KR102290018B1 - An Integrated Monitoring Distributing Board Based on IoT for Fault Diagnosis and Prediction - Google Patents

Abstract

The present invention relates to an IoT-based integrated monitoring distributing board, and more specifically, to an IoT-based integrated monitoring distributing board for fault diagnosis and prediction, which can wirelessly receive status information measured for each distributing board facility to be collected in one data collection unit, transmit the collected information through IoT wireless communication to allow a monitoring system for the distributing board facility to be built quickly, easily and economically, by using the same, accurately and quickly predict and diagnose the failure of distributing boards, save time and cost for maintenance and repair, and collect and monitor data smoothly even for distributing board facilities in multiple areas at low communication cost. The IoT-based integrated monitoring distributing board includes: an environmental condition measuring unit; a data collection unit; a data management unit; a grouping unit; and a fault prediction unit.

Description

An Integrated Monitoring Distributing Board Based on IoT for Fault Diagnosis and Prediction}

The present invention relates to an IoT-based integrated monitoring switchboard, and more particularly, wirelessly receives status information measured for each switchboard facility so that it can be collected in one data collection unit, and the collected information is used for IoT wireless communication Through the transmission, the monitoring system for the switchboard facility can be built quickly, easily and economically, and through this, it is possible to accurately and quickly predict and diagnose the failure of the switchboard, and save time and cost for maintenance and repair It relates to an IoT-based integrated monitoring switchboard for fault diagnosis advance prediction that enables smooth data collection and monitoring at low communication costs even for switchboard facilities in multiple regions.

The electricity produced in the power plant is transmitted and distributed through the transmission line under the high voltage of tens of thousands of V, and on the consumer side, the tens of thousands of V AC voltage is reduced to the required voltage through the switchboard equipment such as a transformer to supply power to each customer or load stage. will supply What is needed in this process is called a closed switchgear or switchboard facility, and the standard specifications include high-voltage switchgear, low-voltage switchgear, motor control panel, and distribution board.

In general, in the consumer's electrical room (switchboard facility), the received 22.9kV electricity is converted to 380~220V through a transformer, etc. do.

If an unexpected failure occurs in the switchboard equipment used in this process, electricity cannot be supplied until the cause of the failure is repaired, or in the case of a high-cost equipment such as a transformer, it is inefficient to replace the entire transformer due to a failure. There was a problem in which the maintenance was performed.

Therefore, in order to solve this problem, monitoring of switchboard facilities, etc. is carried out as shown in the following patent documents, but since all the facilities for temperature measurement are connected by wire, a lot of time and construction cost must be invested in the installation of the system, and maintenance ·Repair takes a lot of time and money, and it is difficult to integrate monitoring of switchboard facilities installed in multiple areas, and the accuracy and speed of diagnosing or predicting failures in advance are poor.

(Prior Literature) Utility Model Registration No. 20-0303183 (Registered on January 22, 2003) "Abnormal temperature monitoring device for high voltage closed switchboard"

The present invention has been devised to solve the above problems,

The present invention wirelessly receives the status information measured for each switchboard facility so that it can be collected in one data collection unit, and transmits the collected information through IoT wireless communication, so that the monitoring system for the switchboard facility can be quickly It is easy and economical to build and, through this, accurate and prompt failure prediction and diagnosis of switchboards is possible, and time and cost for maintenance can be saved, and also for switchboard facilities in many areas. The purpose is to provide an IoT-based integrated monitoring switchboard that enables smooth data collection and monitoring at low communication costs.

The present invention collects information through wireless communication for high voltage switchboards, voltage switchboards, motor control panels, etc. accommodated in a specific facility room, and collects information through wireless or wired communication for distribution boards installed in each floor or area. , the purpose of this is to provide an IoT-based integrated monitoring switchboard that enables the smooth collection of information on distribution boards installed in each floor or area.

In the present invention, when each switchboard facility is formed in a building, the aggregate data transmission unit is formed separately outside the building, and when each switchboard facility is formed outside the building, the aggregate data transmission unit is formed integrally with the data collection unit in one form. The purpose of this is to provide an IoT-based integrated monitoring switchboard that allows the wireless transmission of data by the data transmission unit to be smoothly performed while simplifying the device configuration and increasing the speed and convenience of installation and maintenance.

The present invention aims to provide an IoT-based integrated monitoring switchboard that enables fault diagnosis and pre-prediction of failures based on environmental and state information data of switchboard facilities such as high-voltage switchgear, low-voltage switchgear, motor control board, and distribution board.

The present invention groups switchboard facilities with similar environmental and state information for switchboard facilities distributed in various regions, and enables accurate and efficient fault diagnosis and failure prediction through comparative analysis of relative temperature change trends within the grouping. It aims to provide an IoT-based integrated monitoring switchboard.

An object of the present invention is to provide an IoT-based integrated monitoring switchboard that enables not only predicting failure in advance of switchboard facilities, but also predicting deterioration of transformers, in particular, based on failure history data and switchboard facility information for switchboard facilities.

The present invention is implemented by an embodiment having the following configuration in order to achieve the above object.

According to an embodiment of the present invention, an IoT-based integrated monitoring switchboard according to the present invention includes: an environmental condition measuring unit that measures and provides various environment and state information of a switchboard facility; a data collection unit for collecting and transmitting information measured by the environmental condition measuring unit for a plurality of switchboard facilities; And, a single data collection unit for collecting information transmitted by the individual data transmission unit of each switchboard facility, and an aggregate data transmission unit for transmitting the information collected by the data collection unit using IoT wireless communication. characterized.

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the individual data transmitter includes a high-voltage switchgear data transmitter for wirelessly transmitting the measured state information for the high-voltage switchboard, and the measurement for the low-voltage switchboard A low-voltage switchgear data transmission unit that wirelessly transmits the state information obtained, a motor control panel data transmission unit that wirelessly transmits the measured status information for the motor control panel, and a distribution panel data transmission unit that transmits the status information measured on the distribution panel by wire or wirelessly It is characterized by including wealth.

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the high-voltage switchgear data transmission unit includes a transformer data transmission control module for controlling the transmission of state information measured for the transformer, and the state of the transformer A transformer data wireless communication module that allows information to be transmitted to the data collection unit through wireless communication, a relay data transmission control module that controls the transmission of the status information measured for the relay, and the status information of the relay to the data collection unit through wireless communication and a relay data wireless communication module for transmitting, wherein the low voltage switchgear data transmission unit includes a low voltage switchgear data transmission control module for controlling the transmission of the measured status information for the low voltage switchboard, and the low voltage switchgear status information is data through wireless communication and a low-voltage switchgear data wireless communication module to be transmitted to the assembling unit, wherein the motor control panel data transmission unit includes a motor control panel data transmission control module for controlling the transmission of measured state information to the motor control panel, and the state information of the motor control panel is wirelessly communicated and a motor control panel data wireless communication module for transmitting to the data collection unit through It is characterized in that it includes a distribution board data wired/wireless communication module to be transmitted to the data collection unit through communication.

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the data collection unit collects information by wirelessly communicating with a data collection control module for controlling data collection and transmission, and switchboard facilities a wireless communication collection module that communicates with switchboard facilities by wire to collect information, a wired communication module that transmits the collected information to the aggregated data transmission unit by wire, and the state or aggregated information of the data collection unit It is characterized in that it comprises a status display module for displaying the.

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the aggregate data transmission unit includes a data transmission/reception control module for controlling transmission and reception of data, and the data collection unit is connected by wire to perform wired communication. It characterized in that it comprises a wired data receiving module for receiving data through the IoT wireless transmission module for transmitting the data received from the data collection unit through IoT wireless communication.

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the aggregate data transmission unit is formed integrally with the data collection unit and directly transmits information collected from each switchboard facility through IoT wireless communication. It is characterized in that it is transmitted through

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the environmental condition measuring unit includes an ambient temperature measuring unit for measuring temperature information around the switchboard facility, and an ambient hygrometer for measuring the humidity information around the switchboard facility. A high-voltage switchgear status measurement unit that measures various environmental and status information of the side and high-voltage switchboard, a low-voltage switchboard status measurement unit that measures various environmental and status information of the low-voltage switchboard, and a motor control panel that measures various environmental and status information of the motor control panel It includes a state measurement unit, a distribution panel state measurement unit for measuring various environmental and state information of the distribution board, and an earthquake detection measurement unit for sensing an earthquake, wherein the high-voltage switchboard condition measurement unit, the low-voltage switchboard condition measurement unit, the motor control panel condition measurement unit, and the distribution panel condition measurement unit include: It is formed to be connected to each high-voltage switchgear, low-voltage switchboard, motor control panel, and distribution panel to transmit measured information through each high-voltage switchboard data transmission unit, low-voltage switchboard data transmission unit, motor control panel data transmission unit, and distribution panel data transmission unit, and the surrounding It is characterized in that the temperature measuring unit, the ambient humidity measuring unit, and the earthquake sensing measuring unit are formed integrally with the data collection unit.

According to another embodiment of the present invention, the IoT-based integrated monitoring switchboard according to the present invention includes: a data management unit for storing and managing various information transmitted from the data collection unit; It includes a failure prediction unit that predicts and provides a failure of the switchboard based on the information provided by the data collection unit, wherein the failure prediction unit includes a temperature change trend comparison analysis based on various environments and conditions of the switchboard facility. It is characterized by predicting failure.

According to another embodiment of the present invention, the IoT-based integrated monitoring switchboard according to the present invention further includes a grouping unit for grouping switchboard facilities having similar environmental and state information based on the information provided by the data collection unit; , the failure prediction unit predicts a failure by comparing and analyzing measurement information between switchboard facilities having similar environment and state information grouped through the grouping unit, and the grouping unit is a switchboard based on indoor or outdoor installation conditions of the switchboard facility An installation condition-based grouping module for grouping facilities, a power usage rate-based grouping module for grouping switchboard facilities with similar power usage rates based on the power usage information of the switchboard facility and the capacity information of the switchboard facility provided by the data collection unit; A grouping integration module for integrating and grouping the switchgear facilities subject to comparative analysis based on the grouping information of the installation condition-based grouping module and the power usage rate-based grouping module, wherein the failure prediction unit includes an ambient temperature among high-voltage switchboards having similar installation conditions and power usage rates / A high voltage switchgear fault diagnosis module that diagnoses the failure of a specific high voltage switchgear based on humidity condition, transformer temperature change, busbar temperature change and arc occurrence information, and ambient temperature/humidity among low voltage switchgears with similar installation conditions and power usage rate A low-voltage switchgear fault diagnosis module that diagnoses a specific low-voltage switchgear failure based on conditions, busbar temperature change and arc occurrence information, and ambient temperature/humidity conditions and busbar temperature change among motor control panels with similar installation conditions and power usage A motor control panel failure diagnosis module that diagnoses the failure of a specific motor control panel based on information, It is characterized in that it includes a distribution board failure diagnosis module.

According to another embodiment of the present invention, in the IoT-based integrated monitoring switchboard according to the present invention, the data management unit separately stores historical data of ambient temperature/humidity, power consumption and various temperature information of the switchboard facility in which the failure occurred. , A failure history data management module to manage, and a switchboard facility information management module for storing and managing data on installation conditions, year, and individual capacity of the switchboard facility, wherein the failure prediction unit stores the information of the failure history data management module High-voltage switchgear failure prediction module that predicts the possibility of failure based on the trend of transformer temperature change and busbar temperature change through comparative analysis with the high-voltage switchboard with a past failure history among high-voltage switchboards with similar installation conditions and power usage rate based on the And, based on the information of the failure history data management module, a failure occurred based on the trend of busbar temperature change and the frequency of arc occurrence through comparative analysis with the low voltage switchboard with a past failure history among the low voltage switchboards with similar installation conditions and power usage rate. It is characterized in that it further comprises a low voltage switchgear failure prediction module for predicting the possibility.

According to another embodiment of the present invention, the IoT-based integrated monitoring switchboard according to the present invention further includes an aging prediction unit for predicting the degree of deterioration of a transformer among switchboard facilities, wherein the aging prediction unit is the switchboard facility information management module A usage rate-based aging prediction module that predicts aging by analyzing the amount of use versus capacity of the transformer based on the information of the switchboard facility information management module. It is characterized by including a temperature-based aging prediction module to predict, and an integrated aging prediction module for calculating and presenting integrated information on the aging of the target transformer based on the information of the usage rate-based aging prediction module and the temperature-based aging prediction module. .

The present invention can obtain the following effects by the configuration, combination, and use relationship described below with the present embodiment.

The present invention wirelessly receives the status information measured for each switchboard facility so that it can be collected in one data collection unit, and transmits the collected information through IoT wireless communication, so that the monitoring system for the switchboard facility can be quickly It is easy and economical to build and, through this, accurate and prompt failure prediction and diagnosis of switchboards is possible, and time and cost for maintenance can be saved, and also for switchboard facilities in many areas. It has the effect of enabling smooth data collection and monitoring at low communication costs.

The present invention collects information through wireless communication for high voltage switchboards, voltage switchboards, motor control panels, etc. accommodated in a specific facility room, and collects information through wireless or wired communication for distribution boards installed in each floor or area. , it has the effect of enabling the smooth collection of information on distribution boards installed in each floor or zone.

In the present invention, when each switchboard facility is formed in a building, the aggregate data transmission unit is formed separately outside the building, and when each switchboard facility is formed outside the building, the aggregate data transmission unit is formed integrally with the data collection unit in one form. While the wireless transmission of data by the data transmission unit is performed smoothly, there is an effect of simplifying the device configuration and increasing the speed and convenience of installation, maintenance, and repair.

The present invention has an effect of enabling fault diagnosis and failure prediction based on environmental and state information data of switchboard facilities such as high-voltage switchgear, low-voltage switchgear, motor control panel, and distribution board.

The present invention groups switchboard facilities with similar environmental and state information for switchboard facilities distributed in various regions, and enables accurate and efficient fault diagnosis and failure prediction through comparative analysis of relative temperature change trends within the grouping. has the effect of

The present invention has an effect of enabling predictive failure of the switchboard facilities, as well as the prediction of deterioration of the transformer, in particular, based on the failure history data and switchboard facility information for the switchboard facilities.

1 is a reference diagram showing the distribution state of switchboard facilities widely distributed in a specific area;
2 is a block diagram of an IoT-based integrated monitoring switchboard according to an embodiment of the present invention;
3 is a block diagram of an IoT-based integrated monitoring switchboard according to another embodiment of the present invention;
4 is a block diagram showing the configuration of a data collection unit;
5 is a block diagram showing the configuration of an individual data transmission unit;
6 is a block diagram showing the configuration of a data collection unit;
7 is a block diagram showing the configuration of an aggregated data transmission unit;
8 is a block diagram showing the configuration of an environment state measuring unit;
9 is a reference diagram showing a system for performing failure prediction for a plurality of switchboard facilities;
10 is a block diagram showing the configuration of a data management unit;
11 is a block diagram showing the configuration of a grouping unit;
12 is a block diagram showing the configuration of a failure prediction unit;
13 is a block diagram showing the configuration of an aging prediction unit;

Hereinafter, preferred embodiments of the IoT-based integrated monitoring switchboard for fault diagnosis advance prediction according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Throughout the specification, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated. Terms such as “…unit” and “…module” mean a unit that processes at least one function or operation, and may be implemented as hardware or software or a combination of hardware and software.

When an IoT-based integrated monitoring switchboard for fault diagnosis advance prediction according to an embodiment of the present invention is described with reference to FIGS. 2 to 13, the IoT-based integrated monitoring switchboard measures and provides various environment and state information of the switchboard facility. an environmental condition measuring unit 10 and; and a data collection unit 20 that collects and transmits information measured by the environmental condition measurement unit 10 for a plurality of switchboard facilities.

As shown in FIG. 1 , the switchboard receives and monitors the environment and state information measured for the switchboard facility from the switchboard facility installed in a plurality of areas, thereby enabling efficient management of a plurality of switchboard facilities. Hereinafter, the switchgear facility is defined as a concept that encompasses high-voltage switchgear, low-voltage switchgear, motor control panel, and distribution board.

In particular, the switchboard according to the present invention collects information measured for each switchboard facility through wireless communication while measuring the environment and state of each switchboard facility, and collects the collected information using IoT wireless communication to a separate server By transmitting the data to the switchboard, it is possible to easily and accurately predict the fault diagnosis of the switchboard. Therefore, the switchboard does not need to carry out the construction of installing a large-scale wired network for the construction of the monitoring system, and it is enough to simply attach the devices capable of wireless communication to each switchboard facility. can make it build.

First, if the data collection unit 20 is described, the data collection unit 20 is configured to collect and transmit information measured for each switchboard facility, and each measured by the environmental condition measurement unit 10 is It collects the status and environmental information of the switchboard facility and transmits it to the outside. In particular, the data collection unit 20 wirelessly collects and collects information measured for each switchboard facility, and transmits the information collected from one device to a server, device, etc. for monitoring through the IoT network, With the construction of a simple device, maintenance and repair can be performed conveniently. In addition, since information on a plurality of switchboard facilities is collected and transmitted in one device by short-distance wireless communication without the need to transmit information remotely from each switchboard facility, the accuracy of data transmission and reception is improved and communication costs are reduced. can do. To this end, the data collection unit 20 collects the information transmitted from the individual data transmission unit 210 that is individually installed in each switchboard facility and transmits the measured information, and the individual data transmission unit 210, and transmits the information to the outside. A data aggregation unit 220 for transferring to the aggregated data transmission unit 230 for can

The individual data transmission unit 210 is installed in each switchboard facility and transmits information measured on the status and environment of each switchboard facility to the data collection unit 220, preferably using short-distance wireless communication. transmission can be made. For example, the individual data transmission unit 210 may transmit information measured for a high-voltage switchboard, a low-voltage switchboard, a motor control panel, and a distribution board. In the case of double high voltage switchgear, low voltage switchgear, and motor control panel, since they are generally installed in a specific space such as a facility room, stable data transmission can be made to the data collection unit 220 in the same space through short-distance wireless communication. In the case of a distribution board, since it is common to be installed on each floor or space area, wireless communication may not be performed smoothly due to walls, floors, etc., so wireless or wired data transmission can be made according to the installation environment. For example, the individual data transmission unit 210 may include a high voltage switchboard data transmission unit 211, a low voltage switchboard data transmission unit 212, a motor control panel data transmission unit 213, and a distribution panel data transmission unit 214. there is.

The high-voltage switchgear data transmission unit 211 is configured to transmit the measured state and environmental information for the high-voltage switchboard to the data collection unit 220, and preferably transmit the measured data using short-distance wireless communication. there is. The high-voltage switchgear data transmission unit 211 transmits information measured by the high-voltage switchgear state measurement unit 130 to be described later of the environmental condition measurement unit 10, for example, is formed in each of the transformer and the relay, each of the transformer and the relay. It is possible to transmit information measured from To this end, the high voltage switchboard data transmission unit 211 includes a transformer data transmission control module 211a, a transformer data wireless communication module 211b, a relay data transmission control module 211c, and a relay data wireless communication module 211d. The transformer data transmission control module 211a and the transformer data wireless communication module 211b are integrally formed and mounted on the transformer, and the relay data transmission control module 211c and the relay data wireless communication module 211d are separate. It can be integrally formed and mounted on the relay.

The transformer data transmission control module 211a is configured to control the transmission of information measured by the transformer, and enables wireless transmission of information through the transformer data wireless communication module 211b. The transformer data transmission control module 211a may, for example, be applied to a remote terminal unit (RTU), and may transmit temperature information of the transformer measured by the transformer temperature management module 131 to be described later.

The transformer data wireless communication module 211b is configured to transmit the measured information as a wireless communication signal to the data collection unit 220, and a wireless communication collection module 222 and a wireless communication module 222 of the data collection unit 220 to be described later. make communication happen. The transformer data wireless communication module 211b may apply a short-distance wireless communication method, and preferably transmits information by Zigbee communication, but is not necessarily limited thereto.

The relay data transmission control module 211c is configured to control the transmission of information measured by the relay, and enables wireless transmission of information through the relay data wireless communication module 211d. The relay data transmission control module 211c may be applied to, for example, a remote terminal unit (RTU), a high voltage switchboard power consumption management module 132, a high voltage switchboard bus bar temperature measuring module 133, and a high voltage switchboard arc measurement to be described later. Transmission of information measured by module 134 may be made.

The relay data wireless communication module 211d is configured to transmit the measured information as a wireless communication signal to the data collection unit 220, and the wireless communication collection module 222 and the wireless communication module 222 to be described later of the data collection unit 220 make communication happen. The relay data wireless communication module 211d may apply a short-range wireless communication method, and preferably, transmit information by Zigbee communication, but is not necessarily limited thereto.

The low-voltage switchgear data transmission unit 212 is configured to transmit the measured state and environmental information for the low-voltage switchgear to the data collection unit 220, and preferably transmit the measured data using short-range wireless communication. there is. The low-voltage switchgear data transmission unit 212 transmits information measured by the low-voltage switchgear state measurement unit 140 to be described later of the environmental condition measurement unit 10 . To this end, the low voltage switchgear data transmission unit 212 may include a low voltage switchgear data transmission control module 212a and a low voltage switchgear data wireless communication module 212b.

The low-voltage switchgear data transmission control module 212a is configured to control the transmission of information measured in the low-voltage switchgear, and enables wireless transmission of information through the low-voltage switchgear data wireless communication module 212b. The low voltage switchboard data transmission control module 212a may be, for example, a remote terminal unit (RTU), a low voltage switchboard power consumption management module 141, a low voltage switchboard bus bar temperature measuring module 142, which will be described later, a low voltage switchboard arc Information measured by the measurement module 143 may be transmitted.

The low voltage switchgear data wireless communication module 212b is configured to transmit the measured information as a wireless communication signal to the data collection unit 220, and a wireless communication collection module 222 to be described later of the data collection unit 220 and Enable wireless communication. The low-voltage switchgear data wireless communication module 212b may apply a short-range wireless communication method, and preferably transmits information by Zigbee communication, but is not limited thereto.

The motor control panel data transmission unit 213 is configured to transmit the measured state and environmental information for the motor control panel to the data collection unit 220, preferably to transmit the measured data using short-distance wireless communication. there is. The motor control panel data transmission unit 213 transmits information measured by the motor control panel condition measurement unit 150 to be described later of the environmental condition measurement unit 10 . To this end, the motor control panel data transmission unit 213 may include a motor control panel data transmission control module 213a and a motor control panel data wireless communication module 213b.

The motor control panel data transmission control module 213a is configured to control the transmission of information measured by the motor control panel, and enables wireless transmission of information through the motor control panel data wireless communication module 213b. The motor control panel data transmission control module 213a may, for example, be applied to a remote terminal unit (RTU), and may transmit information measured by the motor control panel bus bar temperature measuring module 151 to be described later.

The motor control panel data wireless communication module 213b is configured to transmit the measured information as a wireless communication signal to the data collection unit 220, and a wireless communication collection module 222 to be described later of the data collection unit 220 and Enable wireless communication. The motor control panel data wireless communication module 213b may apply a short-range wireless communication method, and preferably transmits information by Zigbee communication, but is not necessarily limited thereto.

The distribution panel data transmission unit 214 is configured to transmit the state and environment information measured on the distribution panel to the data collection unit 220, and may transmit the measured data using wireless or wired communication. The distribution board data transmission unit 214 may also allow data to be transmitted using wireless communication, but the distribution board is different from a high voltage switchboard, a low voltage switchboard, and a motor control panel installed together in a specific facility room, etc., for each floor or each zone. Therefore, when using short-distance wireless communication, the transmission and reception of data may be hindered by the building structure. Therefore, the distribution board data transmission unit 214 may transmit data through a wireless network or a wired network depending on the installation environment. Therefore, installation and maintenance costs can be reduced, and data transmission and reception can be performed smoothly. The distribution panel data transmission unit 214 transmits information measured by the distribution panel state measurement unit 160 to be described later of the environmental condition measurement unit 10 . To this end, the distribution board data transmission unit 214 may include a distribution board data transmission control module 214a and a distribution board data wired/wireless communication module 214b.

The distribution board data transmission control module 214a is configured to control the transmission of information measured on the distribution board, and enables wireless or wired transmission of information through the distribution board data wired/wireless communication module 214b. The distribution board data transmission control module 214a may, for example, be applied to a remote terminal unit (RTU), and may transmit information measured by the distribution board bus bar temperature measuring module 161 to be described later.

The distribution board data wired/wireless communication module 214b is configured to transmit the measured information to the data collection unit 220 as a wired or wireless communication signal, and a wireless communication collection module 222 of the data collection unit 220 to be described later. Alternatively, wired communication with the wired communication collection module 223 is made. A data communication method by a wireless network or a wired network may be applied to the distribution board data wired/wireless communication module 214b, and a short-distance wireless communication method such as Zigbee or a wired communication method such as 485 communication may be applied.

The data collection unit 220 is configured to collect information transmitted from the individual data transmission unit 210 and transmit it to the aggregate data transmission unit 230 . (212), the motor control panel data transmission unit 213, so as to receive information transmitted from the distribution panel data transmission unit 214. The data collection unit 220 collects information through wireless communication from the high voltage switchgear data transmission unit 211, the low voltage switchboard data transmission unit 212, and the motor control panel data transmission unit 213, and the distribution panel data transmission unit ( 214) may collect information through wireless or wired communication, and collect the collected information and transmit it to the aggregate data transmission unit 230 through wired communication. In addition, the data collection unit 220 can be formed in the same space together with the high-voltage switchboard, the low-voltage switchboard, the motor control panel, etc. where the individual data transmission unit 210 is installed, and the ambient thermometer of the environmental condition measuring unit 10 to be described later. The side part 110, the ambient humidity measuring part 120, and the earthquake detecting and measuring part 170 are built-in or are formed to be connected together, so that the temperature and humidity around the switchboard facility and the occurrence of an earthquake can be detected. The data collection unit 220 may include a data collection control module 221 , a wireless communication collection module 222 , a wired communication collection module 223 , a wired transmission module 224 , and a status display module 225 . .

The data collection control module 221 is configured to control data collection from the individual data transmission unit 210 and data transmission to the aggregate data transmission unit 230, and collects the collected information in real time. to transmit to the outside. The data collection control module 221 may be applied, for example, to a remote terminal unit (RTU), to receive data by the wireless communication collection module 222 and the wired communication collection module 223, and to transmit the received data. It is transmitted to the data collection unit 220 by the wired transmission module 224 .

The wireless communication collection module 222 is configured to receive data from the individual data transmission unit 210 through wireless communication, and is wirelessly connected to the individual data transmission unit 210 through short-range wireless communication such as Zigbee. Accordingly, the wireless communication collection module 222 is the transformer data wireless communication module 211b, the relay data wireless communication module 211d, the low voltage switchboard data wireless communication module 212b, the motor control panel data wireless communication module 213b, or It is wirelessly connected to the distribution panel data wired/wireless communication module 214b to receive information measured in the high voltage switchboard, the low voltage switchboard, the motor control panel, and the distribution board.

The wired communication collection module 223 is configured to receive data from the individual data transmission unit 210 through wired communication, and is connected to the individual data transmission unit 210 through wired communication such as 485. The wired communication collecting module 223 may be connected to the distribution panel data wired/wireless communication module 214b when the distribution panel is connected by wire to receive information measured by the distribution panel.

The wired transmission module 224 is configured to collect information transmitted from the individual data transmission unit 210 and transmit it to the aggregate data transmission unit 230 , and a wired communication method such as 485 may be applied.

The status display module 225 is configured to display the state of the data collection unit 220, and may be formed as a screen such as an LCD, to display the operating state of the data collection unit 220 or to display collected information. can do.

The aggregate data transmission unit 230 is configured to transmit the information transmitted from the data collection unit 220 to the outside using the IoT wireless communication network, so that the status of the switchboard facilities can be monitored. The aggregated data transmission unit 230 may be formed outdoors, is connected to the data collection unit 220 by wire, and receives information measured by the environmental condition measurement unit 10 by wire and transmits it through an IoT communication network. let it do To this end, the aggregated data transmission unit 230 may include a data transmission/reception control module 231 , a wired data reception module 232 , and an IoT wireless transmission module 233 .

The data transmission/reception control module 231 is configured to control the reception of data from the data aggregator 220 and transmission of data through the IoT wireless network. For example, a Remote Terminal Unit (RTU) may be applied, and wired data reception The information received by the module 232 is transmitted to the outside through the IoT wireless transmission module 233 .

The wired data receiving module 232 is configured to receive data by being connected to the data collection unit 220 by wire, and may be formed in various wired communication methods such as 485 to be connected to the wired transmission module 224. .

The IoT wireless transmission module 233 is configured to transmit data received from the data collection unit 220 to the outside through the IoT wireless network, and may use an IoT wireless network such as LoRa. Therefore, by using the data transmitted by the IoT wireless transmission module 233, it is possible to monitor the switchboard facilities installed in a plurality of areas, and to diagnose and predict failures or aging.

In addition, as shown in FIG. 3 , when the switchboard facilities are installed outdoors, the aggregate data transmission unit 230 may be integrated with the data collection unit 220 and formed integrally without being formed separately. In this case, an IoT wireless transmission module 233 is additionally formed in the data collection unit 220 to transmit information transmitted from the individual data transmission unit 210 to the IoT communication network through the IoT wireless transmission module 233 as a straight line. can make it

The environmental condition measuring unit 10 is a configuration that measures and provides various environmental and state information of the switchboard facility, and measures not only the environmental information around the switchboard facility where the switchboard facility is located, but also the status information of the switchboard facility itself. A system for monitoring to be provided, etc. To this end, the environmental condition measuring unit 10 includes an ambient temperature measuring unit 110 that measures and provides ambient temperature information of a switchboard facility, an ambient humidity measuring unit 120 that measures and provides humidity information around a switchboard facility, and a variety of high-voltage switchboards. The high voltage switchgear state measuring unit 130 that measures and provides environmental and state information, the low voltage switchgear state measuring unit 140 that measures and provides various environmental and state information of the low voltage switchgear, and the various environmental and state information of the motor control panel are measured The electric motor control panel condition measurement unit 150 provided by ) may be included.

The ambient temperature measuring unit 110 is configured to measure and provide temperature information around the switchboard facility, and by measuring and providing environmental conditions such as the temperature around the switchboard facility, to be utilized for grouping and relative comparison analysis of switchboard facilities in the future can do. Various temperature sensors may be used as the ambient temperature measuring unit 110 , and may be formed together with the data collecting unit 220 .

The ambient humidity measurement unit 120 is configured to measure and provide humidity information around the switchboard facility, and by measuring and providing environmental conditions such as humidity around the switchboard facility, to be utilized for grouping and relative comparison analysis of switchboard facilities in the future can do. Various humidity sensors, etc. may be utilized as the ambient humidity measuring unit 120 , and may be formed together with the data collecting unit 220 .

The high-voltage switchgear state measuring unit 130 is configured to measure and provide various environmental and state information of the high-voltage switchboard. For this purpose, a transformer temperature management module 131 that specifically manages and provides transformer temperature-related information, and a high-voltage switchboard A high-voltage switchgear power consumption management module 132 that manages and provides information related to the power consumption of It may include a high voltage switchboard arc measurement module 134 to measure and provide.

The transformer temperature management module 131 is configured to manage and provide information related to the temperature of the transformer, and by measuring the temperature related information inside the transformer included in the high voltage switchgear facility or receiving related information and managing and providing it, It will grasp the temperature change trend, and will be used for diagnosis and prediction of various future failures and aging prediction. In addition, the transformer data transmission control module 211a and the transformer data wireless communication module 211b of the high voltage switchgear data transmission unit 211 are formed in the transformer temperature management module 131 , and the data is transmitted to the data collection unit 220 . It can be transmitted wirelessly.

The high-voltage switchgear power consumption management module 132 is a configuration that manages and provides information related to the power usage of the high-voltage switchboard. Compared to simply predicting a failure based on only the temperature change of the transformer in the high-voltage switchboard as an index, the actual power usage rate of the high-voltage switchgear By using temperature change as an index compared to (‘power usage rate’ is the concept of power consumption versus capacity of the facility), it is possible to increase the accuracy of fault diagnosis and prediction and aging prediction of the present invention. It is a configuration that measures related data or receives related information and manages and provides it. The high-voltage switchgear power consumption management module 132 may be formed in the relay of the high-voltage switchboard, and the relay data transmission control module 211c and the relay data wireless communication module 211d of the high-voltage switchboard data transmission unit 211 are provided. Through this, the measured data may be wirelessly transmitted to the data collection unit 220 .

The high voltage switchgear bus bar temperature measuring module 133 is configured to measure and provide the bus bar temperature of the high voltage switchboard, and by measuring and providing the bus bar temperature used in the high voltage switchgear, the bus bar temperature is used as an additional indicator in addition to the previous transformer temperature. By using the bar temperature change trend, it is possible to increase the accuracy of fault diagnosis and prediction and aging prediction. The high voltage switchgear bus bar temperature measuring module 133 may be formed in the relay of the high voltage switchgear, and the relay data transmission control module 211c and the relay data wireless communication module 211d of the high voltage switchgear data transmission unit 211 ) It is possible to wirelessly transmit the measured data to the data collection unit 220 through .

The high-voltage switchgear arc measuring module 134 is configured to measure and provide arc generation in the high-voltage switchboard, and is not only used as a fire-related indicator in the case of arc occurrence in the switchboard facility, but also in the diagnosis of failure and aging due to overload in the facility. Since it can also be used as an index, it is necessary to measure and provide relevant information through the above configuration. The high-voltage switchgear arc measuring module 134 may be formed in the relay of the high-voltage switchboard, and the relay data transmission control module 211c and the relay data wireless communication module 211d of the high-voltage switchboard data transmission unit 211 through The measured data may be wirelessly transmitted to the data collection unit 220 .

The low-voltage switchgear state measuring unit 140 is configured to measure and provide various environmental and state information of the low-voltage switchgear. For this purpose, the low-voltage switchgear power usage management module 141 specifically manages and provides information related to the power usage of the low-voltage switchgear. ), and a low voltage switchgear bus bar temperature measuring module 142 for measuring and providing the bus bar temperature of the low voltage switchgear, and a low voltage switchboard arc measuring module 143 for measuring and providing arc generation in the low voltage switchgear. The low voltage switchgear state measuring unit 140 is connected to the low voltage switchgear data transmitting unit 212 to wirelessly transmit the measured data to the data collecting unit 220 .

The low-voltage switchgear power usage management module 141 is a configuration that manages and provides information related to the power usage of the low-voltage switchgear. Compared to simply predicting a failure based on only the temperature change of busbars in the low-voltage switchboard as an index, the actual low-voltage switchgear By using the temperature change versus the power usage rate (‘power usage rate’ is the concept of power usage versus capacity of the facility) as an index, it is possible to increase the accuracy of fault diagnosis and prediction and aging prediction of the present invention. It is a configuration that measures power usage related data or receives related information to manage and provide it.

The low voltage switchgear bus bar temperature measuring module 142 is configured to measure and provide the bus bar temperature of the low voltage switchboard, and by measuring and providing the bus bar temperature used in the low voltage switch board, the bus bar as an additional indicator together with other indicators By utilizing the temperature change trend, it is possible to increase the accuracy of fault diagnosis and prediction and aging prediction.

The low-voltage switchgear arc measurement module 143 is configured to measure and provide arc generation in the low-voltage switchboard. As described above, in the case of arc occurrence in the switchgear facility, it is used as a fire-related indicator, as well as failure due to overload in the facility. Since it can be used as an indicator of whether or not and aging diagnosis, it is necessary to measure and provide related information through the above configuration.

The motor control panel state measuring unit 150 is configured to measure and provide various environmental and state information of the motor control panel. For this purpose, the motor control panel bus bar temperature measuring module 151 specifically measures and provides the bus bar temperature of the motor control panel. ) may be included. The motor control panel state measurement unit 150 is connected to the motor control panel data transmission unit 213 to wirelessly transmit the measured data to the data collection unit 220 .

The motor control panel bus bar temperature measuring module 151 is configured to measure and provide the bus bar temperature of the motor control panel, and by measuring and providing the bus bar temperature used in the motor control panel, the bus bar as an additional indicator together with other indicators By utilizing the temperature change trend, it is possible to increase the accuracy of fault diagnosis and prediction and aging prediction.

The distribution board state measuring unit 160 is configured to measure and provide various environmental and state information of the distribution board. For this purpose, it specifically measures and provides the distribution board bus bar temperature measuring module 161 of the distribution board. can The distribution panel state measurement unit 160 is connected to the distribution panel data transmission unit 214 to transmit the measured data to the data collection unit 220 by wire or wirelessly.

The distribution board bus bar temperature measuring module 161 is configured to measure and provide the bus bar temperature of the distribution board, and by measuring and providing the bus bar temperature used in the distribution board, the bus bar temperature change trend as an additional index along with other indexes It is possible to increase the accuracy of fault diagnosis and prediction, aging prediction, etc.

The earthquake detection and measurement unit 170 is configured to measure and provide information related to whether an earthquake has occurred around the switchboard. In the case of the switchboard facility of the present invention, if necessary, a separate seismic resistance equipment for improving performance such as earthquake resistance. Because it is necessary to detect and respond to the occurrence of an earthquake for performance such as a necessary earthquake resistance, the earthquake detection and measurement unit 170 configuration as described above may be required. As the earthquake detection and measurement unit 170, a vibration sensor or the like may be used, but preferably, a three-axis sensor capable of detecting an amount of inclination change may be used. The earthquake detection and measurement unit 170 may be formed to be embedded in the data collection unit 220 .

The switchboard according to the present invention can predict the degree of failure and deterioration of the switchboard facility using the data provided by the data collection unit 20 as shown in FIG. 9, and the switchboard facility installed in a plurality of areas monitoring can be made.

In particular, there was a problem that the accuracy of diagnosis and prediction was low in the conventional techniques for fault diagnosis and prediction for conventional switchboard facilities based only on variables such as specific temperature conditions for each switchboard facility. The invention made it possible to provide not only fault diagnosis but also advance prediction and aging prediction with high accuracy based on comparative analysis or various measurement information within a group in which various environmental and state information is similar. To this end, the switchboard includes a data management unit 30 for storing and managing various information collected and transmitted through the data collection unit 20; a grouping unit 40 for grouping switchboard facilities having similar environment and state information based on the information provided through the data collection unit 20; a failure prediction unit 50 for predicting and providing a failure of the switchboard facility based on the information provided through the data collection unit 20; and an aging prediction unit 60 for predicting the degree of deterioration of the transformer among the switchboard facilities.

The data management unit 30 is configured to store and manage various information measured by the environmental condition measurement unit 10 and the like and transmitted through the data collection unit 20. Specifically, the data management unit 30 has a malfunction. A failure history data management module 310 that separately stores and manages historical data of ambient temperature/humidity, power consumption and various temperature information of the switchboard facility, and data on individual installation conditions, year, and individual capacity of the switchboard facility. , may include a switchboard facility information management module 320 to manage.

The failure history data management module 310 is configured to separately store and manage history data of ambient temperature/humidity, power consumption, and various temperature information of the switchboard facility in which the failure occurred. Basically, the data management unit 30 is the It stores, manages, and provides various information measured or generated and provided by the environmental condition measuring unit 10, the failure predicting unit 50, the aging predicting unit 60, and the like, and among these data, in particular, the failure history data management module ( 310), various related historical data before and after the failure of the equipment (ambient temperature/humidity change trend, (capacity-to-capacity) power consumption (i.e. power usage rate) trend, transformer temperature By separately storing and managing various information such as change trend, busbar temperature change trend, arc generation trend, age, etc.), it is used to improve the accuracy of fault diagnosis and prediction, aging prediction, etc. of the present invention by providing it.

The switchboard facility information management module 320 is a configuration that stores and manages data on the installation conditions, year, and individual capacity of the switchboard facility, and installation conditions such as whether the switchboard facility is installed indoors or outdoors It stores, manages, and provides basic information such as related information, the age of the corresponding switchboard facility, and various capacities such as the maximum capacity and rated capacity of various configurations such as transformers constituting the switchboard facility.

The grouping unit 40 is a configuration for grouping switchboard facilities having similar environment and status information based on information measured and provided by the environmental condition measuring unit 10, etc. As described above, failure of existing switchboard facilities Since the techniques for diagnosis and prediction are based only on variables such as specific temperature conditions for each switchboard facility, in order to solve the point that the accuracy of diagnosis and prediction is inevitably low, the present invention provides a group in which various environmental and state information is similar. Based on comparative analysis and various measurement information within the company, it is intended to provide high accuracy from failure diagnosis as well as prior prediction and even prediction of aging. Based on the grouping of switchboard facilities with the most similar conditions, it is a grouping configuration to increase the accuracy of diagnosis and prediction through relative comparison and analysis within the group. To this end, the grouping unit 40 is more specifically installed condition-based grouping module 410 for grouping the switchboard facilities based on the indoor or outdoor installation conditions of the switchboard facility provided by the switchboard facility information management module 320 and , A power usage rate-based grouping module for grouping switchboard facilities of similar power usage rates based on the power usage information of the switchboard facility measured by the environmental condition measuring unit 10 and the switchboard facility capacity information provided by the switchboard facility information management module 320 420, and a grouping integration module 430 for integrating and grouping the switchgear equipment subject to comparative analysis based on the grouping information of the installation condition-based grouping module 410 and the power usage rate-based grouping module 420, and the failure history data The management module 310 may include a grouping correction module 440 for correcting the grouping information of the switchgear facility subject to comparative analysis based on the failure history information of each switchboard facility.

The installation condition-based grouping module 410 is a configuration for grouping the switchboard facilities based on the indoor or outdoor installation conditions of the switchboard facility provided by the switchboard facility information management module 320, and the actual switchboard facility is located indoors. Depending on the installation conditions such as condition or outdoor conditions, the surrounding environment, especially conditions such as temperature and humidity, and internal temperature information of the switchboard facility may be affected, so the installation conditions (indoor or outdoor) where the switchboard facility is actually located etc.) group similar switchgear facilities and provide related information to the grouping integration module 430, which will be described later, and the like.

The power usage rate-based grouping module 420 derives the power usage rate versus the capacity of the switchboard facility based on the power usage information of the switchboard facility measured by the environmental condition measurement unit 10, and groups the switchboard facilities with similar power usage rates. As a result, the internal temperature change trend of a specific switchboard facility can be interpreted differently depending on the ratio of actual power usage to the rated capacity of the switchboard facility (power usage rate). By grouping the switchboard facilities showing the power usage rate, related information is provided to the grouping integration module 430, which will be described later, and the like.

The grouping integration module 430 is a configuration for integrating and grouping the switchgear equipment subject to comparative analysis based on the grouping information of the installation condition-based grouping module 410 and the power usage rate-based grouping module 420, and the above-described installation condition-based Based on the grouping information grouped by separate criteria in the grouping module 410 and the power usage rate-based grouping module 420, it is integrated and installed for distribution panel facilities (to be managed) scattered in a specific area It is possible to improve the accuracy of diagnosis and prediction according to the present invention by grouping the switchboard facilities having the most similar environmental and state information in consideration of the surrounding information such as conditions and the actually operated power usage rate.

The grouping correction module 440 is a configuration that can modify the grouping information of the switchboard facility subject to comparative analysis in the future based on the failure history information of each switchboard facility of the failure history data management module 310, and the grouping integration described above In a situation where grouping is made by the module 430 and used for failure diagnosis and prediction, etc., if a failure occurs in an actual switchboard facility after that, comparative analysis by modifying or updating the existing grouping information based on the actual failure history information, etc. It ensures that the grouping of the target switchboard facilities can always be precisely managed. The grouping correction module 440 may modify or update the existing grouping information by reflecting the change information when the surrounding environment and internal state information of each switchboard facility as well as the failure history of each switchboard facility are changed.

The failure prediction unit 50 is a configuration that predicts and provides failures for the switchboard equipment based on information measured by the environmental condition measurement unit 10 and provided through the data collection unit 20. In particular, the grouping integration module The accuracy of diagnosis and prediction is increased by diagnosing and pre-predicting a failure by relative comparison and analysis of measurement information between switchboard facilities having similar environment and state information grouped through 430. For this, specifically, installation conditions and power High-voltage switchgear failure diagnosis module 510 that diagnoses the failure of a specific high-voltage switchboard based on ambient temperature/humidity conditions, age, transformer temperature change, busbar temperature change, and arc occurrence information among high-voltage switchboards with similar usage rates, and installation A low-voltage switchgear failure diagnosis module 520 that diagnoses the failure of a specific low-voltage switchboard based on ambient temperature/humidity conditions, age, busbar temperature change, and arc occurrence information among low-voltage switchboards with similar conditions and power usage, and installation conditions A motor control panel failure diagnosis module 530 for diagnosing a failure of a specific motor control panel based on information such as ambient temperature/humidity conditions, age, bus bar temperature change, etc. Among these similar distribution boards, a distribution board failure diagnosis module 540 that diagnoses a failure of a specific distribution board based on information such as ambient temperature/humidity conditions, age, bus bar temperature change, etc., as well as the failure history data management module 310 of the Predict the possibility of failure based on the trend of transformer temperature change, bus bar temperature change, and arc occurrence frequency through comparative analysis with high voltage switchgear with a history of failure among high voltage switchboards with similar installation conditions and power usage rate based on information Based on the information of the high-voltage switchgear failure prediction module 550 and the failure history data management module 310, the It may include a low voltage switchgear failure prediction module 560 that predicts the possibility of failure based on the bar temperature change trend and the arc occurrence frequency.

The high-voltage switchgear failure diagnosis module 510 is a specific high-voltage switchboard failure based on ambient temperature/humidity conditions, age, transformer temperature change, busbar temperature change, and arc occurrence information among high-voltage switchboards with similar installation conditions and power usage rates. As a configuration for diagnosing , through the relative comparison among the switchgear facilities grouped through the grouping and integration module 430 described above, the ambient temperature/humidity condition and age of the high voltage switchboard of the group, and the transformer temperature change, busbar temperature Based on the change and arc occurrence information, the temperature change trend of the transformer of a specific high-voltage switchgear varies by more than a certain level compared to the ambient temperature/humidity condition or year, or the change in the bus bar temperature changes differently by more than a certain level, or the frequency of arcing When a change such as a relative difference is detected, a failure of the corresponding high-voltage switchboard is diagnosed based on this. In particular, as described above, in the present invention, similar switchgear facilities are grouped in consideration of the installation conditions and power usage rate of switchboard facilities through grouping, and changes are detected and diagnosed through relative comparison within the group, thereby increasing the accuracy of diagnosis.

The low-voltage switchgear failure diagnosis module 520 is configured to diagnose the failure of a specific low-voltage switchboard based on ambient temperature/humidity conditions, age, busbar temperature change, and arc occurrence information among low-voltage switchboards with similar installation conditions and power usage rates. As a result, through the relative comparison among the switchgear facilities grouped through the grouping and integration module 430 described above, the ambient temperature/humidity conditions and age of the low voltage switchboard of the corresponding group, and the busbar temperature change and arc occurrence information based on As a result, if a change is detected, such as a change in the busbar temperature change of a specific low voltage switchgear by more than a certain level, or a relatively different arc occurrence frequency compared to the ambient temperature/humidity conditions or model year, based on this, the to diagnose the fault.

The motor control panel failure diagnosis module 530 is configured to diagnose the failure of a specific motor control panel based on information such as ambient temperature/humidity conditions, age, and bus bar temperature change among motor control panels with similar installation conditions and power usage rate, Through the relative comparison among the switchboard facilities grouped through the grouping and integration module 430 described above, based on information such as ambient temperature/humidity conditions, age, and busbar temperature change among the motor control panels of the corresponding group, the ambient temperature /If a change is detected, such as a change in the temperature change trend of the busbar of a specific motor control panel by more than a certain level compared to the humidity condition or year, the failure of the motor control panel is diagnosed based on this.

The distribution board failure diagnosis module 540 is configured to diagnose a failure of a specific distribution board based on information such as ambient temperature/humidity conditions, age, busbar temperature change, etc. among distribution boards having similar installation conditions and power usage rates. Through the relative comparison among the switchboard facilities grouped through the grouping integration module 430, the ambient temperature/humidity condition or When a change is detected, such as a change in the busbar temperature change of a specific distribution board by more than a certain level, the failure of the corresponding distribution board is diagnosed based on this.

On the other hand, the high-voltage switchgear failure prediction module 550 is based on the information of the failure history data management module 310 through comparative analysis with a high-voltage switchboard with a past failure history among high-voltage switchboards with similar installation conditions and power usage rates. It is a configuration that predicts the possibility of failure based on the transformer temperature change trend, the bus bar temperature change trend, and the arc occurrence frequency. In contrast to diagnosing as a failure when the temperature change of temperature varies by more than a certain level (threshold) or when the frequency of arcing differs by more than a relatively critical value, the failure prediction function is not a failure at the present time, but in the future (early point in time). It is a function to predict in advance the situation with a high probability of a failure and prepare for it before a failure occurs. Through the analysis of the failure history data of the high-voltage switchgear, the point at which the relative change in the temperature/humidity condition, age, and power usage rate compared to the temperature/humidity condition, age, and power usage rate at the time before the failure occurs and the rate of change after that point occurs Based on this, the failure prediction information is analyzed and provided by predicting the probability of failure at the point in time when a change occurs based on the existing failure history data, even if it is not a change above a certain level or threshold based on the trend analysis.

The low-voltage switchgear failure prediction module 560 is based on the information of the failure history data management module 310. Based on the information of the failure history data management module 310, among the low-voltage switchboards with similar installation conditions and power usage rates, the busbar through comparative analysis with a low-voltage switchboard with a past failure history. It is a configuration that predicts the possibility of failure based on the temperature change trend and the arc occurrence frequency. Similar to the high-voltage switchgear failure prediction module 550 described above, the low-voltage switchboard failure prediction module 560 is also installed similarly to the existing one. Through the analysis of the failure history data of the low voltage switchboard where the failure occurred in the past among the low voltage switchboards in the grouping with condition and status information, Analyze the point at which a relative change occurs in the change trend and the change rate trend after that point, and based on this, the probability of failure occurring at the point in time when a change occurs based on the existing failure history data, even if it is not a change above a certain level or threshold, is determined. It analyzes and provides such failure prediction information by predicting.

The aging predicting unit 60 is a configuration for predicting the degree of deterioration of the transformer among the switchboard facilities, and for this purpose, specifically, by analyzing the capacity versus usage of the transformer based on the information of the switchboard facility information management module 320 to predict aging A usage rate-based aging prediction module 610 and a temperature-based aging prediction module 620 that predicts aging by analyzing the trend of temperature change for a certain period compared to the average temperature change standard of the transformer based on the information of the switchboard facility information management module 320 And, based on the information of the usage rate-based aging prediction module 610 and the temperature-based aging prediction module 620, it may include an integrated aging prediction module 630 that calculates and presents integrated information on the aging of the target transformer. .

The usage rate-based aging prediction module 610 is a configuration that predicts aging by analyzing the usage versus capacity of the transformer based on the information of the switchboard facility information management module 320, and even if the average usage of the transformer is similar for a certain period of time, each The amount of usage versus the capacity of the transformer may be different, and even if the transformer has a similar capacity, the lifespan and aging may differ depending on the actual usage for a certain period. By analyzing the usage for a certain period of time compared to the capacity of the target transformer, it is possible to predict the deterioration and increase the accuracy of the prediction.

The temperature-based aging prediction module 620 is a configuration for predicting aging by analyzing the temperature change trend for a certain period compared to the average temperature change standard of the transformer based on the information of the switchboard facility information management module 320, and the transformer has its own capacity Since a difference may occur in the lifespan and aging depending on the average transformer temperature change amount for a certain period of time due to actual use compared to the average expected temperature change standard based on the By analyzing the trend of temperature change for a certain period compared to the average temperature change standard of the target transformer, aging is predicted, and the prediction accuracy is improved.

The aging integrated prediction module 630 is configured to calculate and present integrated information on the aging of the target transformer based on the information of the usage rate-based aging prediction module 610 and the temperature-based aging prediction module 620, as described above. Based on the information of predicting the aging of the transformer with separate criteria in the usage rate-based aging prediction module 610 and the temperature-based aging prediction module 620, it is integrated and compared to the capacity of the corresponding transformer for a specific transformer By comprehensively considering the degree of deterioration based on actual usage and temperature change, it is possible to most accurately predict and provide the degree of deterioration of the corresponding transformer. Through this, it is possible to increase the maintenance efficiency of the power system by allowing replacement of existing expensive transformers in batches based on only the age of the transformer, rather than simply replacing them based on the exact degree of aging, before the occurrence of a failure due to extended use or aging.

In the above, the applicant has described various embodiments of the present invention, but these embodiments are only one embodiment that implements the technical idea of the present invention, and any changes or modifications as long as the technical idea of the present invention is implemented in the present invention should be construed as falling within the scope of

10: environmental condition measuring unit 110: ambient temperature measuring unit 120: ambient humidity measuring unit
130: high voltage switchgear state measuring unit 131: transformer temperature management module
132: high voltage switchboard power consumption management module 133: high voltage switchboard bus bar temperature measuring module
134: high voltage switchboard arc measuring module 140: low voltage switchboard state measuring unit
141: low voltage switchboard power consumption management module 142: low voltage switchboard bus bar temperature measuring module
143: low voltage switchboard arc measurement module
150: motor control panel state measuring unit 151: motor control panel bus bar temperature measuring module
160: distribution panel state measurement unit 161: distribution panel bus bar temperature measurement module
170: earthquake detection and measurement unit 20: data collection unit 210: individual data transmission unit
211: high voltage switchboard data transmission unit 211a: transformer data transmission control module
211b: transformer data wireless communication module 211c: relay data transmission control module
211d: relay data wireless communication module 212: low voltage switchboard data transmission unit
212a: low voltage switchgear data transmission control module
212b: low voltage switchboard data wireless communication module 213: motor control panel data transmission unit
213a: motor control panel data transmission control module
213b: motor control panel data wireless communication module
214: distribution panel data transmission unit 214a: distribution panel data transmission control module
214b: distribution panel data wired/wireless communication module 220: data collection unit
221: data collection control module 222: wireless communication collection module 223: wired communication collection module
224: wire transmission module 225: status display module 230: aggregate data transmission unit
231: data transmission/reception control module 232: wired data reception module
233: IoT wireless transmission module 30: data management unit 310: failure history data management module
320: switchboard facility information management module 40: grouping unit 410: installation condition-based grouping module
420: power usage rate-based grouping module
430: grouping integration module 440: grouping correction module
50: failure prediction unit 510: high-voltage switchboard failure diagnosis module
520: low voltage switchboard fault diagnosis module 530: motor control panel fault diagnosis module
540: distribution board failure diagnosis module 550: high voltage distribution board failure prediction module
560: low voltage switchgear failure prediction module 60: aging prediction unit
610: usage rate-based aging prediction module 620: temperature-based aging prediction module
630: aging integrated prediction module

Claims (11)

an environmental condition measuring unit that measures and provides various environmental and condition information of the switchboard facility; a data collection unit for collecting and transmitting information measured by the environmental condition measurement unit for a plurality of switchboard facilities; a data management unit for storing and managing various information transmitted from the data collection unit; a grouping unit for grouping switchboard facilities having similar environment and state information based on the information provided by the data collection unit; and a failure prediction unit that predicts and provides a failure of the switchboard based on the information provided by the data collection unit;
The failure prediction unit predicts failure through temperature change trend comparative analysis based on various environments and conditions of the switchboard facility,
The data collection unit,
An individual data transmission unit installed in each switchboard facility to wirelessly transmit measured information, a single data collection unit collecting information transmitted by the individual data transmission unit of each switchboard facility, and the data collection unit It includes an aggregate data transmission unit that transmits the received information using IoT wireless communication,
The individual data transmission unit,
A high-voltage switchgear data transmission unit for wirelessly transmitting the status information measured for the high-voltage switchboard, a low-voltage switchboard data transmission unit for wirelessly transmitting the measured status information for the low-voltage switchboard, and a wireless transmission of the status information measured for the motor control panel It includes a motor control panel data transmission unit, and a distribution panel data transmission unit for transmitting the measured state information on the distribution panel by wire or wirelessly,
The environmental condition measuring unit,
Ambient temperature measuring unit for measuring ambient temperature information of switchgear facilities, ambient humidity measuring unit measuring humidity information around switchgear facilities, high-voltage switchgear status measuring unit for measuring various environment and state information of high-voltage switchboard, and various environments and states of low-voltage switchgear A low-voltage switchboard state measuring unit for measuring information, a motor control panel state measuring unit for measuring various environmental and state information of the motor control panel, a distribution board state measuring unit for measuring various environmental and state information of the distribution panel, and an earthquake detecting and measuring unit for detecting an earthquake including,
The high-voltage switchgear state measuring unit, low-voltage switchgear state measuring unit, motor control panel state measuring unit, and distribution board state measuring unit are formed to be connected to each high-voltage switchboard, low-voltage switchboard, motor control panel, and switchboard, and each high-voltage switchboard data transmission unit, low-voltage switchboard data transmission unit, and electric motor To transmit the measured information through the control panel data transmission unit and the distribution panel data transmission unit,
The high voltage switchgear state measuring unit includes a transformer temperature management module that manages and provides information related to the transformer temperature, a high voltage switchgear power usage management module that manages and provides information related to power usage of the high voltage switchboard, and measures the busbar temperature of the high voltage switchboard and a high-voltage switchboard bus bar temperature measuring module provided by
The low-voltage switchgear state measuring unit includes a low-voltage switchgear power consumption management module that manages and provides information related to power usage of the low-voltage switchgear, a low-voltage switchgear bus bar temperature measurement module that measures and provides the bus bar temperature of the low-voltage switchboard, and a low-voltage switchgear inside It includes a low voltage switchgear arc measuring module that measures and provides arc generation,
The motor control panel state measuring unit includes a motor control panel bus bar temperature measuring module for measuring and providing a bus bar temperature of the motor control panel,
The distribution board state measuring unit includes a distribution board bus bar temperature measuring module that measures and provides the bus bar temperature of the distribution board,
The grouping unit includes an installation condition-based grouping module for grouping the switchboard facilities based on indoor or outdoor installation conditions of the switchboard facility, and the power consumption information of the switchboard facility and the capacity information of the switchboard facility provided by the data collection unit. A power usage rate-based grouping module for grouping the switchboard facilities of the power usage rate, and a grouping integration module for integrating and grouping the switchboard facilities subject to comparative analysis based on the grouping information of the installation condition-based grouping module and the power usage rate-based grouping module,
The failure prediction unit predicts failure by comparing and analyzing measurement information between switchboard facilities in the same group having similar environment and state information grouped through the grouping integration module,
A high-voltage switchgear failure diagnosis module that diagnoses a specific high-voltage switchboard failure based on ambient temperature/humidity conditions, transformer temperature change, busbar temperature change, and arc occurrence information among high-voltage switchboards with similar installation conditions and power usage, and installation conditions A low-voltage switchgear failure diagnosis module that diagnoses the failure of a specific low-voltage switchgear based on ambient temperature/humidity conditions, busbar temperature change, and arc occurrence information among low-voltage switchgears with similar power usage rates and electric motors with similar installation conditions and power usage rates A motor control panel failure diagnosis module that diagnoses the failure of a specific motor control panel based on ambient temperature/humidity conditions and busbar temperature change information among control panels, and ambient temperature/humidity conditions, busbar IoT-based integrated monitoring switchboard, characterized in that it includes a switchboard fault diagnosis module for diagnosing a specific switchboard failure based on temperature change information. delete According to claim 1, wherein the high voltage switchboard data transmission unit
A transformer data transmission control module for controlling the transmission of the status information measured for the transformer, a transformer data wireless communication module for transmitting the status information of the transformer to the data collection unit through wireless communication, and the transmission of the status information measured for the relay a relay data transmission control module for controlling the
The low voltage switchgear data transmission unit,
A low voltage switchgear data transmission control module for controlling the transmission of the measured status information to the low voltage switchgear, and a low voltage switchgear data wireless communication module for transmitting the status information of the low voltage switchgear to the data collection unit through wireless communication,
The motor control panel data transmission unit,
A motor control panel data transmission control module for controlling the transmission of the measured status information to the motor control panel, and a motor control panel data wireless communication module for transmitting the status information of the motor control panel to the data collection unit through wireless communication,
The distribution board data transmission unit,
A distribution board data transmission control module for controlling the transmission of measured status information to the distribution board, and a distribution board data wired/wireless communication module for transmitting the status information of the distribution board to the data collection unit through wired or wireless communication IoT-based characterized in that it includes Integrated monitoring switchboard. 4. The method of claim 3, wherein the data collection unit
A data collection control module for controlling data collection and transmission; a wireless communication collection module for wirelessly communicating with switchboard facilities to collect information; a wired communication collecting module for collecting information by communicating with switchboard facilities by wire; An IoT-based integrated monitoring switchboard comprising: a wired transmission module that transmits the collected information to the aggregated data transmission unit by wire; and a status display module that displays the status of the data collection unit or the aggregated information. 5. The method of claim 4, wherein the aggregate data transmission unit
A data transmission/reception control module for controlling data transmission/reception, a wired data reception module connected to the data collection unit by wire to receive data through wired communication, and IoT for transmitting data received from the data collection unit through IoT wireless communication IoT-based integrated monitoring switchboard comprising a wireless transmission module. 6. The method of claim 5, wherein the aggregated data transmission unit
IoT-based integrated monitoring switchboard, characterized in that it is formed integrally with the data collection unit and directly transmits information collected from each switchboard facility through IoT wireless communication. delete delete delete The method of claim 1, wherein the data management unit
A failure history data management module that separately stores and manages historical data of ambient temperature/humidity, power consumption, and various temperature information of the switchboard facility where the failure occurred, and data on the installation conditions, year, and individual capacity of the switchboard facility are stored, Includes a switchboard facility information management module to manage,
The failure prediction unit,
Based on the information of the failure history data management module, the possibility of failure based on the trend of transformer temperature change and busbar temperature change through comparative analysis with the high voltage switchboard with a past failure history among high voltage switchboards with similar installation conditions and power usage rate Busbar temperature change trend through comparative analysis between a high-voltage switchgear failure prediction module that predicts And IoT-based integrated monitoring switchboard, characterized in that it further comprises a low voltage switchgear failure prediction module for predicting the possibility of a failure based on the arc occurrence frequency. 11. The method of claim 10, wherein the switchboard
It further includes an aging prediction unit that predicts the deterioration degree of the transformer among the switchboard facilities,
The aging prediction unit, a usage rate-based aging prediction module for predicting aging by analyzing the usage versus capacity of the transformer based on the information of the switchboard facility information management module, and the average temperature change standard of the transformer based on the information of the switchboard facility information management module A temperature-based aging prediction module that predicts aging by analyzing the trend of temperature change over a certain period of time, and calculates and presents integrated information on the aging of the target transformer based on the information of the utilization-based aging prediction module and the temperature-based aging prediction module IoT-based integrated monitoring switchboard comprising an aging integrated prediction module.

Images