KR102173507B1 - Switchboard with vibration damping - Google Patents

Abstract

According to an aspect of the present invention, in a switchboard, provided is a switchboard having a vibration damping function which comprises: a switchboard box formed of a housing and a cover, having the interior formed as a waterproof space, and provided with electrical equipment (D) therein; an inner plate formed in a form of a plate, coupled with the switchboard box and an inner plate buffer member interposed therebetween, having a portion coupled with the inner plate buffer member formed by bending, and having the electrical equipment coupled to one side surface; an inner seismic component disposed at a coupled portion between the inner plate and the electrical equipment; and an outer seismic component disposed at a coupling portion between the switchboard box and an installation wall. The outer seismic component is provided with an outer skin material and an inner skin material, a support body is coupled and connected between the outer skin material and the outer skin material. An elastic filler material is filled between the outer skin material and the inner skin material.

Description

Switchboard with vibration damping

The present invention relates to a switchboard, and more particularly, to a switchboard having a vibration damping function and applicable to a military ship.

In general, the switchboard performs the function of safely supplying power to power equipment and protecting the system from electric accidents. In particular, in case of vibration or shock applied to the switchboard due to external factors such as positional change or explosion in the switchboard used in ships and moving structures, electrical components such as the internal power unit, wiring and protection relay of the control panel may be damaged. In addition, there is a risk that the supply of power may be interrupted or an accident may occur due to a power failure.

Accidents of buildings or ships are occurring due to natural disasters such as earthquakes, typhoons, tsunamis, etc., which have become frequent in recent years, and economic losses are increasing. In this case, the seismic design standards are gradually strengthened in order to minimize the interruption of the power supply due to damage and the resulting economic loss.

Embodiments of the present invention are to provide a switchboard having a vibration damping performance by using the surface method.

According to an aspect of the present invention, in a switchboard, a switchboard box formed of a housing and a cover so that the inside is formed as a waterproof space and an electrical equipment (D) is provided therein; is formed in the form of a plate to fill the switchboard box and the inner plate An inner plate coupled with a member interposed therebetween, a portion coupled with the inner plate buffer member being bent, and coupled to one side of the electrical equipment; An inner seismic component disposed at a coupling portion between the inner plate and the electrical equipment; An outer seismic component disposed at a coupling portion of the switchboard box and the installation wall; Including, wherein the outer seismic part is provided with an inner skin material and a shell material, a support body is coupled and connected between the shell material and the shell material, and vibration damping formed by filling an elastic filler material between the shell material and the inner skin material A switchboard with a function may be provided.

Embodiments of the present invention may reduce vibrations and shocks in multiple directions transmitted to the switchboard by applying the inner and outer seismic parts, and thereby prevent failure or damage.

1 is a view showing a cross section of a switchboard according to an embodiment of the present invention.
FIG. 2 is an enlarged view of the outer seismic component illustrated in FIG. 1.
3 is a view showing a modified example of the outer seismic component shown in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, it should be noted that the following embodiments are provided to aid understanding of the present invention, and the scope of the present invention is not limited to the following embodiments. The following embodiments are provided to more completely describe the present invention to a person with average knowledge in the relevant technical field, and detailed descriptions of known configurations that are determined to unnecessarily obscure the technical subject matter of the present invention are provided. I will omit it.

1 is a perspective view showing a schematic view of a switchboard according to an embodiment of the present invention.

Referring to FIG. 1, the switchboard may include a switchboard box 100.

The switchboard box 100 may have a predetermined space in which the electrical equipment D may be embedded. The switchboard box 100 may include a cover 102 and a housing 101. In addition, the coupling portion between the cover 102 and the housing 101 may be waterproofed with rubber packing or O-ring. Accordingly, the inside of the housing may be a waterproof space. The housing 101 may be supported and positioned on a wall surface.

Meanwhile, the inner plate 110 may be located inside the housing 101. The inner plate 110 may be in a form of a plate having a predetermined thickness and have a bent end that is coupled to the housing 101 and fixed. Electrical equipment (D) may be installed on one side of the inner plate 110. In addition, the bent end of the inner plate 110 may be coupled to and supported on one side of the housing 101.

In this case, the inner plate buffer member 120 may be disposed at a portion where the inner plate 110 and the housing 101 are coupled. The inner plate buffer member 120 may be formed of a material capable of forming an elastic flow up, down, left and right against external vibration or impact.

For example, the inner plate buffer member 120 may be formed of rubber, silicone, or EPDM (Ethylene Propylene Diene Monomer rubber). The inner plate buffer member 120 may act as a spring against vibration or shock. Due to this, external vibrations and shocks transmitted to the inner plate 110 may be absorbed.

On the other hand, between the electrical equipment (D) and the inner plate 110, the inner vibration-resistant part 130 may be coupled. The inner seismic component 130 may be located in a path of a force through which vibration and shock transmitted to the inner plate 110 are transmitted.

The inner seismic component 130 may include a circuit bolt 131.

The circuit bolt 131 may be penetrated and fastened so as to connect the electrical equipment D and the inner plate 110. The circuit bolt 131 may be formed in the form of a general bolt having a bolt head on one side.

In addition, a fastening nut 132 may be coupled to an end of the circuit bolt 131. The fastening nut 132 may be fastened to the rear side of the inner plate 110. The fastening nut 132 may be positioned to be spaced apart from the inner plate 110 by a predetermined distance. A circuit bolt spring 134 to be described later may be disposed between the fastening nut 132 and the inner plate 110. In this case, the elastic force may be adjusted according to the degree of contraction of the circuit bolt spring 134 according to the distance formed between the fastening nut 132 and the inner plate 110. Accordingly, the position where the fastening nut 132 is disposed can be adjusted to correspond to the required damping force.

On the other hand, a support 133 may be provided at a coupling portion between the electrical equipment D and the inner plate 110. The support 133 may be formed in a circular or hexagonal column shape. Further, the support 133 may be formed to have a predetermined length in which the electrical equipment D and the inner plate 110 do not contact. The support 133 may be located at each corner of the front product (D). Accordingly, by preventing the rear end of the electrical equipment D and the inner plate 110 from contacting, a short circuit and friction damage may be prevented.

Meanwhile, a circuit bolt spring 134 may be provided between the inner plate 110 and the fastening nut 132. The circuit bolt spring 134 may be located under the inner plate 110. The circuit bolt spring 134 may be formed in a coil spring shape. In addition, the circuit bolt spring 134 may be positioned in a form coupled to the circuit bolt 131. The circuit bolt spring 134 formed in such a structure may flow to the left and right when shock and vibration occur. Accordingly, vibrations or shocks transmitted to the electronic device D may be attenuated. In addition, the inner plate buffer member 120 and the inner seismic component 130 may be disposed between the inner plate 110 and the housing 101 to suppress vibrations of different frequencies.

FIG. 2 is an enlarged view of the outer seismic component illustrated in FIG. 1.

1 and 2, the switchboard may include an outer seismic component 200.

The outer seismic component 200 may be disposed between the installation wall surface A1 and the switchboard box 100. The outer seismic component 200 may be formed in a form in which an elastic filler (C) is filled between the outer cover material 210 and the inner cover material 220.

The outer seismic component 200 may have a shell material 210 positioned on the outside. The shell material 210 may be formed of a structural material such as stainless steel. The shell material 210 may be formed to correspond to the length of the width according to the weight of the switchboard to be mounted. In general, the width of the shell material may be formed within about 50mm ~ 150mm. In addition, the shell material 210 may be formed of a thin plate having a thin thickness, so that a fluid movement against an external force may be formed.

In addition, the shell material 210 may be formed in a semicircular shape and provided in a pair of upper and lower portions. At this time, the pair of outer coverings 210 may be combined to form an elliptical shape.

An inner skin material 220 may be positioned inside the outer shell material 210 spaced apart from each other by a predetermined distance. The inner covering material 220 may be formed of a structural material such as stainless steel such as the outer covering member 210. In addition, the inner cover material 220 may be formed of a thin plate so that a fluid movement with respect to an external force may be formed. The inner covering material 220 may be formed smaller than the size of the outer covering member 210 by a predetermined ratio. In addition, the inner cover material 220 may be formed in a similar shape in correspondence with the outer cover material 210.

As such, the inner covering material 220 and the outer covering member 210 may be connected to and coupled to the support 230. The support 230 may be disposed between the inner covering material 220 and the outer covering member 210. The support 230 may be formed by a combination of the support plate 231 and the support plate coupling member 232.

The support plate 231 may be formed in a rectangular plate shape having a predetermined thickness. The support plate 231 may be located in the middle of the outer covering 210 and the inner covering 220 to be connected. In detail, the support plate 231 is in contact with and coupled to the side surface of the inner covering material 220 so that the inner covering material 220 positioned above and below may be connected. In addition, the support plate 231 is in contact with and coupled to the side surface of the shell material 210 so that the shell material 210 positioned above and below may be connected. At this time, the inner cover material 220 and the outer cover material 210 of the support plate 231 may be coupled by fastening the support plate coupling member 232. Support plate coupling member 232 may be a member such as rivets, bolts, etc., as long as the inner cover material 220 and the outer cover material 210 is a member capable of maintaining the coupling may be any.

Meanwhile, an outer seismic component installation hole M1 may be formed in the center of the support 230. A fastening member 233 may be inserted into the outer seismic component installation hole M1 to be fixed to the wall surface or the distribution box 100. The fastening member 233 may be any member that can be fastened to and supported by the wall surface A1 and the switchboard box 100 such as nails, anchor bolts, and pins. In addition, the outer seismic component installation hole M1 may be formed through all of the central portions of the outer shell material 210, the inner skin material 220, and the support plate 231. Accordingly, the outer seismic component 200 may be connected to and supported by the wall surface A1 and the distribution box 100 by the fastening member 233.

Meanwhile, an elastic filler (C) may be filled in the space partitioned by the inner covering material 220 and the outer covering material 210. The elastic filler (C) may be a material that dampens impacts such as epoxy resin damping compound. Epoxy resin damping compounds can be materials that dampen the forces of vibration and impact. Accordingly, when vibration and shock are transmitted through the elastic filler (C), the force may be attenuated and transmitted.

3 is a view showing a modified example of the outer seismic component shown in FIG.

1 and 3, in the outer seismic component 200-1 according to the modified example, the inner cover material 220-1 and the outer cover material 210-1 are provided in a pair at the top and bottom, so that a predetermined portion is formed in a waveform. Can be. In this embodiment, a portion adjacent to the coupling portion of the inner covering material 220-1 and the outer covering material 210-1 disposed above and below may be formed in a waveform shape. Accordingly, when vibration or shock is transmitted to the inner covering material 220-1 and the outer covering material 210-1, a portion around the coupling may periodically flow up and down. Such a flow may enable the outer cover material 210-1 and the inner cover material 220-1 to absorb the force transmitted to the switchboard box 100 by using elasticity. At this time, the force absorbed by the outer cover material 210-1 and the inner cover material 220-1 may be reduced by the filled elastic filler material C-1. Accordingly, vibration or impact in the longitudinal direction transmitted to the switchboard box 100 may be alleviated.

Meanwhile, the elastic support 230-1 may be coupled to the inner covering material 220-1 and the outer covering member 210-1. The elastic support 230-1 may be provided in each of the left and right sides to form a pair, but is not limited thereto. Two or more elastic supports 230-1 may be disposed in one direction according to the support force required to be supported on the wall surface A1 or the switchboard box 100.

The elastic support 230-1 is a silicone cap that is positioned between the support plate 231-1 and the support plate 231-1 connecting the inner cover material 220 and the cover material 210 to relieve vibration and impact. (234-1) may be included. In addition, a middle pin 233-1 and a pin guide head 235-1 coupled to the center of the elastic support 230-1 may be included.

The support plate 231-1 may be formed in a rectangular plate shape. In addition, the support plate 231-1 may be formed to connect a pair of the inner covering material 220-1 and the outer covering material 210-1 positioned above and below. In addition, the support plate 231-1 may be connected to the inner cover material 220-1 and the outer cover material 210-1 by a support plate coupling member 231-1 coupled to one side.

Meanwhile, a silicon cap 234-1 may be disposed between the support plates 231-1 disposed on the left and right sides. The silicone cap 234-1 may be located at the center of the elastic support 230-1. The position of the silicon cap 234-1 may be a path for transverse shock and vibration force transmitted from the installation wall A1. The silicon cap 234-1 may be in the shape of a circular rotating sphere having a predetermined thickness. The size of the silicone cap 234-1 may be formed such that the inner covering material 220 and the outer covering material 210 are not in contact with each other by vibration and impact. In addition, the inside of the silicon cap 234-1 is formed as a hollow, so that an air layer may be formed in the internal space.

Accordingly, when the lateral shock and vibration are transmitted from one side of the silicon cap 234-1, the elastic force of the silicon cap 234-1 and an air layer therein become an air spring, so that shock and vibration can be reduced.

On the other hand, the elastic support 240 may include a middle pin (233-1). The middle pin 233-1 may be formed from the outside of the shell material 210-1 to penetrate the inner skin material 220-1. One middle pin 233-1 may be disposed in a symmetrical shape on the left and right sides around the silicon cap 234-1.

In addition, a pin guide head 245-1 may be provided outside the shell material 210-1 to guide the insertion path of the middle pin 233-1. The pin guide head 245-1 may be formed in a screw shape in which an installation hole M1-1 through which the middle pin 233-1 passes is formed in the center. The installation hole M1-1 may be formed through the center of the pin guide head 245-1, the support plate 231-1, and the silicon cap 234-1. Further, the pin guide head 235-1 may be disposed symmetrically to the left and right with respect to the silicon cap 234-1. Specifically, the middle pins 233-1 may be fastened through one side of the pin guide head 235-1 to the silicon cap 234-1 on the left and right sides. Accordingly, each component constituting the elastic support 230-1 may be positioned in a straight line, and one side may be in contact with each other to be coupled.

In addition, one end of the middle pin 233-1 may be fastened to the switchboard box 100 or the installation wall surface A1. Specifically, one end of the middle pin 233-1 may be coupled to the switchboard box 100 or the installation wall surface (A1), and the other end may be in the form of coupling the elastic support (230-1). Accordingly, the vibration and shock transmitted in multiple directions may flow in the vertical direction. In addition, the outer seismic component 200 may reduce vibration and impact by fixing the wall surface or the switchboard box 100.

In the above, embodiments of the present invention have been described, but those of ordinary skill in the art will add, change, delete or add components within the scope not departing from the spirit of the present invention described in the claims. Various modifications and changes can be made to the present invention by means of the like, and it will be said that this is also included within the scope of the present invention.

100: switchboard box 101: housing
102: cover 110: inner plate
120: inner plate buffer member 130: inner seismic part
131: circuit bolt 132: fastening nut
133: support 134: circuit bolt spring
200: outer seismic part 210-1: outer shell material
220-1: inner skin 230-1: elastic support
231-1: support plate 233-1: middle pin
234-1: Silicon cap 235-1: Pin guide head
C: Elastic filler D: Electrical equipment
A1: Installation wall

Claims (5)

In the switchboard,
It is formed of the housing 101 and the cover 102 so that the inside is formed as a waterproof space,
A switchboard box 100 in which the electrical equipment D is provided therein;
Formed in the form of a plate
It is coupled with the switchboard box 100 and the inner plate buffer member 120 therebetween,
The portion coupled to the inner plate buffer member 120 is formed by bending,
An inner plate 110 to which the electrical equipment D is coupled to one side;
An inner seismic component 130 disposed at a coupling portion between the inner plate 110 and the electrical equipment (D);
An outer seismic component 200 disposed at a coupling portion of the switchboard box 100 and the installation wall surface A1; Including,
The inner seismic component 130 is
A circuit bolt (131) coupled through the electrical equipment (D) and the inner plate (110);
A support (133) disposed between the electrical equipment (D) and the inner plate (110);
A fastening nut 132 fastened to the end of the circuit bolt 131; And
A circuit bolt spring 134 positioned between the inner plate 110 and the fastening nut 132 and flowing left and right by vibration and shock; Including,
The outer seismic component 200 is
An outer shell material 210-1 having a predetermined portion formed in a waveform shape and flowing up and down in response to vibration and impact transmitted in the longitudinal direction;
An inner skin material 220-1 positioned inside the outer skin material 210-1 and formed in a similar shape; And
It includes an elastic support (230-1) to which the inner cover material (220-1) and the cover material (210-1) is connected,
The elastic support (230-1) is
It is located between the inner cover material (220-1) to the cover material (210-1)
It is formed in the shape of a circular rotating sphere,
The inside is hollow, so an air layer is formed in the inner space,
A silicone cap 234-1 flowing to the left and right in response to the impact and vibration in the transverse direction;
A support plate (231-1) to which the inner covering material 220-1 to the outer covering member 210-1 are connected; And
It is fastened through the center of the outer seismic component 200
A middle pin 233-1 to which the outer seismic component 200 is supported on the wall surface A1 or the switchboard box 100;
A pin guide head 245-1 for guiding the insertion path of the middle pin 233-1; Including
The elastic support (230-1) is
The support plate (231-1) and the support plate (231-1) are coupled to the screw-shaped pin guide head (235-1) in which the pin is inserted into the center (M1-1) is inserted The silicon cap (234-1) is located in a straight line,
The inner cover material 220-1 and the outer cover material 210-1 are
It is provided in a pair at the top and bottom, and an elastic filler (C-1) is filled between
The middle pin 233-1 is
One end is fastened to the switchboard box 100 or the installation wall (A1), the other end is coupled to the elastic support (230-1)
The outer seismic component 200 is
A switchboard having a vibration damping function in which the elastic support 230-1 disposed on the switchboard box 100 and the elastic support 230-1 disposed on the wall are spaced apart from each other. delete delete The method according to claim 1
The inner plate 110 is
A switchboard having a vibration damping function in which an inner plate buffer member 120 and an inner seismic component 130 are disposed between the electrical equipment D and the housing 101. delete

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