air conditioning facility AC.
That is, the effect of the energy saving member ES is subtracted from the annual CO ₂ emission amount by the air conditioning equipment AC.

For example, using a calculation sheet created by a spreadsheet application, the number of air conditioning equipment AC, the number of power outputs, the operating hours per day, the operating days per month, the load factor of the equipment, The user inputs the unit price, the reduction rate by the energy saving member ES, and the like to the computer via the keyboard.
Then, based on the input conditions, the control unit of the computer calculates how much CO ₂ emission reduction can be expected by using the energy saving member ES for the air conditioning equipment AC.

In step S2, as a total amount calculation step, the control unit calculates a total discharge amount of the business operator.
That is, equipment other than the air conditioning equipment AC (equipment that emits energy-derived CO ₂ such as LED lighting equipment, non-energy-derived CO ₂ , etc.) to the CO ₂ emission amount of the air conditioning equipment AC after subtracting the effect of the energy saving member ES. discharging the raw fuel use those excluding) by year CO ₂ emissions waste a facility, and, other gases _{(CH 4, N 2 O,} HFC, PFC, etc. SF 6, NF ₃₎ The total amount of emissions is calculated by adding the amount of emissions.
For example, as equipment other than the air conditioning equipment AC, the user inputs the CO ₂ emission amount by the LED lighting equipment into the computer via the keyboard.
Then, the control unit of the computer calculates the total discharge amount based on the input numerical values and conditions.

In step S3, as a reduction essential amount calculation step, the control unit calculates the reduction essential amount by multiplying the total discharge amount by a predetermined ratio.
For example, when the required reduction amount is 1% of the total emission amount, the user inputs 1% to the computer via the keyboard.
Then, the control unit of the computer calculates an indispensable reduction amount based on the input numerical values and conditions.

In step S4, as a determination step, the control unit determines whether or not crediting is possible.
In other words, the control unit determines whether or not crediting is possible from the amount of effect by the energy saving member ES and the amount of reduction required.
The control unit compares the amount of the effect of the energy saving member ES with the amount of reduction required. If the amount of the effect of the energy saving member ES is larger than the amount of reduction required, it is determined that credit can be made, and the process proceeds to step S5. move on.
On the other hand, when the amount of the effect by the energy saving member ES is smaller than the amount of reduction required, it is determined that crediting is impossible and an error occurs. In this case, it is only necessary to increase the number of energy saving members ES and start again from step S1.

In step S5, as a credit distribution step, the control unit distributes credits to the annual CO ₂ emissions from the following year when credits are possible.
Note that the control unit of the apparatus calculates how much CO ₂ emission reduction (hereinafter may be referred to as CO ₂ emission reduction) can be expected by using the energy saving member ES. Then, the control unit may request the provider terminal (not shown) for the same amount of credit as the calculated CO ₂ emission reduction amount.
The provider terminal is a terminal of an offset provider (broker operator). An offset provider is an operator that supports the creation and use of credit.
Alternatively, the control unit subtracts the calculated CO ₂ emission reduction amount from the CO ₂ emission amount of the air conditioning facility AC before the energy saving member ES is attached to the air conditioning facility AC, so that the air after the energy saving member ES is attached. Calculate the CO ₂ emissions of the conditioned equipment AC (hereinafter sometimes referred to as residual CO ₂ emissions) (subtract the effect of the energy-saving member ES from the annual CO ₂ emissions of the air-conditioning equipment AC to obtain the residual CO 2 ₂ emissions are calculated), and a credit corresponding to the calculated remaining CO ₂ emissions is requested from the provider terminal.
In this case, the provider terminal generates a credit receipt for the requested credit (CO ₂ emission reduction amount or remaining CO ₂ emission amount credit). Then, the provider terminal transmits the generated credit deposit certificate to the apparatus. Then, the control unit distributes the same amount of credit as the amount described in the credit receipt certificate to the annual CO ₂ emission amount after the next year.
For example, the control unit distributes the credit to the annual CO ₂ emission amount after the next year of a predetermined ratio (for example, a reduction essential amount) of the total emission power.
As an example, if the amount of reduction required is 30 tons at 1% of the total emission, and the amount of reduction by attaching the energy saving member ES is 320 tons,
320 ton / 30 ton = about 10 years, which means that by introducing the energy-saving member ES, the target achievement CO ₂ amount for about 10 years can be held as a credit.
That is, by introducing the energy-saving member ES, credits can be distributed from the next year to 10 years, and a reduction essential amount can be achieved for 10 years.
As described above, the estimated calculation method for the greenhouse gas emissions described above can be used to determine the amount of CO ₂ emission subtraction expected by using the energy-saving member ES and whether credits can be used.
As a result, it is possible to make a carbon offset and credit transfer prospects for the following year.
For example, the estimated amount of CO ₂ emissions in the following year may be offset with your own credits and offset by carbon. If you cannot offset with your own credits, credit from other companies or third parties (offset providers) You may purchase a carbon offset.
Moreover, you may sell to the other company or a third party organization (offset provider) what you have credited.

The method for predicting and calculating the greenhouse gas emissions that is the embodiment of the present invention thus obtained includes a subtraction step S1 for subtracting the effect due to the energy saving member ES from the annual CO ₂ emissions due to the air conditioning equipment AC, Total amount calculation step S2 for calculating the total emission amount of the operator by adding the annual CO ₂ emission amount of the equipment other than the air conditioning facility AC to the CO ₂ emission amount of the air conditioning facility AC after the subtraction, and the total emission amount A required reduction amount calculation step S3 for multiplying a predetermined ratio to calculate a required reduction amount, a determination step S4 for determining whether or not crediting is possible from the amount of effect by the energy saving member ES and the required reduction amount, and crediting possible In some cases, the credit distribution step S5 for distributing credits to the annual CO ₂ emissions from the next year onward is provided. Bon offset and credit transfer can be expected.

Further, the energy saving member ES is formed in a sheet shape having a hole ES1 penetrating in the front and back direction of the sheet, and contains a first ceramic that radiates far infrared rays. The first ceramic is composed of SiO ₂ , Fe By containing ₂ O ₃ , Al ₂ O ₃ , MgO, and CaO, the heat exchange efficiency in the air-conditioning equipment AC is improved, and the power consumption of the air-conditioning equipment AC, that is, the CO2 emission amount is reduced. Can be reduced.

An apparatus for predicting and calculating greenhouse gas emissions according to an embodiment of the present invention includes a keyboard that is an example of an input unit and a control unit, and controls based on numerical values input via the keyboard. The subtracting step S1 for subtracting the effect due to the energy saving member ES from the annual CO ₂ emission amount by the air conditioning equipment AC, and the CO ₂ emission amount of the air conditioning equipment AC after the subtraction by equipment other than the air conditioning equipment AC Total amount calculation step S2 for calculating the total emission amount by the operator by adding the annual CO ₂ emission amount, reduction essential amount calculation step S3 for calculating the reduction essential amount by multiplying the total emission amount by a predetermined ratio, and energy saving member Judgment step S4 for determining whether or not credit can be made from the amount of effect by ES and the amount of reduction required, and if the credit can be made, annual CO after the following year By executing the credit distribution step S5 for distributing the credits to the _two emissions, the effect can be enormous, such as the possibility of making a carbon offset in the following year and the possibility of credit transfer.

AC ... Air conditioning equipment AC1 ... Inlet port AC2 ... Exhaust port AC3 ... Inlet cover ES ... Energy-saving member ES1 ... Hole

Claims (3)

A method for predicting and calculating greenhouse gas emissions in an apparatus having an input unit and a control unit,
CO ₂ emission reduction that shows how much reduction of CO ₂ emissions can be expected for the air conditioning equipment by attaching an energy saving member to the air conditioning equipment to reduce the power consumption of the air conditioning equipment. Calculating a CO ₂ emission reduction amount calculating step;
A CO ₂ emission reduction credit request step in which the control unit requests a provider terminal for the same amount of credit as the CO ₂ emission reduction amount of the air conditioning equipment ;
Said apparatus, and said CO ₂ emission reductions CO ₂ emission reductions credit deposit receipt certificate receiving step of receiving credit deposit receipt document that are transmitted from the provider terminal,
A credit distribution step in which the control unit distributes credits of the credit deposit certificate to the annual CO ₂ emissions from the next year;
Equipped with,
A method for predicting and calculating greenhouse gas emissions , wherein the energy-saving member can be attached to the outside of an air inlet of an air conditioner . The energy saving member is formed in a sheet shape having a hole penetrating in the sheet front and back direction, and contains ceramics that emits far infrared rays,
The ceramic is a SiO _{2, Fe} and 2 _{O 3,} and _Al 2 _{O 3,} MgO and prediction calculation method for greenhouse gas emissions according to claim 1, characterized by containing a CaO . An apparatus for predicting and calculating greenhouse gas emissions comprising an input means and a control unit,
How much reduction in annual CO ₂ emissions can be expected for the air conditioning equipment by attaching an energy-saving member that reduces the power consumption of the air conditioning equipment to the outside of the air inlet of the air conditioning equipment ? A CO ₂ emission reduction amount calculating step for calculating a CO ₂ emission reduction amount indicating
A CO ₂ emission reduction credit request step in which the control unit requests a provider terminal for the same amount of credit as the CO ₂ emission reduction amount of the air conditioning equipment ;
Said apparatus, and said CO ₂ emission reductions CO ₂ emission reductions credit deposit receipt certificate receiving step of receiving credit deposit receipt document that are transmitted from the provider terminal,
A credit distribution step in which the control unit distributes credits of the credit deposit certificate to the annual CO ₂ emissions from the next year ;
A device that predicts and calculates greenhouse gas emissions.