KR20130054789A - External case for distributing board having an vibration-prevent fluid tank - Google Patents

Abstract

PURPOSE: An external box for switchgear panel which has a fluid tank for a vibration control is provided to suppress the vibration of the external box by fluid of the inside of the vibration control tank in case a vibration acts on the external box. CONSTITUTION: An external box for switchgear panel(10) mounts a side plate(12) on a base plate(11) and mounts a roof plate(13) and a door(14) on an inside skeleton. A separate vibration control tank(20) is mounted on the external box for switchgear panel. The vibration control tank divides an internal space into multiple divided spaces(22,22') by partitions(21,21') which are in the crossing direction. Fluid is injected into the divided spaces.

Description

Switchgear enclosure with vibration damper {External case for distributing board having an vibration-prevent fluid tank}

The present invention relates to an enclosure for a switchgear in which equipment for drawing electricity and equipment for distributing electricity are incorporated. More particularly, the enclosure for a switchgear made of a base plate, a frame, a door, a side plate, and a roof plate, Mount a separate vibration damper tank in which fluid is injected into the upper part of the enclosure, wherein the vibration damping tank consists of a partition inside and a water hole formed in the partition, and when the vibration acts on the enclosure, the fluid in the vibration damping tank is It moves in the opposite direction to suppress the vibration of the enclosure.

In general, in order to use electricity in a building, it is necessary to receive power equipment for drawing electricity from an electric line, and in order to distribute the received electricity to each interior space of the building, a proper distribution equipment will be required.

Accordingly, the switchgear should be applied to buildings and structures as essential, and the switchgear should be safely protected and installed through a separate enclosure.

Such a switchgear enclosure is typically framed frame is installed in the upper part of the base plate that is firmly installed on the ground, the above-mentioned switchgear equipment as the door, side plate and roof plate are coupled to each other It can be safely protected and managed.

However, since earthquakes frequently occur in Korea in the near future, such a switchgear enclosure may not be considered safe from vibration caused by such an earthquake, so the seismic design of the enclosure is made so that the switchgear equipment can be safely and protected. The trend is losing.

In particular, "telecommunication equipment" in accordance with the contents of the "Building Guide for Seismic Design of Building Electrical Equipment" issued by the Korea Electrical and Technology Association (Korea Electrotechnical Standards Committee) and "Regulations on Technical Standards of Telecommunication Equipment" announced by the Institute of Telecommunications. According to the seismic test method (Radio Wave Research Laboratory Publication No. 2009-3), the design and construction for the fixing and fixing of electrical facilities such as faucets and power distribution rooms, etc. The seismic design must be made.

Here, the matters to be considered in the seismic design of the enclosure for the switchgear, the seismic load for the inertial force acting on the structure when the structure is vibrated by the earthquake, and the structure of the structure considering the vibration period and the vibration type applied to the structure The design should take into account both the dynamic characteristics, the ground characteristics, the ductility of the structure, and the importance of the structure.

Accordingly, the power distribution equipment and the power distribution equipment are installed in the enclosure of the existing switchgear using the base plate and the frame, and the power receiving equipment is mounted on a high damping rubber (HDR) to support it. It is installed, and distribution equipment is also installed on high damping rubber (HDR) to support it. That is, it is made by mounting the power receiving equipment or power distribution equipment on these high damping rubber in the state of fixing the high damping rubber using the base plate and the frame.

Accordingly, the high attenuation rubber is to prevent the damage or failure to the power receiving equipment and distribution equipment by effectively buffering and absorbing the vibration when the vibration caused by the earthquake.

In addition, the frame of the enclosure as described above is assembled by attaching a corner brace in the diagonal or inclined shape with respect to the vertical and horizontal frame connection portion to ensure the seismic design as the frame itself.

However, the conventional enclosure for the switchgear having the seismic design structure as described above, the seismic design is made by applying a high damping rubber, which is a type of seismic isolation device, the vibration isolator acts on the enclosure when the earthquake occurs. In order to prevent transmission, practically no direct seismic design of the frame of the enclosure has been made.

That is, when the enclosure is exposed to the vibration caused by the earthquake, the enclosure may be shaken forward or backward, or left, right and up and down depending on the characteristics of the seismic wave, or may be shaken in combination. As such, the vibration acting on the enclosure will only serve to reduce transmission to the switchboard, and as a result, the vibrations such as the fatigue fracture or shear or bending or twisting of the enclosure frame itself occur.

As such, when the deformation of the enclosure frame itself occurs, negligence may occur in protecting or fixing the internal switchgear. Therefore, a direct seismic design of the enclosure for the switchgear is urgently required.

In addition, the corner brace is applied to prevent the deformation of the frame itself is not applied to the front and rear door portion that requires the access or access of the operator is limited to only the side of the frame, so the front and rear directions to act on the frame Although it is stiff in vibration, it is vulnerable to vibrations in the left and right directions, and it is true that extensive seismic design cannot be achieved from vibrations having unpredictable directionality.

Therefore, there is an urgent need for an earthquake-proof or seismic isolation device capable of safely maintaining the front and rear directions as well as the left and right directions of the frame in the enclosure for the switchgear.

The present invention has been made to solve the problems as described above, wherein a separate vibration damper tank is formed in the enclosure for the switchgear, the vibration damping tank is injected with a fluid for dust removal of the enclosure therein the vibration damping tank It consists of a partition partitioning the inner space and the water hole formed in the partition, the inner partition space of the vibration damping tank by the partition has a different size, or divided space adjacent to each other by adjusting the size and number of water holes As the flow rate of the alternating current to the fluid in the configuration is made,

When the vibration is applied to the enclosure for the switchgear to provide an enclosure for the switchgear having a vibration damping fluid tank characterized in that the vibration acting on the enclosure for the switchgear is suppressed due to the characteristics of the fluid having a vibration cycle in the opposite direction to the vibration cycle. It is an object of the present invention.

The present invention for achieving the object as described above, in the enclosure for the switchgear is mounted on the base frame of the side plate, roof plate and door on the base plate,

A separate damping tank is mounted in the enclosure for the switchgear, wherein the damping tank is divided into a plurality of divided spaces by partitions in an intersecting direction, and fluid is injected into the divided spaces.

The present invention is to suppress the vibration of the enclosure by the fluid in the damping tank when the vibration acts on the enclosure for the switchgear by using the characteristics of the fluid having a vibration period in the opposite direction to the vibration acting on the enclosure for the switchgear, The vibration damping tank with various size and number of water holes formed in the partition for constituting the partition space with various sizes corresponds to various vibration cycles acting on the enclosure for the distribution panel, and the fluid moves in the opposite direction to the vibration. By more effectively suppressing the vibration of the cabinet for the switchgear, not only to protect various equipment inside, but also to protect the enclosure itself.

1 is an overall view of the enclosure for a switchgear of a general type;
Figure 2 is an overall perspective view of the enclosure for switchboard according to the invention
Figure 3 is an exploded perspective view of the vibration damping tank of the switchgear enclosure according to the present invention
Figure 4 is an open inner view of the vibration damping tank of the switchgear enclosure according to the invention
5 is a detailed view of the coupling portion for the vibration damping tank of the switchgear enclosure according to the present invention;
Figure 6 is an internal view of the usual vibration damping tank of the switchgear enclosure according to the present invention
Figure 7 is a view of the vibration damper tank when the vibration action in one direction in the enclosure for the switchgear according to the present invention
Figure 8 is a view of the vibration damper tank when the vibration action in the other direction in the enclosure for the switchgear according to the present invention

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

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

1 is a general view of a switchgear enclosure of a general form, Figure 2 is a perspective view of the switchgear enclosure according to the invention, Figure 3 is an exploded perspective view of the vibration damping tank of the switchgear enclosure according to the invention, Figure 4 Open internal view of the vibration damping tank of the switchgear enclosure according to the present invention.

As shown in the figure, the enclosure 10 for the distribution panel has a base plate 11 so that the enclosure can be firmly supported on the ground. The side plate 12 and the upper side of the base plate 11 are provided. The roof plate 13 and the door 14 for opening and closing the inside of the enclosure are mounted. The side plates 12, the roof plate 13, and the door 14 are mounted inside the enclosure as described above. At the same time, there is a skeleton that can be fixedly installed inside the various devices.

Such a switchgear enclosure 10 is equipped with a separate damping tank 20 in which fluid is injected therein to suppress vibrations acting on the switchgear enclosure 10 by the damping tank 20. The switchboard enclosure 10 is to maintain a safe installation state from vibration.

At this time, the vibration damping tank 20 may be mounted in the interior of the switchgear enclosure 10 and, if necessary, may be installed on the outer upper portion of the roof plate 13, which is the upper part of the enclosure for the switchgear 10. . Hereinafter, in the detailed description, the above-described vibration damping tank 20 is installed on the upper part of the enclosure 10 for the distribution panel as a preferred embodiment.

The vibration damping tank 20 is a wide and flat sealed enclosure, and can be used by injecting a fluid such as water, a conductive fluid, or an insulating oil therein. In order to prevent safety accidents, special watertight treatment should be performed in parallel. When the stabilizer with double bulkheads is used or when steel sheets are used, the welding process to maintain watertightness should be performed. The reinforcement structure should be applied enough to withstand the load of the tank itself and the load force due to the flow of the internal fluid.

In addition, the vibration damping tank 20, even if it is water, conductive fluid, or insulating oil, because the leakage of the fluid inside by vibration may cause various electrical accidents, etc. Standard for airtightness (KOSHA CODE D-31-2005) It shall be applied with the test of airtightness and watertightness in accordance with the airtight test by or the hydraulic test standard of general storage tanks.

The vibration damping tank 20 having such a structure has a plurality of divided spaces 22 (in the inner space of the vibration damping tank 20 by a plurality of partitions 21 and 21 'fixedly installed in a cross direction therein) ( 22 ') is partitioned, and the partitions 21 and 21' are provided with water holes 25 and 25 'for communicating the adjacent divided spaces 22 and 22' as necessary. It is.

At this time, each of the divided spaces 22 and 22 'by the partitions 21 and 21' may have the same size, or the partitions 22 and 22 'may have different positions, respectively. The 22 'can be produced to have different areas.

In addition, the through holes 25 and 25 'formed in the partitions 21 and 21' also have different inner diameters for the partitions 21 and 21 'or each partition 21 and 21'. ') Can also be produced by applying different numbers of individual water holes 25 and 25'.

As such, the divided spaces 22 and 22 'having different areas by the partitions 21 and 21' are caused by the difference in the area of the fluid injected into each of the divided spaces 22 and 22 '. This is to induce to have a differential vibration period is to maximize the vibration suppression effect of the enclosure by the fluid having the opposite vibration period coinciding with the vibration period acting on the enclosure 10 for the distribution panel.

In addition, the reason for the difference in the inner diameter or the individual difference between the through holes 25 and 25 'formed in the partitions 21 and 21' is also defined in the respective divided spaces 22 and 22 'by different sizes and numbers. As the vibration acting on the fluid is caused to vibrate at different periods in each of the divided spaces 22 and 22 ', it is possible to appropriately cope with the vibration period of the unpredictable switchgear enclosure 10.

In particular, when the damping tank 20 as described above is to be installed on the upper part of the switchgear enclosure 10, as shown in FIG. 5, outwardly open on the upper roof plate 13 of the switchgear enclosure 10. The frame 15 having a "c" shaped cross section is fixed and installed, and the vibration damping tank 20 is fixedly installed by using the frame 15. The upper surface of the enclosure 10 for the distribution panel is an enclosure. Anchor bolt hole for the transport or movement of the will be formed so that the frame 15 can be easily fixed in various forms on top of the enclosure 10 for the switchgear.

At this time, the frame 15 serves to evenly spread and support the weight of the vibration damping tank 20 in a state in which fluid is injected therein, as well as to easily fix the vibration damping tank 20. It will play a role.

Accordingly, the vibration damping tank 20 may be firmly fixed to each other by lifting the vibration damping tank 20 on the frame 15 as described above. The fastening bolt 23 is formed on the bottom of the vibration damping tank 20 downwardly. When the fastening bolts 23 of the vibration damping tank 20 are inserted through the upper part of the frame 15, the separate fastening nuts 24 are firmly assembled to the exposed fastening bolts 23 so that the frame 15 and The firm coupling of the vibration damping tank 20 can be made. In addition to the bolt and nut coupling structure as described above, the lower end of the frame 15 and the vibration damping tank 20 may be directly fixed by welding.

Thus, as described above, the vibration damping tank 20 is fixed to the upper part of the switchgear enclosure 10 of the present invention, and the partition space 22 by the partitions 21 and 21 'inside the vibration damping tank 20 ( 22 ') is filled with a fluid, such as insulating oil, the fluid may be added or subtracted depending on the weight and type and location of the internal electrical equipment for the switchgear 10 is preferably 50 from the inner height of the vibration damping tank 20 It is injected to have only a height corresponding to ˜70% so that the flow of fluid in the internal space can be freely made.

Therefore, when vibration does not act on the cabinet 10 for the switchgear, as shown in FIG. 6, the fluid inside the vibration damping tank 20 maintains a horizontal state, and vibrations act on the cabinet 10 for the switchgear. In this case, according to the vibration cycle, the cabinet 10 for the switchgear is directional and flows, and when the vibration force is received from one side as shown in FIG. 7, the fluid inside the vibration damping tank 20 is the cabinet 10 for the switchgear 10. While moving in a direction opposite to the moving direction of the) and hits the inner wall and partition (21, 21 ') of the vibration damping tank 20 will have a vibration suppressing effect, as shown in Figure 8 the cabinet 10 for the switchgear When the vibration force in the opposite direction is received, the fluid inside the vibration damping tank 20 also moves in a direction opposite to the vibration direction acting on the enclosure, and the inner walls and partitions 21 and 21 'of the vibration damping tank 20 Switching board Which will thereby suppress vibrations acting on the enclosure (10).

That is, since the vibration direction acting on the switchgear enclosure 10 and the vibration direction of the fluid inside the vibration damping tank 20 are opposite to each other, the vibration switch between the fluid and the vibration damping tank 10 Vibration force acting on) can be effectively attenuated and suppressed.

In addition, the partitions 21 and 21 ′ in the vibration damping tank 20 serve as damping nets that hinder the movement of the fluid, thereby increasing damping coefficients for the fluid and improving vibration damping performance.

In particular, the divided spaces 22 and 22 'in the vibration damping tank 20 having different areas depending on the fixing positions of the partitions 21 and 21' are fluids in the respective divided spaces 22 and 22 '. By setting the oscillation period for the different will be an effective response from the vibration of the various cycles acting on the enclosure 10 for the switchboard.

In addition, the through holes 25 and 25 ′ formed in the partitions 21 and 21 ′ are also divided spaces 22 and 22 where fluids flowing in the respective divided spaces 22 and 22 ′ are adjacent to each other. ') So that the inflow and outflow can be flowed repeatedly, thereby acting to attenuate the resonance effect generated by the vibration period of the enclosure 10 and the vibration period of the fluid coincide with each other. It is possible to minimize the structural damage of the enclosure (10).

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the present invention as defined by the appended claims. Examples should be understood.

10: enclosure for switchboard 11: base plate
12: side plate 13: roof plate
14 door 15 frame
20: damping tank 21,21 ': partition
22,22 ': Partition space 23: Tightening bolt
24: Tightening nut 25,25 ': Water filtration

Claims (6)

In the cabinet 10 for the switchboard, in which the side plate 12, the roof plate 13, and the door 14 are mounted on an internal frame on the base plate 11,
A separate vibration damping tank 20 is mounted on the switchboard enclosure 10, wherein the vibration damping tank 20 has a plurality of divided spaces 22 by partitions 21 and 21 ′ in an intersecting direction. And an enclosure for water distribution panel having a damping fluid tank, characterized in that a fluid is injected into each of the divided spaces (22, 22 ').
The method of claim 1,
The vibration damping tank 20 is positioned on the outer top of the enclosure for the switchgear 10, and the frame 15 of the cross-section "C" shaped to be opened outward is fixed to the upper surface of the enclosure for the switchgear 10, and the vibration damping tank The fastening bolt 23 is formed to protrude downward from the bottom of the 20 so that the fastening bolt 23 penetrates the upper part of the frame 15 to be coupled and fixed to the frame 15 by a separate fastening nut 24. Enclosure for switchgear having a vibration damping fluid tank characterized in that the configuration.
The method of claim 1,
The compartments 22 and 22 ′ of the vibration damping tank 20 are enclosures for switchboards having a vibration damping fluid tank, characterized in that their respective areas are configured differently.
The method of claim 1,
The partitioning fluid (21) (21 ') of the vibration damping tank (20) is provided with a through hole (25, 25') for communicating the adjacent divided spaces (22, 22 ') to each other. Cabinets for switchboards with tanks.
5. The method of claim 4,
The water distribution holes 25 and 25 'formed in the partitions 21 and 21' have a water discharge panel having a vibration damping fluid tank, characterized in that they are formed with different inner diameters with respect to each of the partitions 21 and 21 '. Enclosure.
5. The method of claim 4,
The water-permeable holes 25 and 25 'formed in the partitions 21 and 21' have at least two or more objects with different numbers for each of the partitions 21 and 21 '. Cabinets for switchboards with tanks.

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