KR101778083B1 - Earthquake-Resistant Swichboard with Attenuation Apparatus and Restriction Apparatus of Displacement - Google Patents

Abstract

The present invention relates to a seismic distribution board comprising: a distribution unit; and a seismic unit installed in a lower part of the distribution unit to prevent the distribution unit from being turned over by overturn moment generated by earthquake or vibration, controlling a vertical displacement to prevent the distribution unit from being separated by the vertical displacement with an interface force, and attenuating earthquake force or vibration. The seismic unit comprises four seismic devices installed at four corners of an enclosure. The seismic device includes upper and lower plates, a horizontal/vertical attenuation unit, a supporting block unit, a spring unit, and a displacement restriction unit. Accordingly, the horizontal/vertical attenuation unit and the spring unit to maintain durability of the horizontal/vertical attenuation unit are included to attenuate the earthquake force, and a horizontal displacement over a predetermined level is overcame by an internal force of a circular steel plate and a horizontal displacement restriction round rod, thereby providing an effect capable of preventing breakage.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an Earthquake-Resistant Swichboard with Attenuation Apparatus and Restriction Apparatus of Displacement,

The present invention relates to an earthquake-resistant switchboard capable of attenuating an earthquake-induced seismic force and restricting vertical displacement due to supporting force or vibration, and more particularly, to an earthquake-resistant switchboard installed at a lower portion of a power- It is possible to prevent the power distribution portion from being conducted by a conduction moment generated by earthquake or vibration and to prevent the power distribution portion from being separated due to vertical displacement by restricting vertical displacement and to damp earthquake or vibration To an earthquake-resistant switchboard that attenuates seismic force and controls vertical displacement.

An earthquake is a phenomenon in which the energy inside the earth comes to the surface and the earth is divided and shaken and acts as a load on the building.

The seismic load is the inertial force due to the ground motion, and the building may be horizontal or vertical irregular, or the unexpected action of the non-structural element may cause the load to be concentrated on a specific layer or a specific structural member.

Therefore, all structures subject to the earthquake-proof design and their constituent members should be provided with a certain strength to withstand the earthquake and ductility capable of flexibly responding to the earthquake shake .

Seismic design means a design considering additional earthquake load in designing to maintain the safety and function of the structure even after earthquake or earthquake. However, it is not designed to prevent damage to all expected earthquakes, The following three items are targeted.

 Structural and non-structural members should not be damaged in small-scale earthquakes. In mid-scale earthquakes, damage to non-structural members should not be allowed. Structural members should not be damaged. And should not cause injury to persons.

The requirement for earthquake-resistant design was introduced in 1988, and the earthquake-resistant design obligation was applied to six or more floors or buildings with a floor area of 100,000 or more. In 1995, the building was expanded from more than 6 floors to more than 10,000 floors. It has been expanded to more than 1,000, and by 2015, seismic design has been mandated for all buildings with more than three floors or more than 500.

In general, telecommunication panels such as switchgear, surveillance panel, distribution panel and telecommunication panel are installed on the lower frame and installed on the concrete foundation floor or floor fixing plate because they are bulky and have a large load.

Therefore, when an earthquake occurs in a building with such a telecommunication panel, damage to the panel occurs. The magnitude of the seismic force affecting the building in case of an earthquake varies depending on the structural characteristics such as height, shape and material of the building. It is necessary to protect the panel from earthquake. To protect the panel, an earthquake-proof earthquake-proof mount is required.

In particular, in areas where systems are required to be processed online / real-time, such as information and communication panels, especially in areas with high publicity, in our country, which is close to Japan where earthquakes are frequent, There is a desperate need.

Therefore, the earthquake disaster countermeasures law (Law 9636) and the earthquake disaster countermeasures enforcement ordinance (Presidential order 21362) require all earthquake disaster countermeasures law (Law 9636) and earthquake disaster countermeasures enforcement order (Presidential decree 21362) to establish earthquake countermeasures for all public buildings and facilities.

In general, switchgear is an electrical facility that supplies industrial power to users securely, and is a device used for monitoring, controlling, and protecting electrical systems when power is sent from a power plant or substation to a customer several times.

The switchboard comprises an enclosure defining an internal space of a predetermined size; And a distribution device such as a busbar, an air circuit breaker, a wiring breaker, and a relay, which are installed inside the enclosure and installed for distribution, control, and protection to various electric equipment systems.

The enclosure should be able to safely store the power distribution device and satisfy the conditions that it is strong against vibration and external impact, but the manufacturing cost is low and the inside and outside appearance should be considerable.

Since the above-mentioned switchboard is fixed to the ground, there is a problem that the enclosure provided in the switchboard may be deformed due to the vibration of the seismic wave when an earthquake occurs, or various electric devices installed inside the switchboard may be damaged, there was.

In this case, there is a problem that power can not be stably supplied to a place where electric power is required, and electric shock or the like may occur due to a short circuit.

Therefore, even if vibration is applied to the switchboard due to earthquake, it prevents the internal parts of the switchboard from being damaged and prevents the switchboard from falling down, preventing the switchboard enclosure from being damaged and preventing safety accidents such as power outage, A power transmission and distribution panel is desperately required.

In addition, when an earthquake occurs, vibration shocks applied to the switchboard by the seismic equipment under the switchboard are mitigated, but some impacts are not completely mitigated and some impacts are transmitted to the devices in the switchboard. In order to mitigate such shocks, the lower edge of the switchboard, 4 to 6 vibration and earthquake resistant devices were required.

It is necessary to install the seismic equipments on the switchboard to mitigate the impact on the equipment sufficiently to maintain the performance of the power distribution equipment even in the event of an earthquake.

An earthquake-resistant switchboard should be able to control the vertical displacement because the upper unidirectional maximum displacement width of the earthquake should be less than 75mm and should not be deviated from the fixed part or deformed or broken. Therefore, it is necessary to control the vertical displacement or vertical displacement by seismic force or vibration. Should be able to.

1. Korean Registered Patent No. 10-1632256 (Registered Date: June 15, 2016) Seismic Switchgear 2. Korean Registered Patent No. 10-1253774 (Date of Registration: April 05, 2013) 3. Korean Patent Registration No. 10-1269899 (Date of Registration: May 27, 2013) An electric switchboard having a support for vibration and shock prevention 4. Korean Registered Patent No. 10-1480853 (registered on Jan. 5, 2015) A switchboard having an anti-vibration and anti-vibration function 5. Korean Registered Patent No. 10-1042577 (Registered Date: June 13, 2011) Seismic Function Switchboard

In order to solve the above-mentioned problems, the present invention can attenuate horizontal displacement and vertical displacement due to seismic force or vibration within a certain range, attenuates horizontal and vertical displacement to overcome a certain range, And a spring portion for supporting a damping portion and a displacement restricting portion for restricting a vertical displacement of a predetermined or more horizontal displacement and a horizontal displacement for a predetermined horizontal displacement or more, and a displacement limiter The present invention provides an earthquake-resistant switchboard having a part.

An earthquake-resistant switchboard according to the present invention comprises an enclosure 11 including a lower frame and forming an internal space of a predetermined size, and an enclosure 11 installed inside the enclosure 11 and installed for power distribution, control, A distribution part comprising a distribution device including a busbar, an air circuit breaker, a circuit breaker, and a relay; The power distributing portion is provided at a lower portion of the power distributing portion to prevent the power distributing portion from being conducted due to the earthquake or the vibration generated by the vibration and to control vertical displacement to prevent the power distributing portion from being displaced due to vertical displacement, And an anti-vibration part capable of damping vibration.

The earthquake-resistant portion is composed of four earthquake-resistant devices installed at four corners of the enclosure.

The apparatus includes an upper plate coupled to the lower frame and receiving a load of the power distributing unit; A lower plate coupled to a concrete foundation or a lower mounting frame on which the earthquake-resistant switchboard is installed to transmit a load of the earthquake-resistant switchboard to the concrete foundation or the lower mounting frame; And the vertical force due to the seismic force or vibration is attenuated by the elastic force of the elastic rubber. The horizontal force to a certain extent is attenuated by the elastic force of the elastic rubber, and the horizontal force exceeding a certain range is transmitted to the four horizontal and vertical A horizontal and vertical attenuation section composed of an attenuator; And the upper part of the quadrangle is formed symmetrically with respect to the upper part of the quadrangle, and the four horizontal and vertical attenuators are symmetrically arranged on the upper part of the quadrangle, A supporting block for supporting the horizontal and vertical attenuator at the bottom and for supporting a horizontal force exceeding a predetermined range such as the horizontal and vertical attenuator to withstand the load; And vertical displacement generated by a seismic force or vibration, such as the horizontal and vertical dampers, is absorbed and accumulated by elastic deformation, and the impact transmitted to the power distributing portion is reduced, A spring for restoring the durability of the horizontal and vertical dampers; The upper plate is coupled to the upper plate, the lower portion is coupled to the lower plate, and the lower plate is connected to the lower plate in order to prevent the power distributing portion from being conducted to a conduction moment generated by a seismic force or vibration. And a displacement restricting portion for restricting the vertical displacement caused by the seismic force or vibration within a certain range.

In order to maintain strength, durability and elasticity, the horizontal and vertical attenuator is formed by alternately stacking a circular steel plate and a circular elastic rubber plate and wrapping them in a layer of elastic rubber having a predetermined thickness.

And a horizontal displacement limiting round bar of the supporting block is inserted into the center of the horizontal and vertical damper to limit the horizontal displacement when the horizontal displacement is greater than a predetermined level by the resistance of the circular steel plate and the horizontal displacement limiting round bar, A plurality of upper plate coupling holes for coupling with the upper plate are formed on an upper portion of the horizontal and vertical attenuator, and a lower plate coupled to the lower plate is coupled to the lower plate. A plurality of lower plate coupling holes are formed.

The upper plate coupling hole and the lower plate coupling hole are respectively coupled to the upper plate and the lower plate and are respectively provided with eight sleeves each having a female screw formed therein to prevent breakage of the coupling portions of the upper plate and the lower plate due to seismic force, .

The spring portion is of a cylindrical compression spring type so that the spring portion can uniformly receive the compression load due to the seismic force in the direction of the coil center line and the repulsive force limit is limited up to the height of the horizontal and vertical damper to maintain the durability of the horizontal and vertical damper.

Wherein the supporting block portion is a quadrangular hexagon with an inner hollow shape with a cover at the top and a cover at the bottom, the block cylindrical hole having the spring portion and the displacement restricting portion is formed at the center of the supporting block portion, Vertical damper is installed at the center of the four places where the horizontal and vertical attenuators are installed and inserted into the damper cylindrical hole of the horizontal and vertical attenuator so as to limit the horizontal displacement together with the circular steel plate of the horizontal and vertical attenuator, And a plurality of attenuator coupling holes for coupling with the horizontal and vertical attenuator are formed on an upper portion of the supporting block portion.

The displacement restricting portion is coupled to the upper plate so as to prevent the power distributing portion from being conducted to a conduction moment generated by the seismic force or vibration, and to prevent the power distributing portion from falling due to seismic force or vertical displacement due to vibration, To prevent the deterioration of the vehicle. In order to prevent the conduction preventing rod portion from being transmitted to the conduction moment generated by the earthquake or vibration like the conduction prevention rod portion, And a conduction preventing cylinder portion which receives the conduction moment with the same strength as the above-mentioned conduction preventing rod portion and controls vertical displacement caused by seismic force or vibration to move the conduction preventing rod portion up and down within a certain range.

The above-described earthquake-resistant switchboard can solve the problem to be solved by the present invention.

According to the seismic switchboard having the damping portion and the displacement restricting portion of the present invention, the horizontal and vertical damping portions and the spring portions that maintain the durability of the horizontal and vertical damping portions attenuate the seismic force, . It has improved restoring force and durability. It has the anti-fall prevention rod and anti-fall prevention cylinder part so that it can operate only at a certain vertical displacement and can control the vertical displacement. It can prevent the conduction moment of the switchboard by preventing the conduction moment. There is an effect that can be done.

1 is an overall front view of an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
2 is a schematic view of an earthquake-resistant apparatus according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
3 is a cross-sectional view taken along the line AA of a seismic isolation device according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
4 is a schematic view of an upper plate according to an anti-seismic switchboard having a damping portion and a displacement restricting portion of the present invention
5 is a schematic view of a bottom plate according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
6 is a schematic view of a horizontal and vertical damping portion according to an anti-vibration switchboard having a damping portion and a displacement restricting portion of the present invention
7 is a schematic view of a horizontal and vertical attenuator according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
8 is a cross-sectional view of the horizontal and vertical damper BB according to the seismic switchboard having the damping portion and the displacement restricting portion of the present invention
9 is a schematic diagram of a supporting block according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
10 is a schematic view of a displacement restricting part according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention
11 is a schematic view of a portion of an anti-tip rod according to an anti-vibration switchboard having a damping portion and a displacement restricting portion of the present invention
12 is an exploded view of an anti-reverse rod portion according to an anti-vibration switchboard having a damping portion and a displacement restricting portion of the present invention
13 is a schematic view of a portion of an anti-reverse cylinder according to an anti-vibration switchboard having a damping portion and a displacement restricting portion of the present invention
14 is a schematic view of a spring portion according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, 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.

In the following description, the term " seismic switchboard having a damping portion and a displacement limiting portion "according to the present invention can be used. The present invention is not limited thereto.

Hereinafter, a preferred embodiment of a "seismic switchboard having a damping portion and a displacement restricting portion" according to the present invention will be described in detail.

The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

2 is a schematic view of an earthquake-resistant apparatus according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention, Fig. 3 is a perspective view of the earthquake- 4 is a schematic view of an upper plate according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention, FIG. 5 is a perspective view of the damping portion and the displacement restricting portion of the present invention, 6 is a schematic view of a horizontal and vertical damping portion according to an anti-seismic switchboard having a damping portion and a displacement restricting portion according to the present invention, Fig. 7 is a schematic view of a damping portion and a displacement restricting portion 8 is a schematic view of a horizontal vertical attenuator BB section according to an earthquake-resistant switchboard having a damping section and a displacement restricting section according to the present invention, And FIG. 9 is a schematic view of a supporting block according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion of the present invention, FIG. 10 is a schematic view of a displacement restricting portion according to an earthquake-resistant switchboard having a damping portion and a displacement restricting portion, 11 is an outline view of an anti-reverse rod according to an anti-vibration switchboard having a damping portion and a displacement restricting portion of the present invention, FIG. 12 is an exploded view of an anti- FIG. 14 is a schematic view of a spring according to an anti-earthquake switchboard having a damping portion and a displacement restricting portion of the present invention. FIG. 14 is a schematic view of an anti-collision cylinder portion according to an anti-vibration switchboard having a damping portion and a displacement restricting portion of the present invention.

1, an earthquake-resistant switchboard A according to the present invention includes an enclosure 11 including a lower frame 111 and forming an internal space of a predetermined size, and an enclosure 11 installed inside the enclosure 11 A power distribution unit (1) composed of a power distribution device (12) including a busbar, an air circuit breaker, a wiring breaker, and a relay installed to distribute, control and protect power to the electrical system; Is provided at a lower portion of the power distributing portion (1) to prevent the power distributing portion (1) from being conducted by a conduction moment generated by an earthquake or vibration and to control the vertical displacement, And an anti-seize part (2) for preventing seizure and vibration from occurring.

The seismic resistant portion 2 is composed of four earthquake-resistant devices 2a installed at the four corners of the enclosure 11.

The seismic equipments 2a are installed at the bottom edge of the power distributing unit 1. When the bottom edge of the power distributing unit 1 and the length of one side of the power distributing unit 1 are longer than a certain length, It may be installed in six places in total.

1, the dustproof portion 2 is prefabricated on a lower mounting frame 31 to be installed on the concrete foundation 3, and the dustproof portion 2 is installed on the upper portion of the dustproof portion 2 Or may be installed directly on the concrete foundation 3 without the lower mounting frame 31.

The dustproof portion 2 may be completely set on the lower frame 111 and the lower mounting frame 31 and then installed on the concrete foundation 3 and installed on the upper portion of the power distribution unit 1. In this case, It is possible that the integral frame 31 is not included in the enclosure 11.

2 and 3, the seismic equipments 2a include an upper plate 21 coupled to the lower frame 111 and receiving a load of the power distribution unit 1; A lower plate 22 coupled to the concrete foundation or lower mounting frame 3 on which the earthquake-resistant switchboard A is installed and to transmit the load of the earthquake-resistant switchboard A to the concrete foundation or the lower mounting frame 3; The upper portion is coupled with the upper plate 21 and the vertical force due to the seismic force or vibration is attenuated by the elastic force of the elastic rubber. The horizontal force to a certain range is attenuated by the elastic force of the elastic rubber, A horizontal and vertical attenuation section 23 consisting of horizontal and vertical attenuators 23a; The upper part is formed in the shape of a quadrangle and the upper part is formed with a cylindrical cylindrical hole 241 at the center, the lower part is coupled with the lower plate 22, and the upper part of the quadrangle is symmetrical The horizontal and vertical attenuators 23a are coupled to support the horizontal and vertical attenuators 23a from below and the horizontal blocks 18a and 18b are supported by supporting blocks 24 )Wow; The vertical displacement generated by the seismic force or the vibration is absorbed and accumulated by the elastic deformation in the block cylindrical hole 241 of the supporting block part 24 and attenuated by the horizontal and vertical attenuation parts 23, A spring portion 25 for reducing the impact transmitted to the front portion 1 and restoring the displacement, and maintaining the durability of the horizontal and vertical damping portion 23; The upper part is coupled to the upper plate 21 and the lower part is coupled to the lower plate 22. The power transmission part 1 is installed in the inside of the spring part 25, And a displacement restricting unit 26 which limits the vertical displacement caused by the seismic force or the vibration within a certain range, such as the horizontal / vertical damping unit 23, to prevent the moment from being conducted.

In the seismic equipments (2a) of the present invention, the horizontal and vertical dampers (23) attenuate the vertical force due to the seismic force or vibration by the elastic force of the elastic rubber, and the horizontal force to a certain range is attenuated by the elastic force of the elastic rubber, The horizontal portion of the spring portion 25 is supported by the spring portion 25. The spring portion 25 absorbs and accumulates the vertical displacement generated by the seismic force or the vibration by the elastic deformation such as the horizontal and vertical damping portion 23, And the displacement restricting portion 26 serves to reduce the impact transmitted to the power distributing portion 1 by the seismic force or vibration Vertical attenuation portion 23 to prevent conduction to a conduction moment generated by the horizontal and vertical attenuation portions 23, And it serves to limit, and prevents the whole ship 1 is conducted to the conductive moment caused by seismic forces or vibration.

As shown in FIG. 4, the upper plate 21 is coupled with the lower frame 111 to receive a load of the power distribution unit 1, and has a rectangular shape with a predetermined thickness.

A load-head insertion groove 211 for inserting the upper end of the displacement restricting portion 26 into the upper plate 21 so that the upper plate 21 is horizontal without being exposed to the outside; A rod upper insertion groove 212 into which the upper end of the sliding cylindrical portion 2612 of the displacement limiting portion 26 is inserted; Four lower frame engaging holes 213 formed at the corners for engaging with the lower frame 111; A plurality of damper engaging holes 214 are formed in the shape of a plate screw bolt for engaging with the upper portion of each of the horizontal and vertical attenuators 23a and the plate screw bolts.

In order to prevent the horizontal and vertical attenuator 23a from being detached from the installation position of the upper plate 21, the horizontal and vertical attenuators 23a are installed at four positions on the lower surface of the upper plate 21, An upper damper insertion groove 215 into which a part of the upper portion of the damper 23a is inserted may be formed.

When the horizontal attenuator 23a is coupled only with the screw thread bolt, the material of the horizontal and vertical damper 23a is fixed to the circular steel plate 231 and the circular elastic rubber plate 232 via the elastic rubber The horizontal and vertical attenuator 23a should not be detached when the vibration proof portion 2 receives a conduction moment due to a certain depth because it is likely to be torn when the horizontal force is applied. (The example in which the horizontal and vertical attenuator 23a is inserted into the upper attenuator insertion groove 215 is not shown)

When the upper end of the sliding cylinder portion 2612 of the turn-off preventing rod portion 261 protrudes from the horizontal portion of the upper plate 21, the load-head insertion groove 211 may have a problem in joining with the lower frame 111 So that the power distributing unit 1 is not installed in a horizontal position. Therefore, the level of the power distributing unit 1 must be the same as that of the upper plate 21.

Similarly, when the dish screw head of the dish screw bolt protrudes from the horizontal part of the upper plate 21, there arises a problem in coupling with the lower frame 111, so that the power distributing part 1 It should be level with the upper plate 21 because it is not installed in a horizontal position.

The dish screw q bolts connecting the upper plate 21 and the horizontal and vertical damper 23a are screwed to the female screw formed on the sleeve 237 provided on the horizontal and vertical damper 23a, It should have a certain thickness to have strength.

5, the lower plate 22 is coupled to a concrete foundation 3 or a lower mounting frame 31 on which the earthquake-resistant switchboard A is installed, so that the load of the earthquake- To the base (3) or the lower mounting frame (31).

The lower plate 22 has a rectangular shape having the same shape as the upper plate 21 and the supporting block portion 24 is welded to the upper supporting block portion joining line 223.

Four lower mounting frame engaging holes 221 formed at corners of the lower plate 22 for engaging with the concrete foundation 3 or the lower mounting frame 31; Three to five displacement restricting portion engaging holes 222 for engaging with the displacement restricting portion 26 are formed.

6, the upper portion of the horizontal and vertical damping portion 23 is coupled to the upper plate 21, and the vertical force due to seismic force or vibration is attenuated by the elastic force of the elastic rubber, The horizontal force, which is attenuated by the elastic force of the elastic rubber and exceeds a predetermined range, is constituted by four horizontal vertical attenuators 23a which withstand the proof stress.

Although not shown in the figure, the upper portion of the horizontal and vertical damping portion 23 is connected to the upper plate 21 so that the horizontal and vertical damper 23a is not separated from the lower portion of the upper plate 21 and the upper portion of the supporting block portion 24, And a lower portion of the horizontal and vertical damping portion 23 can be inserted into the upper portion of the supporting block portion 24. [

As shown in FIGS. 7 and 8, the horizontal and vertical attenuator 23a is coupled with the upper plate 21, and the vertical force due to the seismic force or vibration is attenuated by the elastic force of the elastic rubber, The horizontal force is attenuated by the elastic force of the elastic rubber, and the lateral force over a certain range serves to withstand the force.

The horizontal and vertical attenuator 23a is formed by alternately stacking the circular steel plate 231 and the circular elastic rubber plate 232 so as to maintain strength, durability and elasticity, and the outside is wrapped with an elastic rubber 233 of a certain thickness .

A horizontal displacement limiting round bar 242 of the supporting block 24 is inserted into the center of the horizontal and vertical damper 23a and the circular steel plate 231 and the horizontal displacement limiting round bar 242 A damper cylinder hole 234 is formed which is larger than the diameter of the horizontal displacement limiting round bar 242 by an allowable horizontal displacement.

A plurality of upper plate coupling holes 235 for coupling with the upper plate 21 are formed on the horizontal and vertical attenuator 23a.

A plurality of lower plate coupling holes 236 for coupling with the lower plate 22 are formed below the horizontal and vertical attenuator 23a.

The upper plate coupling hole 235 and the lower plate coupling hole 236 are coupled to the upper plate 21 and the lower plate 22 by plate head screw bolts 2371 and screw bolts 2372, Eight sleeves 237 each having a female screw may be inserted in order to prevent the upper plate 21 and the lower plate 22 from being damaged.

The uppermost layer and the lowermost layer of the circular steel plate 231 are bonded to the sleeve 237 or to the plate head screw bolt 2371 and the screw bolt 2372 in order to increase the bonding strength It should be designed thick.

As shown in FIG. 9, the supporting block portion 24 has a hexahedron shape and an upper portion is formed into a quadrangular shape. A cylindrical block cylindrical hole 241 is formed at the center of the supporting block portion 24, The four horizontal and vertical attenuators 23a are coupled symmetrically to the upper surface of the quadrangle to support the horizontal and vertical attenuator 23a from the lower part thereof and the same as the horizontal and vertical attenuator 23a, Horizontal force over the range helps to withstand the load.

The supporting block portion 24 is a quadrangular bar having an inner hollow shape with a cover at the top and a cover at the bottom.

The support cylindrical portion 24 has a cylindrical cylindrical hole 241 formed at the center thereof to which the spring portion 25 and the displacement restricting portion 26 are provided.

Vertical vertical attenuators 23a of the supporting block 24 are inserted into the attenuator cylindrical holes 234 of the horizontal and vertical attenuator 23a at the centers of the horizontal and vertical attenuators 23a, Together with the circular steel plate 231 of the attenuator 23a, a horizontal displacement limiting round bar 242 for limiting the horizontal displacement is formed.

Since the horizontal and vertical damper 23a is broken when the horizontal and vertical damper 23a excessively corresponds to the horizontal displacement of the seismic force, the horizontal displacement limiting round bar 242 and the circular steel plate 231 ) To limit the horizontal displacement.

A plurality of attenuator coupling holes 243 for coupling with the horizontal and vertical attenuator 23a are formed on the supporting block portion 24.

In order to prevent the horizontal and vertical attenuator 23a from being detached from the installation position of the upper plate, the horizontal and vertical attenuator 23a is installed at four positions where the horizontal and vertical attenuator 23a on the upper surface of the supporting block 24 is installed. A lower damper insertion groove 244 into which a lower portion of the lower damper insertion groove 244 is inserted may be formed.

10, the displacement restricting portion 26 is installed inside the spring portion 25, the upper portion is engaged with the upper plate 21, and the lower portion is coupled with the lower plate 22 , The horizontal and vertical dampers (23) are designed to have a cone-like moment and a vertical displacement caused by the seismic force or the vibration to be constant, to prevent the power transmission part (1) from being conducted to a conduction moment generated by seismic force or vibration. It is a limitation within the range.

The displacement restricting portion 26 is coupled to the upper plate 21 so as to be able to withstand the conduction moment with a strength in order to prevent the discharge portion 1 from being transmitted to a conduction moment generated by a seismic force or vibration, Preventing rod portion 261 moving up and down within a certain range due to vertical displacement caused by the vertical displacement caused by the vertical displacement caused by the vertical displacement. The conduction preventing rod portion 261 is inserted into the space to allow the conduction preventing rod portion 261 to move up and down. The conduction preventing portion 261, like the conduction preventing rod portion 261, In order to prevent the conduction moment from being transmitted to the conduction moment generated by the vibration or the vibration, the conduction moment wins with the same strength as the conduction prevention rod portion 261, and the vertical displacement due to the seismic force or vibration is controlled, Preventing cylinder portion 262 for moving the cylinder block 262 up and down within a certain range.

As shown in FIGS. 11 and 12, the conduction prevention rod portion 261 is coupled to the upper plate 21 to prevent the power transmission portion 1 from being conducted to a conduction moment generated by a seismic force or vibration And it acts to move up and down within a certain range by vertical displacement due to seismic force or vibration.

The top end portion of the conduction preventing rod portion 261 is inserted into the upper plate 21 and has a certain length when the seismic equipments 2a cause compressive vertical displacement directed downward by compressive force due to seismic force or vibration, A main rod portion 2611 having a bolt-like shape in which a load male thread 261121 is formed at a lower end portion thereof by a predetermined length; The main rod portion 2611 is inserted into a rod insertion hole 26122 formed at the center and integrated with each other. An upper end portion of the main rod portion 2611 is inserted into the upper plate 21 to have a predetermined depth, and a frictional reducing means 26121 Is provided to allow the anti-falling rod portion 261 to move up and down smoothly without clearance in the interior of the conduction preventing cylinder portion 262, and the seismic equipments 2a can be tensioned or vibration- A sliding cylindrical portion 2612 in which the vertical displacement amount is limited by the upper end of the conduction preventing cylinder portion 262 when the vertical displacement is caused; A lower disk portion 2613 having a disk-like shape and having a predetermined thickness is formed by screwing the rod male screw portion 261121 at the lower end of the main rod portion 2611 to make the sliding cylindrical portion 2612 come into close contact with the upper plate portion 21 .

The main rod portion 2611 includes a rod head portion 26111 inserted into the upper plate 21 and having a hexagonal groove 261111 formed therein so as to be rotatable by a wrench; A rod bolt portion 26112 which is connected to the lower portion of the rod head portion 26111 and is inserted into the sliding cylindrical portion 2612 and has the rod male screw portion 261121 formed thereunder and threadedly engaged with the lower circular plate portion 2613 ).

The sliding cylindrical portion 2612 is provided on the upper portion of the friction reducing means 216121 and is provided with a vertical displacement limiting ring 26123 which is in contact with the upper end of the transmission preventing cylinder portion 262 to limit the vertical displacement amount.

A disk female screw 26131 for screwing the rod male screw 261121 is formed at the center of the lower disk 2613.

The friction reducing means 26121 includes two sliding cylinder portions 2612 so as not to shake.

As shown in FIG. 13, the conduction preventing cylinder portion 262 provides space for the conduction preventing rod portion 261 to move up and down by inserting the conduction preventing rod portion 261 therein, In order to prevent the power distributing section 1 from being conducted to a conduction moment generated by an earthquake or vibration like the conduction preventing rod section 261, the conduction moment wins with the same strength as the conduction preventing rod section 261, And the vertical displacement caused by the vibration is controlled to move the conduction prevention rod unit 261 up and down within a certain range.

The conduction preventing cylinder portion 262 has a hollow therein. The conduction preventing rod portion 261 is inserted into the inside of the conduction preventing rod portion 261 so as to move up and down while rubbing against the inner surface of the conduction preventing rod portion 261. In order to overcome the conduction moment due to the seismic force, A cylinder body portion 2621 of a cylindrical shape having a thickness that is equal to the thickness of the cylinder body; The upper portion of the conduction preventing rod portion 261 is restricted by the portion of the conduction preventing rod portion 261 contacting the upper portion of the conduction preventing rod portion 261, A disk-shaped upper cover portion 2622 for supplementing the strength of the cylinder body portion 2621; The lower end of the cylinder body portion 2621 and the lower end of the lower plate 2221 are fixed to each other so that the cylinder body portion 2621 is not detached when the transition prevention rod portion 261 is vertically displaced in the cylinder body portion 2621. [ And blocks the lower portion of the cylinder body portion 2621 and contacts the lower end of the conduction prevention rod portion 261 to restrict the downward vertical displacement to complement the strength of the cylinder body portion 2621 Shaped lower cover portion 2623 which is shaped like a disk.

A lower cover bolt insertion hole 26231 for screw bolt connection with the lower plate 22 is formed in the lower cover portion 2623.

The vertical displacement amount restricting ring 26123 contacts the lower surface of the upper cover portion 2462 to prevent the transition prevention rod portion 261 from rising up, thereby restricting the vertical displacement of the upper portion.

A main rod passage hole 26221 through which the main rod portion 2611 of the turn prevention rod portion 261 passes is formed at the center of the upper cover portion 2622.

Four to eight body bolt insertion holes 26211 are formed at the lower end of the cylinder body portion 2621 and are formed with a female screw for screw connection with a coupling bolt between the lower cover portion 2623 and the lower plate 22.

14, the spring member 25 is installed in the cylindrical cylindrical hole 241 of the supporting block portion 24 so as to be perpendicular to the horizontal and vertical dampers 23, The displacement is absorbed and accumulated by using elastic deformation, and the impact transmitted to the power distributing unit 1 is reduced, the displacement is restored, and the durability of the horizontal and vertical damping unit 23 is maintained.

 The spring portion 25 is of a cylindrical compression spring type so as to uniformly receive a compression load due to a seismic force in the direction of the coil center line, and the repulsive force limit is set so that the horizontal and vertical damping portions 23, To the height of the portion (23).

That is, if the repulsive force of the spring portion 25 is larger than the horizontal / vertical damping portion 23, the horizontal / vertical damping portion 23 can not perform the main function of absorbing and attenuating vibration, If the repulsive force of the spring portion 25 is smaller than the horizontal and vertical damping portions 23, the durability of the horizontal and vertical damping portions 23 becomes a problem and the performance of the overall damping and vibration absorption is deteriorated It happens.

According to the earthquake-resistant switchboard A having the damping portion and the displacement restricting portion of the present invention, the horizontal and vertical damping portions 23 and the horizontal and vertical damping portions 23 have the spring portions 25 for maintaining durability, The horizontal force displacement equal to or greater than a certain level is prevented by collapsing due to the internal force of the circular steel plate 231 and the horizontal displacement limiting round bar 242 and has an improved restoring force and durability. It can operate only at a certain vertical displacement to control the vertical displacement, and it is possible to overcome the conduction moment with the load and to prevent the switchboard from being conducted.

A: Seismic Switchboard
1: Distribution part 11: Enclosure
111: lower frame 12: distribution device
2:
2a: Seismic equipment 21: Upper plate
211: load-head inserting groove 212: rod upper inserting groove
213: lower frame coupling hole 214: upper attenuator insertion groove
22: Lower plate
221: Lower mounting frame fitting hole 222: Displacement restraining fitting hole
23: Horizontal vertical attenuator 23a: Horizontal vertical attenuator
231: round steel plate 232: circular elastic rubber plate
233: elastic rubber 234: attenuator cylindrical hole
235: upper plate engaging hole 236: lower plate engaging hole
237: Sleeve 2371: Flat head screw bolt
2372: Screw bolt 24: Supporting block part
241: Block cylindrical hole 242: Horizontal displacement limiting round bar
243: Attenuator coupling hole 244: Lower damper insertion groove
25: spring portion
26: Displacement restricting portion 261:
2611: Main rod section 26111: Load head section
261111: Hexagon groove 26112: Rod bolt part
261121: Rod male thread 2612: Sliding cylindrical part
26121: Friction reducing means 261211: Ball bearing set
261212: Stopper ring 26122: Rod insertion hole
26123: Vertical displacement limiting ring 2613: Lower disc portion
26131: disc female screw 262: anti-falling cylinder part
2621: Cylinder body part 26211: Body bolt insertion hole
262111: female screw 2622: upper cover part
26221: Main rod passage hole 2623: Lower cover part
26231: Lower cover bolt insertion hole
3: Concrete foundation 31: Lower mounting frame

Claims (8)

An enclosure 11 which includes a lower frame 111 and forms an internal space of a predetermined size, a booth bar installed inside the enclosure 11 and installed for power distribution, control and protection in an electrical equipment system, (1) composed of a power distribution device (12) including a breaker, a wiring breaker, and a relay;
Is provided at a lower portion of the power distributing portion (1) to prevent the power distributing portion (1) from being conducted by a conduction moment generated by an earthquake or vibration and to control the vertical displacement, An earthquake-resistant switchboard (A) comprising an earthquake-resistant portion (2) capable of preventing separation and capable of damping seismic forces and vibrations,
The seismic resistant portion 2 is composed of four earthquake-resistant devices 2a installed at the four corners of the enclosure 11,
The earthquake-proof apparatus (2a) includes an upper plate (21) coupled to the lower frame (111) and receiving a load of the power distribution unit (1);
A lower plate 22 connected to the concrete foundation or lower mounting frame 3 on which the earthquake-resistant switchboard A is installed and for transmitting the load of the earthquake-resistant switchboard A to the concrete foundation 3 or the lower mounting frame 31; )Wow;
The upper portion is coupled with the upper plate 21 and the vertical force due to the seismic force or vibration is attenuated by the elastic force of the elastic rubber. The horizontal force to a certain range is attenuated by the elastic force of the elastic rubber, A horizontal and vertical attenuation section 23 consisting of horizontal and vertical attenuators 23a;
The upper part is formed in the shape of a quadrangle and the upper part is formed with a cylindrical cylindrical hole 241 at the center, the lower part is coupled with the lower plate 22, and the upper part of the quadrangle is symmetrical The horizontal and vertical attenuators 23a are coupled to support the horizontal and vertical attenuators 23a from below and the horizontal blocks 18a and 18b are supported by supporting blocks 24 )Wow;
The vertical displacement generated by the seismic force or the vibration is absorbed and accumulated by the elastic deformation in the block cylindrical hole 241 of the supporting block part 24 and attenuated by the horizontal and vertical attenuation parts 23, A spring portion 25 for reducing the impact transmitted to the front portion 1 and restoring the displacement, and maintaining the durability of the horizontal and vertical damping portion 23;
The upper part is coupled to the upper plate 21 and the lower part is coupled to the lower plate 22. The power transmission part 1 is installed in the inside of the spring part 25, And a displacement restricting section 26 which, like the horizontal / vertical damping section 23, prevents the moment from being conducted, and which limits the vertical displacement due to seismic force or vibration within a certain range,
The displacement restricting portion 26 is coupled to the upper plate 21 so as to be able to withstand the conduction moment with a strength in order to prevent the discharge portion 1 from being transmitted to a conduction moment generated by a seismic force or vibration, Preventing rod portion 261 moving up and down within a certain range due to vertical displacement caused by the vertical displacement caused by the vertical displacement caused by the vertical displacement.
The conduction preventing rod portion 261 is inserted into the space to allow the conduction preventing rod portion 261 to move up and down. The conduction preventing portion 261, like the conduction preventing rod portion 261, In order to prevent the conduction moment from being transmitted to the conduction moment generated by the vibration or the vibration, the conduction moment wins with the same strength as the conduction prevention rod portion 261, and the vertical displacement due to the seismic force or vibration is controlled, And an anti-detachment cylinder portion (262) for moving the anti-rotation cylinder portion (262) up and down within a predetermined range.
The method according to claim 1,
The horizontal and vertical attenuator 23a is formed by alternately stacking a circular steel plate 231 and a circular elastic rubber plate 232 so as to maintain strength, durability and elasticity, and the outside is wrapped with an elastic rubber 233 of a certain thickness ,
A horizontal displacement limiting round bar 242 of the supporting block 24 is inserted into the center of the horizontal and vertical damper 23a and the circular steel plate 231 and the horizontal displacement limiting round bar 242 A damper cylinder hole 234 which is larger than the diameter of the horizontal displacement limiting round bar 242 by an allowable horizontal displacement is formed,
A plurality of upper plate coupling holes 235 for coupling with the upper plate 21 are formed on the horizontal and vertical attenuator 23a,
And a plurality of lower plate coupling holes (236) for coupling with the lower plate (22) are formed in the lower part of the horizontal and vertical attenuator (23a). The vibration damping switchgear
The method according to claim 1,
The supporting block portion 24 is a quadrangular bar having an inner hollow shape with a cover at the top and a cover at the bottom,
The block cylindrical hole 241 in which the spring portion 25 and the displacement restricting portion 26 are provided is formed at the center of the supporting block portion 24,
Vertical vertical attenuators 23a of the supporting block 24 are inserted into the attenuator cylindrical holes 234 of the horizontal and vertical attenuator 23a at the centers of the horizontal and vertical attenuators 23a, A horizontal displacement limiting round bar 242 for limiting the horizontal displacement is formed with the circular steel plate 231 of the attenuator 23a by a force,
And a plurality of attenuator coupling holes (243) for coupling with the horizontal and vertical damper (23a) are formed on an upper portion of the supporting block portion (24).
The method according to claim 1,
The upper plate 21 has a rectangular shape with a predetermined thickness,
A load-head insertion groove 211 for inserting the upper end of the displacement restricting portion 26 into the upper plate 21 so that the upper plate 21 is horizontal without being exposed to the outside;
A rod upper insertion groove 212 into which the upper end of the sliding cylindrical portion 2612 of the displacement limiting portion 26 is inserted;
Four lower frame engaging holes 213 formed at the corners for engaging with the lower frame 111;
A plurality of damper coupling holes 214 in the form of a screw thread bolt for coupling with an upper portion of each horizontal and vertical damper 23a by a screw thread bolt are formed,
The lower plate 22 has a rectangular shape having the same shape as that of the upper plate 21,
Four lower mounting frame engaging holes 221 formed at corners of the lower plate 22 for engaging with the concrete foundation 3 or the lower mounting frame 31;
And three to five displacement restricting portion engaging holes (222) for engaging with the displacement restricting portion (26) are formed.
delete 3. The method of claim 2,
The upper plate coupling hole 235 and the lower plate coupling hole 236 are coupled to the upper plate 21 and the lower plate 22 and are coupled to the upper plate 21 and the lower plate 22 Eight sleeves 237 each having a female thread formed therein are inserted and inserted in order to prevent breakage of the portion,
The spring portion 25 is of a cylindrical compression spring type so as to uniformly receive the compression load due to the seismic force in the direction of the coil center line, and the repulsive force limit is set by the horizontal and vertical attenuator 23a 23a) of the earthquake-resistant switchboard
5. The method of claim 4,
In order to prevent the horizontal and vertical attenuator 23a from being detached from the installation position of the upper plate 21, the horizontal and vertical attenuators 23a are installed at four positions on the lower surface of the upper plate 21, An upper damper insertion groove 215 into which a part of the upper portion of the damper 23a is inserted is formed,
In order to prevent the horizontal and vertical attenuator 23a from being detached from the installation position of the upper plate, the horizontal and vertical attenuator 23a is installed at four positions where the horizontal and vertical attenuator 23a on the upper surface of the supporting block 24 is installed. 23a) of the lower damper insertion groove (244) into which a part of the lower damper insertion groove (244)
The method of claim 1, wherein
The top end portion of the conduction preventing rod portion 261 is inserted into the upper plate 21 and has a predetermined length when the seismic equipments 2a cause compressive vertical displacement directed downward by a compressive force due to seismic force or vibration, A main rod portion 2611 having a bolt-like shape in which a compression vertical displacement amount is limited, a seismic force or a shear moment due to vibration is taken as a proof load, and a rod male screw thread 261121 is formed at a lower end portion thereof;
The main rod portion 2611 is inserted into a rod insertion hole 26122 formed at the center and integrated with each other. An upper end portion of the main rod portion 2611 is inserted into the upper plate 21 to have a predetermined depth, and a frictional reducing means 26121 Is provided to allow the anti-falling rod portion 261 to move up and down smoothly without clearance in the interior of the conduction preventing cylinder portion 262, and the seismic equipments 2a can be tensioned or vibration- A sliding cylindrical portion 2612 in which the vertical displacement amount is limited by the upper end of the conduction preventing cylinder portion 262 when the vertical displacement is caused;
A lower disk portion 2613 having a disk-like shape and having a predetermined thickness, which is screwed with the rod male screw 261121 at the lower end of the main rod portion 2611 to closely contact the sliding cylinder portion 2612 with the upper plate 21, Lt; / RTI >
The main rod portion 2611 includes a rod head portion 26111 inserted into the upper plate 21 and having a hexagonal groove 261111 formed therein so as to be rotatable by a wrench;
A rod bolt portion 26112 which is connected to the lower portion of the rod head portion 26111 and is inserted into the sliding cylindrical portion 2612 and has the rod male screw portion 261121 formed thereunder and threadedly engaged with the lower circular plate portion 2613 ),
The sliding cylinder portion 2612 is provided with a vertical displacement limit ring 26123 which is installed on the friction reducing means 26121 and contacts the upper end of the conduction preventing cylinder portion 262 to limit the vertical displacement amount of the tension,
A disk female thread 26131 for screw connection with the rod male thread 261121 is formed at the center of the lower disk 2613,
The friction reducing means 26121 includes two sliding cylinder portions 2612 so as not to shake,
The conduction preventing cylinder portion 262 has a hollow therein. The conduction preventing rod portion 261 is inserted into the inside of the conduction preventing rod portion 261 so as to move up and down while rubbing against the inner surface of the conduction preventing rod portion 261. In order to overcome the conduction moment due to the seismic force, A cylinder body portion 2621 of a cylindrical shape having a thickness that is equal to the thickness of the cylinder body;
The upper portion of the conduction preventing rod portion 261 is restricted by the portion of the conduction preventing rod portion 261 contacting the upper portion of the conduction preventing rod portion 261, A disk-shaped upper cover portion 2622 for supplementing the strength of the cylinder body portion 2621;
The lower end of the cylinder body portion 2621 and the lower end of the lower plate 2221 are fixed to each other so that the cylinder body portion 2621 is not detached when the transition prevention rod portion 261 is vertically displaced in the cylinder body portion 2621. [ And blocks the lower portion of the cylinder body portion 2621 and contacts the lower end of the conduction prevention rod portion 261 to restrict the downward vertical displacement to complement the strength of the cylinder body portion 2621 And a lower cover portion (2623) shaped like a circular plate and having a damping portion and a displacement restricting portion

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