KR101021628B1 - The electric-safety monitoring system managing state of the local leakage curcuit breaker and distributing board - Google Patents

Abstract

The present invention relates to a system for managing electrical safety of a market or a shopping mall. More specifically, the electric disaster that may occur in individual stores of a market or a shopping mall is utilized in an electrical installation of a regional distribution panel or a distribution panel by using an optical communication network. It is a system that prevents the risk of fire or electric shock due to fire.

The present invention provides an electrical safety monitoring system for managing the state of switchboards and switchboards installed in each region, wherein the local server is connected to the switchboard and switchboards in a network to receive and store data detected by the switchboards and switchboards; An electric fire prediction unit connected to a network with the local server and analyzing the data received by the local server through a fuzzy inference technique to generate an electric fire prediction index and to store it in the local server; And a management server connected to a network with the local server and receiving data stored in the local server in real time, and managing data through the web. Present an electrical safety monitoring system.

The electrical safety monitoring system using the optical communication network of the present invention manages electrical safety through real-time data such as short-circuit, overcurrent, arc, and leakage current of distribution panels and distribution panels for each region and the fire occurrence prediction index analyzed through the data. It can be effective.

Distribution board, optical communication, photocoupler, electric fire prediction unit, trunk protection unit

Description

The electric-safety monitoring system managing state of the local leakage curcuit breaker and distributing board}

The present invention relates to a system for managing electrical safety of a market or a shopping mall. More particularly, the present invention relates to an electric disaster that may occur in individual stores such as a market or a shopping mall in an electrical installation of a regional distribution panel or a distribution panel using an optical communication network. This system prevents the risk of fire or electric shock from electricity.

Typically, the main causes of electrical fires are short circuits, overcurrents, arcs and leakage currents. As a continuous effort to reduce the occurrence of electrical fires, individual equipment such as breakers can be used to prevent fire accidents in power distribution boards and switchboards by preventing power supply in the event of short circuit, over current, or short circuit.

However, the system that can monitor the arc and leakage current status through the manager at all times, to predict the electric fire potential in advance is still insufficient.

In particular, the electric fire according to the arc has no importance in comparison with the causes of other electric fires according to the classification method of fire statistics, and since it was passive in the arc detection technology development, there is virtually no prevention of the fire due to the arc. It is a state.

However, due to the difficulty in the investigation of the electric fire, a considerable portion of the electric fire due to the arc is judged to be another cause and statistically processed, and it is estimated that the accident share is actually higher.

In order to reduce the electric fire, it is possible to prevent the electric fire by extracting the electrical signal characteristics of arc and the signals such as overcurrent, leakage current, overvoltage, and taking quick measures for the electrical equipment with signs of electric fire.

There is a need for a system that can obtain objective and scientific data on arcs, overcurrents, overvoltages, leakage currents, etc., and can evaluate electrical fire precursors and take appropriate measures.

In addition, when a circuit breaker installed in a conventional distribution panel or a distribution panel is seen, a micro switch is mounted inside to transmit a state inside the circuit breaker.

1 shows a three-phase wiring circuit breaker equipped with a micro switch for detecting a power supply state installed in a conventional distribution board. Referring to FIG. 1, a circuit breaker for a wiring includes a micro switch.

More specifically, the conventional circuit breaker for three-phase circuit breaker is operated by turning on / off the contact of the micro switch using the mechanism inside the circuit breaker using the micro switch.

In addition, the circuit breaker is configured by adding a remote monitoring function so that the administrator can monitor the operation state as an external signal. In other words, the micro switch generates an alarm signal indicating that a trip occurred due to an abnormal state, and sends an alarm signal to an external manager to notify that the breaker is tripped.

However, in the case of the circuit breaker equipped with the micro switch 10, it is not easy to mount the micro switch in a narrow space, the cost is increased due to the increase in the number of installation of the circuit breaker, and the contact loss due to the friction in the driving direction of the mechanism part is feared. It is becoming.

In addition, the micro-switch 10 is virtually difficult to install in a small circuit breaker such as a single-phase earth leakage breaker, so that there is no distribution panel having a function of accurately detecting the state of the earth leakage breaker.

In addition, unlike a circuit breaker, a switchboard equipped with a line switch for transmitting a signal to the outside by installing a micro switch for each earth leakage breaker installed in a plurality of switchboards is also a problem in terms of price and difficulty in equipment. It has a problem that is virtually impossible.

In order to solve the above problems, the present invention provides an optical communication network system for managing electrical safety through the real-time data, such as short circuit, overcurrent, arc, leakage current of the distribution panel and distribution panel by region and the fire occurrence prediction index analyzed through the data. It is for the purpose of presentation.

In addition, it is an object of the present invention to provide an electrical safety management network system having a distribution panel and a distribution panel for each region equipped with a circuit breaker that can monitor the power state of the load side and the power side of the circuit breaker without the micro switch.

In addition, it is an object of the present invention to provide a network system for electrical safety management that can easily monitor the possibility of local fire occurrence, and can respond immediately.

In order to achieve the above object, the present invention is an electrical safety monitoring system for managing the state of the switchgear and switchboards installed for each region, the network is connected to the switchgear and switchboards received data detected in the switchgear and switchboards Local server by region; An electric fire prediction unit connected to a network with the local server and analyzing the data received by the local server through a fuzzy inference technique to generate an electric fire prediction index and to store it in the local server; And a management server connected to a network with the local server and receiving data stored in the local server in real time, and managing data through the web. Present an electrical safety monitoring system.

The trunk line protection unit for detecting the input-output difference value of the current through the current sensor in the trunk line from the switchboard to the distribution panel and transmits the input-output difference value to the local server through a network.

The distribution panel may include: a data detector configured to detect, digitize, and analyze electrical safety related data through a circuit breaker built in the distribution panel; An arc detection unit for comparing the current and voltage data of the distribution panel with a predetermined reference voltage and reference current data to determine whether a dangerous arc is detected and to transmit data to the data detection unit; A communication unit which receives the data analyzed by the data detection unit through a serial interface and transmits the data to the local server through a network; And a display unit for receiving and displaying the data detected by the data detector and the data received through the arc detector through short-range communication.

The circuit breaker is connected to the power supply terminal of the circuit breaker and receives a power supply from the power supply side and emits light and a power supply photocoupler for receiving a signal output from the terminal of the transistor that is conducting when the diode emits light to detect the power supply state on the power supply side A load side photocoupler and a power side connected to a load-side terminal of the circuit breaker and receiving a power from the load side to receive a signal and a signal output from a terminal of a transistor that is turned on when the diode emits light to sense a power state of the load side and the power side And a signal output terminal for transmitting a signal of an overload photocoupler, and the data detector includes a detection terminal receiving signals from the power supply side and the load side photocoupler to determine a power supply state through the circuit breaker. Can be configured.

The communication unit includes a serial interface for transmitting and receiving data to and from the data detector in both directions; An Ethernet controller for connecting a network to the local server; RF receiving unit for receiving data from an external sensor device; And a main controller converting the received data into serial data or Ethernet data.

The management server, receiving and storing the data of the distribution panel and switchboard for each region from the local server, the monitoring server for displaying the status of the distribution panel and switchboard for each region on the web through the built-in web application based on the stored data; An SMS server for transmitting an SMS to an administrator terminal through a network based on the data transmitted to the monitoring server; And a remote power server that remotely manages power of the distribution panel by identifying a distribution panel in which an abnormal symptom is displayed based on the data transmitted to the monitoring server.

The monitoring server may have a built-in electrical safety map application combined with a geographic information system may be configured to provide a visual alarm through the electrical safety map of the regional distribution panel and switchgear by interlocking with the web application.

The web application of the monitoring server has a built-in timer alarm function so that a notification message is transmitted to the monitoring server about the status of distribution panels and switchboards for each region while the time timer is operating, and the alarm highlights are displayed on the electrical safety map on the web. Can be configured.

The timer alarm function of the web application may be configured to repeatedly display the state of the switchgear and switchgear by region at regular intervals, including a refreshing function of the electric safety map indicating the state of the switchgear and switchgear by region as alarm highlights.

When a problem occurs in the region displayed on the electrical safety map, the monitoring server may be configured to send a notification message to the local administrator terminal by requesting the SMS server.

In order for the SMS server to track the location of the local administrator terminal, a GIS or FMS server may be further constructed in the management server so as to determine in real time the location of the administrator terminal equipped with the GIS or FMS system.

The monitoring server may have a built-in wiring diagram of the electrical equipment of the distribution panel and the distribution panel for each region supporting the electrical safety map application.

The monitoring server may be configured to provide a predetermined permission-specific electric safety map through the electric safety map application according to the authentication information requesting access to the web.

According to the present invention, the following effects can be obtained by the electric safety monitoring system for managing the state of the distribution panel and the distribution panel installed for each region.

First, the electrical safety monitoring system using the optical communication network of the present invention in real time by the real-time data such as short circuit, over-current, arc, leakage current of the distribution panel and distribution panel by region and the fire occurrence index analyzed through the data It has the effect of managing safety.

Secondly, the photocoupler is mounted on the load side and the power side, respectively, and a circuit breaker capable of receiving remote signals can be used to monitor the power state of the breaker's load side and the power side without the micro switch being installed, without the need for a micro switch. It monitors the status and has an effect that can be remotely managed through the remote power server of the management server when an abnormal current occurs.

Third, through the management server built-in application that combines the data received from the trunk protection unit configured in the present invention and the electronic map, it is possible to monitor the entire area more easily and also remote power server in the distribution panel that may cause a fire It is effective to take immediate action through and SMS server.

Below. With reference to the accompanying drawings, the electrical safety monitoring system for managing the state of the distribution panel and switchgear provided by the region of the present invention will be described in detail.

FIG. 2 is an overall schematic diagram of an electrical safety monitoring system according to the present invention. Referring to FIG. 2, there is shown an electrical safety monitoring system for managing a state of a distribution panel and a distribution panel installed in a market or a shopping mall by region. 100 and the distribution panel 200 in the mall is connected to the local server 300 in the market or mall for each region through the optical communication network and transmits data to the local server 300.

In other words, the local server 300 for each region is connected to the switchboard 100 and the switchboard 200 through a network to receive and store the data detected by the switchboard 200 and the switchboard 100.

The switchboard 100 includes a switchboard diagnostic unit (not shown) built therein, and detects an arc generation signal caused by an abnormality of a connection part in the switchboard, a partial discharge signal generated in an electrical facility of the switchboard, and the like. It is transmitted to the local server 300 to be able to diagnose in advance whether there is an abnormality of the electrical equipment.

The electric fire prediction unit 400 connected to the local server 300 through a network analyzes the data received by the local server 300.

To this end, the electric fire prediction unit 400 generates an electric fire prediction index through the fuzzy inference technology and stores the numerical value quantifying the risk status of the distribution panel in each market or mall in the local server 300.

The management server 500 configured in the present invention is connected to the network with the local server 300 to receive data stored in the local server 300 in real time to manage the situation information data related to electrical safety through the web.

In addition, the trunk line protection unit 600 is configured in the trunk line, which is not directly connected to the load from the switchboard 100 to the distribution panel 200, to install a current sensor, such as a CT, in the trunk line, and then through the CT. By detecting the input and output difference value of the transmission to the local server 300 through the network to the input and output difference value to prevent the electric fire in advance to transmit the data to the local server 300.

The management server 500 receives and stores data of the distribution panel 200 and the distribution panel 100 for each region from the local server 300 and stores the state of the distribution panel and switchboard for each region based on the stored data through a built-in web application. On the web based on the monitoring server 520 and the data transmitted to the monitoring server based on the SMS server 540 for transmitting the SMS to the administrator terminal over the network and the abnormal signs appeared based on the data transmitted to the monitoring server It is configured to include a remote power server 560 to grasp the distribution panel and remotely manage the power of the distribution panel.

Figure 3 shows a block diagram of the distribution boards installed in each market or mall according to the present invention, Figure 4 shows an internal block diagram of the distribution boards installed in each market or mall according to the present invention, Figure 5 Figure 6 is a block diagram for detecting and managing a power supply state through a circuit breaker built in a distribution board installed in each market or a shopping mall according to the present invention. Represents a block diagram.

Referring to FIG. 5, the regional distribution panel 200 includes a data detector 220 for detecting, digitizing, and analyzing electrical safety-related data through the built-in circuit breaker 210, and setting the reference voltage and the current and voltage data of the distribution panel. An arc detector 230 for transmitting data to the data detector by determining whether a dangerous arc is compared with the current data, and a communication unit receiving the data analyzed through the serial interface from the data detector and transmitting the data to the local server through a network ( 240, and a display unit 250 for receiving and displaying the data detected by the data detector and the data received through the arc detector through short-range communication.

An SMPS unit 260 is separately configured in the distribution panel to supply DC power and AC power to the data detector 220, the arc detector 230, the communication unit 240, and the display unit 250.

In order to determine the power supply state through the circuit breaker 210 built in the distribution panel 200, the short circuit, the arc, the leakage current through the image current transformer (ZCT) built in the circuit breaker 210 in the data detector 220. And the like, and receives a signal output from the plurality of detection sensors (CT, ZCT) built in the circuit breaker 210 to detect a power failure state such as overcurrent.

In addition, a pair of photocouplers 210a and 210b for sensing the power supply side and the load side power supply state of the circuit breaker 210 to detect the power supply state of each circuit breaker 210 are built in the circuit breaker, And a signal output terminal 210c for transmitting signals of the power supply side and the load side photocoupler.

In addition, the data detector 220 includes a detection terminal 220a as a serial interface for receiving signals from the power supply side and the load side photocouplers 210a and 210b to determine a power supply state through the circuit breaker. .

The power supply side photocoupler 210a is composed of a diode connected to the power supply terminal of the circuit breaker and applied with a voltage to emit light, and a transistor connected with a base voltage when the diode emits light.

The detection terminal 220a of the data detector 220 receives a signal output from a connector terminal or an emitter terminal of the transistor to detect a power supply state of the power supply side.

In addition, the load side photocoupler 210b is also composed of a diode connected to the load side of the circuit breaker to receive power and emit light, and a transistor to which the base voltage is applied when the diode emits light, and the detection terminal 220a is the transistor. It receives the signal output from the connector terminal or emitter terminal of and detects the power state of the load side.

The power side photocoupler 210a has a resistor that acts as a pull-up resistor in series with the line between the power side and the diode to which power is supplied to maintain a constant signal level.

In other words, the voltage applied to the diode at the power supply side is kept constant through a resistor serving as a pull-up resistor, and thus the voltage applied to the power supply side is kept constant, thereby generating an abnormal voltage. This prevents malfunction of the photocoupler and circuit breakage.

Similarly, the load side photocoupler 210b has a resistor acting as a pull-up resistor in series between the load-side end of the power supply and a diode to maintain a constant input signal level, thereby providing a resistor serving as a pull-up resistor. Through this, the voltage applied to the diode at the load-side terminal is kept constant to prevent malfunction of the photocoupler and circuit breakdown.

Signals are output through emitter terminals and collector terminals of the transistors of the power supply side and the load side photocouplers 210a and 210b of the circuit breaker 210, respectively, and are controlled through the detection terminal 220a of the data detector 220. It is configured to be transmitted to the communication unit 240 through the microprocessor 220d via the digital input / output unit 220c after being input to the digital conversion 220b.

7 is a diagram illustrating a data state of a power circuit of a circuit breaker according to an exemplary embodiment of the present invention. In FIG. Data relating to the case where the output terminal of the transistor is set as the connector terminal.

In other words, the figure shows the data received remotely while being analyzed after being output through the communication unit 240 when a signal is output through the connector terminals of the transistors of the power supply side and the load side photocouplers 210a and 210b. .

First, when the power is normally supplied to the circuit breaker of the distribution panel or the distribution panel, that is, when the power state is high from both the power supply terminal and the load terminal, all of the photocouplers operate to output the output signal from the connector terminal of each transistor. If it detects, all low signal is detected.

For reference, when the output is detected at the connector stage due to the characteristics of the photocoupler, a low signal is output when the photocoupler is on, and a high signal is output when the photocoupler is off.

Therefore, the remote manager can recognize from the data that normal power is supplied to both the load side and the power side.

Next, when the circuit breaker trips and the contact of the circuit breaker is opened, or the wiring state on the load side is bad, or when a forced trip signal is generated, the low signal is output from the power supply side photocoupler 210a. The load side photocoupler 210b has a high signal.

Therefore, the remote manager can recognize that the circuit breaker trips through the data and that the contact is open or there is a bad wiring on the load side.

Next, when the power supply is interrupted by the circuit breaker such as when the main circuit breaker 260 of the distribution panel is operated or when the entire wiring supply line is defective, power is not supplied to both the power supply side and the load side of the circuit breaker.

In this case, a high signal is output from the power supply side photocoupler 210a, and a high signal is also output from the load side photocoupler 210b.

Therefore, the remote manager may recognize that the contact is open or the overall wiring state of the distribution panel is defective as the main circuit breaker 260 of the distribution panel is tripped through the data.

However, in view of the characteristics of the photocoupler, preferably, the output terminal of the transistors configured in the photocouplers 210a and 210b on the power supply side and the load side is selected as an emitter terminal, and a high signal is output when power is supplied to the power supply side and the load side. Configuring to output a low signal when there is no power will allow the remote administrator to easily visualize the power status of the distribution panel or switchboard.

In addition, the digital input / output unit 220c receives the remote signal received from the remote power server 400 of the management server 400 and converts the forced trip signal into an analog signal at the control unit 220b to form a circuit breaker 5. By outputting through the burnt pin terminal, by generating a current through the image transformer 200 generates an unbalanced state of the vector sum of the current passing through the image transformer 200 to apply a voltage to the trip coil (not shown) of the circuit breaker It will open the contact of.

The communication unit 240 receives data from a serial interface 240a for transmitting and receiving data to and from the data detection unit 220 in both directions, a network adapter controller 240b for connecting a network to the local server, and an external sensor device. The RF receiver 240c and the main controller 240d for converting the received data into serial data or Ethernet data are included.

In more detail, the RF receiver 240c receives a digital signal as data wirelessly with external devices that monitor fire and intrusion based on the Zigbee network protocol.

That is, the main controller 240d may change the wireless data received from external devices into a serial data format and send the data to the data detector 220 of the distribution panel, or receive the main information of the distribution panel through serial communication and change it to Ethernet communication. It serves to send to the local server (400).

Hereinafter, the operating state of the electrical safety monitoring system of the present invention will be described in more detail.

8 is a diagram showing data including an electric fire prediction index measured by an electric fire prediction unit in a management server according to the present invention.

In the electric safety monitoring system of the present invention, if local servers 300 are installed in management offices of markets (for example, 200 to 300 stores) nationwide, data such as switchboards, trunk lines, and distribution boards of the markets are stored in local servers ( It is transmitted to the management server 500 through 300 to monitor and manage the electrical safety.

Electricity which is transmitted from the regional distribution panel 200 and the distribution panel 100 and analyzes the data stored in the local server 300 to predict the electrical fire precursor signal in advance through the fuzzy reasoning technique in the electrical fire prediction unit 400 The fire prediction index is generated and stored in the local server 300, and the stored electric fire prediction index data is transmitted to the management server 500.

As shown, the electric fire prediction index generated by the electric fire prediction unit 400 is shown on the monitoring screen of the management server 500 for managing the status of the distribution panel for each region.

9 is a view showing an operating state operating in conjunction with a web application and an electrical safety map application embedded in the monitoring server according to the present invention, Figure 10 is a management server according to the present invention for monitoring the status of the distribution panel by region This is a displayed diagram.

FIG. 11 is a diagram illustrating a state of distribution boards for each region by establishing an electric safety map in a management server according to the present invention, and FIG. 12 is a diagram illustrating a timer alarm function of a web application embedded in a monitoring server according to the present invention.

Referring to FIG. 5, the monitoring server 520 includes a web application for monitoring and managing distribution panels and switchboards for each region on the web, and the web application also includes an electrical safety map application combined with a geographic information system embedded in the monitoring server. It manages the status of distribution panels and switchboards by region on the web.

Maps for each region are displayed on the web operated by the management server 500. When the electrical safety monitoring system according to the present invention is installed in the national market, for example, the headquarters of Korea Electrical Safety Corporation wants to monitor the electrical safety of the 000 market in Daejeon. When the map of the area is displayed, you can step into the market and mall of the area.

Monitoring of the management server 500 is configured to provide the status of the distribution panel and switchboard for each region as a visual alarm through the electrical safety map through the electrical safety map application interlocked with the web application, the monitoring server access request to the web According to the authentication information to the configured through the electrical safety map application is configured to provide a predetermined authority-specific electrical safety map.

The management server 500 stores data such as distribution boards, and the web page displays the data of the transmitted management server 500. At this time, one part of the web page is composed of an electronic map to display a map, and a map. When the electrical safety map application requests geographic information of a shopping mall that has a problem in a web application, the web application sends data to the electrical safety map application to display the area and information of the shopping mall that has a problem on a web page. It is a structure made.

Alarm area display indicates the alarm area of the market where the electric safety problem occurred when the electric safety monitoring system was installed in the markets of the whole country. For example, if an error occurs in the 000 store in Guro market in Guro-gu, Seoul Will display a map of.

The web application of the monitoring server has a built-in timer alarm function to receive a notification message to the monitoring server 520 about the status of distribution boards and switchboards for each region while the time timer is operating. It is configured to be displayed.

That is, the alarm message is configured to be displayed as an alarm highlight on the electric safety map on the web operated by the management server through a notification message received in real time from the rocker server during a predetermined time during which the time timer operates.

In other words, the timer alarm function is to send a notification message to the monitoring server 520 when an abnormality such as an arc occurs in the distribution panel while the time timer is operating in the monitoring server 520 and the alarm appears on the screen. This alarm is displayed as an alarm highlight on the electrical safety map, which requests the time for the notification message.

In addition, the timer alarm function of the web application is configured to repeatedly display the state of the switchgear and switchboard for each region, including a refreshing function of the electric safety map showing the state of the distribution panel and switchboard for each region as the alarm highlight at regular intervals.

13 is an operational state diagram of the SMS server of the management server according to the present invention. As shown, when a problem occurs in the area displayed on the electrical safety map, the monitoring server 520 is configured to send a notification message to the local administrator terminal by requesting the SMS server 540, as described above As described above, the remote power server 560 manages power while grasping a distribution board having an abnormal indication based on the data transmitted to the monitoring server, forcibly tripping the circuit breaker of the distribution board.

In order for the SMS server 540 to track the location of the corresponding local manager terminal, the management server 500 has a GIS server 570 or an FMS server so as to determine in real time the location of the manager terminal equipped with a GIS or FMS system. 580 may be further constructed.

At this time, the corresponding area administrator terminal is configured to receive a preset electric safety map for each authority through the electric safety map application according to the predetermined authentication information of the administrator terminal requesting access when accessing the management server.

The monitoring server may have a built-in wiring diagram of the electrical equipment of the distribution panel and the distribution panel for each region supporting the electrical safety map application.

14 is a view showing the state of the switchboard by establishing an electrical safety map in the management server according to the present invention by establishing a disconnection diagram, and FIG. 15 to FIG. Drawing.

Referring to the figure, the disconnection diagram is configured to show the disconnection connection data configured in more detail by region and by mall for the regional distribution boards.

In the detailed description of the present invention, specific embodiments have been described. However, it will be apparent to those skilled in the art that various modifications can be made without departing from the scope of the present invention.

1 shows a three-phase wiring breaker equipped with a micro switch for detecting a power supply state installed in a conventional distribution panel.

2 is an overall configuration diagram schematically illustrating the electrical safety monitoring system according to the present invention.

3 is a block diagram of a distribution panel installed in a market or a mall for each region according to the present invention.

4 is an internal block diagram of a distribution panel installed in a market or a shopping mall for each region according to the present invention.

5 is a block diagram of detecting and managing a power supply state through a circuit breaker built in a distribution panel installed in a market or a shopping mall for each region according to the present invention.

6 is an operation block diagram of a communication unit of a distribution panel installed in a market or a mall for each region according to the present invention.

7 is a diagram illustrating a data state of a power supply of a circuit breaker according to the present invention.

8 is a diagram showing data including an electric fire prediction index measured by an electric fire prediction unit in a management server according to the present invention.

9 is a view showing an operating state operating in conjunction with a web application and an electrical safety map application embedded in the monitoring server according to the present invention.

10 is a view showing the state of the distribution panel by region by building an electrical safety map in the management server according to the present invention.

FIG. 11 is a diagram illustrating an electrical safety map in a management server according to the present invention, which displays the state of the switchboard by establishing a disconnection diagram.

12 is a view showing a timer alarm function of the web application embedded in the monitoring server according to the present invention.

FIG. 13 is a view showing data for monitoring the status of distribution panels for each region in the management server according to the present invention.

14 is an operation state diagram of the SMS server of the management server according to the present invention.

15 to 17 are views showing the operation state of the electric safety map application according to the present invention.

* Description of Symbols for Major Parts of Drawings *

100: switchboard 200: switchboard

210: circuit breaker 210a: power supply side photocoupler

210b: load side photocoupler 210c: signal output terminal

220: data detector 220a: detection terminal

220b: control unit 220c: digital input / output

220d: microprocessor 230: arc detector

240: communication unit 250: display unit

260: SMPS part

300: local server by region 400: electric fire prediction unit

500: management server 520: monitoring server

540: SMS server 560: remote power server

570: GIS server 580: FMS server

Claims (13)

In the electrical safety monitoring system that manages the status of the distribution panel and distribution panel installed by region, A local server connected to the switchboard and the switchboard by a network to receive and store data detected by the switchboard and the switchboard; An electric fire prediction unit connected to a network with the local server and analyzing the data received by the local server through a fuzzy inference technique to generate an electric fire prediction index and to store it in the local server; A management server connected to a network with the local server and receiving data stored in the local server in real time and managing data through a web; And The trunk line protection unit for detecting the input-output difference value of the current through the current sensor in the trunk line from the switchgear to the distribution panel and transmits the input and output difference value to the local server through a network; Electrical safety monitoring system that manages the status of distribution panels and switchboards. The method of claim 1, wherein the distribution panel, A data detector for detecting, digitizing and analyzing electrical safety related data through a circuit breaker built in the distribution panel; An arc detection unit for comparing the current and voltage data of the distribution panel with a predetermined reference voltage and reference current data to determine whether a dangerous arc is detected and to transmit data to the data detection unit; A communication unit which receives the data analyzed by the data detection unit through a serial interface and transmits the data to the local server through a network; And Electrical safety monitoring to manage the status of the distribution panel and switchboards provided for each region, characterized in that it comprises a; display unit for receiving and displaying the data detected by the data detection unit and the data received through the arc detection unit in the short-range communication; system. 3. The method of claim 2, The circuit breaker is connected to the power supply terminal of the circuit breaker and receives a power supply from the power supply side and emits light and a power supply photocoupler for receiving a signal output from the terminal of the transistor that is conducting when the diode emits light to detect the power supply state on the power supply side A load side photocoupler and a power side connected to a load-side terminal of the circuit breaker and receiving a power from the load side to receive a signal and a signal output from a terminal of a transistor that is turned on when the diode emits light to sense a power state of the load side and the power side It includes a signal output terminal for transmitting the signal of the overload photocoupler, The data detector includes a detection terminal configured to receive signals from the power supply side and the load side photocoupler in order to determine a power supply state through the circuit breaker. Safety Surveillance System. The method of claim 2, wherein the communication unit, A serial interface for transmitting and receiving data to and from the data detector in both directions; An Ethernet controller for connecting a network to the local server; RF receiving unit for receiving data from an external sensor device; And An electrical safety monitoring system for managing the status of the distribution panel and switchboard installed in each region comprising a; a main controller for converting the received data into serial data or Ethernet data. The method of claim 1, wherein the management server, A monitoring server receiving and storing data of distribution panels and switchboards for each region from the local server, and displaying the status of distribution panels and switchboards for each region on the web through an embedded web application based on the stored data; An SMS server for transmitting an SMS to an administrator terminal through a network based on the data transmitted to the monitoring server; And Manage the status of the distribution panel and switchboard installed in each region, characterized in that it comprises a; a remote power server to remotely manage the power of the distribution panel by identifying the distribution board that has an abnormal indication based on the data transmitted to the monitoring server Electrical safety monitoring system. The method of claim 5, The monitoring server has a built-in electrical safety map application combined with a geographic information system is integrated with the web application, the distribution panel installed by region, characterized in that configured to provide a visual alarm through the electrical safety map of the distribution panel and switchboard for each region Electrical safety monitoring system that manages the status of electrical and switchgear. The method of claim 6, The web application of the monitoring server has a built-in timer alarm function to receive a notification message to the monitoring server about the status of distribution boards and switchboards for each region while the time timer is operating, and configured to display alarm highlights on the electrical safety map on the web. Electrical safety monitoring system for managing the status of the distribution panel and switchboard installed by region, characterized in that. The method of claim 7, wherein The timer alarm function of the web application is configured to repeatedly display the state of the switchgear and switchgear by region at regular intervals, including a refreshing function of the electric safety map showing the state of the switchgear and switchgear by the alarm highlights at regular intervals. Electrical safety monitoring system that manages the status of distribution panels and switchboards equipped with The method of claim 6, When a problem occurs in the area displayed on the electrical safety map, the monitoring server to manage the status of the distribution panel and switchgear equipped for each region, characterized in that configured to send a notification message to the local administrator terminal by requesting the SMS server Electrical safety monitoring system. The method of claim 9, In order for the SMS server to track the location of the local administrator terminal, the management server has a GIS or FMS server further configured to determine the location of the administrator terminal equipped with a GIS or FMS system in real time Electrical safety monitoring system that manages the condition of installed distribution panel and distribution panel. The method of claim 6, The monitoring server is an electrical safety monitoring system for managing the status of the distribution panel and switchboards installed by region, characterized in that the electrical wiring breakdown diagram of the regional switchgear and distribution board supporting the electrical safety map application. The method of claim 6, The monitoring server is an electrical safety monitoring to manage the status of the distribution panel and switchboards installed by region, characterized in that for providing the electric safety map for each predetermined authority through the electrical safety map application according to the authentication information requesting access to the web. system. delete

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