KR20210104524A - Outdoor power electric switchgear having self convective heat transfer - Google Patents

Abstract

The present invention relates to an outdoor self-convective switchgear device, capable of natural exhaust, which comprises: first and second vertical partition plates (12a, 12); a self-convective heat emitting unit (6) between the first and second vertical partition plates; and a rainwater blocking step (5) for blocking raindrops.

Description

Self-convection switchgear for outdoor use with natural exhaust {OUTDOOR POWER ELECTRIC SWITCHGEAR HAVING SELF CONVECTIVE HEAT TRANSFER}

The present invention relates to an outdoor switchgear, and in particular, heat generated inside an outdoor switchgear can be naturally discharged to the outside using natural convection without forced exhaust using a power source, and at the same time, it can be used in an external environment under adverse conditions such as rain or wind. It relates to an improvement of an outdoor self-convection switchgear device that enables the components provided inside the enclosure to be safely protected.

In general, water substation facilities supply stable power to factories and rooms, and play an important role in securing power for production facilities, information processing, security, and disaster prevention. Accordingly, improving the performance and reliability of the water substation facility has become an essential task.

In the case of large-capacity electric switchgear, the efficiency is lowered by increasing the electrical resistance coefficient of each device and conductor due to the high heat inside the panel.

The switchboard provided to distribute and control large-capacity external power to internal power demand places such as schools, buildings, apartment complexes, factories, etc. bar) to supply power to each element indoors and outdoors, and at the same time, it is responsible for opening and closing the supply power.

These switchgears and control panels are built in cabinets of a certain size or larger, and since they are an assembly of electrical devices that generate a lot of heat, such as transformers, reactors, semiconductor devices, inverters, and large-capacity capacitors, the heat dissipation means must be taken.

In particular, in the case of an outdoor switchgear, the external environment such as excessive exposure from the sun, rainwater intrusion, and dew condensation is severe, so protection against it must be better.

Since the enclosure of the outdoor switchgear is mostly made of iron plates, excessive temperature rise in the enclosure caused by solar radiation and self-heating from the components installed inside the panel reduces the efficiency and performance of the devices in the panel and can lead to major accidents such as device damage. can

As one of the heat dissipation means of the outdoor switchgear, the forced blowing method using a motor fan is used. This forced blowing method operates when the internal temperature of the motor fan reaches a constant temperature (about 40℃), and the internal temperature of the panel is the same. In the case below, the heat is retained in the panel as it is, which may interfere with the normal operation of the devices in the panel and lower the reliability of the lifespan of each part. Moreover, if the motor fan breaks down, the internal temperature of the panel rises excessively and the electrical resistance coefficient of each device and conductor inside is greatly increased, which reduces the operating efficiency and may lead to burnout or fire accidents.

Existing forced blow method requires a lot of installation cost because parts such as thermometer, temperature sensor, motor circuit breaker, auxiliary relay must be additionally mounted and connected to install the motor fan. It is an environment that cannot be checked. In addition, motor fans exposed to harsh external environments such as winter or summer shorten their lifespan, and when they fail, the outdoor switchgear needs to be turned off for repair, which causes problems in ensuring the reliability of the outdoor switchgear.

In addition, when the motor fan is not operating, rainwater may penetrate into the inside of the panel through the exhaust passage. A high-voltage device may be damaged.

Therefore, effective countermeasures against this are required.

Public Utility Model No. 20-2009-0006608 "Exhaust structure of switchboard"

Therefore, it is an object of the present invention to naturally discharge the heat generated inside the outdoor switchgear housing using natural convection without forced exhaust using a power source, and at the same time, even in adverse external environments such as rain or wind, it is provided inside the housing. An object of the present invention is to provide an outdoor self-convection switchgear device that allows components to be safely protected.

Another object of the present invention is to prevent internal penetration of rain, etc. or to minimize the internal condensation phenomenon due to the temperature difference between the inside and outside of the enclosure, and also to facilitate the installation workability of the self-convection heat dissipation unit. is to provide.

The present invention according to the above object, in the self-convection switchgear device for outdoor use capable of natural exhaust, the first and second roof sloping plates installed above the upper portion of the outdoor enclosure (2) to which the insulator (18) and the bus bar (19) are mounted (4a) and (4b) constitute a sloping roof (4) having a gable portion,

The gable portion of the sloping roof 4 is provided with a first vertical partition plate 12a extending up and down with respect to the tangent line 10 with the first roof sloping plate 4a, and a tangent line with the second roof sloping plate 4b. A self-convection heat dissipation unit having a second vertical partition plate 12 extending up and down with reference to (10) and having an open lower heat collecting space 22 between the first and second vertical partition plates 12b (6), but the inner surface of the roof sloping plate (4a) (4b) in the lower extension plate portion of the tangent line (10) of the first and second vertical partition plates (12a, 12b) of the self-convection heat dissipation unit (6) Convection heat inlet holes 14 that allow the convection heat from the inside of the enclosure that climbed the provided convection heat induction ramp 9 to pass through and flow into the heat collecting space 22 are arranged and formed, and the roof slope plates 4a and 4b ) The first and second vertical partition plates (12a, 12b) protruding above the tangent line (10) upper extension plate portion, the convection heat passing through the hole 16 through which the convective heat retained in the heat collecting space (22) is discharged are arranged. to be formed,

The heat collecting space 22 and the first and second vertical partition plates 12a and 12b are supported on the upper ends of the first and second vertical partition plates 12a and 12b of the self-convection heat dissipation unit 6 . A cover casing 20 is provided to cover the cover casing 20, and steeply inclined bent plate portions 20a are formed on both edges of the main plate portion of the cover casing 20, so that the edge of the cover casing 20 including the steeply inclined bent plate portion 20a and the first, first The heat exhaust acceleration space 50 communicating with the convection heat passing through holes 16 by the upper extension plate portions of the second partition plates 12a and 12b and the first and second roof sloping plates 4a and 4b is provided. The passage of the heat exhaust acceleration space 50 is narrowed by the steeply inclined bending plate portion 20a, so that the bottleneck exhaust gap 23 is formed so that the heat exhaust airflow is accelerated to the outside of the enclosure,

In the heat dissipation acceleration space 50 of the self-convection heat dissipation unit 6, a rainwater blocking sill 5 that blocks rainwater droplets splashing into the inner space through the bottleneck discharge gap 23 is provided with a gable-side roof sloping plate 4a. ) (4b) characterized in that the end is bent and formed by horizontal extension.

The present invention can naturally discharge heat generated inside an outdoor switchgear box without forced exhaust using a power source using natural convection phenomenon, and at the same time, even in adverse external environments such as rain or wind, the components provided inside the enclosure It allows for safe protection, prevents internal penetration of rain, etc., and prevents dew condensation in the interior due to temperature difference between the inside and outside of the enclosure.

1 is an exterior perspective configuration diagram of a self-convection switchgear device for outdoor use according to an embodiment of the present invention;
Figure 2 is a schematic cross-sectional configuration diagram showing the operating principle of the outdoor self-convection switchboard device according to an embodiment of the present invention;
3 is a separate perspective configuration diagram of a self-convection heat dissipation unit installed in a gable portion of a sloped roof and a sloped roof according to the present invention;
4 is a cross-sectional view of the main part of the self-convection heat dissipation unit installed in the gable part of the inclined roof and the inclined roof according to the present invention;
Fig. 5 is an enlarged view of a portion indicated by a dotted line circle indicated by "A" in Fig. 4;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this specification, outdoor switchgear includes transformer switchgear, starter board, inverter switchgear, solar inverter switchgear, etc., and outdoor enclosures (cubicles) for water supply facilities, road construction related facilities, solar power generation facilities, wind power generation facilities, shipyard facilities, etc. A lot of this is installed.

The sloping roof structure configured in the outdoor switchgear implemented in the present invention and the self-convection heat dissipation unit installed extending to the left and right ends in the gable part of the sloping roof are the heat generated inside the switchboard housing and the heat transmitted from the outside, such as radiant heat from the sun, to the motor. It is a means to easily discharge to the outside by using natural convection without a separate power source such as a fan. At the same time, it is a means to prevent internal penetration of rain, etc. or to prevent dew condensation in the interior due to the temperature difference between the inside and outside of the enclosure, and to facilitate the installation workability of the self-convection heat dissipation unit.

1 is an external perspective configuration diagram of an outdoor self-convection switchgear device according to an embodiment of the present invention, and FIG. 2 is a schematic cross-sectional configuration diagram showing the operating principle of an outdoor self-convection switchgear device according to an embodiment of the present invention.

1 and 2, the inclined roof 4 installed on the upper portion of the outdoor enclosure 2 of the outdoor self-convection switchboard device according to the embodiment of the present invention is press-processed using a very long through-iron plate as it is in one direction. Unlike the existing outdoor roof type that has a bay slope, two roof sloping plates, i.e., the first and second roof sloping plates (4a) (4b), are made by cutting and pressing two through steel plates for the convenience of production by workers. makes

And the first and second roof sloping plates (4a, 4b) and the self-convection heat dissipation unit (6) of the gable part are assembled together to form the housing roof.

In the present invention, the sloped roof 4 made of the first and second roof slope plates 4a and 4b cut in two not only plays a role in letting rainwater run down when it rains, but also the first and second roof slope plates ( Each inner surface of 4a)(4b) also serves as a convective heat induction ramp 9 provided directly.

The first and second roof sloping plates 4a and 4b constituting the inclined roof 4 have an inclination range of 1° to 30°. If the slope of the roof slope plates (4a, 4b) is too low, it is difficult for rainwater to flow down the sloped roof surface, and the self-convection heat dissipation unit (6) is installed on the upper side of the outdoor enclosure (2). When the inclination is too high, it is difficult to bend with a large bending molding machine, so workability is reduced, and the height of the completed outdoor enclosure (2) becomes unnecessarily high. Significant difficulties in transportation may occur, such as being caught in the height limit of road passage.

The first and second roof sloping plates 4a and 4b of the inclined roof 4 are formed to face the opening and closing doors 40 of the front and rear of the outdoor enclosure 2, and are configured to have eaves.

According to the present invention, the first and second roof sloping plates 4a and 4b of the sloping roof 4 are preferably arranged symmetrically with each other as shown in FIGS. 1 and 2, but it is understood that an asymmetrical form is also possible. shall.

In the present invention, a self-convection heat dissipation unit in the gable part of the inclined roof 4, where the heat flow can rise the highest, so that natural exhaust is possible and prevents condensation or penetration of rainwater in a harsh environment. (6) is configured to be installed across the left and right ends of the hull.

As shown in FIG. 2, the magnetic convection heat dissipation unit 6 of the present invention is located so that the heat generated in the inner chamber 8 is extended from the center of the inner chamber to the left and right ends due to natural convection, and the lower open heat collecting space ( 22) as well as the convective heat rising from the side of the inner chamber is convective heat induction provided by each inner surface of the roof sloping plates 4a and 4b on both sides, and even the convective heat rising on the inclined inner surface 9. ), and the heat exhaust airflow converged in the heat collecting space 22 is accelerated so that it is quickly discharged to the outside of the outdoor enclosure (2).

In addition, the self-convection heat dissipation unit 6 promotes continuous natural convection to occur in the inner chamber 8, thereby eliminating the dew condensation that occurs mainly in the inner chamber 8 in winter, when there is a large temperature difference. In particular, prevent the dew condensation from falling on the ceiling of the roof to damage the high-voltage equipment inside the enclosure.

3 is an exploded perspective view of the sloping roof 4 and the self-convection heat dissipation unit 6 installed in the gable of the sloping roof 4 according to the present invention, and FIG. 4 is the sloping roof 4 according to the present invention. And it is a cross-sectional configuration view of the main part of the self-convection heat dissipation unit 6 installed in the gable part of the inclined roof 4, and FIG. 5 is an enlarged view of the dotted circle part indicated by "A" in FIG.

The self-convection heat dissipation unit 6 disposed in the gable portion of the sloped roof 4 and the sloped roof 4 according to the present invention is an insulator 18 or busbar 19 installed on the upper side in the outdoor enclosure 2 It is installed on top of it so that it does not touch at all.

That is, as shown in FIGS. 4 and 5, the transverse barrier 24 installed on the upper side of the side wall 26 of the outdoor enclosure 2 to support the self-convection heat dissipation unit 6 is the outdoor enclosure ( 2) It is located above the insulator support (60) installed on the upper side of the inner side. In addition, the lowest point of the self-convection heat dissipation unit (6) is located higher than the lowest point of the inclined roof (4).

The structure of the sloping roof 4 and the gable-side self-convection heat dissipation unit 6 of the present invention is easy to install on the outdoor enclosure 2 in the new outdoor switchboard, but only the roof is removed from the existing outdoor enclosure. It is also very useful for installation and replacement.

The configuration and function of the self-convection heat dissipation unit 6 installed on the gable side of the inclined roof 4 will be described in detail with reference again to FIGS. 3 to 5 .

The self-convection heat dissipation unit 6 of the present invention is disposed in the gable part, some of which are immersed under the first and second roof sloping plates 4a and 4b, and other parts are the first and second roof sloping plates 4a. ) (4b) has a structure that protrudes above it. In addition, the self-convection heat dissipation unit 6 of the present invention includes first and second vertical partition plates 12a and 12b in order to provide a heat collecting space 22 for collecting hot air by natural convection in the gable. be prepared

More specifically, the gable portion of the sloping roof 4 is provided with a first vertical partition plate 12a extending up and down with respect to the tangent line 10 with the first roof sloping plate 4a, and a second roof sloping plate. A heat collecting space 22 having an open lower portion between the first and second vertical partition plates 12b by having a second vertical partition plate 12 vertically extended based on the tangent line 10 to (4b) is provided. make it available

In addition, in the extension plate below the tangent line 10 of the first and second vertical partition plates 12a and 12b of the self-convection heat dissipation unit 6, the inner surface of the roof sloping plate 4a, 4b induces convection heat allowed. Convection heat inlet holes 14 that allow the convection heat inside the enclosure that climbed up the ramp 9 to pass through and flow into the heat collecting space 22 are arranged and formed, and the first protruding above the roof sloping plates 4a and 4b In the upper extension plate portion of the tangent line 10 of the first and second vertical partition plates 12a and 12b, the convection heat passing hole 16 having a smaller unit area than the convective heat inlet large hole 14 retained in the heat collecting space 22 ) to form an array.

In addition, the self-convection heat dissipation unit 6 is supported on the upper end of the first and second vertical partition plates 12a and 12b, so that the heat collecting space 22 and the first and second vertical partition plates 12a and 12b are supported. ) is provided with a cover casing 20 that sufficiently covers.

Furthermore, the cover casing 20 has a flat plate-type main plate portion, and steeply inclined bent plate portions 20a are extended on both edges of the main plate portion to form a steeply inclined bent plate portion 20a. The edge of the cover casing 20 and the first , Convection heat passing through holes 16 of the heat collecting space 22 by the upper extension plate portion of the second partition plates 12a and 12b and the first and second roof sloping plates 4a and 4b and the outside of the enclosure A heat dissipation acceleration space 50 communicating with each other is provided.

In the heat exhaust acceleration space 50, the passage of the heat exhaust acceleration space 50 is narrowed by the steeply inclined bending plate portion 20a, and a bottleneck exhaust gap 23 is formed so that the heat exhaust airflow is accelerated.

In addition, as can be seen in detail in FIG. 5 in the heat dissipation acceleration space 50 of the self-convection heat dissipation unit 6, the rainwater 66 hits the first and second roof sloping plates 4a and 4b and discharges the bottleneck. The rainwater blocking sill 5 that blocks rainwater droplets splashing into the inner space through the gap 23 is formed by bending and horizontally extending the gable side ends of the roof swash plates 4a and 4b.

Therefore, in the outdoor self-convection switchgear device capable of natural exhaust according to the present invention, the heat caused by the operation of the appliance heating element 42 of the instrument transformer, instrument current transformer, transformer, load switchgear, etc. installed in the inner chamber 8 of the switchgear However, internal heat transferred by external radiant heat from the sun 44 exists in the inner chamber 8, and the heat in the inner chamber 8 rises by natural convection, but the self-convection heat dissipation unit on the gable side Each convective heat provided by convection heat directly converges to the heat collecting space 22 through the lower opening of (6) and collides with the inner surfaces of the first and second roof sloping plates 4a and 4b of the inclined roof 4 It is gradually ascended on the induction inclined inner surface (9) and passes through the convection heat inlet hole (14) of the first and second vertical partition plates (12) of the self-convection heat dissipation unit (6) in the gable part to collect heat. (22) is converged.

The heat flow converged in the heat collecting space 22 of the self-convection heat dissipation unit 6 by natural convection is indirectly communicated with the outside of the outdoor enclosure 2, and the first, The second vertical partition plates 12a and 12b pass through the convective heat passing through holes 16 formed in the upper extension plate portion of the tangent line 10 and are moved to the heat exhaust acceleration space 50 .

The heat dissipation acceleration space portion 50 is gradually narrowed in the passage of the heat dissipation acceleration space portion 50 by the steeply inclined bent plate portion 20a, and due to the bottleneck discharge gap 23 directly connected to the outside of the outdoor enclosure 2 Since the heat exhaust airflow is accelerated, the heat exhaust airflow introduced into the heat exhaust acceleration space 50 quickly escapes to the outside through the bottleneck exhaust gap 23 due to the Bernoulli effect.

In the drawings of the present invention, the convection heat passing through holes 16 located at the upper ends of the first and second partition plates 12a and 12b are exemplified that horizontal slit holes are arranged in two rows horizontally to serve as an insect screen, The vertical slit balls or the diagonal slit balls may be arranged horizontally in one row, and the perforations may be formed in a shape selected from among circular, oval, and prismatic shapes.

In addition, in the present invention, if the principle of the self-convection heat dissipation unit 6 is to block rainwater, the external rainwater hitting the first and second roof sloping plates 4a and 4b of the inclined roof 4 is primarily It is blocked by the steeply inclined bent plate part 20a and the bottleneck exhaust gap 23 on both edges of the main plate part of the cover casing 20, and the inflow is further suppressed by the airflow blowing from the heat exhaust acceleration space part 50, , even if raindrops penetrate into the heat discharge acceleration space 50, the heat convergence discharge unit ( 6), it is practically difficult for rainwater to penetrate into the interior of the enclosure.

On the other hand, in the present invention, not only the self-convection heat dissipation is made through the self-convection heat dissipation unit 6 on the gable side of the inclined roof 4, but also the side wall portion 26 of the outdoor enclosure 2 is located at the upper end. The exhaust can also be exhausted through the exhaust passage.

That is, the sidewall exhaust hole 28 at the upper end of the sidewall portion 26 of the enclosure 2 is formed, and the raindrop prevention eaves casing 30 is extended downstream of the roof swash plate 4a and 4b. Raindrop prevention eave casing 30 is a means for preventing the rainwater 46 from entering the inner chamber 8 through the exhaust passage, and the lower bottom surface of the raindrop prevention eave casing 30 is stepped, but relatively to the outside. to form a low water cut-off stair step 34, and a lower exhaust hole 32 communicating with the side wall exhaust hole 28 is formed on the inner side of the bottom surface. Therefore, by the water cut-off stairway 34, rainwater rides on the eaves and prevents infiltration into the inner chamber of the outdoor enclosure (2).

Although specific embodiments have been described in the above description of the present invention, various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be defined by the claims and equivalents to the claims.

The present invention can be used to easily discharge heat generated inside the switchgear to the outside using natural convection without a separate power source.

(2)-- Outdoor enclosure (4)-- Sloped roof
(4a)(4b)-- 1st, 2nd roof sloping plate (5)-- Rainwater sill
(6)-- Magnetic convection heat dissipation unit (8)-- Enclosure interior
(9)-- Convection heat induction ramp (10)-- Tangent
(12a)(12b)-- 1st, 2nd vertical partition plate (14)-- Convection heat inflow anti-aircraft
(16)-- Convection Heat Pass Through Hole (18)-- Insulator
(19)-- Busbar (20)-- Cover casing
(20a)-- Slope bent plate part (22)-- Heat collecting space part
(23)-- Bottleneck exhaust gap (24)-- Horizontal frame
(26)-- side wall part (28)-- side wall exhaust hole
(30)-- Raindrop prevention eaves casing (32)-- Lower exhaust hole
(34)-- Water cut-off stair sill (40)-- Opening and closing door
(42)-- Appliance Heating Element (44)-- Solar
(46)- Rain Stream (50)-- Heat Discharge Acceleration Space Part

Claims (1)

In the outdoor self-convection switchgear device capable of natural exhaust,
A sloped roof 4 having a gable portion is constructed by the first and second roof slope plates 4a and 4b installed above the upper side of the outdoor enclosure 2 to which the insulator 18 and the bus bar 19 are attached,
The gable portion of the sloping roof 4 is provided with a first vertical partition plate 12a extending up and down based on the tangent line 10 with the first roof sloping plate 4a, and a tangent line with the second roof sloping plate 4b. A self-convection heat dissipation unit having a second vertical partition plate 12 extending up and down with reference to (10) and having an open lower heat collecting space 22 between the first and second vertical partition plates 12b (6) constitutes,
Convection heat induction ramp ( 9) The convective heat inlet holes 14 that allow the convection heat inside the enclosure to pass through and flow into the heat collecting space 22 are arranged and formed, and the first, The second vertical partition plates (12a) and (12b), the tangent line (10) upper extension plate portion is configured to form an array of convection heat passing residual holes (16) through which the convective heat retained in the heat collecting space (22) is discharged,
It is supported on the upper end of the first and second vertical partition plates 12a and 12b of the self-convection heat dissipation unit 6 to separate the heat collecting space 22 and the first and second vertical partition plates 12a and 12b. A cover casing 20 is provided to cover the cover casing 20, and steeply inclined bent plate portions 20a are formed on both edges of the main plate portion of the cover casing 20, so that the edge of the cover casing 20 including the steeply inclined bent plate portion 20a and the first, first 2 The upper extension plate of the partition plates 12a and 12b and the first and second roof sloping plates 4a and 4b are configured to provide the heat exhaust acceleration space 50, and are formed by the steeply inclined bending plate portion 20a. The passage of the heat exhaust acceleration space 50 is narrowed so that the bottleneck exhaust gap 23 is formed so that the heat exhaust airflow of the heat exhaust acceleration space 50 that has passed through the convection heat passing hole 16 is accelerated to the outside of the enclosure. make up,
In the heat dissipation acceleration space 50 of the self-convection heat dissipation unit 6, a rainwater blocking sill 5 that blocks raindrops splashing into the inner space through the bottleneck discharge gap 23 is provided with a gable-side roof sloping plate 4a. ) (4b) is a self-convection switchboard device for outdoor use characterized in that it is formed by bending and horizontally extending.

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