KR101035941B1 - Individual electric power usage measuring method using remote electric power meter and monitoring method for reduced greenhouse gas using remote electric power meter - Google Patents

Abstract

PURPOSE: A method for measuring individual power usage using a remote power meter and a monitoring method for reducing greenhouse gas are provided to measure the individual power usage without the interruption of the supply of main power by adding the remote power meter between a socket and a plug. CONSTITUTION: The change of current amount and voltage amount in individual power consumption appliances is detected by a current/voltage detecting unit. A main control unit calculates electric energy(S200). The main control unit stores the electric energy in a memory and transfers an external display unit(S300). The main control unit wirelessly transfers the identification data of a remote power meter and the electric energy data through a data transmitting unit(S400).

Description

Individual electric power usage measuring method using remote electric power meter and monitoring method for reduced greenhouse gas using remote electric power meter}

The present invention relates to a method for measuring individual power consumption using a remote power meter and a method for monitoring greenhouse gas reduction using a remote power meter, and in detail, using a remote power meter installed at an arbitrary individual electricity use site in a unit municipality or a unit workplace. Monitoring and monitoring of GHG reduction by individual individuals or local residents only when monitoring for GHG reduction activities, and monitoring the GHG reduction by individuals, and remotely measuring power consumption to enhance GHG reduction activities by all employees or local residents. It relates to a method for monitoring greenhouse gas reduction using a power meter.

In recent years, governments, local governments, companies and households have made various efforts to reduce the amount of greenhouse gas emissions causing global warming and abnormal temperature. Such energy saving and GHG emission reduction activities are becoming global environmental movements, and countries are introducing various environmental technologies to reduce GHG emissions.

Greenhouse gases managed to prevent global warming are managed by a total of six substances: CO ₂ , CH ₄ , N ₂ O, HFCs, PFCs and SF ₆ .

There is a method of calculating the emission amount of GHG by calculating the energy consumption multiplied by the GHG emission factor.

The basic equation for calculating greenhouse gas emissions is as follows.

GHG emissions = energy source consumption x emission factor x correction factor (calculated)

The emission factor is determined differently according to the type of greenhouse gas and the energy source.

On the other hand, the type of energy source is a variety of power, water, gas, hot water, steam, oil, and the like, even if the same energy source, different consumption of each greenhouse gas emissions are different. Here, different energy consumption targets mean different emission factors due to different industrial sectors (see table below) or different fuel consumption systems (concepts such as different fuel economy per vehicle). In addition, the correction factor defines the amount of greenhouse gas emissions generated even if the same fuel consumption device is generated according to the efficiency of the device.

The following is a source of energy consumption and target-specific emission factor of the CH ₄ gas greenhouse. It can be seen that emission factors differ by industry and energy source.

Therefore, the emission factor for each greenhouse gas can be calculated only when the emission factor calculation data of [greenhouse gas type, energy source type, energy consumption, industrial classification, equipment type, and characteristic value of each facility] is prepared for each measurement point.

As part of the effort to reduce the greenhouse gas as described above, the recent trend of reducing greenhouse gas emissions and monitoring them by equipping facilities such as municipalities or newly built buildings, factories or apartments with low power consumption to be.

Recently, carbon point system, which encourages individual citizens to directly participate in greenhouse gas reduction activities, has been introduced to encourage individual greenhouse gas reduction activities as well as multi-family housing such as local governments, unit buildings, factories or apartments. to be. The Carbon Point System is a nationwide Climate Change Action Program that provides local governments with incentives for voluntary reductions in homes, commercial facilities, and businesses. By specifying specific methods such as type, size, number of payments and time of payment, it is a system to select carbon points within the range determined by local government such as cash, carbon cash bag, transportation card, gift voucher based on garbage, vouchers for public facilities, and souvenirs.

However, it is very important to monitor the GHG reduction activities of individual members in order for the GHG reduction activities of individual apartments or individual buildings, factories or apartments to achieve the desired purpose. The reason for this is that there is no guarantee that the reduction activities of all members will be good unless the reduction activities of individual members are active.

Therefore, it is important to monitor the GHG reduction activities of individual members. Until now, there was no way to measure GHG consumption for individual members. In this context, GHG mainly refers to power consumption. This is because there is a practical limit to monitoring the remaining greenhouse gases collectively.

Hereinafter, the reason why it is difficult to measure the greenhouse gas consumption for the individual member will be described with reference to one embodiment.

Common power devices used by a single employee in an office include computers, monitors, telephones, printers, electrical, electronic and measuring devices for various tasks. These power devices are usually plugged into a single power strip, and currently available power meters have a shape as shown in FIG. 7, and are usually installed and used in one building (or larger unit of measurement). This is because it is impossible to measure individual power devices.

In other words, when the office space is targeted, it is necessary to install a power meter for each office in order to compare the power consumption by offices of the same size. In this case, the number of power meters should be installed as many as the number of power lines entering the office, and the work was paralyzed because the power should be disconnected from the power supply lines during the installation.

In addition, the power devices used by individual employees are not necessarily in one place. For example, a researcher may work in an office, or a laboratory may use various power devices such as a computer or various measuring or testing devices.

Accordingly, there is a demand for development of a method or apparatus capable of measuring individual power device usage and collecting and monitoring a plurality of individual power consumptions.

An object of the present invention for solving the above problems is to install a remote power source to measure the individual power consumption using the power consumption devices that generate greenhouse gases, installed in the upper power supply, the total power consumption of the lower power consumption devices It is to provide a method for transmitting after measuring.

Another object of the present invention is to provide a method for measuring individual power consumption by using a single remote power meter having a unique identification to collectively measure the individual power consumption occurring in any number of places.

Another object of the present invention is to install a remote power source to measure the individual power consumption using the power consumption devices that generate greenhouse gases, installed in the upper power supply by measuring the total power consumption of the lower power consumption devices by transmitting and It is to provide a method of monitoring greenhouse gas reduction by measuring power consumption by total users.

The present invention to achieve the object as described above and to perform the problem for eliminating the conventional drawbacks is to install a remote power meter at the top end of the individual power consumption device to be measured, the remote power meter is a power supply socket of the upper stage Supplying power to the connection;

After that, the main power supply unit is supplied through the lower power transmitter from the upper power inlet installed in the remote power meter and senses the current and voltage changes being used in the individual power consumption device through the current / voltage detector installed in the remote power meter. Calculating the amount of power;

Thereafter storing the calculated amount of power in a memory installed in the remote power meter or transmitting the calculated amount of power to an external display unit;

Thereafter, the main control unit wirelessly transmits the power amount data stored in the memory and the identification information of the corresponding remote power meter through a data transmission unit installed in the remote power meter; Is achieved by providing

In addition, the present invention, when connecting the individual power consumption devices to be measured to the remote power measuring device, when connecting a plurality of power consumption devices connected to a plurality of power consumption devices to the multi-tap power supply lower part of the remote power meter It is characterized by connecting to.

In another aspect, the present invention further comprises the step of measuring by moving the remote power meter to the corresponding location, when the individual power consumption device to be measured to the remote power meter, the installation of the individual power consumption device to be measured is more than one place; It is characterized by.

In addition, in the present invention, the main control unit, when storing the calculated amount of power in the memory, calculates the power consumption used by the lower power consumption device every unit time by using the value detected through the current / voltage detection unit and adds to the existing value Characterized in that having a step.

In addition, the main control unit in the present invention is characterized in that it has a step of performing a memory loading and data transfer and retransmission command in the next transmission when the data error transmitted through the data transmission unit.

In another embodiment, after the step of wirelessly transmitting the power amount data stored in the memory of the individual power consumption measurement method using the remote power meter and the identification information of the corresponding remote power meter through a data transmission unit installed in the remote power meter,

Accumulating and storing, by the monitoring server, power consumption data for each measurement target individual wirelessly transmitted from at least one remote power meter;

The monitoring server processes the cumulatively stored power consumption data to process the power consumption data for each individual, total, and period to analyze information on the increase or decrease of the power consumption compared to the reference time; the remote power meter further comprises a It is achieved by providing a method for monitoring greenhouse gas reduction using

As described above, the present invention has the advantage of measuring individual power consumption by individual or total users by measuring and transmitting power consumption by remote individuals using power consumption devices that easily generate greenhouse gases without additional facility construction.

In addition, the individual power consumption that occurs in any number of places has the advantage that can be integrated measurement using a single remote power meter with a unique identification.

In addition, it is possible to improve the total greenhouse gas reduction activities by analyzing individual power consumption and improving individual greenhouse gas reduction activities for all members.

In addition, when the office space is used, the conventional power meter requires the installation of power meters for each office in order to compare the power consumption of the offices of the same size, and the power meters must be installed as many as the number of power lines entering the office. While the power is disconnected while the power supply line is in progress, work paralysis occurs, but the present invention has the advantage of easy installation of a remote power meter to act as a power meter. That is, the present invention has the advantage that the installation time is completed only by adding the remote power meter between the existing socket (outlet) and the plug, so that the interruption of the main power supply is not necessary, thereby minimizing the work disconnection time.

In addition, in general office spaces, 4 or 6 power strips are used by each employee to use the power of computers, monitors, and peripherals.

Although it is impossible to use the existing power meter, when the remote power meter according to the present invention is fastened to the upper part of the multi-tap held by the employee, the power consumption by employee / hour can be measured, and such data proceeds as an activity of reducing carbon generation. It also has the advantage of being linked to the carbon point system.

In addition, the existing power meter is measured for the entire measurement target, and because the time measurement unit is monthly, it is not suitable to examine the detailed change in power consumption. For example, in the case of selecting the summer air conditioner operation method, if the user wants to select a case where the power consumption is low compared to the case where the temperature is always lowered and the operation time is 24 hours compared to the case of intensive operation during the day when the room temperature increases. With the power meter, there was a problem to compare the results of the steady operation of air conditioners in different ways in July and August (monthly power consumption bill). However, the present invention can be applied in various time / minutes / second units of periodic counting time of power consumption, and thus it is a useful invention having the advantage of shortening the test operation time for determining the air conditioner operation method. This is a highly expected invention.

1 is a block diagram for measuring the individual power consumption of the present invention,
2 is a block diagram of a remote power meter used in the present invention,
3 is a perspective view of a remote power meter used in the present invention according to one embodiment,
4 is a flowchart illustrating a method of measuring an individual power consumption of the present invention;
5 is an overall greenhouse gas reduction monitoring system diagram using a remote power meter of the present invention,
Figure 6 is a flow chart illustrating a method for monitoring the overall greenhouse gas reduction by measuring the individual power consumption of the present invention,
7 is an exemplary view showing a conventional general electricity meter.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a block diagram for measuring the individual power consumption of the present invention.

As shown in the present invention, the upper end of the power consumption device 4 used alone for the purpose of measuring the individual power consumption, or the upper end of the multi-tap 3 in which the plurality of power consumption devices 4 are plugged together. One remote power meter (1) with discriminating power according to the invention is installed, and the remote power meter is configured by being plugged into a wall socket (2) or a socket (2) of a power strip, which is the upper power source.

Therefore, the plug of the power consumption device used by the individual is plugged into the socket of the remote power meter and the plug of the remote power meter is plugged into the socket of the power supply device of the upper stage. Of course, if there are a plurality of power consumption devices used by an individual, the plugs of the individual power consumption devices are plugged into a plurality of sockets formed in the power strip 3, and the plugs of the power strip are plugged into the sockets of the remote power meter.

The remote power measuring device has a plug-in upper power input unit connected to an upper power supply at one side thereof, and a lower power transmission unit which is a socket for supplying power to lower power consumption devices at the other side thereof. In this case, the plug may be configured integrally with a conventional multi-tap type body or may be configured with a plug type connected by an extension line.

The power consumption device refers to a device that consumes power such as computers, monitors, telephones, printers, electricity, electronics, measuring devices, etc. required for various tasks. Therefore, all power consumption devices not listed are included.

In addition, the remote power meter is configured to store the identification code or identification information in the memory to distinguish it from other remote power meter therein. As a result, even when connected to individual power consumption devices not only in a specific place but also in another place, only the power consumption of the individual is measured. Accordingly, the purpose is to measure the individual power consumption that occurs in any number of places in the workplace.

For example, if an individual to be measured uses multiple power-consumption devices in two places, move the remote power meter to the top of the individual power-consumption devices after moving to the place where the power is used. When configured in this way, the amount of power used by each user is accumulated in the memory built into the remote power meter and integratedly managed.

In addition, the power consumption data of one or more individual power consumption devices measured by the remote power meter is accumulated in the internal memory and then transmitted at a certain point in time. The detailed configuration will be described in the description of the remote power meter to be described later.

According to such a configuration, if a conventional power meter is used, the power meter needs to be installed for each office in order to compare the power consumption of each office of the same size, and the power meter must be installed as many as the number of power lines entering the office. Since power should be cut off from the supply line, it is possible to easily prevent the paralysis of work, but it is possible to easily measure and data individual power consumption regardless of the place.

2 is a block diagram of a remote power meter used in the present invention. As shown in the remote power meter according to the present invention, since the upper power source is directly coupled to the remote power meter of the present invention, a measurement unit for current and voltage is provided to enable accurate measurement of power consumption. At this time, the power consumption is calculated by multiplying the current amount and the voltage measured for each unit time. The calculation of the power P consists of the product of the current I and the voltage V (P = IV).

The present invention is to measure the power consumption of a small unit through a simple installation, the power required to drive the measuring device circuit installed therein is directly connected to the device from the socket (outlet type) terminal of the upper power supply, AC inside the device External AC power is converted and supplied to DC for circuit driving through / DC converter.

The configuration of the remote power meter of the present invention includes an upper power supply unit 10 receiving current from an upper end; A lower power transmission unit 11 for supplying the supplied current to the individual power consumption device of the lower stage; A power management unit 12 positioned between the upper power inlet unit 10 and the lower power transmission unit 11 to transmit current, and supplying current to the AC / DC converter 13 through one side; An AC / DC converter 13 for converting AC power supplied from the power management unit 13 into DC power and supplying the internal circuit driving power; A current / voltage detector 14 which is directly fastened to a conductor connected from the power manager 12 to the lower power transmitter 11 and detects a change in the amount of current and voltage used in the individual power consumption device of the lower stage; A main control unit 15 which calculates the amount of power used by the value detected by the current / voltage detector 14 and stores it in a memory, and transmits the amount of power information to the data transmitter 17 or the external display unit 18; A memory 16 for storing the calculated power usage data and an identification code or identification information for identifying the device; A data transmitter 17 which transmits power consumption information measured using wireless communication to the outside; And an external display unit 18 displaying power consumption data, the details of which are as follows.

The remote power measuring device 1 having the above-described configurations may be formed in an insulator such as plastic, and then each configuration may be formed in the printed circuit board (PCB). Of course, the outer surface should be formed of an external display made of LCD or LED, and the terminals of the upper power inlet 10 and the lower power transmission unit 11 having a protruding or inlet therein should be formed.

First, the upper power inlet unit 10 is one or more individual power consumption devices 4 or the like, in which the power supplied in the configuration is supplied to the inside of the device through the terminal formed in the plug type. Individual power consumption devices (4) are connected to the power strip plugged together to supply power.

Another mission is to drive internal circuits.

The lower power transmission unit 11 supplies power to power consumption devices that are target devices for measuring individual power consumption. To this end, it has a socket structure to which an external plug can be connected.

The power manager 12 has one side connected to the upper power inlet 10 and the other side connected to the lower power transmitter 11 to deliver power.

In another task, the power of the upper power inlet unit 10 is transferred to the AC / DC converter 13 to supply internal circuit driving power.

The AC / DC converter 13 converts AC power received from the power manager 13 into DC power and supplies the power to internal circuit driving power.

As such an AC / DC conversion device, a universal device such as a switching mode power supply (SMPS) may be used.

The current / voltage detector 14 is directly connected to the wire connected from the power manager 12 to the lower power transmitter 11 to detect a change in the amount of current and voltage being used at the bottom. At this time, the current amount is detected by using a built-in current transformer (CT), and the change of voltage is used by using a built-in transformer (PT). By configuring in this way, the current amount and the voltage amount for obtaining the electric power amount are known.

The main control unit 15 is configured to receive and drive circuit driving power through the AC / DC converter 13.

In addition, the last detected power consumption data is imported through the memory 16 or the data is stored every time the power consumption is increased.

In addition, by using the value detected by the current / voltage detector 14, the power consumption used by the lower power consumption device 4 per unit time is calculated and added to the existing value.

In addition, the external display unit 18 to display the power consumption so that the user can visually check.

In addition, by using the wireless communication through the data transmission unit 17 to report the power consumption at a predetermined time, or to respond to the request signal of the power consumption from the outside.

In addition, in the event of data error transmitted through the data transmission unit 17, the memory load and the next data loading and retransmission command is performed.

In addition, by using the data transmission unit 17 to report the identification information for each device stored in the memory, or in response to the request signal of the power consumption from the outside, the server recognizes which of the plurality of power consumption of the remote power meter from the power consumption Done. As a result, even when an individual uses more than one power-consumption device in a plurality of users, the power consumption of each user is recognized and managed collectively.

Main control unit (Main Control Unit) is embedded with an embedded program for performing the command to control each connection device for the above operation is to transmit the necessary information by controlling the device-specific identification and various connection devices required by the present invention Done.

The memory 16 is configured to store data of the calculated power usage, to temporarily store transmission failure data, and to store identification codes or identification information for each device.

The data transmitter 17 is configured to transmit the measured power consumption information by using wireless communication at a predetermined time under the control of the main control unit.

In addition, when an inquiry request is immediately generated from the outside, the current power consumption information is configured to transmit to the monitoring server collecting the individual power consumption.

Data transmission method uses existing wireless communication methods such as Zigbee, RF, Wibro, CDMA, HSDPA, appropriately modified according to the actual installation environment.

The external display unit 18 displays power consumption data with the naked eye of a user, and is configured to transmit and output information stored in a memory by a main control unit.

Figure 3 is a perspective view of a remote power meter used in the present invention according to one embodiment, showing an embodiment configured as a one-hole multi-tap as shown, the external display 18 is formed on the outside, one side It can be seen that the plug that is the upper power input unit 10 is formed, and the socket that is the lower power transmission unit 11 is formed on the other side. Of course, the plug-in upper power inlet 10 may be configured to be plugged by extending the electric wire method without being directly plugged into a socket installed on a wall.

The plug of the upper power inlet 10 is plugged into a socket 2 such as a wall, which is the upper power supply terminal, to receive power. The socket of the lower power transmission unit 11 is plugged in the power consumption device (4) or the power strip (3) in which a plurality of power consumption devices are inserted. Therefore, it is always possible to simply and easily use the remote power meter according to the present invention.

When the apparatus of the present invention having the appearance of a one-prong multi-tap according to an embodiment is connected to an upper power supply terminal and a lower power consumption device, the power consumption calculated after adding up and measuring the load of the power consumption device applied to the lower part is visually determined. In addition, it also has the function of transmitting power consumption to the outside through wireless communication, and also performs the remote power measurement function.

The present invention has the form of a single-prong multi-tap, plug the power consumption device to the present invention and then plugged into the upper socket (outlet) for power supply to connect all the procedures of the installation is easy to install and complete the home and The use of various power consumption devices in the office space can be measured alone.

The measuring method of the present invention using the remote power meter 1 having the above configuration will be described below.

4 is a flowchart illustrating a method of measuring an individual power consumption of the present invention. As shown in the present invention, the remote power meter 1 is installed at the top end of the individual power consumption device 4 to be measured, and the remote power meter 1 is connected to the power supply socket at the upper end thereof to supply power. Step (S100);

Thereafter, the power supply unit 10 installed in the remote power meter 1 is supplied through the lower power transmission unit 11 to change the amount of current and voltage used in the individual power consumption device 4 to the remote power meter. Calculating the amount of power by the main control unit 15 after sensing through the installed current / voltage detector 14 (S200);

Thereafter, the main control unit 15 stores the calculated amount of power in the memory 16 installed in the remote power meter or transmits the calculated amount of power to the external display unit 18 (S300);

Thereafter, the main control unit 15 transmits power amount data stored in the memory and identification information of the corresponding remote power meter 1 wirelessly through the data transmission unit 17 installed in the remote power meter (S400). Has

When connecting the individual power consumption device (4) to the measurement target to the remote power meter (1), in the case of connecting a plurality of power consumption devices (4) after connecting a plurality of power consumption devices (4) to the power strip (3) The plug of the power strip 3 is connected to the lower power transmission unit 11 of the remote power meter 1.

In addition, when the individual power consumption device (4) to be measured is connected to the remote power meter (1), when there is more than one place for the individual power consumption device (4) to be measured, the remote power meter (1) is moved and measured. Has a step.

When the main control unit 15 stores the calculated power amount in the memory 16, the main control unit 15 uses the value sensed by the current / voltage detector 14 in the lower power consumption device 4 every unit time. It has a step of calculating the power consumption to add to the existing value.

In addition, the main control unit (15) has a step of loading the memory in the case of a data error transmitted through the data transmission unit 17 and a data loading and retransmission command in the next transmission.

5 is an overall greenhouse gas reduction monitoring system using the remote power meter of the present invention.

As shown, the greenhouse gas reduction monitoring system of the present invention includes one or more remote power meter 1 measuring individual power usage shown in FIG. 1 and a monitoring server 5 collecting personal power usage information wirelessly transmitted therefrom. ) For this purpose, the monitoring server 5 is provided with a means for receiving wireless information, a computer constituting device such as a known storage device, a RAM, a CPU, etc. constituting a conventional server.

The monitoring server accumulates and stores only the individual power consumption transmitted from the remote power meter 1 having the unique identification information having distinctive power with other remote power meters without calculating the individual power consumption by itself. Therefore, the step of obtaining the power command for all the remote power meters 1 is omitted, so that the load is reduced.

The accumulated information is monitored by classifying the individual power consumption by period in the monitoring server 5 to analyze the individual power consumption and to use the greenhouse effect reduction activity.

In addition, the monitoring server 5 transmits a request signal of power consumption to specific or total remote power meters 1 when necessary, so that the main control unit 15 stores power usage information stored in the memory 16 or The power consumption at the request signal is calculated and configured to request transmission.

Figure 6 is a flow chart illustrating a method for monitoring the overall greenhouse gas reduction by measuring the individual power consumption of the present invention. The basic configuration has the flow performed in FIG.

That is, the step of installing the remote power meter (1) at the top end of the individual power consumption device (4) to be measured, and supplying power by connecting the remote power meter (1) to the power supply socket of the upper end (S100) Wow;

Thereafter, the upper power input unit 10 of the remote power meter 1 is supplied through the lower power transmission unit 11 to change the amount of current and voltage used in the power consumption device 4 in the current / voltage detection unit 14. After detecting the main control unit (Main Control Unit, 15) to calculate the amount of power (S200);

Thereafter, the main control unit 15 stores the calculated amount of power in the memory 16 or transmits it to the external display unit 18 (S300);

Thereafter, the main control unit (15) wirelessly transmits the amount of power data stored in the memory and the remote power meter (1) identification information through the data transmitter 17 (S400);

Step S500 of accumulating and storing the individual power consumption data for each measurement target wirelessly transmitted from the at least one remote power meter 1 (S500);

The monitoring server 5 processes the cumulatively stored power consumption data to process the power consumption data for each individual, total, and period, and analyzes information on whether the power consumption increases or decreases from the reference time point (S600).

The reference time point refers to a specific date defined in advance, and may be various time points such as a monitoring service request date or a specific date or a specific quarter or a specific year.

When such an analysis is performed, the monitoring server 5 sends the individual power consumption of the unit factory, the unit municipality, or the carbon point system to the individual plant, or the individual who wants to use the unit municipality or the carbon point system, on the Internet or By using a means of delivery such as mobile phones to inform the results of monitoring, GHG reduction activities are encouraged.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

<Explanation of symbols for the main parts of the drawings>
(1): Remote power meter (2): Socket
(3): power strip (4): power consumption
(5): monitoring server (10): upper power input unit
(11): lower power transmission unit (12): power management unit
(13): AC / DC converter (14): current / voltage detector
(15): Main control unit (16): Memory
(17): data transmission section 18: external display section

Claims (6)

Installing a remote power meter at a top end of a multi-tap connected to each individual power consumption device or a plurality of individual power consumption devices to be measured, and supplying power by connecting the remote power meter to a power supply socket at an upper end thereof (S100); ;
After that, the main power supply unit is supplied through the lower power transmitter from the upper power inlet installed in the remote power meter and senses the current and voltage changes being used in the individual power consumption device through the current / voltage detector installed in the remote power meter. Calculating the amount of power (S200);
Thereafter, the calculated amount of power is stored in the memory installed in the remote control device by the main control unit or transmitted to an external display unit (S300);
Thereafter, the main control unit wirelessly transmits the power amount data stored in the memory and the identification information of the corresponding remote power meter through the data transmission unit installed in the remote power meter (S400);
The main control unit, when storing the calculated amount of power in the memory, using the value sensed through the current / voltage detector to calculate the power consumption used by the lower power consumption device every unit time and add to the existing value; And performing a memory loading on data error transmitted through the data transmission unit and a data loading and retransmission command on the next transmission.
delete The method according to claim 1,
When connecting the individual power consumption device to be measured to the remote power meter, if the installation site of the individual power consumption device to be measured is more than one place, further comprising the step of measuring by moving the remote power meter to the corresponding position; Individual power consumption measurement method using a remote power meter.
delete delete After performing the individual power consumption measurement method using a remote power meter according to any one of claims 1 or 3, the monitoring server (5) monitors the individual power consumption data to be measured wirelessly transmitted from one or more remote power meter (1) Accumulating and storing (S500);
The monitoring server 5 further comprises the step of processing accumulated power consumption data by processing power consumption data for individual, total, and period to analyze the information of increase or decrease of power consumption compared to the reference point (S600). Greenhouse gas reduction monitoring method using a remote power meter.

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