KR101868385B1 - Integrated remote meter reading system - Google Patents

Abstract

Disclosed is an integrated remote metering system capable of monitoring fire occurring inside a watt-hour meter. According to the present invention, the integrated remote metering system is connected to the watt-hour meter, a transmission control unit (TCU), and a control server through a communication network. The watt-hour meter comprises: a first casing; a watt-hour meter detection unit disposed inside the first casing and detecting a watt-hour of a house; a first temperature measurement unit measuring temperature inside the first casing to generate first temperature data; a processing unit to process the watt-hour and the first temperature data; and a communication unit to transmit the watt-hour and the first temperature data to the TCU. The TCU comprises: a second casing; a second temperature measurement unit measuring temperature inside the second casing to generate second temperature data; a processing unit to process the second temperature data; and a communication unit to transmit the watt-hour and the first and second temperature data to the control server. The control server comprises: a communication unit to receive the watt-hour and the first and second temperature data; and a processing unit analyzing the first and second temperature data to determine whether fire occurs in the watt-hour meter.

Description

Integrated remote meter reading system

The present invention relates to an integrated remote meter reading system, and more particularly, to an integrated remote meter reading system capable of determining whether or not an ignition has occurred in a watt hour meter.

A study on the remote meter reading system that remotely measures the amount of electricity used in the home is underway. This remote meter reading system can replace existing mechanical watt-hour meter, induction watt-hour meter with electronic watt-hour meter, and it provides the service to remotely provide the customer's remote meter reading data through the web-based Internet. Through the introduction of the remote meter reading system, customers' satisfaction with the service has been greatly improved compared to the past, and there is an effect that a more transparent and convenient service can be provided as a customer's position. The use of electronic watt-hour meters has been greatly increased on the basis of these service effects.

On the other hand, when a fire occurs in the home, it is suspected to be the main cause of the ignition internal defect in the watt-hour meter. Although various electric devices other than the watt-hour meter are provided in the actual switchboard and the actual ignition occurs in the devices other than the watt-hour meter, the watt-hour meter is suspected to be the primary cause of the ignition. In this case, if the cause of ignition can not be precisely detected, there is a problem that the company that manufactures and delivers the watt hour meter assumes responsibility for the fire.

Due to these problems, it is necessary to develop a technology capable of monitoring the ignition in the watt hour meter.

Korean Patent Publication No. 10-2016-0015059

The present invention provides an integrated remote meter-reading system capable of monitoring the ignition in the watt-hour meter.

The remote meter reading system according to an embodiment of the present invention is connected to a network capable of communicating with a watt hour meter, a TCU, and a maintenance server, and the watt hour meter includes a first casing; A power amount detecting unit which is located in the first casing and detects a power amount of the home; A first temperature measuring unit for measuring a temperature in the first housing to generate first temperature data; A processing unit for processing the power amount and the first temperature data; And a communication unit for transmitting the power amount and the first temperature data processed by the processing unit to the TCU, wherein the TCU comprises: a second casing; A second temperature measurement unit located in the second casing for measuring a temperature in the second casing to generate second temperature data; A processing unit for processing the second temperature data; And a communication unit for transmitting the amount of power, the first temperature data, and the second temperature data to the management server side, wherein the management server comprises a communication unit for receiving the amount of power, the first temperature data, ; And a processor for analyzing the first temperature data and the second temperature data to determine whether or not the watt hour is within the watt hour meter.

In addition, the processing unit of the management server may extract a temperature increase rate at which the first and second temperature data reaches a maximum temperature, a maximum temperature, and a maximum temperature to determine whether or not to ignite the watt- have.

The watt-hour meter and the TCU may further include an electric distribution board, and the first and second casings may be located adjacent to each other.

The apparatus according to claim 1, further comprising a third temperature measuring unit for measuring a temperature of a specific region outside the first casing and the second casing to generate third temperature data, The second temperature data, and the temperature increase rate of the third temperature data. When the temperature increase rate of the first temperature data is the fastest, it is determined that the data is ignited in the first housing. If the first temperature data and the second temperature data have the same temperature increase rate, it is determined that the ignition is performed outside the switchboard .

The third temperature measuring unit may be provided in at least one of the water meter, the hot water meter, the gas meter, and the heating meter.

According to the present invention, it is possible to determine whether or not an internal watt-hour is ignited by measuring the temperature in each of the watt-hour meter, the TCU, and the third point and analyzing the measured temperature data.

1 is a diagram illustrating an integrated remote meter-reading system according to an embodiment of the present invention.
2 is a view showing an electricity distribution meter having a watt-hour meter and a TCU according to an embodiment of the present invention.
3 is a view showing a watt-hour meter according to an embodiment of the present invention.
4 is a diagram illustrating a TCU according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating a T-server according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the technical spirit of the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

In this specification, when an element is referred to as being on another element, it may be directly formed on another element, or a third element may be interposed therebetween. Further, in the drawings, the thicknesses of the films and regions are exaggerated for an effective explanation of the technical content.

Also, while the terms first, second, third, etc. in the various embodiments of the present disclosure are used to describe various components, these components should not be limited by these terms. These terms have only been used to distinguish one component from another. Thus, what is referred to as a first component in any one embodiment may be referred to as a second component in another embodiment. Each embodiment described and exemplified herein also includes its complementary embodiment. Also, in this specification, 'and / or' are used to include at least one of the front and rear components.

The singular forms "a", "an", and "the" include plural referents unless the context clearly dictates otherwise. It is also to be understood that the terms such as " comprises "or" having "are intended to specify the presence of stated features, integers, Should not be understood to exclude the presence or addition of one or more other elements, elements, or combinations thereof. Also, in this specification, the term "connection " is used to include both indirectly connecting and directly connecting a plurality of components.

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 diagram illustrating an integrated remote meter-reading system according to an embodiment of the present invention.

1, the integrated remote meter-reading system 10 includes various meters 110 to 150 for checking the usage amounts of electricity, water, hot water, gas, and heating in one household (A, B, C) And transmits measured data from each of the meters 110 to 150 to the maintenance server 300 through the relays 210, 220, and 230.

The integrated remote meter-reading system 10 includes a watt-hour meter 110 for measuring the amount of electricity used, a water meter 120 for measuring water usage, a hot water meter 130 for measuring the amount of hot water used, A meter 140, and a heating meter 150 for measuring the amount of heating usage.

The repeaters 210 to 230 receive the measurement data from each of the meters 110 to 150 and transmit the received data to the management server 300. The repeaters 210 to 230 include a transmission control unit (TCU) 210, a data concentration unit (DCU) 220, and an IFU 230.

The TCU 210 is provided in each of the hypothesis units A, B, and C and performs wired / wireless communication with the meters 110 to 150 installed in each home. For communication with the TCU 210, the meters 210 - 150 are set to unique addresses of the TCU 210. The TCU 210 communicates with the meters 110 to 150 by means of DCPLC, PLUSE, RS-485, or the like.

The DCU 220 is directly or indirectly connected to a plurality of TCUs 210 and the provisioning server 300 via a wired / wireless communication network. An IFU 230 may be provided between the DCU 220 and the control server 300 and the DCU 220 may communicate with the control server 300 through the IFU 230. According to an embodiment, the DCU 220 may communicate with a plurality of TCUs 210 and a provisioning server in an RS-485 manner. The data collected in the plurality of assumptions A, B and C is collected in the DCU 220 through the TCU 210 and transmitted to the control server 300 through the DCU 220.

FIG. 2 is a view showing a watt-hour meter according to an embodiment of the present invention and an electric distribution panel equipped with a TCU, and FIG. 3 is a view showing a watt-hour meter according to an embodiment of the present invention.

Referring to FIGS. 2 and 3, the integrated remote meter-reading system further includes an electric switchboard 400. The switchboard 400 is provided outside the homes A, B and C and accommodates the watt-hour meter 110 and the TCU 210. Here, the outdoors includes a porch and a house outside for a single-family house, and a common porch for an apartment.

The watt hour meter 110 includes a first casing 111, a power amount detection unit 112, an A / D converter unit 113, a first temperature measurement unit 114, a processing unit 115, a communication unit 116, 117, a power supply unit 118, and a display unit 119.

The first housing 111 is located within the switchboard 400 and provides a space in which the above configurations of the metering system 110 are accommodated.

The power amount detecting unit 112 detects the voltage and current on the load side and detects the amount of power. To this end, the power amount detecting unit 112 is connected to the load side to sense the voltage and current on the load side, and then calculates the amount of power based on the detected voltage and current.

The A / D converter unit 113 converts the amount of power detected by the power amount detecting unit 112 into a digital signal. That is, the amount of power detected through the power amount detecting unit 112 is represented by an analog value. By changing this to a digital signal, it is possible to increase the degree of freedom of signal processing and processing. The power amount information for the power amount changed to the digital signal can be displayed through the display unit 119, so that the user can intuitively grasp information on the amount of power used up to now.

The first temperature measuring unit 114 measures the temperature inside the first casing 111 and generates the first temperature data. The first temperature measuring unit 114 can measure the internal atmosphere temperature of the first casing 111. The first temperature measurement unit 114 includes a power amount detection unit 112, an A / D converter unit 113, a processing unit 115, a communication unit 116, a data storage unit 117, a power supply unit 118, It is possible to measure the temperature in each circuit connecting the portions 119 to each other. The first temperature data measured by the first temperature measuring unit 114 is transmitted to the processing unit 115.

The processing unit 115 processes the power amount information on the amount of power converted into the digital signal through the A / D converter unit 113 and the first temperature data measured by the first temperature measuring unit 114, Lt; / RTI >

The data storage unit 117 stores data processed by the processing unit 115. [

The power unit 118 is connected to an external power source and supplies power to the watt hour meter 110. Further, the power supply unit 118 may further include an auxiliary power unit (not shown). The auxiliary power source unit is constituted by a battery, and the power source unit 118 charges the power source normally. As a result, the watt-hour meter 110 can be supplied with power through the power supply unit 118 and can supply power stored in the battery included in the auxiliary power unit to the watt hour meter 110 even when a power failure occurs. It is possible.

The communication unit 116 transmits data processed in the processing unit 115 and data stored in the data storage unit 117 to the TCU 210 through the processing unit 115. [ The communication unit 116 may include an SIO (Serial Input Output) circuit. That is, when transmitting data from the processing unit 115 to the outside, the communication unit 116 converts data into serial data, and can support input / output so as to be interlocked with various communication devices.

4 is a diagram illustrating a TCU according to an embodiment of the present invention.

4, the TCU 210 includes a second casing 211, a first communication unit 212, a second temperature measurement unit 213, a processing unit 214, a second communication unit 215, a power unit 216, And a data storage unit 217.

The second housing 211 is located in the switchboard 400 and provides a space in which the above configurations of the TCU 210 are accommodated. The second housing 211 may be located adjacent to the watt hour meter 110 in the switchboard 400.

The first communication unit 212 performs wire / wireless communication with the communication units of the various meters 110 to 150, and receives data measured by the various meters 110 to 150. The first communication unit 212 communicates with the communication unit 116 of the watt hour meter 110 and receives the power amount information and the first temperature data. The first communication unit 212 can communicate with the communication unit 116 of the watt-hour meter 110 by means of DCPLC, PLUSE, RS-485, or the like.

The second temperature measuring unit 213 measures the temperature inside the second casing 211 and generates second temperature data. The second temperature measuring unit 213 can measure the internal atmosphere temperature of the second casing 211. The second temperature measuring unit 213 measures the temperature of the circuit connecting the first communication unit 212, the processing unit 214, the second communication unit 215, the power supply unit 216, and the data storage unit 217 with each other Can be measured. The second temperature data measured by the second temperature measuring unit 213 is transmitted to the processing unit 214. [

The processing unit 214 processes the data received from the first communication unit 212 and the temperature data measured by the second temperature measuring unit 213 and transmits the data to the DCU 220 through the second communication unit 215 do.

The second communication unit 215 is capable of communicating with the communication unit of the DCU 220 via wired or wireless lines and transmits the data processed by the processing unit 214 to the communication unit of the DCU 220. [

The power unit 216 is connected to an external power source and supplies power to the TCU 210. In addition, the power source unit 216 may further include an auxiliary power source unit. The auxiliary power unit is constituted by a battery, and the power source unit 216 normally charges the power source. Accordingly, the TCU 210 can be supplied with power through the power supply unit 216 at normal times, and can supply power stored in the battery included in the auxiliary power unit even if a power failure occurs, thereby enabling more stable operation.

The data storage unit 217 stores data processed by the processing unit 214. [

FIG. 5 is a diagram illustrating a T-server according to an embodiment of the present invention.

Referring to FIG. 5, the management server 400 includes a communication unit 410, a processing unit 420, and a data storage unit 430.

The communication unit 410 communicates with the communication unit of the external repeater 230 by wire or wireless, and transmits / receives various data. The data transmitted from the various meters 110 to 150 are received by the control server 400 through the communication unit 410. Specifically, the data received by the communication unit 410 includes the first temperature data received from the watt-hour meter 110, the second temperature data received from the TCU 210, and the third temperature data measured by the third temperature measuring unit . Here, the third temperature measuring unit is provided in a configuration other than the watt hour meter 110 and the TCU 210, and measures the temperature to generate the third temperature data. The third temperature measuring part may be provided in the electric field configuration located in the switchboard 400. Alternatively, the third temperature measuring part may be provided in a configuration located outside the switchboard 400. [ The third temperature measuring unit may be included in at least one of the water meter 120, the hot water meter 130, the gas meter 140, and the heating meter 150.

The data storage unit 430 stores data processed by the processing unit 420.

The processing unit 420 processes and analyzes the data received through the communication unit 410.

The processor 420 monitors the first to third temperature data and informs the manager through an alarm sound or an alarm indicator in case of abnormal overheating.

In addition, the processor 420 may compare and analyze the first to third temperature data to determine whether or not the watt-hour meter 110 is ignited. Specifically, the processing section 420 can estimate the ignition point through the maximum temperature of the first to third temperature data, the time at which the temperature reaches the maximum temperature, and the temperature increase rate that rises to the maximum temperature.

For example, when the watt hour meter 110 is ignited, the first temperature data first reaches the maximum temperature, and the temperature increase rate becomes the most steep. Then, the second temperature data in the TCU 210 located adjacent to the watt hour meter 110 reaches the maximum temperature after the first temperature data, and the temperature increase rate appears rapidly.

Also, when the TCU 210 is ignited, the second temperature data first reaches the highest temperature, and the temperature increase rate becomes the most steep. Then, the first temperature data in the watt-hour meter 110 located adjacent to the TCU 210 reaches the maximum temperature next to the second temperature data, and the temperature increase rate appears rapidly.

In addition, when ignited at a place other than the watt hour meter 110 and the TCU 210, the third temperature data reaches the highest temperature first, and the temperature increase rate becomes the most steep. Then, the first temperature data and the second temperature data reach the maximum temperature at the same time, and the temperature increase also increases with the same trend.

In this way, the processing section 420 can estimate the ignition point by analyzing the characteristics of the first to third temperature data.

In addition, the processor 420 can estimate a specific circuit in which the ignition occurs in the watt-hour meter 110 through the first temperature data analysis. In addition, a specific circuit in which the ignition occurs in the TCI 210 can be estimated through the second temperature data analysis.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

10: Integrated remote meter reading system
110: Watt hour meter
111: first casing
112:
114: first temperature measuring unit
115:
210: TCU
211: Second casing
213: second temperature measuring unit
214:
400: Tertiary server
420:

Claims (5)

1. An integrated remote meter-reading system connected to a network capable of communicating with a watt-hour meter, a water meter, a gas meter, a TCU,
The watt-
A first casing positioned in the switchboard;
A power amount detecting unit which is located in the first casing and detects a power amount of the home;
A first temperature measuring unit for measuring an internal temperature of the first housing to generate first temperature data;
A processing unit for processing the power amount and the first temperature data;
And a communication unit for transmitting the amount of power and the first temperature data processed by the processing unit to the TCU,
The TCU,
A second casing disposed adjacent to the first casing in the switchboard;
A second temperature measuring unit located in the second casing and measuring the internal temperature of the second casing to generate second temperature data;
A processing unit for processing the second temperature data; And
And a communication unit for transmitting the water usage amount measured in the water meter, the gas usage amount measured in the gas meter, the electric power amount, the first temperature data, and the second temperature data to the management server side,
The Tertiary server
A communication unit for receiving the water usage amount, the gas usage amount, the electric energy amount, the first temperature data, and the second temperature data; And
And a processing unit for extracting a temperature increase rate that rises to a maximum temperature and determines whether or not the first and second temperature data are ignited in the watt hour meter. delete delete The method according to claim 1,
Further comprising a third temperature measuring unit for measuring the temperature of the specific region outside the first casing and the second casing to generate the third temperature data,
Wherein the processing unit of the management server compares the temperature increase rates of the first temperature data, the second temperature data, and the third temperature data,
When the temperature increase rate of the first temperature data is the fastest, it is determined that the first temperature data is ignited in the first casing,
When the temperature increase rate of the second temperature data is the fastest, it is determined that the second temperature data is ignited in the second casing,
And determines that the first temperature data and the second temperature data are ignited outside the switchboard when the temperature increase rates of the first temperature data and the second temperature data are the same. delete

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