KR20190090586A - Temperature Rise Preventing Structure for Power Distribution System - Google Patents

Abstract

The present invention relates to a temperature rise preventing structure for an incoming and distributing panel, which converts power transmitted from a substation or the like into a commercial voltage, thereby preventing an enclosure of an incoming and distributing panel supplied to consumers or the like from being heated by direct rays of the sun and naturally discharging heat generated from the incoming and distributing panel. The temperature rise preventing structure comprises: an enclosure (10) having an opening portion formed in an upper end of the front surface thereof and having an incoming and distributing structure built therein; a support member (20) having an upper surface connected to the bottom surface of the enclosure (10) and a lower surface connected to a support structure to support the enclosure; and a door (30) installed in the enclosure (10) to be rotatable to open and close the opening portion of the enclosure (10) and having an observation window (35) on one side thereof. An insulating roof (40) shielding direct rays of the sun is installed on an upper portion of the enclosure (10). Vent holes (15) are formed in upper sides of both sides of the enclosure (10), respectively. In addition, a pair of waterproof caps (50) is installed to be spaced apart from the sides of the enclosure (10) so that the air smoothly moves through the vent holes (15) while rainwater is blocked from entering the vent holes (15).

Description

Temperature Rise Preventing Structure for Power Distribution System

The present invention relates to a temperature rise prevention structure of a switchgear for converting power transmitted from a substation or the like into a commercial voltage to prevent overheating of a switchgear for supplying to a consumer, and in particular, to prevent the housing of a switchgear from being heated by direct sunlight. The present invention relates to a structure for preventing temperature rise of a switchgear, which naturally discharges heat generated from the switchgear.

A switchgear is a power system that converts power transmitted from a power plant or substation into low voltage and distributes it to customers.

In particular, in order to obtain the electric power required by a group electric power source such as a school, a building, an apartment complex, a factory, etc., a switchgear for receiving an extra high voltage supplied from a substation and converting it into a commercially available low voltage commercial voltage is required.

The switchgear is made of a mold transformer for converting extra high pressure to low voltage in one closed enclosure, and a switchgear structure such as an instrument transformer, a fault zone automatic switch for switching a high-voltage inlet line, and a current-limiting high voltage fuse. In accordance with the power consumption of the consumer side, heat is generated in the high-pressure transformer, etc., causing the temperature inside the enclosure to rise.

Excessive increase in the internal temperature of the enclosure in the switchgear, the operating efficiency and accuracy of various components and devices, and may cause a fire, heat radiation is an important problem.

Accordingly, various methods for efficiently dissipating heat generated inside the switchgear have been proposed, and heat dissipation plates may be installed on the upper portion of the housing to dissipate heat from the switchgear. In this case, by enclosing the enclosure, it is possible to suppress the inflow of particulate dust in the switchboard, minimize the occurrence of cooling noise, and prevent condensation in the switchboard. However, the heat radiation plate alone does not provide sufficient heat dissipation.

In addition, by arranging the transformer unit in the lower part of the switchgear and providing an exhaust fan for discharging internal heat from the lower part to the upper part, heat may be released by using forced circulation of air. In the case of severe heat generation, a large fan may be operated outside the switchgear to lower the internal temperature of the switchgear.

However, when operating a large fan from the outside, when foreign matter such as dust enters the switchgear when the switchgear is opened, it may be attached to the internal structure, causing problems such as electric / electronic malfunction, causing an accident.

Meanwhile, as a result of examining the prior art related to the present invention, a number of patent documents have been searched, and some of them are introduced as follows.

Patent Literature 1 includes an enclosure base having an internal space, a plurality of cooling fans configured at an upper portion of the enclosure base and discharging internal air to the outside, and configured on one side surface of the enclosure base to open and close a color steel sheet. And compact laminating and heat-absorbing sound absorbers are sequentially stacked, and include a Calcom door attached through an adhesive therebetween, and the door is composed of a color steel plate and a compact laminating combination, thereby preventing external heat insulation and insulation to ensure safety and longevity of electrical equipment. Disclosed is a switchgear having a Calcom door to improve the efficiency.

Patent Literature 2 provides a discharge plate for discharging heat generated from the equipment to the outside by an upward airflow action and a moisture removing unit for removing moisture generated when the outside air is introduced into the switchboard. By applying a barrier paint to cut off the internal temperature of the enclosure as much as possible to extend the life and the number of internal devices generated by high heat, and to improve the efficiency of the switchboard, the switchboard and transformer enclosure, the outside air in the lower part of the enclosure A suction hole formed for suction, an air induction pipe provided at a position close to the suction hole, a discharge port for discharging heat generated by the device to the outside by the air induction pipe, and residual heat generated in the device. A heat sink having a jacket formed on the front and the top for releasing to the outside of the enclosure, and a support for supporting the enclosure from the ground; Disclosed are a male, a distribution board and a transformer housing with pedestals.

Patent document 3, the main body portion is the case insertion groove is formed so as to be variable in a sliding manner on the front surface of the upper end of the switchboard; A variable part inserted into the case insertion groove by a slide method and having a variable case formed of a reinforced acrylic plate on its entire surface; And a heat dissipation unit provided with a first ventilation fan at a front surface of the lower end of the distribution panel and discharging heat generated in the upper end and the lower end of the distribution panel to the outside, and having a second ventilation fan at the center of the distribution panel. The structure is designed as a separate type of upper and lower parts, and when the temperature inside the main body of the hybrid switchgear rises to a certain level, the internal heat is discharged to the outside by the operation of the fan and the operation of the switchboard. The variable part is slid to operate the opening and closing plate and the fan to provide the effect that the administrator does not have to check at any time, and the entire surface of the variable part is made of tempered plastic or tempered glass so that the manager can easily check the internal condition. Hybrid with detachable, variable heat dissipation to confirm status It discloses a switchboard.

KR 10-1032348 B1 KR 10-2011-0129309 A KR 10-1197428 B1

The present invention has been made to solve the above-described problems of the prior art, and suppresses the temperature rise inside the enclosure due to radiant heat from the sun, and uses the air flow due to the temperature difference between the inside and outside of the enclosure and the air flow due to the wind. It is an object of the present invention to provide a temperature rise prevention structure of a switchgear that enables the heat inside the enclosure to be naturally discharged to suppress the temperature rise inside the enclosure.

In addition, an object of the present invention is to provide a structure for preventing the temperature rise of the switchgear, which can prevent the rain water and the like flow into the interior of the enclosure to prevent abnormality in the switchgear structure.

In addition, an object of the present invention is to provide a structure for preventing the temperature rise of the switchgear so as to prevent foreign matter and fine dust from entering the interior of the enclosure during the flow of air to prevent abnormalities in the switchgear structure.

The present invention for achieving the above object is an opening is formed in the upper front and the housing is a water distribution structure is built; A support member having an upper surface connected to a bottom surface of the enclosure and a lower surface connected to a support structure to support the enclosure; In the switchgear including a door rotatably installed in the enclosure to open and close the front opening of the enclosure, one side of the switchgear, comprising a heat insulating roof for shielding direct sunlight on the upper portion of the enclosure, both sides of the enclosure Ventilation openings are formed on the upper sides of the sides, and a pair of waterproof caps are installed to be spaced apart from the side of the enclosure to a certain extent so that air flows smoothly while preventing rainwater from flowing into the ventilation openings.

In addition, according to the temperature rise prevention structure of the switchgear of the present invention, the insulating roof is projected to the front side than the housing, and characterized in that the upper surface is formed inclined downward toward the front side and the rear side, respectively.

In addition, according to the temperature rise prevention structure of the switchgear of the present invention, the insulating roof is characterized in that it is painted white.

In addition, according to the temperature rise prevention structure of the switchgear of the present invention, it is characterized in that the filter is provided in the vent.

In addition, according to the temperature rise prevention structure of the switchgear of the present invention, the door comprises a left door rotatably installed on the left side of the housing, and a right door rotatably installed on the right side of the housing and provided with a viewing window. It is done.

The temperature rise preventing structure of the switchgear according to the present invention can be prevented from rising in direct sunlight when the altitude of the sun is high as the heat insulation roof is formed on the enclosure of the switchgear, and the upper temperature of the enclosure, respectively on both sides of the enclosure As the vents are formed, heat inside the enclosure is easily released to the outside, and the air inside and outside the enclosure naturally circulates to cool the inside of the enclosure, thereby reducing the internal temperature of the switchboard.

In addition, as the insulation roof protrudes forward from the enclosure, rainwater does not flow into the gap between the enclosure and the door, and the water distribution structure of the interior can be prevented from malfunctioning or being damaged by moisture. As the upper surface is formed as an inclined surface, rain water is accumulated or snow is accumulated, as well as an air layer is formed inside the insulation roof, thereby improving heat insulation performance.

In addition, as the insulating roof is painted in white, sunlight is reflected to prevent heat from being accumulated in the insulating roof.

In addition, the filter is installed in the ventilation holes formed on both sides of the enclosure, so that foreign matter and fine dust do not flow into the interior of the enclosure, preventing malfunction and equipment damage as well as the occurrence of fire as well as equipment malfunction caused by the absorption of fine dust into the power distribution structure. It is effective.

In addition, by installing a lifting ring such as an eye bolt on the insulation roof to lift the entire switchgear, there is an effect that the installation work of the switchgear becomes easy.

1 is an external perspective view of a switchgear to which the temperature rise preventing structure according to the present invention is applied.
Figure 2 is an exploded perspective view of the switchgear according to the present invention.
Figure 3 is a front view of the switchgear according to the present invention.
Figure 4 is a side view of the switchgear according to the present invention.
5 is a bottom view of a switchgear according to the present invention;

Hereinafter, the temperature rise prevention structure of the switchgear of the present invention with reference to the accompanying drawings.

The temperature rise prevention structure of the switchgear according to the present invention, as shown in Figures 1 to 5, the opening 10 is formed in the top of the front and the housing 10, the water distribution structure is built; A support member 20 having an upper surface connected to a bottom surface of the enclosure 10 and a lower surface connected to a support structure to support the enclosure; The door 30 is rotatably installed in the enclosure 10 to open and close the front opening of the enclosure 10 and has a viewing window 35 on one side. Insulating roof 40 to shield direct sunlight is installed on the upper part of the), while the ventilation openings 15 are formed on the upper sides of both sides of the enclosure 10, and the rainwater is prevented from entering the ventilation openings 15, respectively. A pair of waterproof caps 50 are installed to be spaced apart from the side of the enclosure 10 to smoothly move the air.

Accordingly, the heat insulation roof 40 blocks the direct sunlight of the high temperature falling on the upper surface of the enclosure 10 between 11 o'clock and 3 o'clock when the sun is at high altitude, and the enclosure 10 is exposed to the sun's direct sunlight. It is possible to prevent the internal temperature of) from rising.

In addition, heat generated in the water distribution structure located inside the enclosure 10 is released through the pair of vents 15 to prevent the internal temperature of the enclosure 10 from rising. In particular, when the wind blows through the air inlet through one side vent 15, the air is discharged through the other side vent 15 to discharge the heat accumulated in the interior of the enclosure 10 is further improved heat dissipation effect. As the waterproof cap 50 is installed at the front of the vent 15, snow or rain water does not flow into the enclosure 10 through the vent 15 when snow or rain falls.

The insulation roof 40 is protruded toward the front side compared to the housing 10, it is preferable that the upper surface is formed to be inclined downward toward the front side and the rear side, respectively. At this time, the inclination of the front side is formed rapidly and the inclination of the rear side is formed gently. Accordingly, it is possible to prevent rainwater from flowing into the gap between the enclosure 10 and the door 30, as well as to prevent rainwater from accumulating on the upper surface of the insulation roof 40 or snow accumulation. In addition, an air layer is formed inside the insulation roof 40 to prevent heat from being conducted between the insulation roof 40 and the upper surface of the enclosure 10. In addition, the insulating roof 40 is more preferably painted white. Accordingly, the direct sunlight of the sun is reflected by the insulating roof 40 to prevent the temperature rise of the insulating roof 40.

In addition, the insulating roof 40 is preferably provided with a lifting ring for the lifting, the lifting ring is more preferably installed to correspond to each other on both sides in the longitudinal direction of the insulating roof (40). At this time, an eye bolt 45 is used as the lifting ring. Accordingly, by hooking the hook member of the crane to the eye bolt 45, it is possible to lift and move the entire switchgear including the insulation roof 40, the housing 10 and the support member 20, and then move.

On the other hand, the ventilation hole 15 is preferably provided with a filter for preventing the inflow of dust. In this case, the filter 16 may be a HEPA filter (high efficiency particulate air filter). Hepa filter is a filter that can remove fine particles, can remove more than 99.7% of the fine particles or bacteria serves to block the contamination by bacteria or dust. Therefore, when the air is introduced into the interior of the housing 10 by the wind, it is possible to prevent the dust is introduced together to adversely affect the water distribution structure.

The door 30 includes a left door 31 rotatably installed on the left side of the housing 10 and a right door rotatably installed on the right side of the housing 10 and provided with an observation window 35. It is preferable that it consists of (32). At this time, the left door 31 is more preferably formed smaller than the right door 32.

The temperature rise prevention structure of the switchgear of the present invention configured as described above is to suppress the increase in the internal temperature of the switchgear using a heat insulating roof and a pair of vents.

The insulating roof 40 is positioned on the upper part of the enclosure 10 to block direct sunlight from the sun between 11 and 3 o'clock when the sun is at a high altitude, thereby preventing the upper part of the enclosure 10 from being heated and the front. Rainwater or snow flows down by using the inclined surface of the rear and the rear surface to suppress the temperature rise of the enclosure and block water from entering the interior of the enclosure 10.

Then, the heat generated as the water distribution structure inside the enclosure 10 is operated is discharged to the outside through the vents 15 located on both sides of the enclosure, the outside air through the vents 15 the enclosure 10 The internal temperature is lowered by entering and circulating inside. In particular, when the wind blows, the air introduced through the one vent 15 exits the other vent 15 to cool the inside of the enclosure 10.

At this time, since the filter 16 is installed in the ventilation hole 15, foreign matter or fine dust or the like is introduced into the enclosure 10 in a filtered state by the filter 16. Therefore, the water distribution structure inside the enclosure 10 is not contaminated by dust or the like, and malfunction or fire of the water distribution structure generated by adsorption of dust or the like is prevented.

As described above and described with reference to some embodiments for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as described above, it deviates from the scope of the technical idea described in the specification Those skilled in the art will appreciate that many modifications and variations can be made to the present invention without departing from the scope of the invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

10 ... enclosure
15 ... Vent
16 ... filter
20.Support member
30 ... door
31.Left door
32.Right door
35.Observation window
40.Insulation roof
45 ... eye bolt
50 ... waterproof plate

Claims (5)

An enclosure formed at an upper end of the front surface and having a water distribution structure;
A support member 20 having an upper surface connected to a bottom surface of the enclosure 10 and a lower surface connected to a support structure to support the enclosure 10;
In the switchgear comprising a; door 30 is rotatably installed in the enclosure 10 to open and close the front opening of the enclosure 10, the observation window 35 is provided on one side;
An insulating roof 40 is installed on the enclosure 10 to shield direct sunlight.
Ventilation holes 15 are formed on upper sides of both sides of the enclosure 10, and
The temperature rise of the switchgear, characterized in that a pair of waterproof cap 50 is installed to be spaced apart from the side of the enclosure 10 to prevent the rain water flowing into the ventilation hole 15 to move smoothly. Resistant structure.
The method of claim 1,
The insulation roof 40 is protruded to the front side compared with the housing 10,
The upper surface of the switchgear, characterized in that formed inclined downward toward the front and rear, respectively.
The method of claim 1,
The insulation roof 40 is a temperature rise prevention structure of the switchgear, characterized in that painted in white.
The method of claim 1,
The filter 16 is installed in the ventilation hole 15, the temperature rise prevention structure of the switchgear.
5. The method according to any one of claims 1 to 4,
The door 30 has a left door 31 rotatably installed on the left side of the housing 10 and a right door 32 rotatably installed on the right side of the housing 10 and provided with an observation window 35. Temperature rise prevention structure of the switchgear, characterized in that consisting of.

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