KR102638229B1 - Ventilation System of Distributing Board - Google Patents

Abstract

The present invention relates to a ventilation system for switchboards, and more particularly to a ventilation system for switchboards linked to arc exhaust action.
The ventilation system of a switchboard according to an embodiment of the present invention includes a first compartment for accommodating power equipment; A ventilation door is installed on one side of the first compartment, and is normally open for ventilation and closed to block the arc in the event of an arc accident of the electric power equipment. The ventilation door is provided with a plurality of first compartments. A fixing plate having a ventilation hole; and a moving plate having a plurality of second ventilation holes; and, in the event of an arc accident, a driving unit that slides the moving plate, and in a normal state, the plurality of second ventilation holes are the plurality of first ventilation holes. and in the event of an arc accident, the moving plate slides and the first ventilation hole and the second ventilation hole are closed.

Description

Ventilation System of Distributing Board

The present invention relates to a ventilation system for switchboards, and more particularly to a ventilation system for switchboards linked to arc exhaust action.

In general, a switchboard is a device used to monitor, control, and protect the power system. The switchboard houses and uses various electrical devices such as breakers and current transformers for the operation or control of power plants and substations, and the operation of electric motors.

When an arc occurs inside such a switchboard due to a short circuit, ground fault, insulation breakdown, etc., high temperature and high pressure arc gas is generated inside the switchboard. The switchboard must be able to quickly discharge the high-temperature, high-pressure arc gas generated by such accidents to the outside to protect the power equipment in the switchboard and people.

Therefore, a path through which arc gas is discharged is formed in the switchboard. Arc gas generated inside the switchboard can be discharged to the outside through a duct or discharge space provided in the switchboard.

Through this arc discharge passage, the arc gas is cooled and discharged to the outside.

Figure 1 shows the structure of a switchboard according to the prior art.

In the case of high-voltage switchgear, it is usually composed of multiple stages. For example, in Figure 1, there is a transformer room (2) provided at the bottom, a circuit breaker room (3) provided at the middle, a low-voltage equipment room (4) provided at the top, and a busbar and cable room (5) provided at the rear end thereof. ), etc., is shown.

Here, an arc discharge chamber (6) is provided at the upper part of the circuit breaker room (3), that is, between the low-pressure equipment room (4) and the bus bar and cable room (5). The bottom and sides of the arc discharge chamber 6 are open so that arcs generated in the circuit breaker chamber 3 can flow in and be discharged to the outside of the switchboard.

Meanwhile, a ventilation door (9) for ventilation is provided between the arc discharge chamber (6) and the busbar and cable chamber (5). The ventilation door (9) is normally open to ensure good ventilation in the busbar and cable room (5), and is closed when an arc occurs due to a fault current to prevent damage from the arc to the busbar and cable room (5). do.

Figure 2 shows a side view of the circuit breaker room.

A circuit breaker (7) is inserted and installed into the circuit breaker room (3). The circuit breaker 7 includes a main circuit part (energizing part) 7a and an operating part 7b, and a protective plate 7c is formed on the operating part 7b to surround the top, bottom, left, and right sides, thereby protecting IP. It provides protection and arc blocking suitable for the International Protection Marking.

The circuit breaker (7) is inserted into the circuit breaker room (3), and when turned on, the circuit breaker terminal (7d) is coupled to the distribution board terminal (3a) (more precisely, the distribution board terminal inside the terminal bushing) to achieve electricity supply.

When the circuit breaker (7) is operated to cut off, the circuit breaker terminal (7d) is separated from the distribution board terminal (3a) and an arc is generated. Of course, arcs can also be caused by fault currents such as short circuits, ground faults, or insulation breakdown.

Most of the arc must move to the upper arc discharge chamber (6) and be discharged through the exhaust port (8).

At this time, the compartments must be closed except for the part that serves as the surrounding arc discharge passage, so that there is no damage to surrounding components due to the arc.

For example, the ventilation door 9 formed in the cable room 5 must be closed.

Meanwhile, as mentioned above, a cooling system is also needed to lower the temperature generated inside the switchboard. In other words, a vent (ventilation hole) or an open door for ventilation must be provided to ensure smooth ventilation inside the switchboard (1). That is, the ventilation door 9 must be opened.

In other words, from the perspective of preparing for an arc accident, the ventilation door (9) of the switchboard must be blocked in a blocked state, and from the perspective of internal ventilation, the ventilation door (9) must be normally open.

The ventilation door 9 according to the prior art has a structure that is closed by the pressure of arc gas.

However, this rotary door structure has a risk of being reopened due to repulsive force.

The present invention was conceived to solve the above-mentioned problems, and its purpose is to provide a switchboard having a ventilation door that is open in a normal state and closed in the event of an arc incident.

The ventilation system of a switchboard according to an embodiment of the present invention includes a first compartment for accommodating power equipment; A ventilation door is installed on one side of the first compartment, and is normally open for ventilation and closed to block the arc in the event of an arc accident of the electric power equipment. The ventilation door is provided with a plurality of first compartments. A fixing plate having a ventilation hole; and a moving plate having a plurality of second ventilation holes; and, in the event of an arc accident, a driving unit that slides the moving plate, and in a normal state, the plurality of second ventilation holes are the plurality of first ventilation holes. and in the event of an arc accident, the moving plate slides and the first ventilation hole and the second ventilation hole are closed.

Here, the width of the first plate portion formed between the two adjacent first vent holes is larger than the width of the first vent hole, and the width of the second plate portion formed between the two adjacent second vent holes is the width of the first plate portion formed between the two adjacent first vent holes. It is characterized in that it is formed larger than the width of the second ventilation hole.

In addition, the width of the first ventilation hole is formed to be the same as the width of the second ventilation hole, and the width of the first plate portion is formed to be the same as the width of the second plate portion.

In addition, the driving unit may include a magnetic member, one end of which is rotatably installed on the upper panel of the first compartment and rotated by the magnetic force of the arc, and the other end of which is coupled to the moving plate.

In addition, the driving unit may further include an elastic member provided between the upper panel and the magnetic member to provide a return force to the magnetic member.

In addition, the driving unit may further include a link member provided between the magnetic member and the moving plate.

In addition, a guide for supporting and guiding the moving plate is formed to protrude on one surface of the first compartment.

Additionally, the ventilation door is installed on an adjacent surface of the second compartment adjacent to the first compartment.

According to the ventilation system of the switchboard according to an embodiment of the present invention, the ventilation door of the compartment requiring ventilation is opened in a normal state, and when an arc occurs, the ventilation door is closed, so that it normally acts as a ventilation opening in the event of an arc accident. It can effectively perform a dual function as an arc blocking plate.

Here, the ventilation door is driven by the electromagnetic force of the arc, which has the effect of quickly closing the ventilation door in the event of an arc accident.

Meanwhile, the ventilation door is closed by a sliding method, so there is no risk of reopening.

In addition, the ventilation door is opened again when the arc disappears to perform a ventilation role.

Additionally, when the first compartment is adjacent to the outside, workers outside can be protected in the event of an arc accident.

1 is a perspective view of a switchboard according to the prior art.
Figure 2 is a partial side view of a switchboard according to the prior art.
Figure 3 is a perspective view of a switchboard according to an embodiment of the present invention.
Figure 4 is a partial side view of a switchboard according to an embodiment of the present invention.
Figures 5 and 6 are diagrams showing the operation of a ventilation door of a switchboard according to an embodiment of the present invention. Figure 5 shows a normal state and Figure 6 shows an arc blocking state.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, but the purpose is to provide a detailed description so that a person skilled in the art can easily practice the invention. This does not mean that the technical idea and scope of the invention are limited.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, but the purpose is to provide a detailed description so that a person skilled in the art can easily practice the invention. This does not mean that the technical idea and scope of the invention are limited.

The ventilation system of the switchboard according to each embodiment of the present invention will be described in detail with reference to the drawings. Figure 3 is a perspective view of a switchboard according to an embodiment of the present invention, Figure 4 is a partial side view of a switchboard according to an embodiment of the present invention, and Figures 5 and 6 are ventilation doors of a switchboard according to an embodiment of the present invention. As an operation diagram, Figure 5 shows a normal state and Figure 6 shows an arc blocking state.

The ventilation system of the switchboard according to an embodiment of the present invention includes a first compartment (13) that accommodates a circuit breaker (20); It is installed on one side (adjacent surface) of the first compartment 13 or the second compartment 16 adjacent to the first compartment 13, and is normally open for ventilation and in case of an arc accident of the circuit breaker 20, the It is provided with ventilation doors (40, 45) that are closed to block the arc, and the ventilation doors (40.45) include a fixing plate (40) having a plurality of first ventilation holes (41); and a moving plate 45 having a plurality of second ventilation holes 46, and in the event of an arc accident, a driving unit 50 that slides the moving plate 45, and in an open state, the plurality of The second ventilation hole 46 is in communication with the plurality of first ventilation holes 41, and in the event of an arc accident, the moving plate 45 slides to connect the first ventilation hole 41 and the second ventilation hole 46. is characterized by being closed.

The enclosure (cabinet) 11 of the switchboard 10 will be described first. The enclosure of the switchboard 10 according to an embodiment of the present invention is divided into a plurality of compartments. In this example, the enclosure 11 of the switchboard 10 includes a first compartment (breaker room) 13, a second compartment (arc discharge room) 16, a third compartment (low-voltage equipment room) 14, and a fourth compartment ( It may include a transformer room) (12) and a fifth compartment (busbar and cable room) (15).

High-voltage switchboards are usually formed in multiple stages. A multi-stage switchboard includes compartments provided in each of two or more stages. In this embodiment, the enclosure of a three-stage switchboard is shown. The compartment installed in the first stage (bottom) of the switchboard enclosure (11) is called the fourth compartment (transformer room) (12), and the compartment installed in the second stage (middle end) is called the first compartment (breaker room) (13). ). The fourth compartment 12 and the first compartment 13 can accommodate power devices that can be withdrawn and withdrawn, respectively. These devices may be circuit breakers 20 or transformers. That is, the circuit breaker 20 may be installed in the first compartment 13, and the transformer may be installed in the fourth compartment 12.

A third compartment (Low Voltage Compartment) 14 is provided in the upper part of the first compartment 13. At this time, the third compartment 14 is formed shorter than the length (front-rear direction length) of the fourth compartment 12 and the first compartment 13. In the third compartment 14, low-voltage devices, instrument transformers, current transformers, or auxiliary devices may be installed.

A fifth compartment (bus bar and cable compartment) 15 is provided at the rear of the fourth compartment 12 and the first compartment 13.

A second compartment (arc discharge chamber) 16 serving as an air passage or arc discharge passage is provided between the third compartment 14 and the bus and cable room 15.

The left and right sides and bottom of the second compartment 16 are fully or partially open. That is, openings are formed on the left and right sides and bottom of the second compartment 16, respectively. Accordingly, the second compartment 16 becomes a passage through which the arc gas generated in the lower first compartment 13 can not only flow in through the lower opening but also flow to the left and right sides.

An opening portion 17a is provided on the lower surface 17 of the second compartment 16. The upper surface of the first compartment 13 is opened by the opening portion 17a. That is, the opening portion 17a serves as an exhaust passage for arc gas generated in the first compartment 13. When arc gas is generated in the first compartment (13), it enters the second compartment (16) through the opening (17a), and then the arc gas escapes to the outside through the upper cover (18) of the second compartment (16). I'm going out. Here, the upper surface of the first compartment 13 and the lower surface of the second compartment 16 may be configured in common. The panel constituting the upper surface of the first compartment 13 may be the same as the panel constituting the lower surface 17 of the second compartment 16.

The third compartment 14 and the second compartment 16 may be provided above the first compartment 13.

The power equipment may be installed in the fourth compartment 12 of the first stage or the first compartment 13 of the second stage. In this embodiment, the circuit breaker 20 as a power device is installed in the first compartment 13 of the second stage.

The circuit breaker 20 includes a main circuit unit (energizing unit or blocking unit) 21, circuit breaker terminals 22 and 23 formed on the upper and lower parts of the main circuit unit 21, and an operating unit installed on the front of the main circuit unit 21. Includes (24).

A door 13a is provided on the front of the first compartment 13 and can be opened and closed.

A plurality of terminal bushings 28 and 29 are provided at the rear of the first compartment 13 and can be connected to the circuit breaker terminals 22 and 23, respectively.

An upper panel 17 is provided on the upper surface of the first compartment 13 (lower surfaces of the third compartment 14 and the second compartment 16). Each compartment may be composed of panels on the top, bottom, front, rear, left, and right sides. Here, the panels can be shared between adjacent compartments. For example, the upper panel 17 of the first compartment 13 may be shared with the lower panel of the second compartment 16. Additionally, each panel may be supported by a frame.

Ventilation doors 40 and 45 are installed on the rear panel 19 of the second compartment 16. In the normal state of the ventilation doors (40, 45), the ventilation holes (41, 46) are open to communicate with the adjacent compartment, and when an accident current occurs, the ventilation holes (41, 46) are closed to prevent arcs from entering the adjacent compartment. protect the thing

The ventilation doors 40 and 45 may be composed of a fixed plate 40 and a moving plate 45, respectively.

The fixing plate 40 is fixedly installed on the rear panel 19. A plurality of first ventilation holes 41 are formed in the fixing plate 40. For example, a plurality of first ventilation holes 41 may be arranged in a grid shape. The first ventilation hole 41 is distinguished from the first plate portion 42. Here, the portion formed between two adjacent first ventilation holes 41 will be referred to as the first plate portion 42. Here, the width w1 of the first plate portion 42 is preferably formed to be larger than the width w2 of the first ventilation hole 41.

The moving plate 45 is movably installed on the rear panel 19. At this time, the direction of movement follows the longitudinal direction (up and down direction in the drawing) of the rear panel 19. The moving plate 45 is installed to face the fixed plate 40. That is, in a normal state, the moving plate 45 can be installed while being overlapped with the fixed plate 40.

A plurality of second ventilation holes 46 are formed in the moving plate 45. For example, a plurality of second ventilation holes 46 may be arranged in a grid shape. The second ventilation hole 46 is distinguished from the second plate portion 47. Here, the portion formed between two adjacent second ventilation holes 46 will be referred to as the second plate portion 47. Here, the width v1 of the second plate portion 47 is preferably formed to be larger than the width v2 of the second ventilation hole 46.

Meanwhile, the width of the first ventilation hole 41 is formed to be equal to the width of the second ventilation hole 46, and the width of the first plate part 42 is formed to be equal to the width of the second plate part 47. It can be.

In a normal state, the second ventilation hole 46 of the moving plate 45 is installed to communicate with the first ventilation hole 41 of the fixed plate 40. Accordingly, the first ventilation hole 41 and the second ventilation hole 46 are communicated to allow free circulation of air between adjacent compartments.

When blocking the fault current, the moving plate 45 is arranged to slide along the longitudinal direction of the rear panel 19 so that the second ventilation hole 46 is shifted from the first ventilation hole 41. Accordingly, the first ventilation hole 41 is closed by the second plate part 47, and the second ventilation hole 46 is closed by the first plate part 42. Accordingly, the ventilation holes 41 and 46 are closed to block circulation of air or gas between adjacent compartments.

A driving part is provided to provide driving force to move the moving plate 45.

An example of such a driving unit is a magnetic member driven by magnetic force generated during arc gas.

A magnetic member 50 is rotatably installed on the lower surface of the upper panel 17 of the first compartment 13. The magnetic member 50 may be a metallic member such as an armature. One end 51 of the magnetic member 50 is rotatably installed on the upper panel 17, and a moving plate 45 is connected to the other end 52, so that the moving plate is attracted toward the terminal by the magnetic force generated during an arc accident. Move by sliding.

An elastic member 70 is provided to fix the position of the moving plate 45 and provide a returning force. The elastic member 70 is installed between the magnetic member 50 and the upper panel 17. At this time, one end of the elastic member 70 may be fixed to a part of the upper panel 17, and the other end of the elastic member 70 may be fixed to the magnetic member 50.

Here, the elastic member 70 may be composed of a coil spring, leaf spring, or torsion spring.

A link member 60 may be provided to provide flexibility between the movement of the moving plate 45 and the magnetic member 50. One end of the link member 60 is rotatably installed on the lower end of the moving plate 45, and the other end of the link member 60 is rotatably installed on the other end of the magnetic member 50. The linear movement of the moving plate 45 is ensured by the link member 60.

A guide 80 is provided to ensure and support the linear movement of the moving plate 45. The guide 80 may be composed of an 'ㄱ' shaped member protruding from the rear panel 19.

Looking at the operation, it is as follows.

In a normal state, the fixed plate 40 and the moving plate 45 are arranged side by side. At this time, the second ventilation hole 46 of the moving plate 45 is arranged to communicate with the first ventilation hole 41 of the fixed plate 40, so that the first ventilation hole 41 and the second ventilation hole 46 are connected to each other. Air circulates freely between adjacent compartments (for example, the second compartment and the fifth compartment).

When a fault current occurs and the circuit breaker 20 operates, an arc occurs at the circuit breaker terminals 22 and 23 of the circuit breaker 20. The magnetic member 50 is sucked and rotated by the magnetic force generated around the arc, and the moving plate 45 is pulled downward through the link member 60. Accordingly, the second ventilation hole 46 and the first ventilation hole 41 are misaligned and the ventilation doors 40 and 45 are closed to prevent the arc from entering the fifth pattern.

When the arc disappears, the magnetic force also disappears, and the moving plate 45 returns upward due to the restoring force of the elastic member 70.

According to the ventilation system of the switchboard according to an embodiment of the present invention, the ventilation door of the compartment requiring ventilation is opened in a normal state, and when an arc occurs, the ventilation door is closed, so that it normally acts as a ventilation opening in the event of an arc accident. It can effectively perform a dual function as an arc blocking plate.

Here, the ventilation door is driven by the electromagnetic force of the arc, which has the effect of quickly closing the ventilation door in the event of an arc accident.

Meanwhile, the ventilation door is closed by a sliding method, so there is no risk of reopening.

In addition, the ventilation door is opened again when the arc disappears to perform a ventilation role.

Additionally, when the first compartment is adjacent to the outside, workers outside can be protected in the event of an arc accident.

The embodiments described above are embodiments of the present invention, and those skilled in the art will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. In other words, the scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of the present invention.

13 1st compartment 16 2nd compartment
20 circuit breaker 40 fixing plate
41 First ventilation hole 42 First plate part
45 Moving plate 46 Second ventilation hole
47 Second plate portion 50 Magnetic member
60 link member 70 elastic member

Claims (8)

A first compartment for accommodating power equipment;
A ventilation door installed on one side of the first compartment, which is normally open for ventilation and closed to block the arc in the event of an arc accident of the power equipment, is provided,
The ventilation door is,
A fixing plate having a plurality of first ventilation holes; and
It includes a moving plate having a plurality of second ventilation holes,
In case of an arc accident, a driving unit that slides the moving plate;
In a normal state, the plurality of second ventilation holes are in communication with the plurality of first ventilation holes, and in the event of an arc accident, the moving plate slides and the first ventilation hole and the second ventilation hole are closed,
The width of the first plate portion formed between the two adjacent first ventilation holes is formed to be larger than the width of the first ventilation holes,
A ventilation system for a switchboard, characterized in that the width of the second plate portion formed between the two adjacent second ventilation holes is formed to be larger than the width of the second ventilation holes. delete According to paragraph 1,
The width of the first ventilation hole is formed to be the same as the width of the second ventilation hole,
A ventilation system for a switchboard, characterized in that the width of the first plate portion is formed to be the same as the width of the second plate portion. According to paragraph 1,
The driving unit,
A ventilation system for a switchboard, comprising a magnetic member, one end of which is rotatably installed on the upper panel of the first compartment and rotated by the magnetic force of the arc, and the other end of which is coupled to the moving plate. According to clause 4,
The driving unit,
The ventilation system of the switchboard further includes an elastic member provided between the upper panel and the magnetic member to provide a return force to the magnetic member. According to clause 5,
The driving unit,
A ventilation system for a switchboard, further comprising a link member provided between the magnetic member and the moving plate. According to paragraph 1,
A ventilation system for a switchboard, characterized in that a guide for supporting and guiding the moving plate is protruding from one surface of the first compartment. According to paragraph 1,
The ventilation system of a switchboard, characterized in that the ventilation door is installed on an adjacent surface of a second compartment adjacent to the first compartment.

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