KR101379223B1 - Door locking system having a function of enhance a safety of operator in electric power equipments - Google Patents

Abstract

The present invention discloses a door locking system having a safety reinforcement function capable of securing entrance safety to a power device.
According to an embodiment of the present invention, a door locking system includes a door locking system and a door locking system for a power device including a housing having a predetermined shape having a door, comprising: a fire monitoring camera for fire monitoring; A thermal imaging camera for monitoring a heating state of each component; A flash surveillance camera for comparing an image before and after work to detect and warn when a work tool or article is placed after a worker's entrance and exit; And a control device for locking and controlling the locking device when a risk factor in the power device is recognized from the signals detected by the respective cameras.
Therefore, the present invention monitors the internal state of power equipment such as GIS (Gas Insulated Switchgear), switchgear, distribution board and the like in real time, due to problems in the power equipment such as electric shock, explosion due to fire, leakage If the operator's safety is not secured, the door is closed, or if an unidentified object is not placed inside the power equipment, it is regarded as a risk factor and the door of the power equipment is locked and the door is locked under the administrator's certification. By releasing, it has the effect of ensuring the safety of the worker.

Description

DOOR LOCKING SYSTEM HAVING A FUNCTION OF ENHANCE A SAFETY OF OPERATOR IN ELECTRIC POWER EQUIPMENTS}

The present invention relates to a door locking system of a power device, and more particularly, to monitor the internal state of a power device such as a gas insulated switchgear (GIS), a switchgear, a switchgear, and the like in real time. The present invention relates to a door locking system having a safety reinforcement function of a power device operator that can enhance the safety of an operator by closing a door when the operator cannot secure safety due to an internal problem such as an electric shock or explosion.

In general, the switchgear is a structure for opening and closing the converter or controlling the device by arranging an instrument, an indicator light, a relay, an operation switch, and the like, and is installed in a building, a power plant, a substation having an electric facility, and the like. For example, a closed switchgear is usually divided into a low voltage part and a high voltage part, and the high voltage part is composed of a breaker section automatic breaker, a vacuum circuit breaker, an arrester, an instrument transformer, a high voltage fuse, a transformer, and the like. Equipped with measuring instruments, earth leakage breakers, wiring breakers, current transformers, and terminal blocks.

In addition, the conventional switchgear is equipped with a technology for monitoring the charging voltage by the voltage detector (VOLTAGE DETECTOR) as a method for detecting the charging voltage of the power supply main circuit. However, the prior art as described above has a drawback that a safety accident is likely to occur due to the charging current of the main circuit even when the power source is not completely cut off or the power is cut off when the operator opens the door for inspection and repair of the switchgear. have.

The attached patent document provides a method for performing safety certification of the above-described door system, which will be described in detail with reference to the accompanying drawings.

First, Figure 1 is a block diagram showing a door stability authentication system of the conventional switchgear. As illustrated, the switchboard 100 includes a sensor unit 110 including various types of sensors such as an overcurrent sensor 111, a temperature sensor 112, a humidity sensor 113, a distance sensor 114, and the like. Amplification and filtering (low pass filter) the measured value measured from the unit 110 at a predetermined ratio, and converts the analog measurement value to a digital value 120 and through a wired / wireless network Lock / unlock the network interface unit 131 connected to the management server 200, the wireless interface unit 132 connected to the inspection terminal 400 through a wireless network (wireless communication network), and the door of the switchboard 100. The lock device 140, the touch panel 150 provided on the front of the switchboard 100, the address information of the management server 200, the address information of the expert terminal 300, and the identification of the switchboard 100. A storage unit 160 for storing information and the like, and a history when a problem occurs or periodically When the history message including the information is transmitted to the management server 200 and safety authentication is requested through the touch panel 150, the touch panel 150 displays the warning information according to the internal state detected by the sensor unit 110. It includes a control unit 170 for outputting through.

If the switchboard 100 is driven, the control unit 170 prevents the door opening for malicious purpose by maintaining the door in the automatic lock state through the locking device 140. When the lock release signal is received from the inspection terminal 400, the controller 170 releases the lock state of the locking device 140 so that the inspector can open the door.

In this case, when a problem is detected through a safety authentication procedure, the controller 170 may prevent the lock state from being released even when a lock release signal is received from the inspection terminal 140. prevent. That is, the controller 170 maintains the automatic locking state through the locking device 140 so that only the inspector and the expert who transmits the unlocking signal while preventing the public from opening the door can open the door.

In addition, when a problem occurs in the switchboard 100, the control unit 170 may maintain the lock even when a lock release signal is received. To prevent any safety accidents.

The overcurrent sensor 111 of the sensor unit 110 detects a current flowing in a metal component such as a housing and wiring due to problems such as deterioration of electrical components of the switchboard 100, and the temperature sensor 112 and the humidity sensor ( 113) is installed inside one or more to measure the internal temperature value and humidity value. The distance sensor 114 detects a movement within a predetermined range, that is, a human body movement within a predetermined range.

After amplifying the measured value measured by the sensor unit 110 of the converter 120 at a predetermined rate, the filter is filtered through a low pass filter, and the controller 170 recognizes the analog measured value by converting it digitally. To help. On the other hand, in the warning mode, the control unit 170, when a problem occurs when the distance sensor 115 detects a movement within a certain distance, and outputs a warning sound or a warning message (warning) to prevent a safety accident, for example, to access the public When a mode change signal is received, the system is switched to the management mode so that an alarm or warning message is not output even if the inspector approaches within a certain distance, so that the internal state can be checked after the administrator has processed the safety certification procedure. To help.

When the inspector selects the start of safety authentication through the touch panel 150, the controller 170 outputs warning information based on a temperature value, a humidity value, a current value, and the like detected by the sensor unit 110. Therefore, before the inspector of the switchgear approaches and opens the door, the safety authentication procedure is performed through the touch panel, and if the safety state is secured, the door can be opened to secure safety.

However, the door safety certification system of the conventional switchgear performs the safety certification of the door of the switchgear from the current leakage, the overcurrent, the temperature, the humidity, the motion sensor of the switchgear, and the door is opened and closed only when a risk factor is generated. In other words, there is a problem that can not be detected in advance for the actual risk factors. For example, if the administrator has left any objects (drivers, spanners, etc.) in the switchgear, even though there is a risk of fire due to conductive objects, there is a problem that the detection of the door is not possible and the stability of the door opening and closing is impaired. Done.

1. Republic of Korea Patent Publication 10-2011-0138560, published date December 28, 2011, the name of the invention 'door safety certification system and method of the switchgear'.

The present invention was created to solve the above problems, and an object of the present invention is to monitor the internal state of power equipment such as a gas insulated switchgear (GIS), a switchgear, a switchgear, and the like in real time to prevent fire and leakage. It is to provide a door locking system having a safety function of the power equipment operator that can enhance the safety of the operator by closing the door when the operator cannot secure the safety due to problems inside the power equipment such as an electric shock or explosion caused by. .

Another object of the present invention, when an unidentified object not registered in the power device is placed, it is regarded as a risk factor to keep the door of the power device in a locked state, by unlocking the door lock under the administrator's authentication, It is to provide a door locking system having a safety enhancement function of the power equipment operator to ensure the safety of.

It is still another object of the present invention that a controller provided in one panel for accommodating a power device is configured to control the internal condition monitoring and door opening and closing of a peripheral panel, thereby performing network based door opening and closing, An object of the present invention is to provide a door locking system having a safety enhancement function for a power equipment operator capable of reducing equipment costs.

According to an aspect of the present invention, there is provided a door locking system having a safety reinforcing function for a power equipment operator, the door locking system including a door lock device and a predetermined shape of a housing provided with a door. Fire surveillance cameras for fire surveillance; A thermal imaging camera for monitoring a heating state of each component; A flash surveillance camera for comparing an image before and after work to detect and warn when a work tool or article is placed after a worker's entrance and exit; And a control device for locking and controlling the locking device when a risk factor in the power device is recognized from the signals detected by the respective cameras.

On the other hand, the control device according to an embodiment of the present invention, the driver for converting the video signal detected from the fire surveillance camera, thermal imaging camera and flash surveillance camera to a prescribed rated signal and outputs; And a driver connected with the driver to recognize a fire occurrence in the power device from the video signal of the fire surveillance camera, or to recognize a heating state of components in the power device from the video signal of the thermal imaging camera, or to a video signal of the flash surveillance camera. When it is recognized whether any object in the power device is placed or left, characterized in that it is configured as a controller for instructing the locking of the door to the locking device.

The door locking system having a safety reinforcement function of the power equipment operator proposed by the present invention monitors the internal state of power equipment such as a gas insulated switchgear (GIS), a switchgear panel, a distribution panel, and the like, and causes fire and leakage. If the operator's safety cannot be secured due to a problem inside the power equipment such as electric shock or explosion caused by an electric shock or explosion, if the door is closed or an unidentified object not registered inside the power equipment is regarded as a risk factor, By keeping the door in the locked state and releasing the door locking under the administrator's authentication, the safety of the operator can be secured.

1 is a block diagram showing a door authentication system of a conventional switchgear.
2 is a view for explaining a power device according to the present invention.
3 is a configuration diagram illustrating the control device of FIG. 2.
4 is a reference picture for explaining the operation principle of the flash surveillance camera according to the present invention.

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

2 is a configuration diagram illustrating a door lock system of a power device according to the present invention. The illustrated power device may include a gas insulated switchgear (GIS), a switchgear, a switchgear, and the like. However, in the present embodiment, a switchgear is exemplified and will be collectively referred to as a power device in the following description. In addition, the enclosure in which the power equipment is housed is defined as a panel.

The power device includes a housing 201 having a predetermined shape including a door locking device 211 and a door 207, and a circuit breaker 203 and a ground switch may be formed inside the housing 201 for accommodating the power device. Power components such as 205 are provided. Accordingly, in the present invention, the fire monitoring camera 225 for fire monitoring inside the enclosure 201, the thermal imaging camera 229 for monitoring the heating state of each component, and the work tool or article after the worker's entry and exit are placed. If necessary, in order to detect and warn the flash monitoring camera 227 for comparing the image of the state before and after the operation, and the risk factors in the power device from the signals detected from each camera, and the locking device according to the determination result Control device 213 for locking and unlocking (211).

Here, it is obvious that the control device 213 can be interlocked with the leakage current detector 221 and the temperature detector 223 for detecting the amount of current flowing through the breaker 203 or the ground switch 205 to determine whether there is an overcurrent. something to do.

On the other hand, the control device 213 may include an authentication system, such as password input, fingerprint recognition or iris recognition for separate authentication when the operator or administrator enters and exits. In addition, the control device 213 may further include a communication system for talking to an external manager, which is to allow the worker's access to be approved from the external manager when a risk factor in the power device is found.

The fire monitoring camera 225 is for monitoring the fire state in the power device, consisting of CCTV and can be always monitored by an external manager through a communication network. In addition, the thermal imaging camera is a thermal infrared camera, it is possible to detect the infrared radiation emitted by the heat generated when the heat generated in the components in the power device, or to take a dark space in the power device in real time.

The flash monitoring camera 227 is for capturing the interior of the power device when the operator or the manager enters the power device. The flash monitoring camera 227 compares the photographed flash image information with the state before and after the entrance and exit. This is to determine whether the worker or the manager has left the power device in a state where the goods are placed. That is, if any object is left in the power device, it may cause a fire due to high voltage, and the flash monitoring camera 227 detects such a hazard and notifies the control device 213.

3 is a configuration diagram for explaining the main functions of the control device according to the present invention.

As shown, a driver 309 for converting the video signal detected from the fire surveillance camera 225, the thermal imaging camera 229 and the flash surveillance camera 227 to a prescribed rated signal and outputs it; 309, the fire signal in the power device is recognized from the video signal of the fire surveillance camera 225, or the heating state of the components in the power device is recognized from the video signal of the thermal imaging camera 229, or The controller 301 instructs the locking device 211 to lock the door when recognizing that any object in the power device is placed or left unattended from the video signal of the flash monitoring camera 227.

In addition, the controller 301 includes a display unit 303 for notifying or warning a dangerous factor detected from each camera to an operator scheduled to enter or exit the screen, and after notifying the dangerous factor to an external manager terminal, It includes a communication module 305 for receiving the door release approval information from the administrator terminal.

In addition, the controller 301 is interlocked with the access authentication module 307 for access approval in the power device, the access authentication module 307 is coupled to any one or more of a password input function, fingerprint recognition function, iris recognition function. May include functionality.

Meanwhile, the driver 309 converts the signals detected from the leakage current detector 221 and the temperature detector 223 into digital signals and provides them to the controller 301, and the controller 301 is detected from each detector. The opening or releasing of the locking device 211 is approved based on the result information.

As such, the control device 213 proposed in the present invention locks the door of the power device when any one or more risk factors are detected from the image information detected from each camera and the power device state information detected from each detector. The safety of workers or managers is secured first.

When a risk factor is detected in the power device, the door is opened with the approval of an external manager. This is because an accident occurs when the accessor of the power equipment does not clearly recognize the situation inside the power equipment. Therefore, when a risk factor is detected, an outside manager grasps the situation inside the power equipment and opens the door of the power equipment. Prevent accidents beforehand.

Here, the door opening of one panel for accommodating a power device is controlled from the controller 301 mounted to the door, but in another embodiment of the present invention, any one controller is interlocked with the controller of another panel in proximity to Will be able to control the door opening and closing.

Substantially, since the controller 301 proposed in the present invention controls the opening and closing of the door based on various signal processing, the economic burden on the operation management including the facilities of the controller 301 is increased. Therefore, one panel is defined as the main panel, and the controller 301 of the control device 213 installed in the main panel performs communication with other panels in close proximity, thereby enabling door opening / closing control of other panels. Here, the controller of the other panel receives a signal from various cameras or detectors of the other panel, and transmits the signal to the controller of the main panel, the controller of the main panel recognizes the internal situation of the panel, and controls the opening and closing of the door of the panel. do.

Accordingly, the controller of the other panel includes a communication module for performing communication with the controller of the main panel, and includes only an access authentication module for access authentication of an operator or an administrator, thereby increasing the ease of system equipment design.

Hereinafter, the operation of the present invention will be described.

First, the leakage current detector 221 is a CT element, the temperature detector 223 may be assumed to be a temperature sensor. The temperature detector 223 is mounted on a part outside the photographing range of the thermal imaging camera 229 or on a specific part having a high risk of heat generation. Therefore, the driver 309 converts the signals detected by the leakage current detector 221 and the temperature detector 223 into digital signals and provides them to the controller 301.

The controller 301 determines whether a leakage current in the power device occurs or a temperature rises in any component, and the result is notified to an external manager terminal through the communication module 305. At the same time, the controller 301 instructs the locking device 211 to lock the door when a leakage current occurs or heat generation occurs in an arbitrary component. In addition, the display unit 303 warns an operator or a manager by displaying the current situation of the power device as textual information.

Meanwhile, the driver 309 receives the detection result of each detector and receives image information from the fire monitoring camera 225 and the thermal imaging camera 229 and provides the image information to the controller 301. Accordingly, the controller 301 may recognize whether a fire in the power device has occurred from the captured image of the fire monitoring camera 225, and recognizes whether a component in the power device is generating heat from the thermal imaging camera 229. .

Image information provided from each camera is provided to the external manager terminal in real time through the communication module 305, and the external manager terminal monitors the captured image of each camera at a spaced position. The controller 301 recognizes a fire occurrence or a heat generation state of components in the power device based on the images photographed from each camera, and the result is provided through the display unit 303.

If the controller 301 recognizes that a fire has occurred in the power device or detects a heat generation condition exceeding a reference value in any component, the controller 301 notifies the external manager terminal and controls to lock the door.

When a worker or a manager wants to enter the power device through the access authentication module 307 in a state where a risk factor is found as described above, the controller 301 maintains the locked state of the door regardless of the access authentication procedure. That is, the controller 301 provides a predetermined guide message to the person who has been approved by the access authentication module 307, and then requests the access approval from the external manager terminal through the communication module 305.

Accordingly, after the external manager terminal establishes a communication channel with the accessor, the external manager terminal sufficiently transmits the situation inside the power device, and thus access approval is made. The external manager terminal provides the approval information for access approval to the controller 301, and the controller 301 releases the locked state of the door.

Meanwhile, the controller 301 determines whether a risk factor exists in the power device based on the image signal detected from the flash monitoring camera 227. This is the same as when the risk is recognized in each camera and detector, the door locking control is performed, the operation of the flash monitoring camera 227 is based on the entry of the person through the access authentication module 307.

That is, the controller 301 stores the flash image photographed by the flash surveillance camera 227 in the internal memory, and after the person is generated, the flash surveillance camera 227 is photographed and compared with the previously stored flash image. Be aware of the change. Here, the change of the image is a state in which the state before the worker or the manager enters and exits the state after the entry and exit is changed, and indicates a state where the work tool or any object is left unattended.

This is because, as shown in Figure 4, in the process of monitoring any part in the power device, by comparing the flash picture information of the state before and after the worker's entry and exit, the flash picture information of the state after the entry and exit of the operator, whether any object is placed Judge. The image captured by the flash surveillance camera 227 is divided into cells, and is prepared for each cell for photo information before and after the worker's entrance and exit.

In this process, the controller 301 detects all cells having different data by comparing photo information, that is, flash image data, in units of cells. In addition, the controller 301 determines the ratio of the changed cells, and when an image change rate of 5% or more is generated, the controller 301 determines that an arbitrary object is placed.

As such, when the controller 301 recognizes that an operator or an administrator who enters or exits through the access authentication module 307 is present, the controller 301 receives a flash image photographed from the flash monitoring camera 227 after the entrance and exit. To compare with the flash image. From the comparison result, it is determined whether any object is left inside the power device.

As a result of the determination by the controller 301, if it is recognized that an arbitrary object is left inside the power device, the controller does not permit entry of a subsequent person, and notifies the external manager terminal of the entry. Therefore, when a worker or a manager wants to enter and exit the power device, the outside manager imprints a risk factor on the person who passes the access, and the access is made. Accordingly, the controller 301 releases the door locking after receiving the approval information according to the access permission from the external manager terminal.

On the other hand, the controller 301 controls the opening and closing of the door provided in one panel, but when a plurality of panels are grouped as described above, the controller mounted on one main panel is linked with the controller of the other panel The door opening and closing of another panel can be controlled.

That is, one panel includes a monitoring device such as a plurality of cameras and a detector, and the monitoring device is connected to a controller which is a control device mounted on the door of the panel, and the controller controls the opening and closing of the door from the monitoring result of the monitoring device. . Thus, the controller of the main panel defined as the one panel is to communicate with the controller of the other panel to control the doors of other panels installed in the periphery.

Therefore, the controller provided in the other panel is provided with an access authentication module, transmits the access authentication information and the status monitoring results of the panel to the controller of the main panel, the door of each panel based on the door opening and closing approval information from the controller of the main panel Is controlled. This significantly reduces the equipment cost of a power monitoring system with multiple panels and increases system stability by integrating system operation.

201: enclosure 203: breaker
205: grounding switch 207: door
211: locking device 213: control device
221: leakage current detector 223: temperature detector
225: fire surveillance camera 227: flash surveillance camera
229: thermal imaging camera 301: controller
303: display unit 305: communication module
307: access authentication module 309: driver

Claims (5)

In the door locking system of a power device provided with a door and a door locking device for access control of the panel,
Fire surveillance cameras for fire surveillance;
A thermal imaging camera for monitoring a heating state of each component;
A flash surveillance camera for comparing an image before and after work to detect and warn when a work tool or article is placed after a worker's entrance and exit; And
And a control device for locking and controlling the locking device when a risk factor in the power device is recognized from the signals detected by the respective cameras.
The control device includes:
A driver for converting and outputting a video signal detected from the fire surveillance camera, the thermal imaging camera, and the flash surveillance camera into a prescribed rated signal; And
Connected to the driver, and recognizes the occurrence of a fire in the power device from the video signal of the fire monitoring camera, the heat state of the components in the power device from the video signal of the thermal imaging camera, or from the video signal of the flash surveillance camera When it is recognized whether any object in the power device is placed or left, it is made of a controller instructing the locking device to lock the door,
The controller is interlocked with the access authentication module for a separate authentication when the operator or the administrator of the access, and interlocks with the communication module for the call with the external manager;
The driver is connected with a leakage current detector and a temperature detector for detecting an amount of current for a component in the power device to determine whether there is an overcurrent;
The controller is a door locking system having a safety function of the operator of the power equipment, characterized in that when the risk is found in the power device or when an abnormal signal is detected from each detector is allowed to enter or exit the operator. delete delete According to claim 1, The access authentication module,
A door locking system with a safety enhancement function for a power equipment operator, characterized in that it is implemented from any one of password input, fingerprint recognition, or iris recognition. The method according to claim 1 or 4,
The control device is a door locking system having a safety strengthening function of the power device operator, characterized in that for opening and closing the door of the other panel based on communication with other panels in close proximity.

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