KR101607241B1 - Vibration Isolation Device and Distributing Board, Control Board comprising the same - Google Patents

Abstract

The present invention provides a biaxial vibration isolation device which comprises: a vibrating unit having a pair of coupling axes formed long at the center side by side along a lengthwise direction, and having the bottom surface formed in a lower part of the coupling axis in an orthogonal direction to be installed in a part where the vibration is generated; a unit to be vibrated fixated to the bottom surface of a structure by being arranged to be separated from un upper side of the vibrating unit, and having a first fastening hole formed in the center to be elastically coupled on the coupling axis; and a vibration isolation unit blocking the vibration to be transferred by being inserted into the coupling axis between the vibrating unit and the unit to be vibrated, and formed with a plurality of layers.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double shaft type vibration isolation device, a vibration isolation device and a control board,

[0001] The present invention relates to a biaxial shaft type vibration isolation device, and to a biaxial type vibration isolation device and a motor control panel having the biaxial type vibration isolation device capable of minimizing direct transmission of vibration generated by an external force such as an earthquake, A power distribution board, a distribution board, and a motor control board.

In general, the switchgear is responsible for receiving power from the power supplier and supplying power to the equipment requiring power consumption, and has installed related facilities of a conventional power transformer room equipped with a power receiving facility and a power distribution facility in the internal accommodation space .

For example, in the interior of the above-mentioned power plant, there are a power receiving facility receiving electricity from KEPCO, a transformer supplying power supplied through the power receiving facility to a voltage or capacity required by the user, And a breaker to protect the entire plant from accidents.

In consideration of the safety of electric shock and fire in the process of use, the switchboard used in this case is an insulated main body having a switchgear door for restricting direct contact with the outside and for inspecting or maintaining the inside of the switchgear, In consideration of reliability against a supply voltage, various protective devices such as a circuit breaker and a lightning arrester are installed in the main body as essential requirements.

The switchgear also includes VCB, VCS, VC, ACB, MCCB, PCB and reactor, inverter, capacitor, measurement control module, SMPS, EMI filter and transformer to supply power.

In addition, the above-mentioned switchgear includes an input unit for outputting a DC current generated from the outside in a serial connection manner, an output unit connected in series to the input unit for outputting a DC current outputted from the input unit to the inverter, And a control unit for detecting and monitoring.

Such a conventional technology relating to a switchboard is described in detail in a registration application No. 20-0457648 entitled "Wiring for a Switchboard ".

However, the conventional switchgear is either provided with a vibration-proofing system corresponding to the vibration applied in either the vertical direction or the horizontal direction from the installation surface, or the vibration-proofing facility is continuously exposed to the load, Problems are pointed out.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a double shaft type vibration isolation device which is improved in that a double shaft type vibration isolation device is not exposed to a load of a structure before a vibration such as an earthquake occurs, The present invention provides a biaxial shaft isolation device capable of minimizing the transmission of vibration to a structure, and also to provide a switchgear, a distribution board, and a motor control panel having the same.

In order to achieve the above object, according to the present invention, a pair of coupling shafts are formed along a longitudinal direction along a longitudinal direction, and a bottom surface formed in a direction orthogonal to a lower end of the coupling shaft is installed at a vibration generating portion. A vibrating part which is disposed on the upper side of the vibrating part and is fixed to the bottom surface of the structure and has a first tightening hole formed at the center so as to be resiliently coupled with the engaging shaft, And a plurality of layers, each of which is formed of a plurality of layers.

Wherein the vibration isolating unit includes an elastic part formed with a pair of first coupling holes to be inserted into the coupling shaft and a vibration preventing part disposed on an upper side or a lower side of the elastic part and having a third coupling hole to be inserted into the coupling shaft, A plurality of the elastic part and the dustproof part may be stacked alternately.

The elastic portion may be formed of a deformable material, and the dustproof portion may be formed of a metal material so that the outer shape of the elastic portion is not deformed.

The vibration isolating unit may be formed such that a bottom of the dustproof portion is at least equal to or larger than a bottom of the elastic portion, or the side surface of the dustproof portion further protrudes from a side extension line of the elastic portion.

The biaxial-type seismic isolation device maintains a predetermined gap between the vibrating part and the to-be-swinged part to prevent the seismic isolation unit from being continuously exposed by the load of the structure. When the vibration exceeding the set range is generated, And may further include a gap maintaining unit.

Wherein the gap holding portion includes a plurality of lower support frames protruding from the upper surface of the vibrating portion at equal intervals around the coupling shaft in the same direction as the projecting direction of the coupling shaft, An upper support frame which is screwed to the formed second fastening hole so as to be movable in the vertical direction and is arranged to be in contact with the upper surface of the lower support frame and a lower support frame which surrounds the outer peripheral surface of the portion, And a seal sticker attached thereto.

The space maintaining unit may include an elastic member disposed to integrally surround the upper frame and the lower frame and elastically protecting an imaginary extension line between the upper frame and the lower frame.

According to another aspect of the present invention, there is provided an air conditioner, comprising: an enclosure main body having a door that can be opened and closed at one side thereof, At least one coupling axis is formed along the longitudinal direction in the center of the upper surface and a bottom surface formed in a direction orthogonal to the coupling axis is provided at a portion where vibration is generated; A pawl portion which is disposed on an upper side of the vibrating portion and is fixed to a bottom surface of the enclosure main body and has a first fastening hole formed at a center thereof so as to be resiliently coupled with the coupling shaft; And a vibration isolating unit which is inserted between the vibrating unit and the vibrating unit to block vibrations from being transmitted to the vibration isolating unit and is spaced apart from the vibrating unit by a predetermined interval between the vibrating unit and the vibrating unit, And a gap maintaining unit for preventing the gap from being continuously exposed due to a load of the enclosure body and deforming the predetermined gap when a vibration exceeding a set range is generated, do.

The booster bar is connected to the other side of the cabinet main body, and the vibration transmitted from the cabinet body is elastically connected to the booth so as to prevent the vibration transmitted from the cabinet body from being directly transmitted to the booth. As shown in FIG.

Wherein the insulator has a plurality of wrinkles protruding along a circumference on an outer circumferential surface thereof and has an insulator main body to which one end of the elastic member is coupled to one side of the insulator, And an earthquake-proof body coupled to be insulated from the insulator body.

The insulator may include an insulating member interposed between the insulator body and the seismic body to prevent contact between the insulator body and the seismic body.

According to another aspect of the present invention, there is provided an air conditioner, comprising: an enclosure main body having a door that can be opened and closed at one side thereof, A pair of coupling shafts extending in the longitudinal direction along the longitudinal direction and a bottom surface formed in a direction orthogonal to the lower end of the coupling shaft, A pawl portion which is disposed on an upper side of the vibrating portion and is fixed to a bottom surface of the enclosure main body and has a first fastening hole formed at a center thereof so as to be resiliently coupled with the coupling shaft; And a vibration isolating unit which is inserted between the vibrating unit and the vibrating unit to block vibrations from being transmitted to the vibration isolating unit and is spaced apart from the vibrating unit by a predetermined interval between the vibrating unit and the vibrating unit, And a gap maintaining portion for preventing the gap from being continuously exposed by a load of the enclosure main body and deforming the predetermined gap when a vibration of a predetermined range or more occurs, do.

According to another aspect of the present invention, there is provided an air conditioner, comprising: an enclosure main body having a door that can be opened and closed at one side thereof, A pair of coupling shafts extending in the longitudinal direction along the longitudinal direction and a bottom surface formed in a direction orthogonal to the lower end of the coupling shaft, A pawl portion which is disposed on an upper side of the vibrating portion and is fixed to a bottom surface of the enclosure main body and has a first fastening hole formed at a center thereof so as to be resiliently coupled with the coupling shaft; And a vibration isolating unit which is inserted between the vibrating unit and the vibrating unit to block vibrations from being transmitted to the vibration isolating unit and is spaced apart from the vibrating unit by a predetermined interval between the vibrating unit and the vibrating unit, And a gap maintaining unit for preventing the gap from being continuously exposed due to a load of the enclosure main body and deforming the predetermined gap when a vibration of a predetermined range or more is generated, to provide.

According to the biaxial seismic isolation device of the present invention and the switchgear, distribution board, and motor control panel having the same,

Firstly, it is possible to prevent the seismic unit from being continuously exposed to the loads of the switchgear, the distribution panel, or the motor control board through the gap holding portion,

Second, since the seismic unit is not continuously exposed to the load, effective elastic restoration force can be expected when vibration or impact occurs,

Third, even if vibrations or impacts are applied by stacking the elastic portion and the dust-proof portion in a plurality of layers, it is possible to make the surface vibration not only in the vertical direction but also in the horizontal direction,

Fourth, since the insulator connecting the high voltage cable inside the switchboard absorbs the shock, it can absorb noise and vibration,

Fifth, seismic or seismic design of double shaft structure is applied inside and outside of the switchgear,

Sixth, there is an effect that it is easy to apply to a distribution panel and a motor control panel as well as a switchboard using a double shaft type isolation device.

1 is a front view showing a switchboard with a double shaft type vibration isolation device according to an embodiment of the present invention.
2 is a side cross-sectional view schematically showing the inside of a switchboard having the double shaft type vibration isolation device shown in Fig.
Fig. 3 is an enlarged view of a part of the insulator inside the power transmission / distribution panel shown in Fig. 2 in an enlarged manner.
4 is a reference view showing a state where vibration is applied to the insulator shown in Fig.
5 is a front view showing the biaxial-type seismic isolator shown in Fig.
Fig. 6 is a side exploded view showing the biaxial shaft type earthquake device shown in Fig. 5 in an exploded state.
Figs. 7 and 8 are reference views showing, from the front, a state in which vibration is applied to the biaxial-type isolator shown in Fig. 5. Fig.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It should be noted that the drawings denoted by the same reference numerals in the drawings denote the same reference numerals whenever possible, in other drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. And certain features shown in the drawings are to be enlarged or reduced or simplified for ease of explanation, and the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details.

1 is a front view showing a switchboard 1 having a biaxial shaft isolation device 200 according to an embodiment of the present invention and FIG. 2 is a front view of a switchboard 1 Sectional view schematically showing the inside of the semiconductor device shown in FIG. Hereinafter, the switchboard 1 may be applied as a distribution board or a motor control board.

1 and 2, a switchboard 1 having a biaxial shaft isolation device 200 according to an embodiment of the present invention includes an inverter module (not shown), a water distribution module (not shown) And a biaxial shockproof device 200 coupled to a lower portion of the enclosure main body 10 and supporting the enclosure main body 10 from an installation surface.

The outer shape of the enclosure main body 10 is formed in a substantially rectangular parallelepiped shape and a receiving space 11 separated by one or a plurality of partition walls (not shown) so that the inverter module, the water distribution module, . Here, the switchboard 1 will be described as an example of a structure. In addition, the switchboard, the switchboard, the motor control panel (MCC), and the like may be applied as other examples of the structure.

In addition, although not shown in the drawings, components such as a PCB, a breaker, a lightning arrester, a fuse, and a switch may be additionally provided within the accommodation space 11, as well as components for basic power and distribution, and heat and moisture.

A door 12 is provided on one side surface of the enclosure main body 10 to selectively open and close the accommodation space 11.

The door 12 may be provided with one or a plurality of openings for fully or partially opening and closing the accommodation space 11. The door 12 may be installed or maintained by the inverter module, Remuneration is achieved.

The door 12 may be formed as a hinged or sliding door structure, and the door 12 is installed in the hinged door 1 according to the present invention as an example.

The double shaft type vibration isolation device 200 has a function of preventing the vibration generated from any one side of the enclosure main body 10 or the installation surface from being transmitted to the other side, and the detailed description will be later.

3 is an enlarged view of a portion of an insulator 100 inside a switchboard (refer to FIG. 1) provided with a biaxial shaft isolation device shown in FIG. 2, and FIG. 4 is an enlarged view of the insulator 100 And is a reference diagram showing a state in which vibration is applied.

3 and 4, the insulator 100 has one side fixed to the side surface or the internal structure of the enclosure main body 10, and the bus bar 150 connected to the other side. The insulator body 110 is fixed to the enclosure body 10 so as to prevent vibration from being transmitted to the enclosure body 10 and the bus bar via the insulator 100, An elastic member 130 provided inside the main body 110 and a seismic main body 120 coupled to the elastic member 130.

One side of the insulator body 110 is fixed to the inside of the enclosure main body 10, and the other end of the insulator main body 120 is inserted into the other side. A plurality of wrinkles 111 are formed on the outer circumferential surface of the insulator body 110 along the circumferential direction. The elastic member 130 is inserted into the insulator body 110.

The elastic member 130 elastically connects the insulator main body 110 and the earthquake-resistant main body 120 to prevent vibration from being transmitted between the insulator main body 110 and the earthquake-resistant main body 120. The elastic member 130 may be a spring or an anti-vibration rubber, and may prevent direct contact between the insulator body 110 and the vibration-proof body 120.

The seismic main body 120 is inserted into the other side of the insulator body 110 and is coupled to the elastic member 130. Accordingly, since the vibration-proof main body 120 is elastically disposed on the insulator main body 110, it is possible to prevent the vibration from being directly transmitted to the bus bar 150. An insulating member 121 is provided on an outer circumferential surface of the earthquake-proof main body 120 to prevent it from contacting the inside of the insulator main body 110 and to insulate it. In addition, it is needless to say that the insulating member 121 may additionally perform a vibration-proof function like the elastic member 130.

4, when the vibration is generated, the vibration-proof main body 120 is elastically conveyed into the insulator main body 110. When the vibration is released, as shown in FIG. 3, 120 are returned to the home position. Since the insulator body 110 and the vibration-proof body 120 are coupled with each other to elastically move relative to each other about the elastic member 130, the insulator body 110 can absorb or transmit the vibration or shock regardless of the direction of the generated vibration or shock. have.

Therefore, a short circuit or a contact failure occurs on the bus bar 150 due to a vibration such as an earthquake, and fire can be prevented from being caused by the deterioration phenomenon. Also, if a structure for connecting the insulator and the bus bar is required, it is applicable to another distribution board and a motor control board.

FIG. 5 is a front view showing the double shaft type vibration isolation device 200 shown in FIG. 2, FIG. 6 is a side exploded view illustrating the double shaft type vibration isolation device 200 shown in FIG. 5, 5 is a reference view showing a state in which vibration is applied to the biaxial shaft type shockproof device 200 shown in FIG. Hereinafter, the biaxial-type seismic isolation device 200 will be described as being installed and applied to the lower part of the switchboard 1 or the distribution panel or the motor control panel.

5 to 8, the double shaft type vibration isolation device 200 includes an excitation part 210 installed at a part where vibration is generated, and an excitation part 210 disposed on the excitation part 210 and fixed to the bottom surface of the structure. An oscillating unit 230 interposed between the vibrating unit 210 and the vibrating unit 220 to absorb vibrations and a vibrating unit 230 disposed between the vibrating unit 210 and the vibrating unit 220 And a gap maintaining unit 240 for preventing the isometric unit 230 from being continuously exposed to the load of the structure.

Here, the vibrating unit 210 and the vibrating unit 220 are names set based on the direction of transmission of vibrations, and conversely, the vibration transmitting direction of the vibrating unit and the vibrating unit can be changed.

A pair of coupling shafts 211 protrude from the center of the upper surface of the vibrating unit 210. Accordingly, the bottom surface of the vibrating unit 210 is fixed on a mounting surface on which a structure such as the switchboard 1 is installed, and the coupling shaft 211 protrudes along the longitudinal direction on the upper surface, And the seismic isolation unit 230 are combined.

6, the grip portion 220 is disposed on the upper portion of the vibrating portion 210 and includes a pair of first fastening holes 221 Is formed at the central portion, a second fastening hole 222 is formed so as to face the first fastening holes 221 on the center line, and the upper surface is fixed to the bottom surface of the structure.

At this time, the seismic isolation unit 230 is disposed between the vibrating unit 210 and the cover 220, and the coupling shaft 211 penetrates through the inside of the vibration isolator 230. The seismic isolation unit 230 includes an elastic portion 231 formed to be deformable in its outer shape and an anti-vibration portion 232 formed to prevent the outer shape from being deformed.

The elastic portion 231 is formed with a first coupling hole 231a through which the coupling shaft 211 passes.

The elastic member 231 and the vibration-proofing unit 232 are alternately arranged in the alternating unit 230 and are formed as a plurality of layers. Here, the height of the elastic part 231 is preferably larger than the height of the vibration-proof part 232, but the height of the elastic part 231 can be adjusted in consideration of the load or scale of the structure. In addition, since the width of the elastic portion 231 may be increased as the height of the elastic portion 231 is increased, the width of the vibration-proof portion 232 may be greater than the width of the elastic portion 231.

The anti-vibration part 232 is formed with a third coupling hole 232a so that the coupling shaft 211 can be coupled therethrough.

The gap holding part 240 includes an upper support frame 241 screwed on the second fastening hole 222 and vertically adjustable in height, A resilient member 243 disposed to surround the upper support frame 241 and the lower support frame 242 and a lower support frame 242 disposed on the upper side of the elastic member 243, And a seal sticker 246 attached to a portion where the upper support frame 241 and the lower support frame 242 contact each other.

A snap ring 247 for supporting the elastic member 243 is coupled to the center of the lower support frame 242. The snap ring 247 may be coupled to one end of the elastic member 243 and elastically connected to the lower support frame 242.

The upper support frame 241 is screwed to the second fastening hole 222 to support the load of the upper structure of the clamped portion 220 from the vibrating portion 210, A nut 223 is provided on an upper portion or a lower portion of the second fastening hole 222 so as to stably support the load.

The elastic member 243 is a kind of resilient spring which is arranged to surround the outer peripheral surface of the upper support frame 241 and the lower support frame 242. The elastic member 243 is disposed between the upper support frame 241 and the lower support frame 242 And is formed so as to be bent and deformed in shape when one of them deviates on a virtual extension line. And guiding the upper and lower support frames 241 and 242 to be positioned on a virtual extension line of the gap holding unit 240 when the gap holding unit 240 is installed. When the upper holding frame 241 is moved upwardly when the gap holding part 240 is restored, the elastic supporting member 243 is moved so that the lower supporting frame 242 can return to a virtual extension line It also provides resilience.

The seal sticker 246 is attached to an outer peripheral surface of a portion where the upper support frame 241 and the lower support frame 242 contact each other. Therefore, when an external force is applied to one of the upper support frame 241 and the lower support frame 242, the seal sticker 246 breaks and the user can see the influence can confirm.

Here, the upper support frame 241 and the lower support frame 242 are mutually different components and are in contact with each other at a coupling position by a load of a structure. However, the upper support frame 241 and the lower support frame 242 are integrally formed, 220 and the exciting unit 210 are separated from each other on a virtual extension line when they are mutually moved relative to each other.

Although not shown in the drawing, the gap holding part 240 may be coupled so as to support the to-be-swelled part 220 while being coupled from the exciting part 210 and conveyed upward.

The vibration isolator 230 includes an elastic portion 231 having an outer shape elastically deformable, a vibration preventing portion 232 having an outer shape so as not to be deformed, an outer peripheral surface of the coupling shaft 211, An impact absorbing layer (not shown) may be provided between the anti-vibration portion 231 and the anti-vibration portion 232.

7 and 8, when an external force is applied to the vibrating part 210, the elastic part 231 absorbs vibrations or shocks generated in the vertical direction while the external shape is deformed, The outer shape is deformed by vibration or impact. The anti-vibration part 232 provides a function of absorbing vibration or impact generated in the vertical direction between the elastic parts 231. The outer shape of the elastic portion 231 is deformed due to the vibration or impact pressure.

As shown in FIG. 7, vibrations are applied to the vibrating unit 210 so that the vibrating unit 210 moves in the horizontal direction. At this time, the gap holding portion 240 is deformed due to the separation of the imaginary extension line as the shaft supporting the load between the vibrating portion 210 and the gripped portion 220 is collapsed. The coupling shaft 211 and the lower support frame 242 are simultaneously moved while the upper and lower support frames 241 and 242 move along the vibrating part 220 under the vibrating part 210. Therefore, The function of the interval maintaining unit 240 is lost by being separated from the imaginary extension line.

8, the thickness of the elastic portion 231 is reduced by the upper load, and the shape of the facing unit 230 is deformed into a substantially parallelogram shape in accordance with the movement of the coupling shaft 211. [ do. This provides an effect of preventing vibration from being transmitted to the to-be-swelled portion 220 in a vertical direction while a load is applied to the beating unit 230 while the vibrating unit 210 moves in the horizontal direction.

Then, the elastic restoring force of the elastic part 231 returns to the original shape.

However, since the gap holding unit 240 is not automatically restored to its original position, the upper and lower structures 220 are lifted and restored. Also, since the seal sticker 246 is broken, it is also required to attach the seal sticker 246 to a new one.

Accordingly, since the interval holding unit 240 prevents the load of the structure such as the transmission and distribution board from being continuously applied to the seismic isolation unit 230, the life span of the seismic isolation unit 230 can be expected to be further increased.

Although not shown in the drawings, additional embodiments will be briefly described.

The present invention relates to an outer case having an outer casing body having a door which can be opened and closed on one surface thereof and having a receiving space therein, a pair of coupling shafts arranged in parallel to the center of the outer casing body along its longitudinal direction, Wherein the bottom surface of the main body is provided with a vibrating part provided on a part where vibration is generated, a fixed part fixed on the bottom surface of the enclosure main body and spaced from the upper part of the vibrating part, And an isolating unit formed of a plurality of layers and interposed between the vibrating unit and the vibrating unit to prevent transmission of vibration, Thereby preventing the unit from being continuously exposed due to the load of the enclosure main body, This applies to a distribution panel provided with a two-axis type seismic isolation device comprising holding parts spacing provided such that every other variations are possible.

And a bottom surface formed in a direction orthogonal to the lower end of the coupling shaft, the coupling shaft having a pair of coupling shafts extending in the longitudinal direction, A vibrating portion which is disposed on the upper side of the vibrating portion and fixed to the bottom surface of the enclosure main body and has a first fastening hole formed at the center so as to be resiliently coupled with the coupling shaft; And a vibration isolating unit which is inserted between the vibrating unit and the vibrating unit to block vibrations from being transmitted to the vibration isolating unit and is spaced apart from the vibrating unit by a predetermined interval between the vibrating unit and the vibrating unit, Thereby preventing continuous exposure by a load of the enclosure main body, and in the case where vibration exceeding a set range is generated, In a motor control panel having a two-axis type base isolation system including a maintenance intervals provided so that variations can be applied.

The above-described distribution panel and motor control panel are similar to each other in the interior of the electric power transmission and distribution panel 1, and the structure of the double shaft type vibration isolation device for earthquake-proof design is applied to the lower part of the structure, The present invention is not limited thereto.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken in conjunction with the present invention. But can be carried out within a range that does not deviate. Accordingly, such modifications are also considered to be within the scope of the present invention, and the true scope of protection of the present invention should be determined by the technical idea of the following claims.

1: Switchboard 10: Enclosure main body
11: accommodation space 12: door
13: perspective window 100: insulator
110: Insulator body 111: Crease
120: Seismic main body 121: Insulation member
130: Elastic member 150: Bus bar
200: Biaxial-type isolator 210: Exciter
211: coupling shaft 212: lower support frame groove
220: blood clot 221: first fastener
222: second fastening hole 223: nut
230: seismic isolation unit 231:
231a: first coupling hole 231b: second coupling hole
231c: engaging projection 232:
232a: third coupling ball 232b: fourth coupling ball
233: an impact absorbing layer 240:
241: upper support frame 242: lower support frame
243: Elastic member 244: Separation frame
246: Seal sticker 247: Snap ring

Claims (13)

A pair of coupling shafts extending in the longitudinal direction along the longitudinal direction and a bottom surface formed in a direction orthogonal to the lower end of the coupling shaft,
A pawl portion which is disposed on the upper side of the excavating portion and is fixed to the bottom surface of the structure and has a first fastening hole at the center so as to be resiliently coupled with the mating shaft;
An elastic part which is inserted in the coupling shaft between the vibrating part and the driven part to block transmission of vibration and has a pair of first coupling holes to be inserted into the coupling shaft and is elastically arranged in the horizontal direction, And an anti-vibration unit disposed on an upper side or a lower side of the elastic portion and having a third engagement hole formed to be inserted into the engagement shaft;
A spacing maintaining unit for maintaining the predetermined interval between the vibrating unit and the to-be-swing unit to prevent the seismic isolation unit from being continuously exposed by a load of the structure, Including,
Wherein the vibration isolating unit is configured such that a plurality of the elastic portion and the vibration preventing portion are alternately stacked, and when the vibration is applied, the interval maintaining portion moves in the horizontal direction to absorb the vibration in the vertical direction while the set interval is deformed. . delete The method according to claim 1,
Wherein the elastic portion is formed of a deformable material, and the vibration-proof portion is formed of a metallic material so that the external shape is not deformed. The method according to claim 1,
The above-
Wherein a bottom portion of the dustproof portion is formed to be at least equal to or larger than a bottom of the elastic portion, or a side surface of the dustproof portion protrudes further from a side extension line of the elastic portion. delete The method according to claim 1,
The space-
A plurality of lower support frames protruding from the upper surface of the vibrating unit in the same direction as the projecting direction of the coupling shaft at equal intervals around the coupling shaft,
An upper support frame which is screwed to a second fastening hole formed corresponding to the position of the lower support frame around the first fastening hole and is movably coupled in a vertical direction and is arranged to be in contact with an upper surface of the lower support frame,
And a seal sticker attached to surround the outer circumferential surface of a portion where the lower support frame and the upper support frame are in contact with each other. The method of claim 6,
The space-
And a resilient member arranged to integrally surround the upper support frame and the lower support frame and elastically protecting an imaginary extension line between the upper support frame and the lower support frame. An enclosure main body having a door capable of being opened and closed at one surface thereof and having a receiving space therein;
At least one coupling axis is formed along the longitudinal direction in the center of the upper surface and a bottom surface formed in a direction orthogonal to the coupling axis is provided at a portion where vibration is generated;
A pawl portion which is disposed on an upper side of the vibrating portion and is fixed to a bottom surface of the enclosure main body and has a first fastening hole formed at a center thereof so as to be resiliently coupled with the coupling shaft;
An elastic part which is inserted in the coupling shaft between the vibrating part and the driven part to block transmission of vibration and has a pair of first coupling holes to be inserted into the coupling shaft and is elastically arranged in the horizontal direction, And an anti-vibration unit disposed on an upper side or a lower side of the elastic portion and having a third engagement hole formed to be inserted into the engagement shaft;
The interval between the vibrating section and the to-be-gripped section is maintained to prevent the vibration isolating unit from being continuously exposed by the load of the enclosure main body, and when the vibration exceeding the set range is generated, And a holding portion,
Wherein the vibration isolating unit is configured such that a plurality of the elastic portion and the vibration preventing portion are alternately stacked, and when the vibration is applied, the interval maintaining portion moves in the horizontal direction to absorb the vibration in the vertical direction while the set interval is deformed. . The method of claim 8,
Further comprising an insulator which is fixed to one side of the enclosure main body and is connected to the other side of the enclosure main body and is elastically connected to prevent vibration transmitted from the enclosure main body from being directly transmitted to the booth. A switchboard with a biaxial isolator. The method of claim 9,
The insulator,
A plurality of wrinkles protruding along the circumference on the outer circumferential surface, an insulator body having one side of the elastic member to which the one end of the elastic member is coupled,
And a seismic main body inserted partially into the insulator main body and coupled to the other end of the elastic member so as to be insulated from the insulator main body. The method of claim 10,
The insulator,
And an insulating member interposed between the insulator main body and the earthquake-resistant main body to prevent contact between the main body and the earthquake-resistant main body. An enclosure main body having a door capable of being opened and closed at one surface thereof and having a receiving space therein;
A pair of coupling shafts extending in the longitudinal direction along the longitudinal direction and a bottom surface formed in a direction orthogonal to the lower end of the coupling shaft,
A pawl portion which is disposed on an upper side of the vibrating portion and is fixed to a bottom surface of the enclosure main body and has a first fastening hole formed at a center thereof so as to be resiliently coupled with the coupling shaft;
An elastic part which is inserted in the coupling shaft between the vibrating part and the driven part to block transmission of vibration and has a pair of first coupling holes to be inserted into the coupling shaft and is elastically arranged in the horizontal direction, And an anti-vibration unit disposed on an upper side or a lower side of the elastic portion and having a third engagement hole formed to be inserted into the engagement shaft;
The interval between the vibrating section and the to-be-gripped section is maintained to prevent the vibration isolating unit from being continuously exposed by the load of the enclosure main body, and when the vibration exceeding the set range is generated, And a holding portion,
Wherein the vibration isolating unit is configured such that a plurality of the elastic portion and the vibration preventing portion are alternately stacked, and when the vibration is applied, the interval maintaining portion moves in the horizontal direction to absorb the vibration in the vertical direction while the set interval is deformed. . An enclosure main body having a door capable of being opened and closed at one surface thereof and having a receiving space therein;
A pair of coupling shafts extending in the longitudinal direction along the longitudinal direction and a bottom surface formed in a direction orthogonal to the lower end of the coupling shaft,
A pawl portion which is disposed on an upper side of the vibrating portion and is fixed to a bottom surface of the enclosure main body and has a first fastening hole formed at a center thereof so as to be resiliently coupled with the coupling shaft;
An elastic part which is inserted in the coupling shaft between the vibrating part and the driven part to block transmission of vibration and has a pair of first coupling holes to be inserted into the coupling shaft and is elastically arranged in the horizontal direction, And an anti-vibration unit disposed on an upper side or a lower side of the elastic portion and having a third engagement hole formed to be inserted into the engagement shaft;
The interval between the vibrating section and the to-be-gripped section is maintained to prevent the vibration isolating unit from being continuously exposed by the load of the enclosure main body, and when the vibration exceeding the set range is generated, And a holding portion,
Wherein the vibration isolating unit is configured such that a plurality of the elastic portion and the vibration preventing portion are alternately stacked, and when the vibration is applied, the interval maintaining portion moves in the horizontal direction to absorb the vibration in the vertical direction while the set interval is deformed. .

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