KR102152451B1 - Temperrature control device for electrical switchboard - Google Patents

Abstract

Disclosed is an automatic exhaust control device for preventing overheating of a switchboard internal temperature, configured to rapidly and smoothly control the temperature of an interior of a switchboard by forcibly discharging the air inside the switchboard to the outside. According to the present invention, in the automatic exhaust control device for preventing overheating of a switchboard internal temperature, an exhaust port communicating with the inside of the switchboard is formed through each of an upper surface of a switchboard housing. An exhaust duct is provided inside a roof panel along the upper surface of the switchboard housing, has one end protruding toward the side of the roof panel, and has a plurality of inlets communicating with the exhaust port formed on a bottom surface.

Description

Automatic exhaust control device to prevent overheating inside the switchboard {TEMPERRATURE CONTROL DEVICE FOR ELECTRICAL SWITCHBOARD}

The present invention relates to an automatic exhaust control device for preventing overheating of the internal temperature of a switchboard, and more particularly, overheating of the internal temperature of a switchboard configured to rapidly and smoothly control the temperature of the interior of the switchboard by forcibly discharging the air inside the switchboard to the outside. It relates to a fire prevention automatic exhaust control device.

In general, the switchboard accommodates various power equipment such as circuit breakers and small generators and prevents them from being exposed to the outside.When installed indoors, it is formed into a small cabinet so that various power equipments are installed inside the cabinet. When the switchboard is installed outdoors, a roof is formed on the upper side of the switchboard to block rainwater from flowing into the switchboard to prevent a short circuit and fire due to flooding.

In addition, in the case of a switchboard installed outdoors, an access door 101 is formed on one side of the switchboard 100 as shown in FIG. 1 to allow an operator or manager to enter the switchboard directly, so that management is easy. In addition, various safety accidents caused by unauthorized people entering and exiting are prevented.

In addition, by forming an inclined roof 200 on the upper side of the switchboard 100, rainwater is smoothly flowing down the roof, and rainwater is prevented from entering the switchboard.

However, the conventional switchboard as described above generates a lot of heat during the operation of various power equipment installed inside, and the heat generated in this way is designed to escape to the outside of the walk-in switchboard by natural convection of air. Accordingly, there is a problem in that the cooling efficiency is deteriorated, causing a malfunction of the power equipment due to high temperature or reducing the operating efficiency.

In order to solve this problem, there have been cases where a general air conditioner such as an air conditioner is installed inside the power equipment, which not only consumes a lot of energy, but also provides a high cooling effect for multiple power equipment installed in a walk-in switchboard of a wide space. There was a problem that was difficult to have.

The present invention has been proposed to improve the above-described problems, and its object is to prevent overheating of the internal temperature of the switchboard by forcibly discharging the air inside the switchboard to the outside to quickly and smoothly control the temperature inside the switchboard. It is to provide a control device.

In addition, its object is to provide an automatic exhaust control device for preventing overheating of the internal temperature of a switchboard, which improves the efficiency of temperature control by allowing the blocking and amount of air discharged to the outside of the switchboard to be adjusted according to the indoor temperature inside the switchboard.

The above-described object is composed of a plurality of switchboard enclosures consisting of a plurality of outer wall panels and forming a space portion in which various power equipment is installed inside, and a plurality of roof panels that are coupled to the top of the switchboard enclosure to form a roof. Controls the indoor temperature of the switchboard, wherein an exhaust port communicating with the inside of the switchboard is formed through each of the upper surface of the switchboard box, and is provided along the upper surface of the switchboard box inside the roof panel, and one end protrudes to the side of the roof panel. However, an exhaust duct having a plurality of inlets communicating with the exhaust port is installed on the bottom surface, installed on the upper side of the roof panel, coupled to one end of the exhaust duct, and exhausting the air from the exhaust duct to the outside. A blower is configured to forcibly introduce the air inside the switchboard housing through an exhaust duct and discharge it to the outside through an exhaust blower to control the interior temperature of the switchboard. This is achieved by means of an exhaust control device.

Here, the inlet is provided by a plurality of inlet holes formed on the bottom of the exhaust duct, and the inlet hole of the exhaust duct controls the amount of air introduced from the switchboard housing to the exhaust duct by adjusting the opening and closing areas of the plurality of inlet holes. The air volume control member is installed, wherein the air volume control member is fitted with a rail formed at both ends of the plurality of inlet holes, and both ends of the rail are slidably fitted to the rail to move in the front and rear direction of the exhaust duct. It is preferable that it is composed of an air control plate configured to control the amount of air introduced into the inlet hole by adjusting the opening and closing area.

And, an automatic opening and closing means for automatically opening and closing the air control plate is further configured, wherein the automatic opening and closing means is engaged with a rack gear part formed on a side of the air control plate and a rack gear part of the air control plate to rotate forward and reverse. It comprises a pinion gear unit for selectively moving the air control plate in the front and rear direction of the exhaust duct by rotation, and a forward and reverse motor for providing power so that the pinion gear unit rotates forward and backward, and a temperature sensor in the switchboard enclosure Is installed and configured to check the temperature of the switchboard housing and transmit it to the control unit, the control unit is configured to selectively rotate the forward or reverse motor according to the temperature checked by the temperature sensor, and the air control plate is the forward and reverse motor It is configured to adjust the amount of air introduced into the inlet hole while sliding by the rotation of, it is preferable to be configured to maintain a constant indoor temperature of the switchboard housing.

In addition, when a plurality of the roof panels are connected to each other in the longitudinal direction, a sealing material is interposed between the roof panel and the roof panel, and the sealing material is formed by compression molding sodium bentonite and then blocking the circumferential surface with a net to have a certain dimension. It is manufactured with BWS (Bentonite Water Stop) processed so that the sealing material is sodium bentonite, 7.5% by weight of chloroprene rubber, 2.5% by weight of trans-1,2-ethylene dicarboxylic acid, and polyamide-amine It is preferable to further mix and mold 2.5% by weight and 2.5% by weight of cellulose diacetate.

The automatic exhaust control device for preventing overheating of the inside temperature of the switchboard according to the present invention is configured to reduce the temperature inside the switchboard by forcibly discharging the air inside the switchboard to the outside through the exhaust duct, thereby quickly reducing the indoor temperature of the switchboard. By smoothly adjusting, there is an effect that it is possible to prevent malfunction of power equipment or deterioration of operation efficiency in the switchboard due to high temperature.

1 is a view showing a conventional switchboard,
2 is a front view showing an automatic exhaust control device for preventing overheating of an internal temperature of a switchboard according to the present invention;
3 is a cross-sectional view of FIG. 2;
4A and 4B are views for explaining the air volume control member in the present invention,
Figures 5a and 5b are views for explaining the automatic opening and closing means in the present invention,
6 is a configuration diagram according to another preferred embodiment of the automatic exhaust control device for preventing overheating of the internal temperature of the switchboard according to the present invention,
7 is a view for explaining a sealing material in the automatic exhaust control device for preventing overheating of the internal temperature of the switchboard according to the present invention.

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

Prior to the description of the present invention, the following specific structure or functional descriptions are exemplified only for the purpose of describing embodiments according to the concept of the present invention, and embodiments according to the concept of the present invention may be implemented in various forms, It should not be construed as being limited to the embodiments described herein.

In addition, since embodiments according to the concept of the present invention can be modified in various ways and have various forms, specific embodiments are illustrated in the drawings and will be described in detail in the present specification. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific type of disclosure, and it should be understood that all modifications, equivalents, and substitutes included in the spirit and scope of the present invention are included.

The automatic exhaust control device for preventing overheating of the internal temperature of the switchboard according to the present invention is improved so that the indoor temperature of the switchboard 100 can be quickly and smoothly controlled by forcibly discharging the air inside the switchboard to the outside.

For example, as shown in Figs. 2 and 3, the automatic exhaust control device for preventing overheating of the internal temperature of the switchboard according to the present invention is composed of a plurality of outer wall panels 111, and a space part S ) Is configured to control the indoor temperature of the switchboard 100, which is formed of a plurality of switchboard enclosures 110, and is coupled to the upper portion of the switchboard enclosure 110 to form a roof panel 120 do.

Here, the switchboard housing 110 is formed in a box shape while a plurality of outer wall panels 111 formed in a certain standard are connected to each other, and an opening and closing door 112 is formed on the front so that the manager can easily manage the interior of the switchboard. At the same time, it is possible to safely protect various power equipment.

In addition, the roof panel 120 forms the roof of the switchboard 100, and a plurality of the roof panels 120 are coupled to the upper end of the switchboard housing 110 in the longitudinal direction to prevent the top surface of the switchboard 100 from being exposed to the outside. , Rainwater or snow flows into the interior of the switchboard 100, which is typically installed outdoors, to prevent a short circuit or short circuit in the power equipment.

In addition, exhaust ports 112 communicating with the inside of the switchboard box are respectively formed through the upper surface of the switchboard box 110.

That is, the exhaust port 112 is a passage through which the air inside the switchboard box 110 is discharged to the outside of the switchboard box.

And, the automatic exhaust control device for preventing overheating of the inside temperature of the switchboard according to the present invention is provided along the upper surface of the switchboard housing 110 inside the roof panel 120, and one end protrudes to the side of the roof panel, and the bottom surface is An exhaust duct 200 having a plurality of inlets 210 communicating with the exhaust port 112 is installed.

That is, the exhaust duct 200 is formed of a conventional piping material through which air flows, but one end is open and the other end is sealed, and the open end protrudes toward the side of the roof panel 120, and the exhaust port of the switchboard enclosure By allowing the internal air of the switchboard housing 110 discharged through 112 to flow into the inlet 210 of the exhaust duct, flow through the exhaust duct 200, and discharge to the outside of the roof panel 120, the switchboard enclosure ( 110) It is configured to allow rapid cooling of internal power equipment.

In addition, an exhaust blower 300 installed above the roof panel 120 and coupled to a part of the exhaust duct 200 to discharge air from the exhaust duct 200 to the outside is configured.

That is, the exhaust blower 300 is formed of a conventional fan that generates a flow of air, is coupled to one end of the exhaust duct 200 to the outside of the switchboard housing 110 through the exhaust duct 200. It is configured so that indoor air from the switchboard enclosure can be discharged smoothly.

Here, the exhaust blower 300 is shown in a form in which one end portion of the exhaust duct 200 is combined, but the number of switchboard enclosures 110 constituting the switchboard 100 and the size of the switchboard enclosure 110 Accordingly, it goes without saying that by allowing a plurality of the exhaust ducts 200 to be spaced apart from each other, the indoor air of the switchboard housing 110 can be quickly discharged.

Accordingly, the automatic exhaust control device for preventing overheating of the internal temperature of the switchboard according to the present invention transfers the internal air heated in the switchboard housing 110 by the operation of the power equipment through the exhaust port 112 and the inlet 210 to the exhaust duct 200. By forcibly inflowing into the furnace and discharging it to the outside through the exhaust blower 300, the indoor temperature of the switchboard 100 is lowered, so that the indoor temperature of the switchboard can be adjusted. Accordingly, it is possible to prevent malfunction of power equipment or deterioration of operating efficiency due to high temperature inside the switchboard 100.

On the other hand, according to the present invention, by adjusting the opening and closing area of the inlet 210 of the exhaust duct, it is configured to control the amount of air flowing into the exhaust duct 200 from the switchboard housing 110.

To this end, the inlet 210 is provided with a plurality of inlet holes 211 formed in the bottom surface of the exhaust duct 200.

In addition, an air volume control member 250 is installed in the inlet hole 211 of the exhaust duct to control the amount of air introduced into the exhaust duct 210 from the switchboard housing 110 by adjusting the opening and closing areas of the plurality of inlet holes. do.

More specifically, the air volume control member 250 is coupled to the rail 251 formed at both ends of the plurality of inlet holes 211, and the both ends of the rail 251 are slidably fitted to the exhaust duct. It is composed of an air control plate 252 configured to adjust the amount of air introduced into the inlet hole 211 by adjusting the opening and closing area of the inlet hole 211 while moving in the front and rear direction of 200.

With this configuration, as shown in FIG. 4A, when the internal temperature of the switchboard housing 110 is higher than the proper temperature, the air control plate 110 is discharged from the rail 252 to open and close the inlet hole 211 By increasing the area, a large amount of high-temperature air from the switchboard housing 110 is introduced into the exhaust duct 200, so that the internal temperature of the switchboard housing 110 can be lowered to an appropriate temperature.

And, as shown in FIG. 4B, when the internal temperature of the switchboard housing 110 is lower than the proper temperature, the air control plate 110 is slid to be closed by the rail 252 so that the opening and closing area of the inlet hole 211 is reduced. By making it narrower, a small amount of high-temperature air from the switchboard enclosure 110 is introduced into the exhaust duct 200 so that the internal temperature of the switchboard enclosure 110 can be increased to an appropriate temperature.

Furthermore, according to the present invention, as shown in FIGS. 5A and 5B, the air control plate 252 automatically slides through the automatic opening/closing means 270 so that the amount of air discharged from the switchboard housing 110 can be adjusted. It is desirable to be configured.

To this end, the automatic opening/closing means 270 is engaged with the rack gear part 271 formed on the side of the air control plate 252 and the rack gear part 271 of the air control plate by forward and reverse rotation. A pinion gear part 272 that selectively moves the air control plate 252 in the front and rear direction of the exhaust duct 200, and a forward and reverse motor 273 that provides power so that the pinion gear part 272 rotates forward and backward. ).

With this configuration, when the pinion gear portion 272 rotates by receiving the power of the forward and reverse motor 273, the rack gear portion 271 is moved forward and backward by the forward or reverse rotation of the pinion gear portion 272. As it moves, the air control plate 252 is moved to the front and rear of the exhaust duct 200. Accordingly, the opening and closing area of the inlet hole 251 is adjusted by the sliding of the air control plate 252 so that the amount of air discharged through the exhaust duct 200 is automatically adjusted.

Further, as shown in FIG. 6, a temperature sensor (S) is installed in the switchboard housing 110 to check the temperature of the switchboard housing 110 and transmit it to the control unit 291, and the control unit 291 ) Is configured to selectively rotate the forward or reverse motor 272 in the forward or reverse direction according to the temperature checked by the temperature sensor S. That is, the air control plate 252 is configured to adjust the amount of air introduced into the inlet hole 211 while sliding by the rotation of the forward and reverse motor 272, and maintain a constant indoor temperature of the switchboard housing 110 It is structured to be able to.

According to this configuration, when the temperature of the switchboard enclosure is higher than the proper temperature, the forward and reverse motor 273 automatically rotates in the forward direction, and the air control plate 252 is slid toward the rear side of the exhaust duct 200 to thereby the inlet hole 211 By increasing the opening and closing area of the switchboard housing 110, the internal air of the switchboard housing 110 is rapidly discharged through the exhaust duct 200, so that the indoor temperature of the switchboard housing 110 can be lowered to an appropriate temperature.

And, when the temperature of the switchboard enclosure is lower than the proper temperature, the forward and reverse motor 273 automatically rotates in the reverse direction and slides the air control plate 252 to the front side of the exhaust duct 200 so that the opening and closing area of the inlet hole 211 is reduced. By narrowing it, the internal air of the switchboard box 110 is slowly discharged through the exhaust duct 200, and the indoor temperature of the switchboard box 110 is increased to an appropriate temperature.

On the other hand, in the present invention, when a plurality of the roof panels are connected to each other along the length direction, as shown in FIG. 7, a sealing material 400 is interposed between the roof panel 120 and the roof panel 120 to provide a roof panel. It may be configured to prevent rainwater or snow flowing along the roof panel from flowing into the gap between the roof panel and the roof panel.

Here, the sealing material 400 is preferably BWS (Bentonite Water Stop, bentonite water expansion index material).

In addition, BWS can be used after compression-molding sodium bentonite with high expandability up to 16 times its volume when in contact with water, and then blocking the circumferential surface with a mesh to obtain a certain dimension.

Such BWS strengthens the sealing property at the interface due to its unique hydration expansion capability. For example, it expands rapidly upon contact with water and maintains perfect sealing property. Furthermore, it implements a self-sealing function that fills and seals the cracks and voids when there are cracks or voids generated at the interface while performing the primary water-stop function by hydration expansion.

In addition, the sealing material 400 is sodium bentonite to be molded is caking without changing the chemical properties, so to increase ductility, durability, and compression deformation, 7.5% by weight of chloroprene rubber in sodium bentonite, trans-1, It can be molded by further mixing 2.5% by weight of 2-ethylene dicarboxylic acid, 2.5% by weight of polyamide-amine, and 2.5% by weight of cellulose diacetate.

At this time, the chloroprene rubber is a hydrophilic polymer that improves moldability, improves deformability during compression, and has elasticity to prevent breakage during deformation, thereby reinforcing a perfect sealing function.

In addition, trans-1,2-ethylene dicarboxylic acid (C ₄ H ₄ O ₄ ) prevents agglomeration between particles, gives dispersion stability, and improves tensile strength and flexural strength to facilitate compression and deformation. have.

In addition, polyamideamine is added because it has an advantageous effect in enhancing the water-stop function while maintaining heat and cold resistance.

In addition, cellulose diacetate is added to improve tensile strength, flexural strength, and impact strength since it has a high glass transition temperature due to the pyranose rings constituting cellulose.

On the other hand, the exhaust duct 200 is configured to insulate vibration by coating a dustproof coating material on the outer surface. Here, as the anti-vibration coating material, polychloroprene, a high molecular compound made of a polymer of chloroprene, is used. The polychloroprene is a material having excellent durability, ozone resistance, heat resistance, and chemical resistance. Such a vibration-proof coating material is a material having excellent vibration-proof performance in a high frequency region, and effectively attenuates vibration, shock, and noise, and prevents excessive vibration, surge, and fluctuation, thereby enhancing an insulation effect.

In particular, the anti-vibration coating material has a fatigue limit in which elastic buffering force is lost due to deterioration due to repetitive contraction and expansion countless times when installed and used by the air discharged to the exhaust duct 200, and hardening due to heat generated during the elastic buffering action. Since there is a shortcoming, in order to solve this, 2.5% by weight of ammonium persulfate, 5.0% by weight of shungite powder, 2.5% by weight of boric acid, and 3.0% by weight of PEBAX (Polyether-block-amide) %, latex emulsion 4.0% by weight, silicone oil 0.2% by weight, polycarboxylic acid soda salt 4.5% by weight, morecurashix 2.5% by weight, rosin 1.5% by weight, and the remaining polychloroprene. desirable.

At this time, the ammonium persulfate is added to suppress thermal deformation by controlling the acidity to enhance oxidation resistance.

In addition, the sunzit is a natural mineral mainly containing silicate and fullerene, and is a powder of a mineral containing a large amount of fine graphite crystals.

These graphite microcrystals enhance heat resistance and reduce the coefficient of thermal expansion, thereby preventing the rubber component of the vibration-proof pad from deteriorating and a sudden decrease in fatigue strength caused by repeated flexing.

In addition, when purezit containing more than 60% of fullerene is used, fullerene, the third allotrope of carbon, blocks the growth and activity of bacteria such as fungi by its natural antioxidant activity, thus preventing contamination and preventing longevity. Very effective to achieve.

In addition, the boric acid is a salt of oxygen acid having boron as a central atom, and because it maintains very little deformation even under load and pressure due to enhanced oxidation resistance by bonding with graphite microcrystals, it suppresses deterioration and prevents deterioration at high temperatures. There is little deformation and chemically also increases corrosion resistance and abrasion resistance.

In addition, the PEBAX (Polyether-block-amide) has a small change in hardness even at low temperatures, has excellent fatigue resistance, and has excellent molding processability due to its low specific gravity, and has low hygroscopicity, resistance to bending fatigue, weather resistance, flexibility, creep resistance, and adhesion. It is added to enhance sex.

In addition, the latex emulsion is added to increase the softening point, increase the elongation, and increase the viscosity at high temperature to enhance heat resistance and abrasion resistance.

In addition, the silicone oil is added in a small amount to eliminate the problem because the latex emulsion is blended in an emulsion state, which may cause a problem of molding defects due to bubble generation.

In addition, the polycarboxylic acid sodium salt is a liquid high-performance dispersant, has excellent color tone and viscosity stability, and is added in the present invention to prevent molding defects such as pinhole generation and wrinkles due to non-uniform dispersion during molding.

In addition, the Molecular Sieves have strong hygroscopicity with adsorption capacity close to the saturation adsorption amount under extremely low partial pressure of water vapor, and sound insulation, sound absorption, and impact buffering by using the characteristics of a three-dimensional network pore crystal structure. It is added to strengthen.

In addition, the rosin is a pale yellow or brown transparent liquid that remains after removing turpentine by distilling rosin with water vapor. It adjusts the viscosity while enhancing the binding properties between components, increasing the dispersibility of latex emulsions, and binding during molding. It is added to increase power.

Finally, the polychloroprene is the base resin described above.

Deterioration resistance was tested for the sample of the exhaust duct coated with the dust-proof coating material thus formed. The test was conducted by applying a load of 2 kg to the sample, hitting the top of the sample with an impact bar rotating 15 revolutions per minute, and this process lasted for 2 months.

After 2 months, the deterioration on the surface of the sample, that is, whether hardening occurred, whether cracks occurred, and whether the elastic return force decreased was confirmed using a magnifying glass and a presser.

As a result of confirmation, hardening did not occur, the elastic return force was maintained in a normal state, there was no discoloration, and no cracks occurred.

100: switchboard 110: switchboard enclosure
120: roof panel 200: exhaust duct
300: exhaust blower

Claims (4)

The interior temperature of the switchboard consisting of a number of roof panels, which is composed of a number of outer wall panels and forms a space in which various power equipment is installed, is installed, and is combined with the upper part of the switchboard box to form a roof. As to control,
Exhaust ports communicating with the inside of the switchboard box are respectively formed through the upper surface of the switchboard box,
An exhaust duct is installed in the roof panel along the upper surface of the switchboard housing, and one end protrudes toward the side of the roof panel, and a plurality of inlets communicating with the exhaust port are formed on the bottom surface,
An exhaust blower installed on the upper side of the roof panel, coupled to one end of the exhaust duct, and configured to discharge air from the exhaust duct to the outside,
It is configured to forcibly introduce the internal air of the switchboard enclosure through an exhaust duct and discharge it to the outside through an exhaust blower to control the temperature of the interior of the switchboard,
When a plurality of the roof panels are connected to each other along the length direction, a sealing material is installed between the roof panel and the roof panel,
The sealing material is made of BWS (Bentonite Water Stop) processed to a certain dimension by compression molding sodium bentonite and blocking the circumference with a net mesh.The sealing material is sodium bentonite, 7.5% by weight of chloroprene rubber, and trans-1,2- It is formed by further mixing 2.5% by weight of ethylene dicarboxylic acid, 2.5% by weight of polyamide-amine, and 2.5% by weight of cellulose diacetate,
The exhaust duct is coated with a vibration-proof coating material on the outer surface to insulate vibration, and the vibration-proof coating material includes 2.5% by weight of ammonium persulfate, 5.0% by weight of suungite powder having a particle size of 0.5 μm, and 2.5% by weight of boric acid. Wow, PEBAX (Polyether-block-amide) 3.0% by weight, latex emulsion 4.0% by weight, silicone oil 0.2% by weight, polycarboxylic acid sodium salt 4.5% by weight, Morecuraxix 2.5% by weight, rosin 1.5% by weight % And the rest of the automatic exhaust control device to prevent overheating of the internal temperature of the switchboard, characterized in that molded from a composition consisting of polychloroprene.
The method of claim 1,
The inlet is provided with a plurality of inlet holes formed on the bottom surface of the exhaust duct,
In the inlet hole of the exhaust duct, an air volume control member for controlling the amount of air introduced from the switchboard housing to the exhaust duct by adjusting the opening and closing areas of the plurality of inlet holes is installed, wherein the air volume control member is at both sides of the plurality of inlet holes. A rail formed at the end, and an air control plate configured to control the amount of air introduced into the inlet hole by adjusting the opening and closing area of the inlet hole while moving in the front and rear direction of the exhaust duct by being slidably fitted to the rail at both ends Automatic exhaust control device to prevent overheating of the internal temperature of the switchboard, characterized in that consisting of.
The method of claim 2,
An automatic opening/closing means for automatically opening and closing the air control plate is further configured, wherein the automatic opening/closing means is engaged with a rack gear part formed on a side surface of the air control plate and a rack gear part of the air control plate to enable forward and reverse rotation. And a pinion gear unit for selectively moving the air control plate in the front and rear direction of the exhaust duct, and a forward and reverse motor for providing power so that the pinion gear unit rotates forward and backward,
A temperature sensor is installed in the switchboard enclosure to check the temperature of the switchboard enclosure and transmit it to the control unit, and the control unit is configured to selectively rotate the forward or reverse motor in a forward or reverse direction according to the temperature checked by the temperature sensor, and the The air control plate is configured to adjust the amount of air flowing into the inlet hole while sliding by the rotation of the forward and reverse motor, and is configured to maintain a constant indoor temperature of the switchboard housing. Device.

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