KR102519550B1 - Fire monitoring and self-diagnosis service - Google Patents

Abstract

The present invention relates to a system monitoring the interior of an enclosure for electrical equipment such as switchboards in real-time and conducting self-diagnosis at preset intervals to quickly and accurately detect the precursor symptoms of fire and the performance degradation of a monitoring device. The system comprises: a fire monitoring unit including a sensor unit consisting of one or more detection sensors installed in the enclosure for electrical equipment such as the switchboards and a filming unit consisting of one or more cameras and configured to transmit a detection value generated by the sensor unit and image information generated by the filming unit to a management server; a simulation device unit including a plurality of test devices virtually implementing a fire situation or a warning situation according to a control signal; and the management server configured to analyze the possibility of fire occurrence by receiving the detection value and image information transmitted from the fire monitoring unit, stage the results of the analysis according to a preset standard, generate a notification signal according to the results, and transmit the same to a designated external device, configured to generate the control signal at the preset intervals and transmit the same to the simulation device unit, and configured to perform self-diagnosis by analyzing the received detection value and image information based on the transmitted control signal.

Description

Fire monitoring and self-diagnosis service {Fire monitoring and self-diagnosis service}

The present invention relates to a fire monitoring and self-diagnosis system for an enclosure for electrical equipment, and more particularly, by monitoring the inside of an enclosure for electrical equipment such as a switchboard in real time and performing self-diagnosis at predetermined intervals to prevent a fire It relates to a system capable of quickly and accurately detecting the precursor symptoms of the occurrence and the performance degradation of monitoring devices.

In general, various devices and parts such as switches, relays, and instruments are installed inside an enclosure for electrical facilities such as a switchboard, an automatic control panel, and an ESS, and a plurality of wires are wired.

In addition, an earth leakage breaker that operates automatically is installed for safety purposes, but a fire caused by deterioration, heat, or overcurrent can occur at any time due to the environment inside the enclosure for electrical facilities where high-voltage current flows, so separate and regular management is absolutely necessary

However, it is difficult for a manager to individually check the failure of devices and parts, and furthermore, the possibility of a failure, and problems such as management gaps and manager's negligence or negligence may occur at any time.

For the above reasons, several inventions for the purpose of fire monitoring for electrical equipment enclosures such as switchboards have been proposed, and one of them, “Switchboard Fire Management System” in Korean Patent Registration No. It is configured to determine the occurrence of a fire by detecting the temperature, amount of carbon dioxide, and smoke with a sensor module, and is configured to determine the occurrence of a fire with an image taken by a thermal imaging camera, so that even in a situation where a problem occurs in either the sensor module or the camera, it is configured to determine the occurrence of a fire. An invention related to a system for a switchboard enabling accurate determination of occurrence has been proposed.

In addition, in “Fire monitoring and extinguishing system for switchgear with AI function” of Korean Patent Registration No. 10-2232261, which is another one of several inventions for fire monitoring purposes, an image taken inside the switchboard and thermal image information are analyzed and At the same time, an invention related to a system for a switchboard that can accurately detect and extinguish a fire by reflecting the environmental state inside the switchboard to detection and analysis has been proposed.

However, the above-mentioned prior inventions can detect a fire that has already occurred without difficulty, but depending on each detailed configuration, there is a problem in that it is not possible to quickly detect the precursor symptoms of a fire occurring in various forms depending on the cause. It can be.

In addition, problems such as inoperability of sensors or cameras installed inside the enclosure for electrical equipment can be identified relatively quickly, whereas partially occurring problems such as deterioration in sensing performance are difficult to quickly identify, As a result, a problem in which a precursor symptom of a fire cannot be quickly discovered may also occur because the detection performance has deteriorated or a sensor or camera with a partial failure cannot be replaced.

That is, since the above-mentioned problems may occur in not only the above-described prior inventions but also other similar prior inventions, these deficiencies may be supplemented or improved to rapidly reduce the symptoms of fire and the performance degradation of monitoring devices such as sensors and cameras. It is a situation in which a system that can accurately detect and detect is required.

Republic of Korea Patent Registration No. 10-1880864 (2018. 07. 16) Republic of Korea Patent Registration No. 10-2156751 (2020. 09. 10)

Depending on the detailed configuration of each of the above-described prior inventions or other prior inventions, a problem may occur in which the precursor symptoms of fire, which occur in various forms depending on the cause, cannot be quickly detected,

Problems such as inoperability of sensors or cameras installed inside the enclosure for electrical equipment can be identified relatively quickly, whereas problems that occur partially, such as deterioration in sensing performance, are difficult to quickly identify. Therefore, the purpose of the fire monitoring and self-diagnosis system according to the present invention is to provide a solution to this problem.

In order to achieve the above object, the present invention

Fire monitoring configured to include a sensor unit composed of one or more detection sensors and a photographing unit composed of one or more cameras, and configured to transmit detected values generated by the sensor unit and image information generated by the photographing unit to the management server. wealth;

A simulation device unit configured to include a plurality of test devices that virtually implement a fire situation or a foreshadowing situation according to a control signal; and,

The detection value and image information transmitted from the fire monitoring unit are received to analyze the possibility of a fire occurrence, the analysis result is staged according to a predetermined standard, and a notification signal is generated according to the result to a designated external device. A management server configured to transmit, configured to generate a control signal at predetermined intervals and transmit the control signal to the simulation device unit, and configured to perform self-diagnosis by analyzing a detected value and image information received based on the transmitted control signal; Suggests a fire monitoring and self-diagnosis system, characterized in that configured to include.

At this time, the management server is characterized in that it is configured to use artificial intelligence in the process of analyzing the possibility of a fire using the received detection value and image information and performing self-diagnosis.

The fire monitoring and self-diagnosis system according to the present invention,

In addition to using one or more sensors installed inside the enclosure for electrical equipment, by analyzing the images taken by one or more cameras with artificial intelligence, the effect of being able to quickly and accurately detect the precursor symptoms of a fire occurs,

Self-diagnosis is automatically performed at predetermined intervals so that a problem occurring in a sensor or camera installed inside an enclosure for electrical equipment can be immediately resolved.

1 is a basic configuration diagram of a fire monitoring and self-diagnosis system according to the present invention.
2 is a detailed configuration diagram of a fire monitoring unit, which is a main component of the present invention.
Figure 3 is an exemplary view showing a state in which a fire monitoring unit and a simulation device, which are the main components of the present invention, are installed in an enclosure for electrical equipment.
4 is a detailed configuration diagram of a simulation device, which is a main configuration of the present invention.
Figures 5a and 5b is an exemplary view showing a rail and a moving unit that are additional components for moving the position of the simulation device unit.
6a and 6b are explanatory diagrams showing some functions of a management server, which is a main component of the present invention.

The present invention relates to a fire monitoring and self-diagnosis system for an enclosure for electrical equipment,

It is configured to include a sensor unit 110 composed of one or more detection sensors and a photographing unit 120 composed of one or more cameras, and the detected values generated by the sensor unit 110 and the values generated by the photographing unit 120 A fire monitoring unit 100 configured to transmit image information to the management server 300; A simulation device unit 200 configured to include a plurality of test devices that virtually implement a fire situation or a foreshadowing situation according to a control signal; And, receiving the detected value and image information transmitted from the fire monitoring unit 100 to analyze the possibility of a fire occurrence, stage the analysis result according to a predetermined standard, and generate a notification signal according to the result It is configured to transmit to a designated external device, and is configured to generate a control signal at each predetermined period and transmit it to the simulation device unit 200, and analyzes the received detection value and image information based on the transmitted control signal to self a management server 300 configured to perform diagnosis; It is characterized in that it is configured to include.

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

First of all, the fire monitoring unit 100 constituting the present invention, shown in FIG. 1, is an assembly of various devices installed for the purpose of real-time fire monitoring in an enclosure for electrical equipment such as a switchboard, an automatic control panel, and an ESS.

That is, as shown in FIG. 2, the fire monitoring unit 100 includes a sensor unit 110 including one or more detection sensors and a photographing unit 120 including one or more cameras. Characterized in that, it is configured to transmit detected values generated by one or more sensors and image information generated by one or more cameras to an external management server 300, thereby enabling real-time fire monitoring.

Therefore, as shown in FIG. 2, the fire monitoring unit 100 collects and temporarily stores detection values and image information, and the data storage unit 130 stores the detected values as analog signals stored in the data storage unit 130. And a converter 140 for converting image information into a digital signal, and a communication unit 150 for transmitting the detected value and image information converted into digital signals to the management server 300. It performs the function for real-time fire monitoring by being installed inside the enclosure for electrical equipment or installed separately inside and outside.

That is, as shown in FIG. 3, the sensor unit 110 and the photographing unit 120 constituting the fire monitoring unit 100 should be installed inside the enclosure for electrical equipment, but the data storage unit 130 and the converter ( 140), other devices such as the communication unit 150 may be installed inside or outside through external wiring depending on the size of the internal space of the enclosure for electrical equipment, in which case an external case for protection It is preferable that is additionally provided.

At this time, the detection sensor constituting the sensor unit 110 is a temperature detection sensor, an arc detection sensor, a smoke detection sensor, a heat detection sensor, a carbon monoxide detection sensor, or a carbon dioxide detection sensor. It may consist of any one or more of the detection sensors, and is preferably installed on the upper side inside the enclosure for electrical equipment, but may be installed or additionally installed in other locations, such as the center of the enclosure, if necessary.

In addition, if it is suitable for the purpose of fire monitoring or can be used for the purpose of assisting other detection sensors, sensors other than the above sensors may be additionally used.

In addition, one or more cameras constituting the photographing unit 120 may be mixed with a thermal imaging camera and a general camera, and may be divided and installed in multiple locations, including the upper part of the enclosure for electrical equipment.

Therefore, as long as the at least one camera constituting the photographing unit 120 has a small size suitable for installation inside an enclosure for electrical equipment having a relatively narrow internal space, any of various known products may be used, but electrical equipment It is okay to use a custom-made one to suit the environment inside the enclosure.

At this time, the thermal imaging camera constituting the photographing unit 120 always maintains an operating state, but a general camera may be configured to operate at predetermined intervals to photograph the inside of the enclosure for electrical equipment, and the environment inside the enclosure for electrical equipment. Considering this, lighting for shooting is possible or a separate lighting device must be provided.

According to the configurations described above, the fire monitoring unit 100 detects the temperature inside the enclosure for electrical equipment and generates a detection value, a detection value generated by detecting arc generation, a detection value generated by detecting the generation of carbon monoxide, or Any one or more of the detection values generated by detecting the generation of carbon dioxide may be transmitted to the management server 300 along with image information according to the shooting of the image, and when an additional sensor configuration occurs, the corresponding detection values are also transmitted to the management server ( 300).

At this time, as shown in FIG. 3, in conjunction with the configuration of the fire monitoring unit 100, a display device 160 for an enclosure including a touch panel or a simple display screen is provided outside the enclosure for electrical equipment. Information transmitted from the management server 300 is displayed on the display device 160 for the enclosure, and a warning sound is output depending on the situation, so that the surrounding manager etc. You can check it accordingly or make it immediately aware.

However, among the information displayed on the enclosure display device 160, the temperature inside the enclosure for electrical equipment may be configured to be directly transmitted and displayed from the fire monitoring unit 100, but since this is optional, considering various factors, the temperature inside the enclosure may be configured to be displayed. It is desirable that an efficient manner be adopted.

In addition, the simulation device unit 200 constituting the present invention, shown in FIG. 1, is an assembly of several devices installed for the purpose of self-diagnosis in the enclosure for electrical equipment in which the fire monitoring unit 100 is installed. It is characterized in that it is configured to include a plurality of test devices 210 that virtually implement a situation or a precursor situation of a fire.

That is, as shown in FIG. 4, the simulation device unit 200 is a high frequency generator used for high frequency heat generation, an arc generator used for arc generation, an ignition device used for spark generation, or a smoke generator used for smoke generation. It may be configured to include any one or more of the test device 210 and the control unit 220 for controlling the test device 210, and does not place a specific limit on the installation position inside the enclosure for electrical equipment.

Rather, the simulation device unit 200 is preferably installed in various locations inside the enclosure for electrical equipment, but this may cause a problem that causes complexity inside the enclosure for electrical equipment.

Therefore, the simulation device unit 200 can be installed in a form capable of position adjustment along the rail 230 installed inside the door that opens and closes the enclosure for electrical equipment in a modularized state, and the position can be adjusted at predetermined intervals. It is possible to virtually implement a fire situation or a precursor situation of a fire while moving.

That is, the simulation device unit 200 can be modularized to be movable at the same time, and the simulation device unit 200 in a modular state is located on the inner side facing the inside of the enclosure among both sides of the door that opens and closes the enclosure for electrical equipment. ) The straight rail 230 for positional movement may be installed vertically or diagonally.

More specifically, as shown in FIG. 5A, the simulation device 200 is equipped with a rail 230 composed of an I-beam or H-beam with a rack gear formed on one side and a plurality of test devices 210 It may be configured in a form that further includes a moving unit 240 that moves along the rail 230 in the state and changes the position of the device for testing 210 .

And as shown in Figure 5a, the moving unit 240 is a rack gear of the rail 230 in a state installed in the center of the main body 241, the main body 241 to which a plurality of test devices 210 are mounted A pinion gear 242 meshed with, a motor 243 providing power to the pinion gear 242, and a plurality of first rotary wheels 244 slidably inserted into grooves on both sides of the rail 230 at the distal end. The main body ( 241) may be configured in a form including a second frame 247 installed in a symmetrical form with the first frame 245 on the other side.

In addition, as shown in FIG. 5B, the moving part 240 is hinged to the body 241 and is configured to rotate upward or downward, and the distal end is engaged with a part of the pinion gear 242 It is configured in a form that can be configured to further include a fixing part 248 that restricts or allows rotation of the pinion gear 242 by rotating the shaft.

Therefore, in the movable unit 240, the pinion gear 242 is engaged with the rack gear of the rail 230, and the plurality of first rotation wheels 244 and the plurality of second rotation wheels are formed in grooves on both sides of the rail 230. When control by the control unit 220 occurs in a state in which 246 is installed inside, the restraint state of the pinion gear 242 by the fixing unit 248 is released and at the same time, the low speed of the pinion gear 242 by the motor 243 is released. It can move along the rail 230 using rotation.

Conversely, as the pinion gear 242 is restrained by the fixing part 248 and the motor 243 is stopped at the same time, it is possible to maintain a fixed state at a specific position.

According to the configurations described above, the simulation device unit 200 moves the location at predetermined intervals and can virtually implement a fire situation or a precursor situation of a fire outbreak, thereby checking the performance of the fire monitoring unit 100. However, an effect that can improve the learning effect of artificial intelligence in the management server 300 is generated.

In addition, the management server 300 constituting the present invention, shown in FIG. 1, is installed outside the enclosure for electrical equipment in which the fire monitoring unit 100 and the simulation device unit 200 are installed to monitor fire in real time. It is a server device used for the purpose of self-diagnosis and self-diagnosis.

That is, the management server 300 may perform real-time fire monitoring in connection with the fire monitoring unit 100, and may perform self-diagnosis at predetermined intervals in connection with the simulation device unit 200, The results of monitoring and self-diagnosis can be recognized or confirmed by the manager of the facility.

Therefore, the management server 300 should be able to communicate with the fire monitoring unit 100 in both directions, and may be configured to communicate with the simulation device unit 200 in both directions, but through communication with the fire monitoring unit 100, the simulation device unit It is preferable for optimization of the configuration to be configured to be linked with (200).

More specifically, the management server 300 analyzes the possibility of a fire by receiving one or more detection values and image information transmitted from the fire monitoring unit 100, and stages the results of the analysis according to predetermined criteria. And, it is characterized in that it is configured to generate a notification signal according to the result and transmit it to a designated external device.

That is, the management server 300 analyzes one or more detected values and image information to determine the state inside the enclosure for electric equipment, such as a normal state without a risk of fire, a state of caution with a precursor symptom of a fire outbreak, and a deterioration in a precursor symptom of a fire outbreak. It can be divided into an imminent fire state in which a fire outbreak is imminent and a fire outbreak state in which a fire has occurred.

At this time, the management server 300 is configured to use artificial intelligence in the process of analyzing the detected value and image information, so that the detected value and image information are not only compared with pre-stored comparison information, but also the normal environment inside the enclosure for electrical equipment, That is, the size and average temperature of the space inside the enclosure for electrical equipment can be reflected in the analysis of the possibility of fire occurrence.

That is, the management server 300 determines the current possibility of a fire by comparing the received detection value with previously stored comparative storage information, but the change in trend of the detection value can be reflected in the determination of the possibility of a fire occurrence. .

In addition, the management server 300 may determine the current possibility of a fire by directly analyzing thermal image information among received image information, and compare general image information among received image information with previous general image information. In this way, it is possible to determine the current possibility of a fire by capturing the swelling phenomenon and soot phenomenon of various parts inside the enclosure for electrical equipment.

In addition, by performing a response according to each condition according to a predetermined process, a measure for preventing a fire or a measure for suppressing a fire by a manager may be immediately executed.

For example, as shown in FIGS. 6A and 6B , the management server 300 generates a first notification signal corresponding to the normal state in a situation in which the state inside the enclosure for electrical equipment is analyzed as a normal state and fire By transmitting to the monitoring unit 100, it is possible to display a phrase indicating that the inside of the enclosure is in a normal state on the display device 160 for the enclosure, and to display the same phrase on the monitoring device 310 provided in the management office, etc. can

At this time, as the first notification signal is received, basic information such as the internal temperature of the enclosure for electric equipment may be displayed on the enclosure display device 160 and the monitoring device 310 together with a corresponding phrase.

In addition, the management server 300 generates a second notification signal corresponding to the caution state in a situation where the state inside the enclosure for electrical equipment is analyzed as a caution state and transmits it to the fire monitoring unit 100, thereby displaying the enclosure display device ( 160) may display a phrase indicating that the state inside the enclosure is an alert state, and the same phrase may be displayed on the monitoring device 310 provided in the management office or the like.

However, from the state in which the second notification signal is received, a low-volume alarm may occur in the enclosure display device 160 and the monitoring device 310, and a warning light may blink in the enclosure display device 160, However, the manager who recognizes the blinking of the alarm or warning light can check the condition inside the enclosure for the electrical equipment and take measures to prevent fire or have another manager take action.

In addition, the management server 300 generates a third notification signal corresponding to the imminent fire state and transmits it to the fire monitoring unit 100 in a situation where the internal state of the enclosure for electrical equipment is analyzed as an imminent fire state, thereby displaying the enclosure display. The device 160 may display a phrase indicating that the internal state of the enclosure is imminent fire, and the same phrase may be displayed on the monitoring device 310 provided in a management office or the like.

At this time, in a state in which the third notification signal is received, an alarm of high volume or maximum volume must be generated in the enclosure display device 160 and the monitoring device 310, and a warning light blinks in the enclosure display device 160. The manager who recognizes the blinking of the alarm or warning light can check the condition inside the enclosure for the corresponding electric facility and take measures to prevent fire or have another manager take action.

In addition, the management server 300 generates a fourth notification signal corresponding to the fire state and transmits it to the fire monitoring unit 100 in a situation where the state inside the enclosure for electrical equipment is analyzed as a fire occurrence state, so that the electric equipment The display device 160 outside the enclosure may display a phrase indicating that the state inside the enclosure is a fire state, and the same phrase may be displayed on the monitoring device 310 provided in the management office or the like.

In a state in which the fourth notification signal is received, an alarm of the maximum volume must be generated in the display device 160 and the monitoring device 310, and a warning light may blink in the enclosure display device 160. A manager who recognizes the blinking of an alarm or warning light may take priority over checking the state of the inside of the enclosure for the electrical equipment and take action to extinguish the fire or have another manager take action.

On the other hand, the enclosure display device may change the blinking color in each situation so that the situation in which the second notification signal is received, the situation in which the third notification signal is received, and the situation in which the fourth notification signal is received can be identified only with the warning light. It is preferable to be configured so that

In addition, the management server 300 is configured to generate and transmit a control signal to the simulation device unit 200 at predetermined intervals, and analyzes the detected value and image information received based on the transmitted control signal to perform self-diagnosis. It is characterized in that it is configured to carry out.

That is, the management server 300 not only analyzes the possibility of a fire using the detected value and image information transmitted from the fire monitoring unit 100 in normal times, but also generates a control signal at each predetermined period to ensure that the fire monitoring unit 100 ) so that it can be transmitted to the simulation device unit 200.

Therefore, a fire situation or a precursor situation can be virtually implemented by the simulation device unit 200, and in the virtual fire situation or a precursor situation, by using the detected value and image information transmitted from the fire monitoring unit 100 By performing self-diagnosis, the performance of the fire monitoring unit 100 can be checked, and artificial intelligence learning for improving self-diagnosis performance can occur.

That is, the management server 300 can generate and transmit a control signal for a fire situation so that the fire situation is implemented by the simulation device unit 200, and the result of analyzing the detected value and image information received accordingly is The state of the fire monitoring unit 100 may be checked by a method of checking whether it is a fire situation.

In addition, the management server 300 may generate and transmit a control signal for predictive situations so that the predictive situations are implemented by the simulation device unit 200, and the result of analyzing the detected values and image information received accordingly is The state of the fire monitoring unit 100 may be confirmed by a method of confirming whether it is a precursor situation.

At this time, when the detected value and the image information by the operation of the simulator unit 200 are received, the display device for the enclosure 160 and the monitoring device 310 do not display a fire situation or an omen situation and a warning sound is generated. The generation of notification signals should be limited so that

On the other hand, the self-diagnosis by the management server 300 is preferably performed in a time zone where the electricity consumption of the building or facility in which the electric facility enclosure is installed is the lowest. It may be configured in a form that further includes a measuring device for measuring and transmitting power usage in a state installed inside.

Therefore, the management server 300 uses artificial intelligence analysis to statisticize the electricity consumption of the building or facility in which the electrical facility enclosure is installed, thereby identifying the time zone with the lowest electricity consumption and providing accurate self-diagnosis. The time may be determined, and at the determined time, a control signal may be arbitrarily generated and transmitted to the simulation device unit 200.

However, the management server 300 checks again the electricity consumption of the building or facility in which the electrical facility enclosure is installed before transmitting the transmission of the control signal, and in a situation where the electricity consumption exceeding the average electricity consumption of the corresponding time zone is confirmed, control The transmission of signals can be canceled and postponed.

The embodiments introduced above are provided as examples so that the technical idea of the present invention can be sufficiently conveyed to those skilled in the art to which the present invention belongs, and the present invention relates to the above-described embodiments. It is not limited and may be embodied in other forms.

In order to clearly explain the present invention, parts irrelevant to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated or reduced for convenience.

Also, like reference numbers indicate like elements throughout the specification.

100: fire monitoring department
→ 110: sensor part
→ 120: camera
→ 130: data storage unit
→ 140: Converter
→ 150: Communication Department
→ 160: display device
200: simulation unit
→ 210: device for testing
→ 220: control unit
→ 230: rail
→ 240: moving part → 241: body
→ 242: pinion gear
→ 243: motor
→ 244: 1st rotation wheel
→ 245: 1st frame
→ 246: 2nd rotation wheel
→ 247: 2nd frame
→ 248: fixed part

300: management server
→ 310: monitoring device

Claims (5)

It is configured to include a sensor unit 110 composed of one or more detection sensors and a photographing unit 120 composed of one or more cameras, and the detected values generated by the sensor unit 110 and the values generated by the photographing unit 120 A fire monitoring unit 100 configured to transmit image information to the management server 300;
A simulation device unit 200 configured to include a plurality of test devices 210 that virtually implement a fire situation or a precursor situation according to a control signal; and,
The detection value and image information transmitted from the fire monitoring unit 100 are received, the possibility of fire occurrence is analyzed, the result of the analysis is staged according to a predetermined standard, and a notification signal is generated according to the result to a designated external It is configured to be transmitted to a device of a predetermined period, and is configured to generate a control signal and transmit it to the simulation device unit 200 at predetermined intervals, and analyzes the detected value and image information received based on the transmitted control signal to perform self-diagnosis. a management server 300 configured to perform; It is characterized in that it is configured to include,
The simulation device unit 200,
A plurality of test devices 210 installed in the enclosure for electrical equipment in which the fire monitoring unit 100 is installed to virtually implement a fire situation or a precursor situation of a fire occurrence;
a control unit 220 controlling the test device 210;
A rail 230 composed of an I beam or H beam with a rack gear formed on one side and installed inside the door for opening and closing the enclosure for electrical equipment; and,
A moving unit 240 that moves along the rail 230 in a state where a plurality of devices for testing 210 are mounted and changes the position of the device for testing 210; A fire monitoring and self-diagnosis system, characterized in that configured to include.
According to claim 1,
The fire monitoring unit 100,
A sensor unit 110 configured to include one or more detection sensors;
a photographing unit 120 including one or more cameras;
a data storage unit 130 that collects and temporarily stores detected values and image information generated by the sensor unit 110 and the photographing unit 120;
a converter 140 that converts the detected values and image information, which are analog signals stored in the data storage unit 130, into digital signals; and,
a communication unit 150 for transmitting the detected values and image information converted into digital signals to the management server 300; Fire monitoring and self-diagnosis system, characterized in that configured to include.
delete According to claim 1,
The moving part 240,
A main body 241 to which a plurality of test devices 210 are mounted;
a pinion gear 242 engaged with the rack gear of the rail 230 in a state installed in the center of the main body 241;
a motor 243 providing power to the pinion gear 242;
A first frame 245 installed on one side of the main body 241 in a state where a plurality of first rotating wheels 244 slidably inserted into grooves on both sides of the rail 230 are installed at the distal end;
Installed on the other side of the main body 241 in a form symmetrical to the first frame 245 in a state where a plurality of second rotation wheels 246 slidably inserted into the grooves on both sides of the rail 230 are installed at the distal end. a second frame 247; Fire monitoring and self-diagnosis system, characterized in that configured to include.
According to claim 1,
The management server 300,
It is configured to use artificial intelligence in the process of analyzing the possibility of fire occurrence and conducting self-diagnosis,
A fire monitoring and self-diagnosis system, characterized in that the artificial intelligence is configured to statisticize the electricity consumption of the building or facility in which the enclosure for electrical equipment is installed and select a time period for the execution of self-diagnosis.

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