KR102609827B1 - Future distribution board having fire prevention function - Google Patents

Abstract

A futuristic switchgear equipped with fire prevention functions through automatic dust removal and moisture temperature control is disclosed. A futuristic switchgear equipped with a fire prevention function through automatic dust removal and humidity temperature control of the present invention includes a temperature and humidity control unit provided in the switchboard main body to control the temperature and humidity inside the switchgear main body; A dust sensor provided in the switchboard main body to detect dust inside the switchboard main body; And a dust removal unit provided in the switchboard main body and operated based on a signal detected by the dust sensor to suck in dust inside the switchboard main body and discharge it to the outside of the switchboard main body.

Description

Futuristic distribution board equipped with fire prevention functions through automatic dust removal and moisture temperature control {FUTURE DISTRIBUTION BOARD HAVING FIRE PREVENTION FUNCTION}

The present invention relates to a switchgear, and more specifically, to a futuristic switchgear equipped with a fire prevention function through automatic dust removal and humidity temperature control that can prevent fires by removing dust inside the switchgear and controlling temperature and humidity. will be.

Generally, buildings, factories, ships, etc. are equipped with a switchgear that accepts electricity supplied by power companies or self-generators and distributes it to each load. This switchboard depressurizes high-voltage or extra-high-voltage electricity according to the purpose and supplies it to each load, as well as automatically shutting off the electricity in the event of abnormalities such as overload or disconnection. It is designed with safety against electric shock and fire in mind. It is installed in a cabinet of the same size.

Inside the cabinet, various circuit breakers and protective equipment such as switches, transformers, main circuit breakers, condensers, molded circuit breakers, power fuses and lightning arresters, and various relay equipment such as current transformers, power meters, zero-phase current transformers, ammeters, and voltmeters are installed.

The high voltage receiving and distribution board consists of a special high voltage receiving board (LBS group), instrument transformer base (MOF group), instrument transformer base (PT group), and special high voltage blocking base (VCB group) in order to receive the supplied high voltage or special high voltage. It consists of a panel, a transformer base installed with a transformer that converts high-voltage electricity into low-voltage electricity, and a low-voltage panel to distribute low-voltage electricity to each load.

Fire risk factors in switchboards can be broadly divided into electrical factors, environmental factors, and physical factors.

Electrical factors include short circuit, overload (overcurrent), poor contact, and current imbalance.

Environmental factors include insulation breakdown, device damage, and malfunction due to moisture (salt, etc.), dust (dust, wood dust, iron, etc.), and temperature (high temperature).

Physical factors include heat generation due to relaxation of electrical connections due to mechanical vibration or shock.

As a result of conducting an on-site survey regarding these fire risk factors, it was confirmed that in some distribution boards, foreign substances such as dust were attached to the surfaces of circuit breakers, wires, terminal blocks, etc., and the surface of the insulation between electrodes was affected by moisture, salt, etc. There is a possibility that a fire may occur due to deterioration.

The technical configuration described above is background technology to aid understanding of the present invention, and does not mean that it is a conventional technology widely known in the technical field to which the present invention pertains.

Korean Patent Publication No. 10-1812157 (Daejin Electric Co., Ltd.) December 19, 2017.

Therefore, the technical task to be achieved by the present invention is to provide a futuristic switchgear equipped with fire prevention functions through automatic dust removal and humidity temperature control that can prevent fires by removing dust inside the switchgear and controlling temperature and humidity.

According to one aspect of the present invention, a temperature and humidity control unit provided in the switchboard main body to control the temperature and humidity inside the switchboard main body; A dust sensor provided in the switchboard main body to detect dust inside the switchboard main body; And a dust removal unit provided in the switchboard main body and operated based on a signal detected by the dust sensor to suck in dust inside the switchboard main body and discharge it to the outside of the switchboard main body. A switchgear can be provided.

The dust removal unit includes a fan unit provided on an upper portion of the main body; a main pipe provided at the upper part of the main body and communicating with the fan unit; a plurality of branch pipes branching from the main pipe and having one end disposed to the lower part of the first to fifth spaces to suck dust in the first to fifth spaces; and a plurality of filter members provided in the main pipe and the plurality of branch pipes to filter air flowing into the main pipe and the plurality of branch pipes, and the plurality of filter members may include a photocatalytic filter.

The dust removal unit includes a plurality of extension pipes branched from the plurality of branch pipes and disposed in close proximity to each of the load switching unit, the instrument transformation unit, the vacuum interrupting unit, the air circuit breaker, and the surge absorbing unit arranged inside the switchgear main body; and a plurality of transfer fans provided in the main pipe and a plurality of branch pipes to help the flow of air transferred to the fan unit, wherein the temperature and humidity control unit is configured to connect the first to fifth spaces of the power panel main body. A temperature sensor unit provided in at least one of the spaces to detect temperature; a humidity sensor unit provided in at least one of the first to fifth spaces to detect humidity; a thermoelectric element body provided on the outer wall of at least one of the first to fifth spaces; and a thermoelectric element unit provided inside the thermoelectric element body to generate heat or cooling energy, wherein the thermoelectric element unit includes a heat exchange block coupled to a partition wall provided inside the thermoelectric element body; a thermoelectric element member provided in front of the heat exchange block to generate heat or cooling energy; and a plurality of heat dissipation fins provided in front of the thermoelectric element member, wherein the temperature and humidity control unit is provided in the thermoelectric element body to be disposed in front of the thermoelectric element member to generate heat or cooling energy from the thermoelectric element member. a first blowing fan that blows air into at least one of the first to fifth spaces; and a second blowing fan provided in the thermoelectric element body to be disposed behind the heat exchange block and blowing heat generated in the heat exchange block to the outside of the thermoelectric element body, wherein the thermoelectric element body is connected to the switchgear body. It is detachably coupled, and the thermoelectric element body, the thermoelectric element unit, the first blower fan, and the second blower fan are provided as one unit, so that when the thermoelectric element body is separated from the switchboard main body, the thermoelectric element body, the first blower fan, and the thermoelectric element body are separated from the switchgear body. 1 The blowing fan and the second blowing fan are also separated, provided in the thermoelectric element body, and electrically connected to the thermoelectric element member, and change the direction of the current supplied to the thermoelectric element member to heat or cool the thermoelectric element member. It may further include a changeover switch that generates energy.

Embodiments of the present invention can prevent fires by removing dust inside a switchboard and controlling temperature and humidity.

Figure 1 is a diagram schematically showing a future switchgear equipped with fire prevention functions through automatic dust removal and humidity temperature control according to an embodiment of the present invention.
FIG. 2 is a diagram schematically showing the interior of the switchboard shown in FIG. 1.
Figure 3 is a diagram schematically showing the main pipe and a plurality of branch pipes shown in Figure 2.
Figure 4 is a control block diagram of this embodiment.
Figure 5 is a diagram schematically showing that the temperature and humidity control unit applied to this embodiment is provided in the main body of the switchgear.

In order to fully understand the present invention, its operational advantages, and the objectives achieved by practicing the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the attached drawings. The same reference numerals in each drawing indicate the same member.

Figure 1 is a diagram schematically showing a future switchgear equipped with fire prevention functions through automatic dust removal and moisture temperature control according to an embodiment of the present invention, and Figure 2 schematically shows the interior of the switchboard shown in Figure 1. It is a drawing, FIG. 3 is a diagram schematically showing the main pipe and a plurality of branch pipes shown in FIG. 2, FIG. 4 is a control block diagram of this embodiment, and FIG. 5 is a temperature and This is a diagram schematically showing that the humidity control unit is provided in the main body of the switchgear.

As shown in these drawings, the future switchgear 1 equipped with fire prevention functions through automatic dust removal and moisture temperature control according to this embodiment is provided in the switchgear main body 100 and the switchgear main body 1000. (1000) A temperature and humidity control unit 2000 that controls the internal temperature and humidity, a dust sensor 100 provided in the switchboard main body 100 to detect dust inside the switchboard main body 1000, and a switchboard main body ( 1000) is provided with a dust removal unit 200 that operates based on a signal detected by the dust sensor 100 to suck in dust inside the switchboard main body 1000 and discharge it to the outside of the switchboard main body.

As shown in FIG. 2, the switchboard main body 1000 includes a first space 1100, a second space 1150, a third space 1200, a fourth space 1250, and a fifth space. It includes a part 1300, and each space part may be provided to be isolated from each other.

In this embodiment, the first space 1100 to the fifth space 1300 are connected by a plurality of bushings 1350, so that electricity supplied from the outside is transmitted from the first space 1100 to the fifth space ( Up to 1300) can be supplied sequentially.

Additionally, in this embodiment, the bushing parts 1350 that are spaced apart from each other may be electrically connected by a fuse link 1400, as shown in FIG. 2.

Furthermore, in this embodiment, a voltage display unit and a voltage display control unit may be provided in the second space 1150, and an instrument transformer may be provided in the third space 1200 and the fifth space 1300. there is.

And, in this embodiment, a temperature display control unit may be provided in the fourth space 1250, and an earth leakage alarm may be provided in the fifth space 1300.

In this embodiment, the main body support body is provided on the lower part of the switchgear main body 1000 to protrude downward, and is elastically supported by a plurality of elastic bars and compression springs to offset external shocks such as earthquakes.

In addition, in this embodiment, a plurality of ventilation holes may be provided to be spaced apart from each other in the switchgear main body 1000. In this embodiment, a plurality of vents may be operated in conjunction with the exhaust fan 212.

The temperature sensor unit 2100 may be slidably inserted into a fixed frame provided inside the switchgear main body 1000 and then detachably coupled to the fixed frame using bolts or pieces. This can be equally applied to the humidity sensor unit 2200.

In this embodiment, the temperature sensor unit 2100 includes a flat plate-shaped sensor base body and a temperature sensor member provided on the sensor base body to detect the internal temperature of the switchboard main body 1000 and connected to the control unit 1850.

In this embodiment, the first to fifth spaces 1300 may be divided into upper and lower parts into a plurality of spaces, as shown in FIG. 2, and in this case, the temperature sensor unit 2100 and the humidity sensor unit 2200 ) can be provided at the top and bottom of the partitioned space, respectively.

The humidity sensor unit 2200 can be slidably inserted into a fixed frame provided inside the switchgear main body 1000 and then detachably coupled to the fixed frame with bolts or pieces, and its structure is the same as the temperature sensor unit 2100 described above. It can be applied easily.

The thermoelectric element body 2300 may be detachably coupled to the outer wall of the switchgear body 1000, as shown in FIG. 5 .

In this embodiment, a partition wall 2300 may be provided inside the thermoelectric element body 2300, as shown in FIG. 5, and the heat exchange block 2410 of the thermoelectric element unit 2400 is located in the partition wall 2300. It can be removably fitted or bolted together.

In addition, in this embodiment, the thermoelectric element body 2300 is provided with a plurality of ventilation holes 2320, as shown in FIG. 5, and the air in the area where the second blowing fan 2600 is provided is supplied through the plurality of ventilation holes 2320. ) can be discharged to the outside of the thermoelectric element body 2300.

Furthermore, in this embodiment, a drain pipe 2330 is provided at the bottom of the thermoelectric element body 2300, and a drain pipe 2330 is provided at the inner bottom of the thermoelectric element body 2300 to drain liquid generated inside the thermoelectric element body 2300. An inclined portion 2340 that allows the flow to be provided may be provided.

As shown in FIG. 5, the thermoelectric element unit 2400 includes a heat exchange block 2410 that is fitted or bolted to a partition wall 2300 provided inside the thermoelectric element body 2300, and a heat exchange block 2410. It includes a thermoelectric element member 2420 provided in front to generate heat or cooling energy, and a plurality of heat dissipation fins 2430 provided in front of the thermoelectric element member 2420.

As shown in FIG. 5, the first blowing fan 2500 is disposed in front of the thermoelectric element unit 2400 and blows heat or electric energy generated from the thermoelectric element member 2420 into the inside of the switchgear main body 1000. can be supplied.

In this embodiment, the electricity required to operate the first blower fan 2500, the second blower fan 2600, and the thermoelectric element member 2420 is electricity generated by the solar power generation unit 4000 or the energy storage device 8700. It can be supplied from.

As shown in FIG. 5, the second blowing fan 2600 is disposed at the rear of the thermoelectric element unit 2400 and blows heat generated from the thermoelectric tube block when the thermoelectric element member 2420 operates to the thermoelectric element body 2300. ) can be discharged to the outside.

The changeover switch 2700 is provided on the thermoelectric element body 2300 or the switchboard main body 1000 and is electrically connected to the thermoelectric element member 2420, and switches the direction of the current supplied to the thermoelectric element member 2420 to change the thermoelectric element member 2420. (2420) can generate heat or cooling energy.

In this embodiment, the changeover switch 2700 can selectively transfer heat or cooling energy to the inside of the switchgear main body 1000 by reversing the polarity of the power input to the thermal insulation element member 2420.

That is, in this embodiment, the interior of the switchboard main body 1000 can be selectively cooled or heated by reversing the polarity of the thermoelectric element member 2420 by the changeover switch 2700, thereby reducing the internal temperature or humidity of the switchgear main body 1000. It can be adjusted. For example, when the internal temperature of the switchboard main body 1000 rises above the set temperature, the thermoelectric element member 2420 sends cooling energy, that is, cold air, to the inside of the switchboard main body 1000 to lower the internal temperature of the switchboard main body 1000. It can be lowered. Conversely, when the internal humidity of the switchboard main body 1000 rises above the set humidity, the humidity can be lowered by sending heat, that is, heated air, into the inside of the switchboard main body 1000.

The dust sensor 100 is provided on the switchboard main body 1000 and can detect dust inside the switchgear main body 1000.

In this embodiment, the dust sensor 100 may detect dust using a capacitance method.

The dust removal unit 200 is provided in the switchboard main body 1000 and operates based on a signal detected by the dust sensor 100 to suck the dust inside the switchgear main body 1000 and remove it to the outside of the switchboard main body 1000. It can be discharged.

In this embodiment, the dust removal unit 200 includes a fan unit 210 provided on the upper part of the switchgear main body 1000, and a main pipe 220 provided on the upper part of the switchgear main body 1000 and communicating with the fan part 210. ) and, branched from the main pipe 220, one end of which is disposed to the lower part of the first space 1100 to the fifth space 1300, and is located in the first space 1100 to the fifth space 1300. A plurality of branch pipes 230 for sucking in dust, and a plurality of pipes provided in the main pipe 220 and the plurality of branch pipes 230 to filter the air flowing into the main pipe 220 and the plurality of branch pipes 230. Includes a filter element (240).

In this embodiment, the plurality of filter members 240 include a photocatalyst filter and can remove odors from the air discharged to the outside of the switchgear main body 1000.

In addition, in this embodiment, the dust removal unit 200 branches off from a plurality of branch pipes 230 and includes a load switch, an instrument transformation unit 5500, and a vacuum cutoff unit 6000 disposed inside the switchgear main body 1000. and a plurality of extension pipes (not shown) arranged in close proximity to each of the air circuit breaker and the surge absorber, and provided in the main pipe 220 and a plurality of branch pipes 230 to help the flow of air transported to the fan unit 210. It may further include a plurality of transfer fans (not shown).

In this embodiment, the dust sensor 100 sends a signal to the control unit 1850 when dust is blown inside the switchgear main body 1000 and the concentration of dust is higher than a preset concentration, and the control unit sends a signal to the exhaust fan 212 of the fan unit 210. ) can be operated to discharge air in the space above a certain concentration to the outside of the switchgear main body 1000.

Meanwhile, this embodiment is provided in the switchgear main body 1000 to receive voltage and current from the transformer and measure the power value, and when a circuit breaker trips due to a short circuit or ground fault in the customer's electrical equipment or when low voltage is detected, the voltage and current before and after the accident are measured. , contact data is stored in the memory unit, and fault analysis information on the occurrence date, fault voltage/current size, and fault waveform is output on the display screen, and the flame detection sensor, temperature sensor member, humidity sensor unit 2200, and arc If it deviates from the standard data set based on the detection data collected from the detector and dust sensor 100, it is diagnosed as an abnormal condition and provides the user with a risk indication, buzzer alarm, circuit breaker control, voice alarm, and remote monitoring using Ethernet communication. It may further include a data analysis and failure monitoring and diagnosis unit.

In this embodiment, the fault monitoring and diagnosis unit may further include an ultraviolet arc detection unit, a non-contact infrared temperature detection unit, a gas concentration detection unit, a display unit, and an integrated sensor module.

The integrated sensor module communicates arc, temperature and gas concentration in real time via Modbus RS485. Additionally, the display unit can be used to display the number of ARC occurrences, temperature changes, and gas concentration changes.

The ultraviolet arc detection unit may include a sensor module capable of detecting the 185nm to 260nm wavelength band to detect ARC generated inside the distribution panel.

The non-contact infrared temperature detection unit can measure the target temperature and ambient temperature using an infrared temperature sensor, such as the temperature of the wire coating inside the distribution panel and the temperature of the bus bar. The temperature measurement range may be -20°C to 300°C.

The gas concentration detection unit may include an electrochemical carbon monoxide detection sensor module to detect carbon monoxide (CO) accompanying before a fire occurs inside the distribution board. In this embodiment, the carbon monoxide detection sensor module can detect carbon monoxide gas of 0 to 500 ppm.

And this embodiment may further include an IoT control unit including an information collection unit, an information analysis unit, and an information provision unit.

The information collection unit receives temperature and humidity information through the temperature sensor member and the humidity sensor unit 2200, flame from the flame detection sensor, arc from the arc detector, dust concentration from the dust sensor 100, and carbon monoxide from the carbon monoxide detection sensor module. Concentration information is received.

The information analysis unit may analyze step-by-step risk level information upon receipt of at least one piece of information received from the information collection department, and then provide the risk level information along with each sensed information to the information provision department.

Here, the information analysis unit analyzes the space in which each sensed information occurs and builds a spatial database.

To this end, it is desirable for the information analysis unit to manage the installation space information within the IoT distribution board case for each sensor and the identification ID of the sensor with each space information.

Here, the information analysis unit creates a cumulative distribution according to the occurrence space for each sensed information when building a spatial database and sets the cumulative distribution as one area, and the distance between the occurrence spaces of each sensed information from the set area on the constructed spatial database If is relatively far, a strength integer inversely proportional to the distance is generated, the strength integer is applied to each received information to generate risk level information, and the average of the risk level information for each sensed information is calculated to determine the final Risk level information can be provided to the information provision department.

The information provision unit periodically transmits each detection information and final risk level information to the remote maintenance server through the network and stores it in the database of the remote maintenance server.

Meanwhile, in this embodiment, the name of the invention may be applied to an intelligent switchgear (high-voltage panel, low-voltage panel, motor control panel, distribution board) applying temperature and humidity / dust, arc / deterioration diagnosis / automatic monitoring and control functions.

As such, the present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and changes can be made without departing from the spirit and scope of the present invention. Accordingly, such modifications or variations should be considered to fall within the scope of the claims of the present invention.

1: Futuristic switchgear equipped with fire prevention functions through automatic dust removal and moisture temperature control
1000: Switchgear main body 2000: Temperature and humidity control unit
100: dust sensor 200: dust removal unit
210: fan unit 211: fan housing
212: exhaust fan 220: main pipe
230: branch pipe 240: filter member

Claims (3)

A temperature and humidity control unit provided in the switchboard main body to control the temperature and humidity inside the switchboard main body;
A dust sensor provided in the switchboard main body to detect dust inside the switchboard main body; and
A dust removal unit provided in the switchboard main body and operated based on a signal detected by the dust sensor to suck in dust inside the switchboard main body and discharge it to the outside of the switchboard main body,
The dust removal unit includes a fan unit provided on an upper portion of the main body; a main pipe provided at the upper part of the main body and communicating with the fan unit; a plurality of branch pipes branching from the main pipe and having one end disposed to the lower part of the first to fifth spaces of the switchgear main body to suck dust in the first to fifth spaces; and a plurality of filter members provided in the main pipe and the plurality of branch pipes to filter air flowing into the main pipe and the plurality of branch pipes, wherein the plurality of filter members include a photocatalytic filter,
The dust removal unit includes a plurality of extension pipes branched from the plurality of branch pipes and disposed in close proximity to each of the load switching unit, the instrument transformation unit, the vacuum interrupting unit, the air circuit breaker, and the surge absorbing unit arranged inside the switchgear main body; And it further includes a plurality of transfer fans provided in the main pipe and a plurality of branch pipes to help the flow of air transferred to the fan unit, wherein the temperature and humidity control unit includes first to fifth spaces of the switchgear main body. A temperature sensor unit provided in at least one space of the units to detect temperature; a humidity sensor unit provided in at least one of the first to fifth spaces to detect humidity; a thermoelectric element body provided on the outer wall of at least one of the first to fifth spaces; and a thermoelectric element unit provided inside the thermoelectric element body to generate heat or cooling energy, wherein the thermoelectric element unit includes a heat exchange block coupled to a partition wall provided inside the thermoelectric element body; a thermoelectric element member provided in front of the heat exchange block to generate heat or cooling energy; and a plurality of heat dissipation fins provided in front of the thermoelectric element member, wherein the temperature and humidity control unit is provided in the thermoelectric element body to be disposed in front of the thermoelectric element member to generate heat or cooling energy from the thermoelectric element member. a first blowing fan that blows air into at least one of the first to fifth spaces; and a second blowing fan provided in the thermoelectric element body to be disposed behind the heat exchange block and blowing heat generated in the heat exchange block to the outside of the thermoelectric element body, wherein the thermoelectric element body is connected to the switchgear body. It is detachably coupled, and the thermoelectric element body, the thermoelectric element unit, the first blower fan, and the second blower fan are provided as one unit, so that when the thermoelectric element body is separated from the switchboard main body, the thermoelectric element body, the first blower fan, and the thermoelectric element body are separated from the switchgear body. 1 The blowing fan and the second blowing fan are also separated, provided in the thermoelectric element body, and electrically connected to the thermoelectric element member, and change the direction of the current supplied to the thermoelectric element member to heat or cool the thermoelectric element member. A switchgear further comprising a transfer switch for generating energy. delete delete