KR102188666B1 - Electric panel fire control device - Google Patents

Abstract

The present invention is an electric panel fire management device that monitors internal parts of a sealed electric panel to determine whether a fire occurs in the electric panel, and according to the determination result, cools the internal parts or cuts off the power supply to prevent fire. As for,
An electric panel fire management apparatus according to an embodiment of the present invention,
A far-infrared thermal image sensor that detects whether internal components of a sealed electrical panel are heated, a smoke sensor that detects smoke generated from the internal components, and a temperature sensor that detects an increase in temperature inside the electrical panel. Sensor unit; When the sensing value sensed by the sensor unit exceeds a preset threshold value, the sensing period of the sensor unit is changed, the internal parts are controlled to cool, and at least one of the internal parts according to a preset priority A control unit for controlling to sequentially cut off the supply of electricity in response to the abnormality; A cooling unit for cooling the internal parts according to a control command from the control unit; And a power management unit selectively shutting off electricity supply to at least one or more of the internal parts according to a control command of the control unit.

Description

Electric panel fire control device}

The present invention relates to an electric panel fire management apparatus, and more specifically, by monitoring internal parts of a sealed electric panel to determine whether a fire occurs in the electric panel, and to cool the internal parts or supply power according to the determination result. It relates to an electric panel fire management device that prevents fire by blocking the fire.

The contents described in this section are merely to provide background information on the embodiments of the present invention, and do not constitute prior art.

More than 30% of general fires are electric fires, and such electric fires are often caused by short circuits and overheating inside most electric switchboards or panels for electricity, including general home appliances.

Likewise, in power plants, substations, factories, and buildings, there is always the possibility of a fire occurring due to internal short circuits and overheating of electrical switchboards installed in electrical rooms or electrical panels of various equipment.

However, due to the structure of the electric switchboard or the panel for electricity, it is difficult to have an adequate fire extinguishing facility to extinguish the fire inside the switchboard or the panel for electricity, such as a fire extinguishing device cannot be directly installed therein.

On the other hand, in Registration Patent No. 10-0509232, in an electric switchboard and an automatic fire extinguishing device for an electric panel for extinguishing a fire occurring inside an electric switchboard or an electric panel, an accommodation space in which the injected gas can be accommodated. And a storage container installed on the electric switchboard or the electric panel; The storage container has a connection passage connected to the receiving space of the storage container, and a plurality of radiation passages that connect the connection passage and the outside to form a passage through which gas in the receiving space passing through the connection passage can radiate to the outside, and the storage container At least one spinning nozzle assembly coupled to; And it is installed in the connection flow path to close the connection flow path to block the flow of the gas in the receiving space to the radiation flow path, and is melted when heat above a predetermined temperature is transferred from the spinning nozzle assembly to open the connection flow path. An automatic fire extinguishing device for an electric switchboard and an electric panel including a thermal fuse is disclosed.

The above patent effectively extinguishes the fire generated inside the electric switchboard or electric panel at an early stage without remodeling the electric switchboard or electric panel and additional installation of external fire extinguishing equipment, and the fire of the electric panel is transferred to a large fire. It can be prevented, but it is a measure after a fire occurs inside the electrical panel, and there is a disadvantage that it cannot be prevented from occurring.

Therefore, before a fire occurs inside the electric panel, the internal parts of the electric panel are monitored to determine whether a fire occurs in the electric panel, and according to the result of the judgment, the internal parts are cooled or the power supply is cut off to prevent fire. The development of electric panel fire management devices is urgent.

Korean Patent Registration No. 10-0509232

The present invention is an electric panel fire management device that monitors internal parts of a sealed electric panel to determine whether a fire occurs in the electric panel, and according to the determination result, cools the internal parts or cuts off the power supply to prevent fire. It aims to provide.

An electric panel fire management apparatus according to an embodiment of the present invention,

A far-infrared thermal image sensor that detects whether internal components of a sealed electrical panel are heated, a smoke sensor that detects smoke generated from the internal components, and a temperature sensor that detects an increase in temperature inside the electrical panel. Sensor unit; When the sensing value sensed by the sensor unit exceeds a preset threshold value, the sensing period of the sensor unit is changed, the internal parts are controlled to cool, and at least one of the internal parts according to a preset priority A control unit for controlling to sequentially cut off the supply of electricity in response to the abnormality; A cooling unit for cooling the internal parts according to a control command from the control unit; And a power management unit selectively shutting off electricity supply to at least one or more of the internal parts according to a control command of the control unit.

In the electric panel fire management apparatus according to an embodiment of the present invention, the control unit includes a fire risk determination module for predicting and determining the possibility of a fire occurrence based on a sensing value sensed by the sensor unit, and the fire risk determination module. A sensor period control module that changes the sensing period of the sensor unit according to the determination result, a cooling unit control module that controls the operation of the cooling unit according to the determination result of the fire risk determination module, and the determination result of the fire risk determination module Accordingly, it may include a power control module for controlling the operation of the power management unit.

In the electric panel fire management apparatus according to an embodiment of the present invention, the fire risk determination module includes a normal range, which is a temperature range during normal operation of the internal parts, and a danger range, which is a temperature range during overheating operation of the internal parts. Information is provided, and the danger range may include a first danger range in which performance of a corresponding part is deteriorated due to heat although the risk of fire is small, and a second danger range in which a fire is likely to occur in the part due to heat.

In the electric panel fire management apparatus according to an embodiment of the present invention, the sensor period control module, when the determination result of the fire risk determination module falls within a danger range, the sensing period of the sensor unit is a normal range sensing period. It can be controlled to change to a second cycle smaller than the first cycle.

In the electric panel fire management apparatus according to an embodiment of the present invention, the cooling unit is installed on a rear surface of an electric panel substrate on which the internal components are mounted, and a coolant in which a low temperature refrigerant directly or indirectly contacts the electric panel substrate flows. A heat exchanger in which a refrigerant heated by heat exchange between a flow path and the electric panel substrate becomes a low-temperature refrigerant again, a refrigerant storage container in which the low-temperature refrigerant is stored, and an amount of refrigerant flowing through the refrigerant flow path And a valve, wherein the cooling unit control module adjusts the opening degree of the control valve according to the determination result of the fire risk determination module to control the flow amount of the refrigerant to normalize the temperature of the internal parts formed on the front surface of the electric panel substrate. Can be adjusted to a range of temperatures.

In the electric panel fire management apparatus according to an embodiment of the present invention, the power management unit individually manages supply power by giving priority to each of the internal parts, and the power control module is the fire risk determination module. As a result of the determination, when a plurality of parts inside the electrical panel fall within a dangerous range, power supply to a component having a lower priority may be preferentially cut off.

In the electric panel fire management apparatus according to an embodiment of the present invention, the power management unit individually manages supply power by giving priority to each of the internal parts, and the power control module is the fire risk determination module. As a result of the determination, when a plurality of parts inside the electrical panel fall within a dangerous range, power supply to a component having a priority priority may be preferentially cut off.

In the electric panel fire management apparatus according to an embodiment of the present invention, a communication unit for transmitting and receiving information with an external manager terminal through a communication network may further be included.

Other specific details of embodiments according to various aspects of the present invention are included in the detailed description below.

According to an embodiment of the present invention, it is possible to prevent fire by monitoring internal components of a sealed electrical panel to determine whether a fire has occurred in the electrical panel, and to cool internal components or cut off power supply according to the determination result. I can.

1 is a photograph showing an electrical panel of an electric switchboard or various equipment installed in an electrical room such as a power plant, a substation, and a factory or building.
2 is a block diagram illustrating an electric panel fire management apparatus according to an embodiment of the present invention.
3 is a block diagram illustrating a control unit of an electric panel fire management apparatus according to an embodiment of the present invention.
4 is an exemplary view conceptually illustrating a cooling unit of an electric panel fire management apparatus according to an embodiment of the present invention installed on the rear of the electric panel.

The present invention is intended to illustrate specific embodiments and to be described in detail in the detailed description, since various transformations can be applied and various embodiments can be provided. However, this is not intended to limit the present invention to a specific embodiment, it is to be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention.

The terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present invention, terms such as'comprise' or'have' are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance. Hereinafter, an electric panel fire management apparatus according to an embodiment of the present invention will be described with reference to the drawings.

1 is a photograph showing an electrical panel of an electric switchboard or various equipment installed in an electrical room such as a power plant, a substation, and a factory or building, and FIG. 2 is a block diagram showing an electric panel fire management apparatus according to an embodiment of the present invention. 3 is a block diagram showing a control unit of an electric panel fire management apparatus according to an embodiment of the present invention, and FIG. 4 is a block diagram of an electric panel fire management apparatus according to an embodiment of the present invention installed on the rear of the electric panel. It is an exemplary diagram conceptually illustrating a cooling unit.

As shown in Figure 2, the electric panel fire management apparatus according to an embodiment of the present invention, a sensor unit 100, a control unit 200, a cooling unit 300, a power management unit 400, Consisting of a display unit 500 and a communication unit 600, it is installed in an electric switchboard installed in an electric room such as a power plant, a substation, and a factory or building, or installed in an electric panel of various equipment to monitor the internal parts of the electric panel. Therefore, it judges whether a fire has occurred in the electrical panel, and according to the result of the judgment, the internal parts are cooled or the power supply is cut off to prevent the fire.

The sensor unit 100 generates a sensing value by monitoring the internal parts A of the sealed electrical panel. The electric panel has a shape of a closed case having a door D as shown in FIG. 1, and the sensor unit 100 is installed to monitor internal components from the back of the door D or from either side of the case.

The sensor unit 100 includes a far-infrared thermal sensor 110, a smoke sensor 120, and a temperature sensor 130.

The far-infrared thermal sensor 110 is a sensor that detects a long-wave infrared image in a wavelength range of 8 μm to 14 μm, and detects whether internal parts of an electrical panel are heated.

The smoke sensor 120 is a type of fire detector that detects smoke caused by a fire and finds an accident more quickly before the occurrence of a fire. There are two types of fire detectors, an ion type and an optical type. It is a method of capturing by change, and Gwangsik is a method of detecting by change of light flux caused by smoke.

The temperature sensor 130 is for detecting an increase in temperature inside the electric panel, and it is preferable to use a semiconductor temperature sensor that converts the sensed temperature into a proportional current output. The semiconductor temperature sensor is also referred to as an IC temperature sensor (Integrated Circuit Temperature sensor), and the measured temperature data is linked to a control application (eg, DSP controller) through I2C communication. I2C refers to a bidirectional serial bus specification that operates by connecting peripheral devices with only two signal lines, unlike a parallel bus called a local bus.

The controller 200 controls an operation period (sensing period) of the sensor unit 100. In addition, the control unit 200 determines whether or not a fire has occurred in the electric panel based on the sensing value of the sensor unit 100, and controls the cooling unit 300 according to the determination result to cool internal parts or the power management unit 400 Control to cut off the power supply to specific parts according to the preset priority. To this end, the control unit 200 includes a fire risk determination module 210, a sensor period control module 220, a cooling unit control module 230, and a power control module 240, as shown in FIG. 3. Each of the modules 210 to 240 is a component that performs a predetermined function, and may be implemented as hardware, software, or a combination of hardware and software. For example, the modules 210 to 240 may refer to program modules, which may be software components that are executed by a processor to perform a predetermined function.

The fire risk determination module 210 predicts and determines the likelihood of a fire on the basis of a sensing value sensed by the sensor unit 100. Here, specifically, the sensing value may be a temperature value sensed by the temperature sensor 130, but even in the case of the far-infrared thermal sensor 110, the color according to the temperature is analyzed in the image obtained by the far-infrared thermal sensor 110 It is possible to obtain the temperature inside the component or electrical panel.

The fire risk determination module 210 has information on a temperature range (normal range) during normal operation of an internal component as a monitored object and a temperature range (hazardous range) during overheating operation. The danger range includes a first danger range in which the performance of a corresponding part is deteriorated by heat although the risk of fire is small, and a second danger range in which a fire is likely to occur in the part by heat. Here, the normal range and the danger range may be determined by an experiment in the manufacturing process of the corresponding part, and the temperature range is not particularly limited. In addition, the normal range and the danger range are not uniform and may be set differently according to parts.

The fire risk determination module 210 predicts and determines the probability of a fire occurrence for each component in stages based on a sensing value sensed by the sensor unit 100. For example, the fire risk determination module 210 corresponds to whether the temperature inside the electrical panel measured by the temperature sensor 130 falls within the normal range for all components or the first danger range in which the performance of the components deteriorates. It is determined whether it falls within the second danger range that may cause fire to the parts. Alternatively, the fire risk determination module 210 acquires the temperature of a specific component from the image acquired by the far-infrared thermal image sensor 110 and determines whether the component falls within the normal range, the first danger range, or the second danger range. do. Here, the temperature of the entire interior of the electric panel may be mainly obtained by the temperature sensor 130, and the temperature of a specific component inside the electric panel may be mainly obtained by the far-infrared thermal image sensor 110, but it is not necessarily limited thereto. no.

The sensor period control module 220 changes the sensing period of the sensor unit 100 according to the determination result of the fire risk determination module 210. In an embodiment of the present invention, each of the sensors 110 to 130 constituting the sensor unit 100 does not always detect and measure whether heat is generated, whether smoke is generated, or a temperature value, but performs a single sensing operation during the first period. Perform. For example, when the temperature inside the electrical panel is within the normal range for all parts, sensing is performed once an hour. That is, the sensing operation is performed by switching to the wake-up mode periodically after being in the sleep mode normally.

The sensor period control module 220 controls the sensing period of the sensor unit 100 to be changed to a second period less than the first period when the determination result of the fire risk determination module 210 falls within the danger range. In addition, according to the steps of the risk range, the first risk range is controlled to be changed to a second cycle 2_1 smaller than the first cycle, and if the second risk range is changed to a second cycle 2_2 smaller than the second cycle. For example, in the normal range in which the sensing operation is performed once an hour, if it is determined as the first danger range according to the temperature increase, the sensing operation is performed once every 5 minutes to more frequently monitor the condition of the inside of the electrical panel and parts. Monitoring is performed, and further, if it is determined as a more dangerous second danger range, it is sensed once a minute and controlled to monitor electrical panels in real time. When it is determined from the dangerous range to the normal range again, the sensor period control module 220 controls the sensing period of the sensor unit 100 to be switched back to the original first sensing period.

In this way, the sensor period control module 220 may minimize unnecessary power consumption of the sensor unit 100 by controlling a sensing period in the case of a normal normal range and a high risk range of a fire occurrence. Therefore, even when the same sensor is used, the battery life of the sensor can be maximized.

The cooling unit control module 230 controls the operation of the cooling unit 300 according to the determination result of the fire risk determination module 210. The cooling unit 300 is installed on the rear surface of the electric panel substrate S on which the components are mounted, and the refrigerant flow path 310 and the substrate S through which a low-temperature refrigerant absorbing heat from the electric panel substrate S flows. It includes a heat exchanger 320 that makes the refrigerant heated by heat exchange of the heat exchanger become a low-temperature refrigerant again, and a refrigerant storage container 330 in which the low-temperature refrigerant is stored. The low-temperature refrigerant stored in the refrigerant storage container 330 flows through the refrigerant flow path 310 installed on the rear surface of the electric panel substrate S by the operation of the control valve 340, and the cooling unit control module 230 is a control valve 340. ) By adjusting the opening degree of the refrigerant to control the flow rate of the refrigerant to adjust the temperature of the components formed on the front surface of the electric panel substrate S to a temperature within the normal range. At this time, the cooling unit control module 230 adjusts the opening degree of the control valve 340 so that more refrigerant flows according to the stages of the danger range. Heat transfer is possible between the electric panel substrate S and the coolant flow path 310, but an insulator 350 that does not conduct electricity may be formed.

The power management unit 400 manages power supplied to components inside the electrical panel. The power management unit 400 may individually manage the supplied power by grouping each or part of the components inside the electric panel according to a predetermined standard. The criteria for grouping can be whether the normal range and the risk range are the same. Alternatively, the power management unit 400 may manage power supply by giving priority to components that require high power use. For example, in the case of an electric panel used in a residential building, priority may be given in the order of cooling and heating devices of the building, home appliances, lighting devices, and refrigerators. These priorities may be set at the time of manufacture of the electric panel fire management apparatus of the present invention, or may be set by a user. That is, when the supplied power is limited, the power management unit 400 may manage to supply power to the corresponding component preferentially according to a set priority.

The power control module 240 controls the operation of the power management unit 400 according to the determination result of the fire risk determination module 210. As a result of the determination of the fire risk determination module 210, when all components inside the electrical panel fall within the danger range, the power control module 240 controls the operation of the power management unit 400 to preferentially supply power to a specific component. Can be blocked. That is, the power supply to the components with the lower priority priority is cut off so that the necessary functions can be performed even in the danger range of possible fire. As a result, the component with the highest priority will be shut off last.

On the other hand, priority may be given according to the price of parts. In other words, if it is determined that the temperature of the part falls within the dangerous range in order to give high priority to expensive parts and lower priority to cheap parts, and to prevent component performance deterioration due to heat or damage to parts due to heat, the power control module The 240 may control the power management unit 400 so that expensive parts having a high priority are first cut off.

The display unit 500 displays a result of the determination by the control unit 200 to the user. The information displayed here includes information on whether an internal component detected by the far-infrared thermal sensor 110 generates heat, information on whether or not smoke is generated in the component detected by the smoke sensor 120, and a temperature sensor 130 It can be information about the temperature inside the electric panel detected by ). In addition, a message (warning message) indicating whether the performance of the component is deteriorated or the second danger range in which a fire may occur in the component may be displayed through the display unit 500.

The communication unit 600 serves to support transmission and reception of various information to and from the manager terminal 700 through a wireless communication network. The communication unit 600 transmits the determination result by the control unit 200 to the manager terminal 700 through a wireless communication network. In this case, the transmitted information may be the same information as the information displayed through the display unit 500 and includes a warning message.

The manager terminal 700 is a terminal that is communicated with an electric panel fire management device, and includes a personal computer (PC), a notebook computer, a personal digital assistant (PDA), and a mobile communication terminal. It can be any one of.

The manager terminal 700 receives information on the internal parts of the electrical panel from the communication unit 600 of the electrical panel fire management device, and the administrator determines that there is a problem with the internal parts from the received information, or the determination result of the control unit 200 In case of receiving a warning message, it approaches the electrical panel and takes measures such as removing or replacing the part.

As described above, one embodiment of the present invention has been described, but those of ordinary skill in the relevant technical field add, change, delete or add components within the scope not departing from the spirit of the present invention described in the claims. Various modifications and changes can be made to the present invention by means of the like, and this will also be said to be included within the scope of the present invention.

100: sensor unit 200: control unit
210: fire risk determination module 220: sensor cycle control module
230: cooling unit control module 240: power control module
300: cooling unit 400: power management unit
500: display unit 600: communication unit
700: administrator terminal

Claims (8)

A far-infrared thermal image sensor that detects whether internal components of a sealed electrical panel are heated, a smoke sensor that detects smoke generated from the internal components, and a temperature sensor that detects an increase in temperature inside the electrical panel. Sensor unit;
When the sensing value sensed by the sensor unit exceeds a preset threshold value, the sensing period of the sensor unit is changed, the internal parts are controlled to cool, and at least one of the internal parts according to a preset priority A control unit for controlling to sequentially cut off the supply of electricity in response to the abnormality;
A cooling unit for cooling the internal parts according to a control command from the control unit; And,
Including; a power management unit that selectively cuts off electricity supply to at least one or more of the internal parts according to a control command of the control unit,
The control unit includes a fire risk determination module that predicts and determines the possibility of a fire occurrence based on a sensing value sensed by the sensor unit, and a sensor cycle control that changes the sensing period of the sensor unit according to a determination result of the fire risk determination module. A module, a cooling unit control module for controlling the operation of the cooling unit according to a determination result of the fire risk determination module, and a power control module for controlling the operation of the power management unit according to a determination result of the fire risk determination module, ,
The fire risk determination module includes information on a normal range, which is a temperature range during normal operation of the internal components, and a danger range, which is a temperature range during overheating operation of the internal components, and the danger range is the performance of the corresponding component by heat. This includes a first danger range that deteriorates and a second danger range in which a fire occurs in the part by heat,
The sensor period control module, when the determination result of the fire risk determination module falls within a dangerous range, controls the sensing period of the sensor unit to be changed to a second period less than the first period, which is a normal range sensing period,
The cooling unit is installed on the rear surface of the electric panel substrate on which the internal components are mounted, and a refrigerant flow path through which a low temperature refrigerant directly or indirectly contacts the electric panel substrate flows, and a refrigerant heated by heat exchange with the electric panel substrate. A heat exchanger for turning back to a low temperature refrigerant, a refrigerant storage container for storing a low-temperature refrigerant, a control valve for adjusting the amount of refrigerant flowing through the refrigerant flow path, and Contains an insulator that transfers heat but does not conduct electricity,
The cooling unit control module controls the flow amount of the refrigerant by adjusting the opening degree of the control valve according to the determination result of the fire risk determination module to adjust the temperature of the internal components formed on the front surface of the electric panel substrate to a temperature within a normal range. and,
The power management unit individually manages the supplied power by giving priority to each of the internal parts in the order of high price based on the price of the component,
The power control module, as a result of the determination of the fire risk determination module, preferentially cuts off the power supply to the expensive components having the priority priority when a plurality of components inside the electrical panel fall within the danger range.
Electric panel fire management device, characterized in that.
delete delete delete delete delete delete The method according to claim 1,
Electrical panel fire management device further comprising a communication unit for transmitting and receiving information with an external manager terminal through a communication network.

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