KR100702633B1 - Remote monitoring system and method for power supply equipment - Google Patents

Abstract

The present invention relates to a remote power monitoring system and a monitoring method that can be transmitted to the operator in a text message or the like if an abnormality occurs in the customer's power equipment. The system of the present invention is installed on the customer side using the power equipment, power monitoring terminal and power monitoring terminal for detecting and transmitting the status of the power equipment such as overload, leakage, voltage, and site conditions such as fire, flooding, etc. By monitoring and managing the monitoring data transmitted through the communication network in the database, the operator can manage the power equipment in real time even in remote locations, and send a text message (SMS) to the operator in case of abnormality such as fire, flooding, overload or leakage. It consists of a power monitoring server that promptly informs the user, and an operator side terminal such as a mobile phone for receiving text messages or a PC for accessing the power monitoring server. Therefore, according to the present invention, if an abnormal condition of the power equipment site is detected, the operator is notified promptly through a text message to properly take measures for emergency conditions such as fire, flooding, power failure, overload, short circuit, low voltage, etc. Taking further damage can be prevented.

Power equipment, monitoring, control, short circuit, overload, terminal, server, text message service

Description

Remote monitoring system and monitoring method {REMOTE MONITORING SYSTEM AND METHOD FOR POWER SUPPLY EQUIPMENT}

1 is a block diagram showing the overall configuration of a remote power monitoring system according to the present invention,

2 is a block diagram showing a detailed configuration of the main board and the setting board shown in FIG.

3 is a schematic diagram showing an example of a switchboard to which the present invention is applied;

Figure 4a is a flow chart illustrating a procedure for monitoring the motherboard in accordance with the present invention,

Figure 4b is a flow chart illustrating a procedure controlled by the motherboard in accordance with the present invention,

5 is a flowchart illustrating a procedure performed by a server according to the present invention;

6 is a schematic diagram showing the overall procedure according to the present invention.

* Explanation of symbols for main parts of the drawings

11: switchboard 12: fire receiver

13: Uninterruptible Power Supply (UPS) 14: Generator

15: water level sensor 10: customer system

102: public telephone network 104: wired and wireless Internet

106: mobile phone network 100: power monitoring terminal

110: main board 120: setting board

130: operator mobile phone 140: operator PC

200: power monitoring server 202: router

210: web server 220: DB server

230: SMS server

The present invention relates to a power monitoring system and a monitoring method that can be used in a factory, a building, a school, a hospital, etc., where a telephone network is installed, and more specifically, when an abnormality occurs in a power equipment of a customer. The present invention relates to a remote power monitoring system and a monitoring method that can prompt an operator by text message.

In general, consumer systems using power equipment such as factories, buildings, schools, hospitals, etc. need a means to manage power equipment. In the past, one or more PCs and terminals are attached to each power equipment, and a plurality of operators alternate in the field. I was checking and managing myself.

However, when the operator directly manages in the field as described above, the operator has to reside in the site, which is inconvenient, and requires a lot of manpower and time for management, which leads to an increase in labor costs. In addition, since expensive monitoring equipment is required for the monitoring, there is a problem in that it costs much to install the monitoring equipment.

The present invention has been proposed to solve the above problems, by installing a terminal in the customer's power equipment and connecting it to the communication network, if an abnormality is detected in the power equipment to promptly inform the operator through a text message to take action in advance The purpose of the present invention is to provide a power monitoring system and a monitoring method that can prevent a fire or a failure of a facility.

Another object of the present invention is to install the terminal in the switchboard of the consumer after transmitting the data monitoring the status of the power equipment (overload, short circuit, low voltage, etc.) and the situation of the site such as fire, flooding to the server to It is to provide a remote power monitoring system and monitoring method that can monitor the status in real time.

In order to achieve the above object, the system of the present invention is installed on the consumer side using the power equipment, the power for detecting and transmitting the status of the power equipment such as overload, leakage, voltage and on-site conditions such as fire, flooding A monitoring terminal; By monitoring and managing the monitoring data transmitted by the power monitoring terminal by the customer in a database, the operator can manage the power equipment in real time even in remote locations, and to the operator in case of an abnormality such as fire, flooding, overload or leakage. Power monitoring server that promptly informs via SMS (SMS); And an operator terminal such as a mobile phone for receiving the text message or a PC for accessing the power monitoring server.

The power monitoring terminal may include an input unit for receiving various monitoring target signals, a memory for storing data, a display unit for displaying an operation state, a communication driver for communicating with an external device, and monitoring data through a communication network. Communication means for transmitting to a power monitoring server, and communicates with an external device through the communication driver, and displays the operation state on the display unit, and stores the detection value input through the input unit in the memory and the detection value If it is determined that the abnormality compared to the preset reference value in the memory may be configured as a control unit for transmitting to the power monitoring server through the communication means, a relay driver for controlling the monitoring target, the power monitoring server is limited to the operator in the place Web services that provide web services to monitor the status of the site without receiving A server, a database server for managing data transmitted by the power monitoring terminal for each customer, and a database for managing the data, and when abnormality detection data is received from the power monitoring terminal, a text message service (SMS) to a preset operator's telephone number It can be configured as a text message server to transmit it using.

In addition, the method of the present invention, in order to achieve the above object, in the power facility monitoring method using a power monitoring server connected to the power monitoring terminal through a communication network to monitor the power equipment from a remote location, the power monitoring Setting a reference value for determining an abnormality of a monitoring target in a terminal; Determining, by the power monitoring terminal, whether an abnormality is detected by comparing the detected value detected from the monitoring target with the reference value; If the determination result is abnormal, transmitting the abnormality data from the power monitoring terminal to the power monitoring server through a communication network; And when the power monitoring server receives the abnormal data, transmitting the abnormal data using a text message service (SMS) to a preset operator's telephone number.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the overall configuration of the power monitoring system according to the present invention, Figure 2 is a block diagram showing a detailed configuration of the main board and the setting board shown in Figure 1, Figure 3 is applied to the present invention It is a schematic diagram which shows the example of the switchboard which becomes.

The power monitoring system according to the present invention, as shown in Figure 1, is installed on the customer side 10 using the power equipment to monitor the on-site conditions such as fire, flooding and the status of the power equipment such as overload, leakage, voltage, etc. The power monitoring terminal 100 and the monitoring data transmitted by the power monitoring terminal 100 through the communication network are classified and stored in a database so that the operator can manage the power facilities in real time even in remote locations, and in case of fire or flooding. When an abnormality such as an overload, a short circuit, etc. occurs, the power monitoring server 200 which promptly informs the operator through a short message service (SMS), and the mobile phone 130 and the server 200 to receive the text message are connected. It consists of an operator-side terminal such as a PC (140).

Referring to FIG. 1, a power monitoring terminal 100 on a consumer side is installed in a distribution panel (distribution box) 11, and includes a current transformer (CT) and an image transformer for detecting a state of power supplied from the distribution panel 11. (ZCT: Zero phase Current Transformer) and the fire receiver 12, the uninterruptible power supply (UPS: 13), the generator 14, the water level sensor (15), and the state of the site, such as fire, flooding, The state of the power equipment such as the overload of the power supplied through the switchboard 11, the short circuit, the voltage of the uninterruptible power supply 13, the voltage of the generator (battery: 14), etc. are transmitted to the server 200 through the communication network.

The power monitoring terminal 100 is composed of a main board 110 that performs a main function for power monitoring, and a setting board 120 for setting various reference values or downloading data stored in the main board 100. Here, the setting board 120 is separated from the main board 110 to be movable, the operator connects the setting board 120 to the main board 110 and RS232C terminal installed in the switchboard and then set the reference value or main The data stored in the board 110 can be downloaded and connected to the RS232C port of the operator PC 140 installed in the office again to manage the data in the operator PC 140.

As shown in FIG. 2, the main board 110 of the power monitoring terminal includes an input unit 111 for receiving various monitoring target signals, a microprocessor (MCU) 112, and an EPIROM for storing data. 113), a RAM 114, a relay driver 115 for driving a relay installed in a monitoring target, a display unit 116 for displaying an operation state, an external device such as a setting board 120 or a PC 140, and the like. RS232C driver 117 for communication, telcomm unit 118 for transmitting the monitoring data to the server 200 via a telephone line, the setting board 120 is RS232C driver 121 for RS232C data communication ), A key input unit 122 for an operator to operate, a microprocessor 123, a memory 124 for storing various data, and an LCD 125 for displaying an operation state.

Referring to FIG. 2, the input unit 111 receives a digital input such as a relay contact or an analog signal such as current / voltage from a monitoring target, and converts the analog signal into digital (A / D) to the microprocessor 112. To pass. The display unit 116 is implemented as an LED or LCD, and displays an operation state or a current voltage / current / load amount, etc. under the control of the microprocessor 112, and the telcom unit 118 is a conventional communication protocol such as an ATM PPP method. In accordance with the telephone network 102 provides a communication function with the power monitoring server 200.

In the switchboard 11 to be monitored according to the present invention, as shown in FIG. 3, an earth leakage breaker ELB is connected to the power lines R, S, T, and N of the three-phase four-wire, and three-phase R, S, T A current transformer CT is installed on each of the power lines so that the secondary side of the current transformer CT is connected to the input unit 111 of the main board 110, and four R, S, T, and N lines connect one image current transformer (ZCT). After passing through, the secondary side of the image current transformer ZCT is connected to the input unit 111 of the main board, and a disconnection detection relay RL1 is installed to turn on the contact during disconnection. Therefore, the main board 110 can detect the magnitude of current flowing through the R, S, and T power lines through the current transformer CT, so that the main board 110 can determine whether an overload is compared with the set reference value, and the vector value of the image current transformer ZCT. When the output is greater than 0, the detected data may be checked to determine whether a short circuit occurs. When the contact of the short circuit detection relay RL1 is turned on, it may be determined to be a short circuit. In addition, a plurality of relay contacts may be connected to the ground fault breaker ELB of the switchboard to control the ground fault breaker ELB according to the relay driving signal. Therefore, in case of an emergency, the operator may cut off the power at a remote location by sending a power cut command through the communication network.

Referring back to FIG. 1, a communication network includes a public telecommunication network (PSTN) 102 for providing a normal wired telephone service and a mobile telephone network for providing a wireless telephone service such as a text message service (SMS) by a text message center (SMC). 106, the Internet 104 for providing data communication services according to the TCP / IP protocol.

The power monitoring server 200 is connected to the router 202 for accessing the ATM PPP method through the telephone network (PSTN: 102) and the Internet 104 so that the operator can monitor the status of the site without being restricted by the place. The web server 210 that provides the web service, the database server 220 for managing the data transmitted by the power monitoring terminal 100 by a database (DB) to separate by the customer, and the abnormal data from the power monitoring terminal 100 When received, it is composed of a text message server 230 for transmitting an alarm message for the occurrence of an abnormality through the text message service of the mobile communication network 106 to the mobile phone 130 of the operator. In this case, the data generated for the text message may take the form of a character in the HEX code, and may include a year, month, date and time, a corresponding terminal ID, and a code for distinguishing an abnormal (alarm) state.

Next, the operation of the power monitoring system according to the present invention configured as described above will be described in detail.

4A is a flow chart illustrating a procedure monitored by the motherboard in accordance with the present invention, and FIG. 4B is a flow chart illustrating a procedure controlled by the mainboard in accordance with the present invention.

Referring to FIG. 4A, the operator of the consumer system 10 in which the power monitoring terminal 100 according to the present invention is installed, sets various reference values after connecting the setting board 120 to the main board 110 in an RS232C manner. (S401). For example, by comparing the current of each phase detected by the current transformer (CT) by comparing the overload reference value for judging as an overload, and the value detected by the image current transformer (ZCT), the reference value, terminal ID, low voltage reference value, load amount The check period and the like are stored in a nonvolatile memory (EEPROM, etc.) of the main board 110 using the setting board 120.

In this state, the microprocessor 112 of the main board receives a detection signal from a monitoring target input through the input unit 111. Typically, the detection signal is a digital signal such as on / off of a relay contact, an analog current signal such as a current value of a current transformer (CT) or an image current transformer (ZCT), a voltage of the uninterruptible power supply 13 or a voltage of the generator 14. As described above, there are analog voltage signals and the like. In the input unit 111, analog signals are converted into digital signals.

Next, the contacts of the disconnection detection relay RL1 of the switchboard, the major alarm contacts of the fire receiver 12, and the contacts of the water level sensor 15 are checked (S402).

The microprocessor 112 determines the on / off of the disconnection detection relay contact as a result of the check, determines that the contact is on, generates an alarm data packet based on a terminal ID, an alarm type, a detection time, and the like. It transmits to the server 200 via a communication network (S403, S414, S415).

Judging the on / off of the main diameter longitudinal contact of the fire receiving panel 12 is judged to be a fire occurrence when the contact is turned on (S404), judging by the flooding when the contact is turned on by judging the on / off of the contact level sensor 15 (S405). If it is determined that the fire occurred or flooded, the alarm data packet is generated by the terminal ID, alarm type, detection time, etc., and then transmitted to the server 200 through the telcom unit 118 through the communication network (S414, S415).

Subsequently, the current value of each phase is calculated by the voltage value of the current sensed by the current transformer CT of each phase of the switchboard, and compared with a preset overload reference value and determined to be an overload if it is greater than the overload reference value (S406, S407). After calculating the phase vector of each phase by the voltage value of the current sensed by the current transformer (ZCT), when the vector value is 0 or more, the detected output value is compared with a preset leakage reference value, and it is determined that the leakage current is higher (S408). S409). If it is determined that an overload or a short circuit, the alarm data packet is generated by the terminal ID, alarm type, detection time, etc. and then transmitted to the server 200 via the telcom unit 118 through the communication network (S414, S415).

Subsequently, the battery voltage values of the uninterruptible power supply device 13 and the generator 14 are checked, and when the detected voltage value is out of a preset reference voltage value, it is determined to be abnormal and generates an alarm data packet in the same manner. 200) (S410, S411).

When the preset load checking period is reached, the load is calculated according to the detection signals of the current transformer CT and the image transformer ZCT, and then the load data is stored in the memory along with the time information and transmitted to the server 200 through the communication network. (S412, S413). Therefore, the load data stored in the memory of the main board is downloaded through the setting board 120 and managed through the operator PC of the field office, and the operator is connected to the server 200 through the PC from a remote place regardless of the location of the power equipment To be able to manage

On the other hand, when the microprocessor 112 of the main board receives a control command from the server 200 through the communication network with the telcomb unit 118, as shown in Figure 4b, decoding the received command if the power-off command, the corresponding relay Drive the circuit breaker (ELB) to cut off the power, if the other command executes the corresponding command (S421 ~ 425). As described above, the present invention enables the ELB to be controlled even at a remote location, so that the operator can see the transmitted text message, grasp the overload or the short circuit, and take premeasures before arriving at the site. Disasters can be prevented from occurring.

5 is a flowchart illustrating a procedure performed by a server according to the present invention.

The server 200 according to the present invention includes a web server 210, a DB server 220, an SMS server 230, and the like, so that a service subscriber or a power monitoring terminal purchaser can monitor a site's electric power facilities at a remote location. do. To this end, the operator of the consumer system accesses the web server 210 and registers operator personal information such as an ID, password, and a phone number for receiving a text message to set a monitoring environment (S501). In addition, the power monitoring terminal 100 installed in each customer system is assigned a unique number can be managed by the audience.

 When the operator accesses the server 200 via the wired / wireless internet, the operator processes an authentication procedure such as a password input to confirm whether the operator is a legitimate operator (S502, S503). If the authentication is successful, the logged-in operator processes the various monitoring data and load data of the power equipment managed by the operator and displays it in graphs, texts, and graphics (S504 to S506). As a service that can be provided to the operator by connecting the power monitoring terminal 100 and the power monitoring server 200 installed in the field to the communication network as described above, in addition to the service described above, by installing a fire detection sensor on the site, courtesy in the street and place The operator can know whether the fire is abnormal through text message (SMS), and the motor of the fire suppression sprinkler is operated through the control command using the wireless or wired telephone of the mobile phone and the earth leakage breaker (ELB) Operation, so a variety of services, such as power off,

On the other hand, the power monitoring server 200 receives the monitoring data of the site from time to time or at regular intervals from the power monitoring terminal 100 installed in each site and stores them in a database classified according to the terminal ID. When receiving the alarm data from the power monitoring terminal 100, after decoding the alarm data and transmits a text message to inform the mobile phone number of the operator set in advance (S507 ~ S509). Accordingly, the operator can monitor the operation status of the power equipment in real time even when not in the field, and can quickly take action in case of emergency such as fire, flooding, power failure, overload, short circuit, low voltage.

Figure 6 is a schematic diagram showing the overall procedure according to the present invention, there is shown a procedure for transmitting the monitoring data from the power monitoring terminal 100 to the server 200 and a procedure for the operator to log in.

As described above, according to the present invention, the power monitoring terminal 100 transmits the data detected from the monitoring target to the server 200, and the server 200 manages the data transmitted from each terminal 100 as a database while the operator accesses the data. The data can then be processed / analyzed and statistically processed and displayed graphically on the Web, allowing operators to easily monitor power facilities in real time, even from remote locations.

As described above, according to the present invention, after installing a power monitoring terminal in a switchboard of a customer system equipped with a high-voltage facility, and connected to the server system through a communication network, the operator can monitor the power equipment regardless of the location and the convenience and In addition, labor costs can be reduced by managing a small number of personnel.

In addition, if an abnormal condition is detected at the power facility site, a text message is notified to the operator promptly. Even if the operator is not on the site, appropriate actions are taken for emergency situations such as fire, flooding, power failure, overload, short circuit, and low voltage. It can be prevented from occurring.

Claims (10)

It is installed on the customer's side using power equipment, and it is detachably connected to the main board for detecting and transmitting the status of power equipment such as overload, leakage, short circuit, voltage, etc. A power monitoring terminal comprising a setting board for setting various reference values required for monitoring or downloading data stored in the main board; The monitoring data received from the power monitoring terminal is classified and stored in a database so that the operator can manage the power equipment in real time even at a remote location, and text messages to the operator in case of abnormality such as fire, flooding, overload or leakage. Power monitoring server for prompt notification via SMS); And It consists of an operator-side terminal consisting of one or more of a mobile phone or a PC for accessing the power monitoring server to receive and confirm monitoring data and text messages and to transmit necessary control signals. The main board and the power monitoring server of the power monitoring terminal perform transmission and reception of monitoring data and control signals through a public telephone network, and the operator side terminal and the power monitoring server are connected to a mobile telephone network and a wired or wireless Internet network. Remote power monitoring system. According to claim 1, The main board of the power monitoring terminal, An input unit for receiving various monitoring target signals; A memory for storing data; A display unit for displaying an operation state; A communication driver for communicating with an external device; Communication means for transmitting monitoring data to the power monitoring server through a communication network; Communicate with an external device through the communication driver, display an operation state on the display unit, store the detected value input through the input unit in the memory, and compare the detected value with a reference value preset in the memory. And a microprocessor for transmitting to the power monitoring server through the communication means when determined. According to claim 2, The main board of the power monitoring terminal, Further comprising a relay driver for controlling the monitoring target, When the control command is received through the communication means, the remote power monitoring system, characterized in that it is possible to control the monitoring target by driving the relay driver after decoding it. According to claim 2 or 3, wherein the setting board of the power monitoring terminal is In the state of being connected with the main board and communicating with the microprocessor through the communication driver to set the reference value in advance and download the detected value stored in the memory, and then separated from the main board in the state connected to the PC of the operator side terminal Remote power monitoring system, characterized in that configured to deliver the detected value. According to any one of claims 1 to 3, The detection value for the monitoring target is a magnitude value of the R, S, T three-phase current sensed through the current transformer (CT) of the switchboard to determine the overload, The phase vector value detected through the ZCT of the switchgear, the detection value for judging the fire, the detection value for the water level sensor, the detection value for detecting the power failure, and the voltage value of the emergency power supply. Remote power monitoring system, characterized in that. The method of claim 1, wherein the power monitoring server A web server that provides a web service for the operator to monitor the status of the site without being restricted by places; A database server for managing the data transmitted from the power monitoring terminal by a customer and managing the data in a database; When the abnormality detection data is received from the power monitoring terminal, a remote power monitoring system comprising a text message server for transmitting this by using a text message service (SMS) to a preset operator's telephone number. The method of claim 6, wherein the power monitoring server When the operator connects to the terminal, the user authenticates according to a predetermined authentication procedure. If the authentication is successful, the monitor data on the power equipment managed by the operator is displayed by graphic or text according to the operator's request, and when the operator's control command is input. Remote power monitoring system, characterized in that for transmitting to the power monitoring terminal through the public telephone network. As a method of monitoring the state of the power equipment such as overload, leakage, short circuit, voltage, and the like, installed on the consumer side using the power equipment by using the remote power monitoring system according to claim 1, Setting a reference value for determining an abnormality of a monitoring target in the power monitoring terminal; Determining, by the power monitoring terminal, whether an abnormality is detected by comparing the detected value detected from the monitoring target with the reference value; If it is determined that the result is abnormal, the power monitoring terminal transmitting abnormal data to the power monitoring server through a public telephone network; And And receiving the abnormality data by the power monitoring server, using a text message service (SMS) to a preset operator's telephone number. The method of claim 8, wherein the power monitoring method, When the operator accesses through the terminal, after authentication, displaying the site status information of the power equipment managed by the operator according to the operator's request, And transmitting the control command to the corresponding power monitoring terminal through the communication network. delete

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