KR101724102B1 - Earthquake-Resistant Swichboard with Function of Attenuation for Seismic Force and Control for Vertical Displacement - Google Patents

Abstract

The present invention relates to an earthquake-resistant switchboard for attenuating seismic force and controlling vertical displacement. The earthquake-resistant switchboard comprises: a cubicle unit (1) consisting of a distribution device (12) including a bus bar, an air circuit breaker, a circuit breaker and a relay; and an earthquake-proof device unit (2) for attenuating seismic forces and vibrations. The present invention can attenuate vertical displacement caused by seismic forces or vibrations through an attenuation cylindrical part and an elastic spring part, attenuate seismic force against conduction of the cubicle part by internal force through a conduction detachment prevention rod part and a cylindrical conduction detachment prevention part, and control vertical displacement.

Description

{Earthquake-Resistant Swichboard with Function of Attenuation for Seismic Force and Control for Vertical Displacement}

The present invention relates to an earthquake-resistant switchboard capable of attenuating seismic force due to an earthquake and controlling vertical displacement due to support force or vibration, and more particularly, to an earthquake-resistant switchboard installed at a lower portion of a cubicle including an enclosure and a power distribution device, A seismic force with an earthquake-resistant device portion capable of preventing the cubicle portion from departing due to the vertical displacement by controlling the vertical displacement and preventing the seismic force or vibration from being transmitted by the conduction moment generated by the earthquake or vibration, To control the 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 the height, shape and material of the building, It is necessary to protect the panel from earthquakes. In order 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 are mitigated by seismic devices under the switchboard, but some impacts are not completely mitigated and some impacts are transmitted to the devices in the switchboard. To mitigate such shocks, the bottom edge of the switchboard, 4 to 6 vibration and earthquake resistant devices were required.

It is necessary to install a seismic isolation system on a switchboard to sufficiently mitigate the impact on the equipment so as to maintain the performance of the power distribution apparatus even in the event of an earthquake, thereby providing a dustproof and seismic performance switchgear capable of maintaining the performance of the entire switchboard.

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

According to an aspect of the present invention, there is provided a damping device for damping vertical displacement caused by a seismic force or vibration by a damping cylindrical part and an elastic spring part, In which the seismic force capable of deflecting the conduction of the cubic portion by the force is controlled and the vertical displacement is controlled.

An earthquake-resistant switchboard of the present invention includes an enclosure including a lower frame and forming an inner space of a predetermined size, a booth bar installed inside the enclosure and installed to control power distribution, , A circuit breaker, and a relay; The cubic portion is provided at a lower portion of the cubic portion to prevent the cubic conduction due to a conduction moment generated by an earthquake or vibration and to control vertical displacement to prevent the cubic portion from departing due to vertical displacement, And an earthquake-resistant device capable of damping.

The earthquake-proof device comprises four to six earthquake-proof devices installed at four to six locations including four corners of the cubicle.

The vibration isolator includes a top plate coupled to the bottom frame and receiving a load of the cubicle 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 is connected to the upper plate portion so as to prevent the cubicle from being transmitted to the conduction moment generated by the seismic force or vibration and to prevent the conduction moment from being transmitted by the vertical force due to the seismic force or vibration, A rod portion; The above-described detachment preventing rod portion is inserted into the space to provide a space in which the detachment prevention rod portion can move up and down, and the cubicle such as the detachment prevention rod portion is conducted to a conduction moment generated by earthquake or vibration And a vertical displacement caused by a seismic force or a vibration to move the up / down prevention rod section up and down within a certain range; And a vertical displacement generated by the vibration or seismic force is damped by a vibration absorbing force so as to reduce an impact transmitted to the cubicle portion and a vertical displacement A damping cylindrical portion having a cylindrical modulus of elasticity capable of being damped by a vibration absorbing force and capable of being deformed to an allowable vertical displacement of the detachment prevention rod portion; A vertical displacement generated by a seismic force or vibration such as the damping cylindrical part is damped by elasticity of a spring which is provided between the damping cylindrical part and the anti-departure prevention cylindrical part to reduce the impact transmitted to the cubic part and restore the displacement, And an elastic spring portion for maintaining the durability of the damping cylindrical portion.

The upper plate portion has a rectangular shape with a predetermined thickness and the upper end portion of the damping cylindrical portion is inserted into the upper plate portion so that the damping cylindrical portion is not separated from the left and right due to earthquake or vibration due to vibration. Groove; A load-head insertion groove for inserting an upper end of the detachment prevention rod portion so that the upper plate portion is horizontal without being exposed to the outside; A rod lifting step insertion groove into which the upper end of the sliding cylindrical portion of the detachment prevention rod portion is inserted; An upper damping cylindrical coupling portion having a dish screw for coupling the damping cylindrical portion to the upper plate portion and a dish screw head of the dish screw being formed in a shape identical to the shape of the dish screw, and; And four lower frame coupling holes for coupling with the lower frame are formed.

The lower plate portion has a rectangular shape with a predetermined thickness and has the same shape as the upper plate portion. A lower end portion of the damping cylindrical portion is inserted into the lower plate portion so that the damping cylindrical portion does not deviate right and left due to earthquake or horizontal force due to vibration. The lower damping-cylinder departure prevention groove of the lower end; A cylindrical lower end insertion groove into which the lower end of the breakaway preventing cylindrical portion is inserted; A lower end damping cylindrical portion having a shape identical to the shape of the dish screw so that the dish screw head of the dish screw does not protrude to the outside, A hole; A plurality of sliding cylindrical coupling grooves which are symmetrically formed so as to have the same shape as that of the dish screw so that the dish screw for coupling the lower end of the detachment preventing cylindrical portion to the lower plate is inserted and the dish screw head of the dish screw does not protrude outward; ; And four lower mounting frame engaging holes for engaging with the concrete foundation or the lower mounting frame are formed.

The upper end portion of the detachment prevention rod portion is inserted into the upper plate portion. When the earthquake-proof device causes compressive vertical displacement downward due to seismic force or vibration, the lower end portion has a limited vertical displacement amount, A main rod having a bolt-like shape and having a load-threaded joint formed at a lower end thereof by a predetermined length; The main rod is inserted into the rod insertion hole formed at the center and integrated with each other, the upper end portion is inserted into the upper plate portion to a predetermined depth, the frictional reducing means is provided on the outer diameter of the cylindrical portion, Wherein the vertical displacement amount is limited by the upper end of the conduction separation preventing cylindrical portion when the earthquake-proof apparatus causes tensile vertical displacement due to seismic force or vibration, Wow; And a lower disk portion having a disk-like shape having a predetermined thickness, which is screwed with the male screw at the lower end of the main rod to closely contact the sliding cylindrical portion with the upper plate portion.

Wherein the main rod portion is inserted into the upper plate portion and has a hexagonal groove formed therein so as to be rotatable with a wrench; And a rod bolt portion which is formed continuously to a lower portion of the rod head portion and inserted into the sliding cylindrical portion and formed with the rod male thread portion at a lower portion and screwed to the lower circular plate portion, A disk female thread is formed.

The conduction separation preventing cylindrical portion is formed in a hollow shape and has a cylindrical shape having a predetermined thickness so as to be able to move up and down while rubbing against the inner surface by inserting the conduction separation preventing rod portion into the inner portion, A cylindrical main body portion;

And the upper end of the conduit main body portion is welded to the upper portion of the cylindrical main body portion so as to cover the upper portion of the cylindrical main body portion, An upper cover portion; Preventing rod portion is vertically displaced in the cylindrical main body portion so that the cylindrical main body portion is not separated from the lower end portion of the cylindrical main body portion and the lower plate portion by a bolt to seal the lower portion of the cylindrical main body portion, Shaped lower cover portion which abuts against the lower end of the departure preventing rod portion to restrict the downward vertical displacement and compensates the strength of the cylindrical main body portion.

A main load through hole is formed in the center of the upper cover to allow the main rod portion of the detachment prevention rod to pass therethrough. The lower end of the cylindrical main body is provided with a female screw for screwing the lower cover and the lower plate. And a lower cover bolt insertion hole is formed in the lower cover part in the same number as the body bolt insertion hole for screw connection between the cylindrical body part and the lower plate part.

The damping cylindrical part should have a certain thickness to disperse the seismic force and improve the durability, and have a tensile strength of 20 MPa or more, an elongation of 500% or more, a hardness of 60 Hs or more, a permanent compression toughness of 35% [(100 ± 1) ° C, 22Hr}, and the upper and lower portions of the damping cylindrical portion are respectively coupled to the upper plate portion and the lower plate portion, respectively. In order to prevent breakage of the upper plate portion and the lower plate portion and the joint portions due to seismic force, Eight sleeves are inserted and formed.

The elastic spring portion is a cylindrical compression spring type so as to uniformly receive a compression load due to the seismic force in the direction of the coil center line. The repulsive force limit should be limited to the height of the damping cylinder portion in order to maintain the durability of the damping cylinder portion.

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

According to the seismic switchboard of the present invention for damping the seismic force of the present invention and controlling the vertical displacement, the cylindrical damping cylindrical portion having a modulus of elasticity that can be deformed to the allowable vertical displacement at the lower portion of the switchboard and the elastic spring portion for maintaining the durability of the damped cylindrical portion It has damping seismic force and improved restoring force and durability. It has a rod for preventing departure from departure and a cylinder for preventing departure from departure, so that it can operate only at a certain vertical displacement to control the vertical displacement and win the conduction moment with strength. There is an effect that can be prevented.

1 is an overall front view of an earthquake-resistant switchboard in which the seismic force of the present invention is attenuated and vertical displacement is controlled;
Fig. 2 is a schematic view of an earthquake-resistant apparatus according to an earthquake-resistant switchboard in which the seismic force of the present invention is attenuated and vertical displacement is controlled
3 is a cross-sectional view of an earthquake-proof apparatus AA according to an earthquake-resistant switchboard in which the seismic force of the invention is attenuated and vertical displacement is controlled
4 is a schematic view of an upper plate according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is damped and vertical displacement is controlled
5 is a schematic diagram of a lower plate portion according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is damped and the vertical displacement is controlled.
Fig. 6 is a schematic view of a detachment preventing rod portion according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is damped and vertical displacement is controlled
7 is an exploded view of a detachment preventing rod portion according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is damped and vertical displacement is controlled.
Fig. 8 is a schematic view of an anti-departure prevention cylindrical portion according to an anti-seismic device of an anti-seismic switchboard for attenuating the seismic force of the invention and controlling vertical displacement
9 is a schematic view of a damping cylinder part according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is damped and the vertical displacement is controlled.
10 is a schematic view of an elastic spring part according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is damped and the vertical displacement is controlled.

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.

The following definitions are defined in consideration of the functions of the present invention and can be changed according to the intention or custom of the user, operator, and the like. The definition is based on the "seismic force damping "Quot; switchboard "of the present invention.

Hereinafter, a preferred embodiment of the "seismic switchboard for attenuating seismic force and controlling vertical displacement" 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-proof apparatus according to an earthquake-resistant switchboard in which the seismic force of the present invention is attenuated and vertical displacement is controlled, and Fig. 3 is a schematic view of an earthquake- 4 is a schematic view of an upper plate according to an earthquake-proof apparatus of an earthquake-resistant switchboard for attenuating seismic force and controlling vertical displacement of the present invention, and Fig. 5 is a schematic view of an earthquake- FIG. 6 is a schematic view of a detachment preventing rod according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which an earthquake-force is damped and vertical displacement is controlled according to an embodiment of the present invention. , Fig. 7 is a view showing a portion of the breakaway prevention rod portion according to the seismic isolation device of an earthquake-resistant switchboard in which the seismic force of the invention is damped and the vertical displacement is controlled Fig. 8 is a schematic view of an anti-segregation preventing cylinder according to an anti-seismic device of an anti-seismic switchboard for attenuating the seismic force of the invention and controlling the vertical displacement. Fig. 9 is a view showing a seismic- 10 is a schematic view of an elastic spring portion according to an earthquake-proof apparatus of an earthquake-resistant switchboard in which the seismic force of the invention is attenuated and vertical displacement is controlled.

1, an earthquake-resistant switchboard A according to the present invention includes an enclosure 11 including a mounting frame 111 and forming an internal space of a predetermined size, A cubicle section (1) composed of a distribution device (12) including a bus bar, an air circuit breaker, a wiring breaker, and a relay installed to distribute, control, and protect water in various electrical equipment systems; The cubic portion 1 is provided at a lower portion of the cubic portion 1 to prevent the cubic portion 1 from being conducted due to a conduction moment generated by an earthquake or vibration and to control the vertical displacement so that the cubic portion 1, and is capable of damping seismic force and vibration.

The earthquake-proof device (2) comprises four to six earthquake-proof devices (2a) installed at four to six locations including four corners of the cubicle.

When the four sides of the cubic section 1 and the four sides of the cubic section and the length of one side of the cubic section are longer than a certain length, the vibration proof device section 2 is provided at six positions May be installed.

1, the vibration isolation device part 2 is prefabricated on a lower mounting frame 31 to be installed on the concrete foundation 3, and the cubicle part 1 is installed on the upper part after the vibration isolation device part 2 is installed. Or may be installed directly on the concrete foundation 3 without the lower mounting frame 31.

The earthquake-proof apparatus unit 2 may be completely set on the mounting frame 111 and the lower mounting frame 31 and then installed on the concrete foundation 3 and on the upper part of the cubicle unit 1, In this case, the integral frame 31 may not be included in the enclosure 11.

As shown in FIGS. 2 and 3, the vibration isolator 2a includes a top plate 21 coupled to the mounting frame 111 to receive a load of the cubicle unit 1; And a lower plate coupled to the concrete foundation 3 or the lower mounting frame 31 on which the earthquake-resistant switchboard A is installed to transmit the load of the earthquake-resistant switchboard A to the concrete foundation 3 or the lower mounting frame 31, (22); In order to prevent the cubicle portion 1 from being transmitted to the conduction moment generated by the seismic force or vibration, the conduction moment is given by the proof force and the vertical displacement caused by the seismic force or vibration (23) for moving up and down in a vertical direction; The lead-out prevention rod portion 23 is inserted into the space to provide a space for the lead-out prevention rod portion 23 to move up and down. The lead- In order to prevent the conduction moment from being transmitted to the conduction moment generated by the earthquake or the vibration, the conduction moment wins with the same strength as the above-mentioned detachment prevention rod portion 23, and the vertical displacement due to the seismic force or vibration is controlled, A conduction separation preventing cylindrical portion 24 for causing the rod portion 23 to move up and down within a predetermined range; The vertical displacement generated by vibration or seismic force is provided outside the conduction separation preventing cylindrical portion 24 to be damped by the vibration absorbing force so as to be connected to the upper plate portion 21 and the lower plate portion 22, Which is capable of attenuating the vertical displacement to the vibration absorbing force and deforming to the allowable vertical displacement of the turn-off prevention rod section 23, Shaped damping cylindrical portion 25; The vertical displacement generated between the damping cylindrical portion 25 and the detachment preventing cylindrical portion 24 and caused by the seismic force or vibration as in the damping cylindrical portion 25 is attenuated by the elasticity of the spring, And an elastic spring part 26 for reducing the impact transmitted to the damping cylindrical part 25 and restoring the displacement and maintaining the durability of the damping cylindrical part 25.

The damping cylindrical portion 25 of the vibration damping device 2a according to the present invention attenuates a vertical force or a horizontal force due to an earthquake or an earthquake or the like and the elastic spring portion 26 is not affected by seismic force or vibration The vertical displacement generated by the spring is damped by the elasticity of the spring to reduce the shock transmitted to the cubic portion 1 to restore the displacement and to maintain the durability of the damping cylindrical portion 25, The prevention rod portion 23 and the detachment preventing cylindrical portion 24 are controlled so that the vertical displacement moves up and down within a certain range to prevent the damper cylinder 25 and the elastic spring portion 26 from being damaged, And the breakaway prevention rod portion 23 and the breakaway prevention cylindrical portion 24 can prevent the breakage of the breakage due to the earthquake or vibration due to the breakage of the breakage- And the cubic To prevent the unit (1) is conducted.

4, the upper plate portion 21 is coupled with the mounting frame 111 to receive a load of the cubic portion 1, and a load due to the load of the cubic portion 1 and a load due to a seismic force It is preferable to have a rectangular shape so as to be able to withstand the mounting frame 111 and have a certain thickness to be able to withstand the mounting frame 111.

The top plate portion 21 is formed with a circular band-shaped attenuating cylindrical portion 25 which is inserted into an upper end portion of the damping cylindrical portion 25 so as to prevent the damper cylindrical portion 25 from being deviated rightward or leftward due to earthquake or vibration, A cylindrical misalignment prevention groove 211; A load-head insertion groove 212 for inserting an upper end of the detachment prevention rod portion 23 so that the upper plate portion 21 is horizontal without being exposed to the outside; A rod lifting end insertion groove 213 into which the upper end of the sliding cylindrical portion 232 of the detachment prevention rod portion 23 is inserted; A dish screw for engaging the damping cylindrical portion 25 with the upper plate portion 21 is inserted and the dish screw head of the dish screw is formed in the same shape as that of the dish screw so as not to protrude to the outside, A top attenuating cylindrical portion engaging hole 214, And four mounting frame coupling holes 215 for coupling with the mounting frame 111 are formed.

Since the damping cylindrical portion 25 is made of an elastic rubber when the damping cylindrical portion 25 is coupled only with the plate screw, the damping cylindrical portion separation preventing groove 211 can be torn easily when receiving the horizontal force. The damping cylindrical portion 25 should not be separated even when the vibration-proofing device portion 2 receives a conduction moment.

When the upper end of the sliding cylindrical portion 232 of the detachment prevention rod portion 23 protrudes from the horizontal portion of the upper plate portion 21, the load-head insertion groove 212 may have a problem in joining with the mounting frame 111 Since the cubicle unit 1 is not installed in a horizontal position, it should be at the same level as that of the upper plate 21.

Likewise, the upper damping cylindrical portion coupling hole 214 also has a problem in that when the dish screw head of the dish screw protrudes from the horizontal portion of the upper plate portion 21, there is a problem in coupling with the mounting frame 111, The upper plate 21 must be kept at the same level as the upper plate 21.

The dish screw for coupling the upper plate part 1 and the damping cylinder part 25 is screwed to a female screw formed on the sleeve 252 provided in the damping cylindrical part 25, It should have thickness.

5, the lower plate portion 22 is coupled to the concrete foundation 3 or the 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), and has a rectangular shape having the same shape as the upper plate portion (21).

The lower plate portion 22 is provided with a lower end damping cylindrical portion 25 in the form of a circular band so that the lower end portion of the damping cylindrical portion 25 is inserted so that the damping cylindrical portion 25 is not separated from the left and right due to earthquake or vibration. A release preventing groove 221; A cylindrical lower end insertion groove 222 into which the lower end of the conduction separation preventing cylindrical portion 24 is inserted; A dish screw for coupling the damping cylindrical portion 25 with the lower plate portion 22 is inserted and the dish screw head of the dish screw is formed in the same shape as that of the dish screw so as not to protrude to the outside, A lower-stage damping-cylindrical-portion coupling hole 223 formed therein; A dish screw for engaging the lower end of the detachment preventing cylindrical portion 24 and the lower plate 22 is inserted and the dish screw head of the dish screw is formed in the same shape as the dish screw so as not to protrude outwardly, Four sliding cylindrical fitting grooves 224; And four lower mounting frame coupling holes 225 for coupling with the concrete foundation 3 or the lower mounting frame 31 are formed.

When the damping cylindrical portion 25 is coupled only with the plate screw, the material of the damping cylindrical portion 25 is elastically deformed when the damping cylindrical portion 25 is engaged only with the dish screw, It is necessary to have a predetermined depth so that the damping cylindrical part 25 should not be separated even when the vibration-proofing device part 2 receives a conduction moment.

The cylindrical lower end insertion groove 222 and the lower end damped cylindrical portion engagement hole 223 are formed in a state in which the lower portion of the lower plate portion 22 is horizontal so as to be coupled to the concrete foundation 3 or the lower mounting frame 31 So that the dish screw head of the dish screw does not protrude to the outside so that the cubic portion 1 can be kept horizontal.

6 and 7, the detachment prevention rod portion 23 is coupled to the upper plate portion 21 to prevent the cubicle portion 1 from being conducted to a conduction moment generated by a seismic force or vibration , And it moves up and down within a certain range by vertical displacement due to seismic force or vibration.

The upper end portion of the detachment prevention rod portion 23 is inserted into the upper plate portion 21 and has a certain length when the vibration-proofing device portion 2 causes compressive vertical displacement directed downward by a compressive force due to seismic force or vibration, A main rod portion 231 having a bolt-like shape in which a load vertical thread 23121 is formed at a lower end portion thereof by limiting the amount of vertical displacement of compression, a shear moment due to seismic force or vibration, The main rod portion 231 is inserted into a rod insertion hole 2322 formed at the center and integrally formed with each other. The upper end portion is inserted into the upper plate portion 21 to a predetermined depth, and a frictional reducing means 2321, So that the breakaway preventing rod portion 23 can move smoothly up and down without a clearance in the interior of the breakaway preventing cylindrical portion 24 and the seismic isolation device portion 2 can be prevented from being damaged due to seismic force or vibration A sliding cylindrical portion 232 whose tensile vertical displacement amount is limited by the upper end of the detachment preventing cylindrical portion 24 when a tensile vertical displacement is caused by the tensile vertical displacement; And a lower circular plate portion 233 having a circular plate shape and having a predetermined thickness to screw the sliding cylindrical portion 232 to the upper plate portion 21 by screwing with the rod male thread 23121 at the lower end portion of the main rod portion 231 .

The main rod portion 231 includes a rod head portion 2311 inserted into the upper plate portion 21 and having a hexagonal groove 23111 formed therein so as to be rotatable by a wrench; A rod bolt portion 2312 formed continuously from the lower portion of the rod head portion 2311 and inserted into the sliding cylindrical portion 232 and having the rod male thread 23121 formed thereunder and screwed to the lower circular plate portion 233 ).

A disk female screw 2331 for screwing the rod male screw 23121 is formed at the center of the lower disk 233.

The friction reducing means 2321 should be formed of two so that the sliding cylindrical portion 232 is not shaken.

The frictional reducing means 2321 includes a ball bearing set 23211 installed in a retainer to which a plurality of balls are always fitted so as to maintain the same spacing and a ball bearing set 23211 installed at upper and lower portions of the ball bearing set 23211, And two stopper rings 23211 that do not move.

The stopper ring 23212 of the upper one of the two friction reducing means 2321 abuts on the upper cover portion 242 of the deviation preventing cylindrical portion 24 to restrict the vertical displacement to the upper portion.

The detachment preventing rod portion 23 is composed of the main rod portion 231, the sliding cylindrical portion 232 and the lower disk portion 233 to facilitate installation in the detachment preventing cylindrical portion 24, When the main rod portion 231 is rotated, the lower disk portion 233 pushes up the sliding cylindrical portion 232 so that the sliding cylindrical portion 232 is brought into close contact with the upper plate portion 21.

The main rod portion 231 must have a predetermined shear strength to have a proof strength to overcome the conduction moment when the conduction moment is received.

As shown in FIG. 8, the detachment prevention cylindrical portion 24 is provided with a space for allowing the detachment prevention rod portion 23 to move up and down by inserting the detachment prevention rod portion 23 therein In order to prevent the cubicle portion 1 from being conducted to a conduction moment generated by an earthquake or vibration as in the case of the detachment prevention rod portion 23, And the vertical displacement caused by the seismic force or the vibration is controlled so that the detachment prevention rod section 23 moves up and down within a certain range.

The breakaway prevention cylindrical portion 24 has a hollow therein and is engaged with the inner surface of the breakaway prevention rod portion 23 to move up and down. A cylindrical main body portion 241 having a predetermined thickness; The upper portion of the cylindrical body portion 241 is welded to the upper portion of the cylindrical body portion 241 and a portion of the underside prevention rod portion 23 is in contact with the upper portion of the cylindrical body portion 241, Shaped upper cover part (242) for supplementing the strength of the cylindrical main body part (241); The lower end of the cylindrical main body portion 241 and the lower end portion of the lower plate portion 241 are formed so as to prevent the cylindrical main body portion 241 from being detached when the detachment prevention rod portion 23 is vertically displaced in the cylindrical main body portion 241 22 prevents the lower portion of the cylindrical body portion 241 from contacting with the lower end of the breakaway prevention rod portion 23 so as to limit the vertical displacement of the lower side portion thereof, And a lower cover portion 243 having a disk shape complementary to the lower cover portion 243.

The stopper ring 23212 abuts against the lower surface of the upper cover portion 242, so that the detachment preventing rod portion 23 can no longer move upward, thereby limiting the vertical displacement of the upper portion.

A main rod through hole 2421 through which the main rod portion 231 of the detachment prevention rod portion 23 passes is formed at the center of the upper cover portion 242.

Four to eight main body bolt insertion holes 2411 are formed at the lower end of the cylindrical main body portion 241 and are formed with threaded engagement by the coupling bolts of the lower cover portion 243 and the lower plate portion 22.

The size and quantity of the body bolt insertion hole 2411 may be set such that when the lower cover portion 243 is coupled to the cylindrical main body portion 241 and the lower plate portion 22, .

The lower cover part 243 is formed with a lower cover bolt insertion hole 2431 in the same number as the body bolt insertion hole 2411 for screw connection between the cylindrical main body part 241 and the lower plate part 22.

9, the damping cylindrical portion 25 is installed between the upper plate portion 21 and the lower plate portion 22 and is attached to the outside of the detachment-preventing cylindrical portion 24, The vertical displacement caused by the seismic force is damped by the vibration absorbing force to reduce the shock transmitted to the cubic section 1 and to restore the vertical displacement and to damp the vertical displacement to the vibration absorbing force, 23 having a modulus of elasticity capable of being deformed up to an allowable vertical displacement.

The damping cylindrical part 25 should have a thickness of a certain thickness in order to disperse the seismic force and improve the durability and have a tensile strength of 20 MPa or more, an elongation of 500% or more, a hardness of 60 Hs or more, 100 占 1) 占 폚, 22Hr} or less.

The upper and lower portions of the damping cylindrical portion 25 are coupled to the upper plate portion 21 and the lower plate portion 22 respectively and are prevented from being damaged by the seizure force of the upper plate portion 21 and the lower plate portion 22, Eight sleeves 252 each having a female thread formed therein are inserted and formed.

And the dish screw is engaged with the sleeve 252.

10, the elastic spring portion 26 is provided between the damping cylindrical portion 25 and the detachment preventing cylindrical portion 24 and is fixed to the damping cylindrical portion 25 by seismic force or vibration The vertical displacement generated is damped by the elasticity of the spring to reduce the impact transmitted to the cubic portion 1, to restore the displacement, and to maintain the durability of the damped cylindrical portion 25.

The resilient spring portion 26 is a cylindrical compression spring type so as to uniformly receive a compression load due to the seismic force in the direction of the coil center line. (25).

That is, when the repulsive force of the elastic spring part 26 is larger than the damping cylindrical part 25, the damping cylindrical part 25 does not perform the main function of absorbing and attenuating vibration, That is, if the repulsive force of the elastic spring portion 26 is smaller than the damping cylindrical portion 25, the durability of the damping cylindrical portion 25 becomes a problem, and the performance of the damping cylindrical portion 25 deteriorates.

According to the seismic switchboard of the present invention for damping the seismic force of the present invention and controlling the vertical displacement, the cylindrical damping cylindrical portion having a modulus of elasticity that can be deformed to the allowable vertical displacement at the lower portion of the switchboard and the elastic spring portion for maintaining the durability of the damped cylindrical portion It has damping seismic force and improved restoring force and durability. It has a rod for preventing departure from departure and a cylinder for preventing departure from departure, so that it can operate only at a certain vertical displacement to control the vertical displacement and win the conduction moment with strength. There is an effect that can be prevented.

A: Switchboard
1: Cubicle part 11: Enclosure
111: mounting frame 12: power distribution device
2: Seismic isolator 2a: Seismic isolator
21: upper plate portion 211: upper damping cylinder departure prevention groove
212: load-head inserting groove 213: rod inserting-step inserting groove
214: upper attenuation cylindrical portion engaging hole 215: mounting frame engaging hole
22: Lower plate portion 221: Lower damping cylinder departure preventing groove
222: Lower end insertion groove of the cylinder part 223: Lower end damping cylinder part engagement hole
224: Sliding cylindrical part engaging groove 225: Lower mounting frame engaging hole
23: detachment preventing rod portion 231: main rod portion
2311: load head portion 23111: hexagonal groove
2312: Rod bolt part 23121: Rod male thread
232: sliding cylindrical portion 2321: friction reducing means
23211: Ball bearing set 23212: Stopper ring
2322: Rod insertion hole 233: Lower disc portion
2331: Round plate female thread 24: Cylinder part for preventing deviation
241: Cylindrical body part 2411: Body bolt insertion hole
24111: Female thread 242:
2421: Main rod passage hole 243: Lower cover part
2431: Lower cover bolt insertion hole 25:
251: hollow portion 252: sleeve
26: Elastic spring portion
3: Concrete foundation 31: Lower mounting frame

Claims (6)

An enclosure 11 including a mounting frame 111 and forming an internal space of a predetermined size; a booth bar installed inside the enclosure 11 and installed for power distribution, control, A cubicle section (1) composed of a distribution device (12) including an air circuit breaker, a wiring breaker, and a relay;
The cubic portion 1 is provided at a lower portion of the cubic portion 1 to prevent the cubic portion 1 from being conducted due to a conduction moment generated by an earthquake or vibration and to control the vertical displacement so that the cubic portion 1 of the earthquake-resistant switchboard (A), and which is capable of damping seismic forces and vibrations,
The earthquake-proof device (2) is composed of 4 to 6 earthquake-proof devices (2a) installed at 4 to 6 places including four corners of the cubicle portion,
The earthquake-proof apparatus (2a) comprises a top plate part (21) coupled with the mounting frame (111) and receiving a load of the cubicle part (1);
And a lower plate coupled to the concrete foundation 3 or the lower mounting frame 31 on which the earthquake-resistant switchboard A is installed to transmit the load of the earthquake-resistant switchboard A to the concrete foundation 3 or the lower mounting frame 31, (22);
In order to prevent the cubicle portion 1 from being transmitted to the conduction moment generated by the seismic force or vibration, the conduction moment is given by the proof force and the vertical displacement caused by the seismic force or vibration (23) for moving up and down in a vertical direction;
The lead-out prevention rod portion 23 is inserted into the space to provide a space for the lead-out prevention rod portion 23 to move up and down. The lead- In order to prevent the conduction moment from being transmitted to the conduction moment generated by the earthquake or the vibration, the conduction moment wins with the same strength as the above-mentioned detachment prevention rod portion 23, and the vertical displacement due to the seismic force or vibration is controlled, A conduction separation preventing cylindrical portion 24 for causing the rod portion 23 to move up and down within a predetermined range;
The vertical displacement generated by vibration or seismic force is provided outside the conduction separation preventing cylindrical portion 24 to be damped by the vibration absorbing force so as to be connected to the upper plate portion 21 and the lower plate portion 22, Which is capable of attenuating the vertical displacement to the vibration absorbing force and deforming to the allowable vertical displacement of the turn-off prevention rod section 23, Shaped damping cylindrical portion 25;
The vertical displacement generated between the damping cylindrical portion 25 and the detachment preventing cylindrical portion 24 and caused by the seismic force or vibration as in the damping cylindrical portion 25 is attenuated by the elasticity of the spring, And an elastic spring portion 26 for reducing the impact transmitted to the damping cylindrical portion 25 and restoring the displacement and maintaining the durability of the damping cylindrical portion 25,
The breakaway prevention cylindrical portion 24 has a hollow therein and is engaged with the inner surface of the breakaway prevention rod portion 23 to move up and down. A cylindrical main body portion 241 having a predetermined thickness;
The upper portion of the cylindrical body portion 241 is welded to the upper portion of the cylindrical body portion 241 and a portion of the underside prevention rod portion 23 is in contact with the upper portion of the cylindrical body portion 241, Shaped upper cover part (242) for supplementing the strength of the cylindrical main body part (241);
The lower end of the cylindrical main body portion 241 and the lower end portion of the lower plate portion 241 are formed so as to prevent the cylindrical main body portion 241 from being detached when the detachment prevention rod portion 23 is vertically displaced in the cylindrical main body portion 241 22 prevents the lower portion of the cylindrical body portion 241 from contacting with the lower end of the breakaway prevention rod portion 23 so as to limit the vertical displacement of the lower side portion thereof, Shaped lower cover portion 243 for complementing the lower cover portion 243,
A main rod passage hole 2421 through which the main rod portion 231 of the detachment prevention rod portion 23 passes is formed at the center of the upper cover portion 242,
Four to eight body bolt insertion holes 2411 are formed at the lower end of the cylindrical body portion 241 and are formed with a female screw for screw connection between the lower cover portion 243 and the lower plate portion 22,
The bottom cover part 243 is provided with a bottom cover bolt insertion hole 2431 formed in the same number as the main body bolt insertion hole 2411 for screw connection between the cylindrical main body part 241 and the lower plate part 22, And the vertical displacement is controlled.
The method according to claim 1,
The upper plate portion 21 has a rectangular shape with a predetermined thickness,
The upper plate portion 21 is provided with an annular band-shaped damping-cylinder-portion separation preventing portion 25 which is inserted into the upper end portion of the damping cylinder portion 25 so as to prevent the damping cylinder portion 25 from being deviated rightward and leftward due to earthquake or vibration. A groove 211;
A load-head insertion groove 212 for inserting an upper end of the detachment prevention rod portion 23 so that the upper plate portion 21 is horizontal without being exposed to the outside;
A rod lifting end insertion groove 213 into which the upper end of the sliding cylindrical portion 232 of the detachment prevention rod portion 23 is inserted;
A dish screw for engaging the damping cylindrical portion 25 with the upper plate portion 21 is inserted and the dish screw head of the dish screw is formed in the same shape as that of the dish screw so as not to protrude to the outside, A top attenuating cylindrical portion engaging hole 214,
And the four mounting frame coupling holes (215) for coupling with the mounting frame (111) are formed at the edges of the mounting frame (111)
The method according to claim 1,
The lower plate portion 22 has a rectangular shape having the same shape as the upper plate portion 21,
The lower plate portion 22 is provided with a lower end damping cylindrical portion 25 in the form of a circular band so that the lower end portion of the damping cylindrical portion 25 is inserted so that the damping cylindrical portion 25 is not separated from the left and right due to earthquake or vibration. A release preventing groove 221;
A cylindrical lower end insertion groove 222 into which the lower end of the conduction separation preventing cylindrical portion 24 is inserted;
A dish screw for coupling the damping cylindrical portion 25 with the lower plate portion 22 is inserted and the dish screw head of the dish screw is formed in the same shape as that of the dish screw so as not to protrude to the outside, A lower-stage damping-cylindrical-portion coupling hole 223 formed therein;
A dish screw for engaging the lower end of the detachment preventing cylindrical portion 24 and the lower plate 22 is inserted and the dish screw head of the dish screw is formed in the same shape as the dish screw so as not to protrude outwardly, Four sliding cylindrical fitting grooves 224;
Characterized in that four lower mounting frame coupling holes (225) are formed at the corners for coupling with the concrete foundation (3) or the lower mounting frame (31)
The method according to claim 1,
The upper end portion of the detachment prevention rod portion 23 is inserted into the upper plate portion 21 and has a certain length when the vibration-proofing device portion 2 causes compressive vertical displacement directed downward by a compressive force due to seismic force or vibration, A main rod portion 231 having a bolt-like shape in which a load vertical thread 23121 is formed at a lower end portion thereof by limiting the amount of vertical displacement of compression, a shear moment due to seismic force or vibration,
The main rod portion 231 is inserted into a rod insertion hole 2322 formed at the center and integrally formed with each other. The upper end portion is inserted into the upper plate portion 21 to a predetermined depth, and a frictional reducing means 2321, So that the breakaway preventing rod portion 23 can move smoothly up and down without a clearance in the interior of the breakaway preventing cylindrical portion 24 and the seismic isolation device portion 2 can be prevented from being damaged due to seismic force or vibration A sliding cylindrical portion 232 whose tensile vertical displacement amount is limited by the upper end of the detachment preventing cylindrical portion 24 when a tensile vertical displacement is caused by the tensile vertical displacement;
And a lower circular plate portion 233 having a circular plate shape and having a predetermined thickness to screw the sliding cylindrical portion 232 to the upper plate portion 21 by screwing with the rod male thread 23121 at the lower end portion of the main rod portion 231 Respectively,
The main rod portion 231 includes a rod head portion 2311 inserted into the upper plate portion 21 and having a hexagonal groove 23111 formed therein so as to be rotatable by a wrench;
A rod bolt portion 2312 formed continuously from the lower portion of the rod head portion 2311 and inserted into the sliding cylindrical portion 232 and having the rod male thread 23121 formed thereunder and screwed to the lower circular plate portion 233 ),
And a disk-shaped female thread 2331 for screwing with the rod male screw 23121 is formed at the center of the lower disk 233. The seismic switchboard 2331 damps the seismic force and controls the vertical displacement.
delete The method according to claim 1,
The damping cylindrical part 25 should have a thickness of a certain thickness in order to disperse the seismic force and improve the durability and have a tensile strength of 20 MPa or more, an elongation of 500% or more, a hardness of 60 Hs or more, 100 占 1) 占 폚, 22Hr} or less,
The upper and lower portions of the damping cylindrical portion 25 are coupled to the upper plate portion 21 and the lower plate portion 22 respectively and are prevented from being damaged by the seizure force of the upper plate portion 21 and the lower plate portion 22, Eight sleeves 252 each having a female thread formed therein are inserted and formed,
The resilient spring portion 26 is a cylindrical compression spring type so as to uniformly receive a compression load due to the seismic force in the direction of the coil center line. (25), and an earthquake-resistant switchboard

Images