JP2003344097A - System, method, and program for measuring energy - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an energy measurement system, an energy measurement method, and an energy measuring program which enable total recognition of the quantity of gas discharge and the quantity of heat radiation by energy consumption. <P>SOLUTION: The energy measurement system 10 is composed comprising an automatic measuring apparatus 12 for detecting the quantity of energy consumption, an input means 14 for inputting the quantity of the energy consumption, a control means 16 which receives the quantity of the energy consumption and computes the quantity of gas discharge and the quantity of heat radiation corresponding to the quantity of the energy consumption, a discharge quantity display means 18 for displaying the computed quantities of the gas discharge and heat radiation, and a cost display means 20 for displaying a cost which corresponds to the quantity of the energy consumption. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy measuring system, an energy measuring method, and an energy measuring program for calculating and displaying an emission amount of carbon dioxide or the like generated by consumption of energy such as electricity or gas.

[0002]

2. Description of the Related Art Conventionally, energy such as electricity or gas has been consumed in homes or factories. By consuming these energy, carbon dioxide, heat, etc. that affect the global environment are released.

[0003]

Therefore, the inventor of the present invention
As a result of earnest research to find out the cause of such a problem and solve such a problem, the present invention has been achieved.

That is, the present invention is an energy measuring system capable of measuring and recognizing carbon dioxide or heat released by energy consumption in a home or factory.
The present invention relates to an energy measuring method and an energy measuring program.

[0005]

SUMMARY OF THE INVENTION An energy measuring system of the present invention includes an automatic measuring device for detecting an energy consumption amount, a gas emission amount and a heat radiation amount corresponding to the energy consumption amount when the energy consumption amount is received. It is characterized in that it includes control means for calculating and emission amount display means for displaying the calculated gas emission amount and heat radiation amount.

In the energy measuring system of the present invention, in the energy measuring system, an input means for inputting an energy consumption amount is input, and the control means receives the input energy consumption amount and outputs the energy consumption amount. It is characterized in that the corresponding gas discharge amount and heat radiation amount are calculated.

The energy measuring system of the present invention is characterized in that, in the energy measuring system, the control means includes a cost display means for calculating a cost corresponding to an energy consumption amount and displaying the calculated cost. .

The energy measuring system of the present invention is characterized in that, in the energy measuring system, the control means includes a converting means for converting the energy consumption into a constant unit.

The energy measuring system of the present invention is characterized in that, in the energy measuring system, the control means includes a correcting means for correcting the energy consumption amount by adding / subtracting or multiplying / dividing a correction value.

The energy measuring method of the present invention comprises a step of detecting an energy consumption amount by an automatic measuring device, and a control means for receiving the energy consumption amount and calculating a gas emission amount and a heat radiation amount corresponding to the energy consumption amount. And a step of displaying the calculated gas discharge amount and heat radiation amount by the discharge amount display means.

The energy measuring program of the present invention is
A computer as a control means for receiving energy consumption from an automatic measuring device and calculating a gas emission amount and heat radiation amount corresponding to the energy consumption amount, and an emission amount display means for displaying the calculated gas emission amount and heat radiation amount It is characterized by functioning.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Next, embodiments of an energy measuring system, an energy measuring method, and an energy measuring program according to the present invention will be described in detail with reference to the drawings.

In FIG. 1, reference numeral 10 is an energy measuring system. This energy measuring system 10
Is an automatic measuring device 12 for detecting an energy consumption amount, an input means 14 for inputting the energy consumption amount, and a control means for receiving the energy consumption amount and calculating a gas emission amount and a heat radiation amount corresponding to the energy consumption amount. 16 and an emission amount display means 18 for displaying the calculated gas emission amount and heat radiation amount,
The cost display means 20 for displaying the cost corresponding to the energy consumption is included.

The automatic measuring device 12 measures the electric power consumption of the electric product and transmits the measured value to the control means 16 in kw units, and the gas measuring amount of the gas product and measures the measured value by m. Gas measuring device 24 for transmitting to the control means 16 in units of ³
And measuring the consumption of tap water and controlling the measured value 16
And a water meter 26 for sending to. The electric measuring instrument 22 is, for example, a power meter that outputs electric power as digital data. The gas measuring device 24 is, for example, a gas meter that outputs the volume as digital data. The input means 14 is
It is a means for inputting the consumption amount of energy that cannot be automatically measured, such as kerosene or outdoor energy, and transmitting it to the control means 16. The amount of energy consumption input to the input means 14 may be grasped by a measuring device or the amount of division.

The control means 16 converts the energy consumption into a fixed unit, the correction means 32 for adding and subtracting a correction value to and from the energy consumption, and the cost corresponding to the energy consumption. And a calculation means 34 for performing the operation.

The conversion means 30 calculates the heat generation amount in kcal units by multiplying the energy consumption amount by a coefficient value for each small energy classification based on the heat generation amount data table 36 shown in FIG. Further, based on the carbon dioxide data table 38 shown in FIG. 3, the energy consumption amount is multiplied by a coefficient value for each energy small classification to calculate the carbon dioxide generation amount in kg unit. In the data tables 36 and 38, city gas is methane gas and butane gas is automobile gas. The data tables 36 and 38 are
Indoor energy and outdoor energy are roughly classified, and further, indoor energy is classified and arranged in the order of electricity, city gas, LP gas, kerosene, and water, and outdoor energy is classified in the order of gasoline, light oil, and LP gas. It has an arranged table structure. As a result, the energy consumption can be divided into indoor and outdoor areas for conversion. Further, since the arrangement order of the large classification and the small classification of the data tables 36 and 38 is the same, it is easy for the computer to search for the coefficient value and convert it. In addition, since the outdoor energy for converting the energy consumption amount based on the data input to the input unit 14 is separately configured, the energy consumption amount can be easily converted by the computer. Here, each coefficient value is a value that takes into account the source of each energy to the place of consumption. For example, in the case of water supply, it is a value that also considers the consumption of power energy for sending water.

The indoor energy correction means 32 stores a correction value in consideration of the accuracy and error of the measuring device for each measuring device, and adds or subtracts the correction value to the energy consumption amount for each small classification of the measuring device and each measuring device. . Based on the cost data table 40 of FIG. 4, the calculation means 34 multiplies the energy consumption amount by the coefficient value for each small energy classification and calculates the cost in units of yen. Further, the calculation means 34 calculates a subtotal of the energy consumption amount for each date and time, each use, and the like.

The energy measuring program of the present invention is calculated by the control means 16 which receives the energy consumption amount from the automatic measuring device 12 and calculates the gas discharge amount and the heat radiation amount corresponding to the energy consumption amount by the computer. It is a program that functions as the emission amount display unit 18 that displays the gas emission amount and the heat radiation amount.

The energy measuring method will be described below by using the energy measuring system 10 as described above.

A user who uses the energy measuring system 10 of the present invention to recognize the total energy consumption of a factory, a home, etc., uses an electric measuring instrument 22 for electric appliances such as a television and a refrigerator, and a gas stove or gas. A gas measuring device 24 is installed for a gas product such as a stove, and a water measuring device 26 is installed for a water product such as a washbasin or a bathtub. Or, if each measuring instrument is already installed, use the existing measuring instrument. The control unit 16, the emission amount display unit 18, and the cost display unit 20 are preferably installed at one place such as a factory or a home.

The case where the energy measuring system 10 is used at home will be described below. At home, for example, by using an electric appliance, an electric measuring instrument 2
2 operates and measures the power and sends it to the control means 16.
In the control unit 16, the conversion unit 30 multiplies the received power value by the coefficient value 2150 (kcal / kw) shown in FIG. 2 to calculate the heat generation amount. Further, the amount of carbon dioxide generated is calculated by multiplying the received power value by the coefficient value 0.96 (kcal / kw) shown in FIG. Also, the gas measuring device 2
4 or the water meter 26 is activated, the calorific value and the carbon dioxide amount are calculated in the same manner. The amount of gasoline used which is not automatically measured is input to the input unit 14 and transmitted to the control unit 16, and the calorific value and the carbon dioxide amount are calculated in the same manner.

The calculation means 34 calculates the calculated calorific value and carbon dioxide amount by summing up for each date and time, for each purpose, or for each small classification. Further, the cost for each small classification is calculated based on the cost data table 40 of FIG. The emission amount display means 18 outputs and displays the calculated heat generation amount and the carbon dioxide amount, and the cost display means 20 displays the calculated cost. 5 and 6 are examples of the calorific value, the carbon dioxide amount, and the cost calculated and output.

Although one embodiment of the present invention has been described above, the energy measuring system of the present invention can be implemented in other forms.

For example, the amount of heat generation, the amount of carbon dioxide, and the cost measured in each home or each factory are transferred to a server via telecommunications to be aggregated, and the server aggregates each region or company. It may be configured. For telecommunications, PHS (Personal Handy-phone Syste)
m), NCU (Network Control Unit), IP (Interne
t Protocol), PDA (Personal Digital Assistant)
t), cable TV, LAN (Local Area Network)
Etc. are possible.

Further, the conversion means stores the power transmission efficiency and the power generation efficiency, and based on the actually measured power consumption value, "power transmission value = (measured power consumption value) / (power transmission efficiency), power transmission loss" The power transmission loss value (kw) is calculated by the formula: value = power transmission value−power consumption value, and “supply energy =
(Power transmission value) / (Power generation efficiency), Power generation loss value = Supply energy-Power transmission value The power generation loss value (kw) is calculated, and "total energy consumption = power consumption value + transmission loss value +"
It is also possible to calculate the total energy consumption by the formula "power generation loss value" and calculate the calorific value and the carbon dioxide amount based on the calculated total energy consumption. In this case, the calorific value and the carbon dioxide amount based on the total energy consumption including the energy loss during power transmission and the energy loss during power generation can be calculated.

Further, the conversion means calculates the consumption rate and the transfer efficiency.
Remember, based on actual measured city gas consumption
"Maximum consumption = (measured city gas consumption) / (consumption
Cost rate), consumption loss value = maximum consumption-city gas consumption "
Consumption loss value (m ³) Is calculated and the “supply city
Gas amount = (maximum consumption amount) / (transfer efficiency), transfer loss value =
Transfer loss according to the formula "Amount of supplied city gas-Maximum consumption"
Value (m³) Is calculated and “total energy consumption = city gas
"Total amount + consumption loss value + transfer loss value"
Calculate the energy consumption and calculate the calculated total energy
Even if you calculate the calorific value and the amount of carbon dioxide based on the amount of consumption
good. In this case, energy loss during consumption and transfer
Total energy consumption including energy loss
Based on this, the calorific value and the carbon dioxide amount can be calculated.

Further, the conversion means stores the consumption rate and the base storage efficiency, and based on the actually measured LP gas consumption, "maximum consumption = (measured LP gas consumption) /
(Consumption rate), calculated consumption loss value (m ³⁾ by consumption loss value = maximum consumption -LP gas consumption "is where" the base before storage LP gas amount = (maximum consumption) / (base storage efficiency ), Storage loss value = amount of LP gas before base storage-maximum consumption ", the storage loss value (m ³ ) is calculated, and" total energy consumption = LP gas consumption + consumption loss value + storage loss value " It is also possible to calculate the total energy consumption by the following equation and calculate the calorific value and the carbon dioxide amount based on the calculated total energy consumption. In this case, the calorific value and the carbon dioxide amount based on the total energy consumption including the energy loss during consumption and the energy loss during transfer can be calculated.

Further, the conversion means stores the consumption rate and the transportation efficiency, and based on the oil consumption actually measured,
The consumption loss value (m ³ ) is calculated by the formula “maximum consumption = (measured oil consumption) / (consumption rate), consumption loss value = maximum consumption−oil consumption”, and “supply oil amount = ( Maximum consumption)
/ (Transport efficiency), Transport loss value = Supply oil amount-Maximum consumption amount "
The transport loss value (m ³ ) is calculated by the following formula, and the total energy consumption is calculated by the formula “total energy consumption = oil consumption + consumption loss value + transport loss value”, and the calculated total energy consumption The calorific value and the carbon dioxide amount may be calculated based on the amount. In this case, the calorific value and the carbon dioxide amount based on the total energy consumption including the energy loss during consumption and the energy loss during transfer can be calculated.

In addition, the technical scope of the present invention includes embodiments in which various improvements, modifications and variations are added based on the knowledge of those skilled in the art without departing from the spirit of the invention. Further, within the scope of producing the same action or effect, any of the matters specifying the invention may be replaced with another technique.

[0030]

According to the energy measuring system, the energy measuring method, and the energy measuring program of the present invention, the amount of energy consumed by energy consuming products such as electric appliances in homes or factories is measured, and the energy consumption is dealt with. The amount of heat generated, the amount of carbon dioxide generated, and the cost can be displayed. Therefore, it is possible to grasp the energy consumption by all or some of the energy consuming products and recognize the calorific value, the amount of generated carbon dioxide, and the cost corresponding to the energy consumption, and the total degree of impact on the environment can be understood. Can understand. In addition, awareness of global environment protection can be raised.

Further, according to the energy measuring system of the present invention including the input means, by inputting the energy consumption amount which cannot be detected by the automatic measuring device, the total energy consumption amount which cannot be detected by the automatic measuring device is also included. Energy consumption can be grasped.

Further, according to the energy measuring system of the present invention including the converting means, since the energy consumption is converted into a fixed unit, it is possible to grasp the energy consumption totally.

Further, according to the energy measuring system of the present invention including the correcting means, the energy consumption is accurately detected by grasping the measurement error for each energy consuming product, and the calorific value, the generated carbon dioxide amount and the cost. Can be accurately recognized.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an energy measuring system of the present invention.

FIG. 2 is a structural diagram of a data table used in the energy measuring system of FIG.

3 is a structural diagram of a data table used in the energy measuring system of FIG.

4 is a structural diagram of a data table used in the energy measuring system of FIG.

5 is a data table showing an example of energy consumption amount, heat generation amount, carbon dioxide emission amount, and cost output by the energy measurement system of FIG.

FIG. 6 is a data table showing an example of energy consumption, heat generation amount, carbon dioxide emission amount, and cost output by the energy measurement system of FIG.

[Explanation of symbols] 10: Energy measurement system 12: Automatic measuring device 14: Input means 16: Control means 18: Emission amount display means 20: Cost display means 22: Electrical measuring instrument 24: Gas measuring instrument 26: Water meter 30: Conversion means 32: Correction means 34: calculating means 36: Calorific value data table 38: Carbon dioxide data table 40: Cost data table

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[Procedure amendment]

[Submission date] May 29, 2003 (2003.5.2)
9)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0014

[Correction method] Change

[Correction content]

The automatic measuring device 12 measures the power consumption of the electric product and transmits the measured value to the control means 16 in kw · h units, and the measured value of the gas consumption of the gas product. Is sent to the control means 16 in m ³ units, and a water supply meter 26 that measures the water consumption of the tap water and sends the measured value to the control means 16. The electric measuring instrument 22 is, for example, a power meter that outputs electric power as digital data. The gas measuring device 24 is, for example, a gas meter that outputs the volume as digital data. Input means 14
Is a means for inputting and transmitting to the control means 16 the consumption amount of energy that cannot be automatically measured, such as kerosene or outdoor energy. The amount of energy consumption input to the input means 14 may be grasped by a measuring device or the amount of division.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0021

[Correction method] Change

[Correction content]

The case where the energy measuring system 10 is used at home will be described below. At home, for example, by using an electric appliance, an electric measuring instrument 2
2 operates and measures the power and sends it to the control means 16.
In the control means 16, the conversion means 30 adds the coefficient value 2150 (kcal / kw ·
h ) is multiplied to calculate the calorific value. Further, the received power value has a coefficient value 0.96 (kcal / kw · h ) shown in FIG.
To calculate the amount of carbon dioxide generated. Also, when the gas measuring device 24 or the water measuring device 26 is activated, the calorific value and the carbon dioxide amount are calculated in the same manner. The amount of gasoline used which is not automatically measured is input to the input unit 14 and transmitted to the control unit 16, and the calorific value and the carbon dioxide amount are calculated in the same manner.

[Procedure 3]

[Document name to be amended] Statement

[Name of item to be corrected] 0025

[Correction method] Change

[Correction content]

Further, the conversion means stores the power transmission efficiency and the power generation efficiency, and based on the actually measured power consumption value, "power transmission value = (measured power consumption value) / (power transmission efficiency), power transmission loss" Value = transmitted power value-power consumption value ", the transmission loss value ( kWh ) is calculated, and the expression" supply energy = (transmitted value) / (power generation efficiency), power generation loss value = supplied energy-transmitted value " Power generation loss value ( kWh )
Is calculated, and the total energy consumption is calculated by the formula “total energy consumption = power consumption value + transmission loss value + generation loss value”, and the calorific value and the carbon dioxide amount are calculated based on the calculated total energy consumption. May be calculated. In this case, the calorific value and the carbon dioxide amount based on the total energy consumption including the energy loss during power transmission and the energy loss during power generation can be calculated.

[Procedure amendment 4]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 2

[Correction method] Change

[Correction content]

[Fig. 2]

[Procedure Amendment 5]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 3

[Correction method] Change

[Correction content]

[Figure 3]

[Procedure correction 6]

[Document name to be corrected] Drawing

[Name of item to be corrected] Fig. 4

[Correction method] Change

[Correction content]

[Figure 4]

Claims (7)

[Claims] 1. An automatic measuring device for detecting an energy consumption amount, a control means for receiving the energy consumption amount and calculating a gas emission amount and a heat radiation amount corresponding to the energy consumption amount, and the calculated gas emission amount. And an emission measuring means for displaying a heat radiation amount. 2. An input means for inputting an energy consumption amount is included, and the control means receives the input energy consumption amount and calculates a gas emission amount and a heat radiation amount corresponding to the energy consumption amount. The energy measurement system according to Item 1. 3. The energy measuring system according to claim 1, wherein the control unit includes a cost display unit that calculates a cost corresponding to an energy consumption amount and displays the calculated cost. 4. The energy measuring system according to claim 1, wherein the control unit includes a conversion unit that converts the energy consumption into a fixed unit. 5. The energy measuring system according to claim 1, wherein the control unit includes a correction unit that adds, subtracts, or multiplies a correction value to the energy consumption amount to correct the energy consumption amount. 6. A step of detecting an energy consumption amount by an automatic measuring device, a step of receiving the energy consumption amount by a control means and calculating a gas emission amount and a heat radiation amount corresponding to the energy consumption amount, and an emission amount. And a step of displaying the calculated gas discharge amount and heat radiation amount by a display means. 7. A control means for receiving energy consumption from an automatic measuring device and calculating a gas emission amount and heat radiation amount corresponding to the energy consumption amount by a computer, and displaying the calculated gas emission amount and heat radiation amount. An energy measurement program that functions as an emission display.