KR102532188B1 - Fixing device of switchboard with seismic function - Google Patents

Abstract

The present invention relates to a fixing device for fixing a switchboard that manages receiving and sending current from a transformer at a substation, a power plant, or a building at a substation to the ground, and more particularly, to a housing (11) installed on a fixing bracket (17) class; a buffer member 27 installed inside the housing 11 to absorb vibration, shock and load; a buffer connection member 20 connected to the upper end of the buffer member 27 and connected to a fixed section 29 installed on a lower surface of a transformer or switchboard; The upper body 12 and the lower body 14 of the housing 11 are coupled with an upper fastening bolt 18, and the lower body 14 and the fixing bracket 17 are coupled with a lower fastening bolt 19, The switchboard fixing device of the present invention is designed to increase vibration isolation efficiency by buffering the seismic force transmitted to the transformer or switchboard even when vertical and horizontal seismic forces are generated.

Description

Fixing device of switchboard with seismic function {Fixing device of switchboard with seismic function}

The present invention relates to a fixing device for fixing a switchboard that manages a transformer in a substation, a power plant, or a building in a substation to receive and send current, to the ground, and more particularly, to resist the movement and overturning moment of a device when an earthquake occurs. And it relates to a switchboard fixing device having a seismic function that resists against seismic force in the horizontal direction and has a damping function.

In general, the enclosure of a switchboard that manages receiving and sending current from transformers in substations, power plants or substation buildings, etc., anchor bolts are driven into the concrete floor inside or outside the building, a floor angle is assembled thereto, and then a pillar is attached to the floor angle. By assembling the angle and assembling the enclosure to the assembled column angle, the panel is assembled by bolting to the floor angle, and no separate earthquake-proof design is made.

In such conventional transformers, switchboards, switchboards, etc., the vibration situation is transmitted to the panel itself for mechanical vibration or earthquake due to electromagnetic force due to the vibration of the floor or the passage of high power, and various devices installed inside it are damaged by the earthquake. It is a situation that often occurs when wearing a .

In particular, in modern times, natural disasters such as earthquakes, typhoons, and tidal waves, which are becoming more frequent due to climate change, are increasing structural collapse accidents and resulting economic losses. Important structures such as transformers and bridges in substations, large buildings such as high-rise buildings, and switchboards installed in various structures, when destroyed, cause enormous human casualties, economic losses, and inoperability of various equipment due to power supply interruption. Because of this, the seismic design standards for this are being strengthened.

Korea is an earthquake zone with moderate and weak earthquakes, and seismic class classification for building electrical installations is not implemented. In general, all seismic ratings for building electrical installations are set to class B and applied. judges and decides

In addition, for building electrical installations installed in buildings with a height exceeding 70m, dynamic analysis is applied to calculate the floor seismic force of the building, and the design seismic force acting on the center of the equipment must be determined by considering the dynamic amplification of the facility.

However, according to the seismic design standards for firefighting facilities, firefighting facilities installed in buildings with a height of 13m or more must be installed in accordance with the seismic design standards set by the Minister of Public Administration and Security in order for the firefighting facilities to operate normally in the event of an earthquake. is stipulated.

Looking at this, among building electrical facilities, substation facilities, self-generation facilities, storage battery facilities, main lines and power facilities, devices and piping included in lighting and weak electricity facilities are targeted, and rotating devices are often installed with anti-vibration devices.

In addition, transformers and circuit breakers also generate acoustic vibration due to magnetization or mechanical sound or vibration when closed, and anti-vibration rubber is installed to prevent transmission of these vibrations. In particular, most dry-type transformers are equipped with anti-vibration rubber.

According to the test data, the seismic response magnification of the equipment supported by the vibration isolator is 15 to 25 times. If a rolling phenomenon occurs in which the natural vibration period of the device and the vibration period of the earthquake resonate, the anti-vibration rubber may break and cause the device to fall off. Therefore, when installing anti-vibration rubber, it is necessary to limit deformation by installing a function to prevent general vibration and a stopper that can resist seismic force.

In other words, anti-vibration rubber is used with a maximum strain rate of 35% or less, and an anti-vibration and fall-preventing stopper (Stopper: anti-vibration device that reduces vibration transmitted to the main body of the device with a spring or anti-vibration rubber) is installed so that the displacement of the upper part of the transformer is 30 mm or less. In one case, if it is not possible to connect directly to the building with anchor bolts, a mounting device to protect the equipment from earthquakes) is installed.

If it is impossible to fix with anchor bolts due to the installation of anti-vibration devices, install a seismic stopper. When installing a seismic stopper, the gap between the stopper and the main body should be narrowed as much as possible within the range of non-contact during normal operation.

It is judged that the seismic force acts on the central position of the device, and the type of earthquake-resistant stopper is selected by examining the possibility of the device overturning. The member of the seismic stopper is selected to be able to sufficiently resist the seismic force acting according to the type of stopper.

Seismic stoppers are fixed to foundations or structures with bolts, etc., so that no activity occurs when seismic force acts. When selecting a stopper, in the case of using a vibration isolator with a large amount of vibration, such as a spring, select the active and fall prevention type. Equipment installed with anti-vibration devices may generate excessive vibration due to seismic motion, so a seismic stopper is installed to prevent activity and conduction.

Looking at the prior art in this field, the anti-vibration stopper with integrated anti-vibration device of Patent Registration No. 10-1853094 (registration date: 2018. 04. 23.) is as shown in FIG.

The anti-vibration stopper integrated with the anti-vibration device includes a base plate fixed to the ground in the form of a flat plate; a housing fixedly installed on the base plate; a shaft having a head part exposed to the outside of the housing while being inserted into the housing in the form of a bar and moving in the vertical direction of the housing; An upper support plate fixedly installed on the top of the shaft in the form of a flat plate and integrally coupled with a structure or facility fixed to a facility; a ball slider installed inside the housing to slide the shaft; a vertical displacement limiting means mounted inside the housing to limit a vertical movement range of the shaft; And an elastic member inserted between the base plate and the upper support plate outside the housing, and a buffer means for elastically supporting the upper support plate while the lower end is in contact with the base plate. While elastically contracting or expanding, the vibration transmitted to the facility is dampened and the shaft slides in the vertical direction along the upper support plate integrally coupled with the facility, and the vertical displacement

When the vertical movement range of the facility exceeds the vertical movement range limited by the vertical displacement limiting means, the limiting means stops the ascending shaft and the upper support plate to limit the movement of the facility, thereby minimizing the movement of the facility. It became.

1 (hereinafter referred to as "prior art"), it can be seen that the housing 3 is installed between the base plate 1 and the upper support plate 7, and a spring buffer is provided on the outer surface of the housing.

In the prior art, the load generated at the top is absorbed by the buffer means 13 installed between the upper support plate 7 and the base plate 1 to be buffered, and the external vibration is absorbed by the buffer means made of a spring. Therefore, the prior art can act to absorb and buffer vibration, shock, load, etc. generated on a vertical line, but is suitable as an earthquake-resistant device that resists seismic force in the horizontal direction in order to resist the activity of the device and the overturning moment when an earthquake occurs. don't

That is, when an earthquake occurs, it should have a function of resisting horizontal seismic force and limiting deformation, but like the prior art, a buffer member is installed between the base plate and the upper support plate, and the shaft and ball slide are stretched and contracted inside the cylindrical tube-shaped housing inside the buffer member. The configuration to be made has a problem in that the damage of the device occurs because the horizontal buffering is not made at all, so that it cannot resist against the overturning moment.

Republic of Korea Patent Registration No. 10-1853094

The present invention is to solve the above problems, and the purpose of the present invention is to resist the seismic force in the vertical and horizontal directions and to have a damping function in order to resist the activity and overturning moment of the device when an earthquake occurs, and in particular, transformers in substations and power plants It relates to a switchboard fixing device that has a function to prevent vibration by being used as a switchboard fixing device that manages receiving and sending current from a substation building and an earthquake-resistant function to increase resistance to vertical and horizontal seismic forces.

The present invention includes a housing installed on a fixing bracket as a means for achieving the above object;

a buffer member installed inside the housing to absorb vibration, shock and load;

a buffer connection member connected to the upper end of the buffer member and connected to a fixed section installed on a lower surface of a transformer or switchboard;

The upper body and the lower body of the housing are coupled with an upper fastening bolt, and the lower body and the fixing bracket are coupled with a lower fastening bolt.

The buffer connection member,

A hemispherical body made of a hemispherical shape, and a neck portion and a bolt portion integrally formed at the upper center of the hemispherical body,

The inner surface of the hemispherical body is formed of a concave groove, and a support rod connected to the buffer member is protruded downward from the center of the groove on the bottom of the hemispherical body.

The housing is made of a combination of an upper body and a lower body, and a storage portion in which a buffer member is installed is formed inside the lower body, and a circular space portion is formed in the interior where the lower body and the upper body are coupled to each other, and a buffer connection member is installed. to be characterized

Thus, the switchboard fixing device having an earthquake-resistant function of the present invention is designed to increase vibration isolation efficiency by buffering the seismic force transmitted to the transformer or switchboard even when vertical and horizontal seismic forces are generated.

The present invention forms a circular space in a housing for a fixing device for a switchboard that manages receiving and sending electricity from a transformer in a substation, a power plant or a substation building, and forms a buffer connection member installed in the space into a hemispherical body. Therefore, in order to resist the overturning moment of the transformer or switchboard when horizontal or vertical seismic force is generated, it resists the vertical and horizontal seismic force and has a damping function to have an earthquake-proof effect.

1 is a perspective view of a conventional anti-vibration device integrated seismic stopper coupled state;
Figure 2 is a perspective view of a coupled state of a switchboard fixing device having an earthquake-resistant function according to the present invention.
Figure 3 is a cross-sectional view of a coupled state of a switchboard fixing device having an earthquake-resistant function according to the present invention.
Figure 4 is an exploded perspective view of a switchboard fixing device having an earthquake-resistant function according to the present invention.
Figure 5 is a cross-sectional view of the installation state of the present invention, an exemplary view showing a state before the shock absorbing member is contracted.
Figure 6 is a cross-sectional view of the installation state of the present invention, an exemplary view showing a contracted state of the buffer member.

Hereinafter, embodiments will be described in detail based on the accompanying drawings of the present invention.

2 is a perspective view of a switchboard fixing device having an earthquake-resistant function according to the present invention in a coupled state, and FIG. 3 is a cross-sectional view of a switchboard fixing device having an earthquake-resistant function according to the present invention in a coupled state.

The "switchboard fixing device" described in the present invention is referred to for convenience, and is installed as a transformer fixing device, a switchgear fixing device, a switchgear fixing device, etc. to prevent vibration of the floor or mechanical vibration due to electromagnetic force due to the passage of high power or an earthquake. The vibration situation is transmitted to the device as it is, so that various devices installed therein are prevented from being damaged by an earthquake or the like.

In the switchboard fixing device 10 of the present invention, a fixing bracket 17 is located at the bottom, and the fixing bracket 17 is coupled to the lower surface of the lower body 14 of the housing 11 by a lower fastening bolt 19.

The housing 11 is composed of a combination of a lower body 14 and an upper body 12.

A buffer member 27 is installed inside the housing 11 installed on the fixing bracket 17 to absorb vibration, shock and load.

The upper end of the buffer member 27 is fitted into the support rod 26 integrally formed on the lower surface of the shock absorber connecting member 20 composed of the bolt part 23 and the neck part 22, and the lower end of the buffer member 27 has the housing 11 It passes through the lower body 14 of the housing 16 and is supported by the bottom fixing racket 17.

The upper body 12 and the lower body 14 of the housing 11 are coupled with an upper fastening bolt 18, and the lower body 14 and the fixing bracket 17 are coupled with a lower fastening bolt 19.

The buffer member 27 is installed inside the housing 11 to buffer vibration, shock and load.

In the shock absorbing connection member 20 installed to be connected to the upper end of the shock absorbing member 27 inside the housing 11, the upper body 12 through hole 13 of the housing 11 includes the neck portion 22 and the bolt portion 23 of the upper portion. ), it is inserted into the bolt hole of the panel formed on the bottom of the transformer or switchboard 30 or the bolt hole of the fixed beam 29 installed on the bottom so that it can be assembled and fixed with a nut.

Figure 4 is an exploded perspective view of a switchboard fixing device having an earthquake-resistant function according to the present invention, wherein the switchboard fixing device of the present invention is a lower body of the housing 11 coupled with a fixing bracket 17 and a fixing bracket 17 at the lower part (14), it consists of a combination of the upper body 12 of the housing 11 coupled to the upper portion of the lower body 14.

The housing 11 of the switchboard fixing device 10 has a storage part 16 and a space part 15 formed therein, and a buffer member 27 and a buffer connection member 20 are installed therein.

The shock absorber connecting member 20 is located in the space 15 inside the housing 11, and the lower end is coupled with the upper end of the shock absorber 27.

The shock absorber connection member 20 has an outer surface formed in a hemispherical shape, and a neck portion 22 and a bolt portion 23 are integrally formed at the top center of the hemispherical body 21 so as to protrude. The neck part 22 and the bolt part 23 serve as coupling members to fix the switchboard 30 or the transformer.

A semi-groove groove 24 is formed on the bottom surface of the hemispherical body 21 of the buffer connection member 20, and a support rod 26 is integrally formed in the center of the groove 24 so as to protrude downward and is located on the bottom surface. It is inserted into the upper end of the buffer member 27 to be positioned in the space portion 15.

The buffer member 27 is made of a spring and is manufactured to withstand a load of 100 kg, and may be manufactured to withstand a load of more than that if necessary.

The buffer member 27 may be made of rubber, urethane, etc. in a block type, and preferably made in the form of a coil spring.

The coil spring has a circular or rectangular cross section.

Figure 5 is a cross-sectional view of the installation state of the present invention, which is an exemplary view showing a state before the shock absorber is contracted, and Figure 6 is a cross-sectional view of the present invention of the installation state, showing an example of a state in which the buffer member is contracted.

In the present invention, a space portion 15 having a circular inner wall is formed in the interior where the upper body 12 and the lower body 14 of the housing 11 are coupled, and a buffer connection member 20 is installed, and a buffer connection member The body of (20) has an outer surface in a hemispherical shape and is formed as a hemispherical body 21 to correspond to the inner surface of the space portion 15, so that when an earthquake occurs, the hemispherical body of the buffer connection member 20 is generated when an earthquake force is generated on the horizon. As the outer hemisphere surface of (21) flows along the inner circumferential surface of the space portion (15), the impact is alleviated.

That is, the buffer connection member 20 is contracted downward on a vertical line by the load of the transformer or switchboard 30, and when a pushing pressure is generated on the horizontal line when an earthquake occurs, the shock absorber connection member of the fixing device connected to the transformer or switchboard 30 ( 20) is pushed to one side, and at the same time, the half-spherical body 21 of the buffer connection member 20 flows along the inner wall of the circular space 15, so that when seismic force is generated, to resist the overturning moment of the transformer or switchboard, the horizontal seismic force It resists and has a damping function to have a seismic effect.

5 attached to the present invention is a cross-sectional view of an installed state, showing a state before the shock absorbing member is contracted, and the neck portion 22 and the bolt portion 23 of the shock absorbing connecting member 20 are connected to the upper body 12 of the housing 11. ) is exposed to the outside of the upper surface through hole 13 .

At this time, the hemispherical body 21 of the buffer connection member 20 is in close contact with the upper inner wall of the space portion 15, and the circumferential surface of the hemispherical body 21 and the space portion 15 of the upper body 12 ) The inner circumferential surface is composed of a circumferential ratio corresponding to each other, and when a horizontal thrust shape is generated, the hemispherical body 21 flows along the inner circumferential surface of the upper body 12 of the housing 11.

At this time, since the support rod 26 protruding from the center of the bottom recess 24 of the buffer connection member 20 to the bottom is connected to the upper end of the buffer member 27, the buffer connection member 20 has a bend in the direction in which it moves. have elasticity.

6 of the present invention shows a state in which the buffer member is contracted by a load in a transformer or switchboard, and the buffer member 27 is contracted and the half-spherical body 21 of the buffer connection member 20 is spaced 15 is separated from the inner wall of the

The top neck part 22 and the bolt part 23 integrally formed in the buffer connection member 20 of the switchboard fixing device 10 are inserted into the bolt holes of the fixed section steel 29 supporting the transformer or switchboard 30, and are then fitted with nuts. , and the shock absorber connection member 20 forms a contracted state by the load of the transformer or switchboard connected thereto and absorbs the vibration generated from the device.

At this time, when the switchboard fixing device 10 is contracted by the load of the upper connected device, the load force transmitted to the buffer connection member 20 is transmitted downward through the neck portion 22, and at the same time, the bottom concave portion of the hemispherical body 21 As the pressing contact surface 25 of (24) presses the top surface of the buffer member 27, it contracts and has elastic resistance.

When the buffer member 27 is contracted by a load generated from the upper part, the upper end is subjected to load pressure by the concave portion 24 on the bottom surface of the hemispherical body 21 of the buffer connection member 20, so that the pressure is not balanced. and shrinks evenly.

That is, the buffer connection member 20 is made of a concave groove 24 with a concave bottom surface of the hemispherical body 21, and when the load generated at the top is transmitted, the upper end of the buffer member 27 is pressed against the pressing contact surface 25 of the groove 24. When this is pressed, a semi-groove shaped recess 24 is formed, so that the force applied to the buffer member 27 is uniformly pressed.

In addition, when an earthquake occurs, when the transformer or switchboard is subjected to pushing pressure by the horizontal support force, the shock absorbing connection member 20 located in the housing 11 of the switchboard fixing device 10 is pushed to one side and at the same time the hemispherical body 21 forms a circular shape. The upper end of the buffer member 27, which flows to one side within the space 15 and is connected to the support bar 26, bends and generates elastic resistance at the same time, so that resistance to the conduction moment of the transformer and switchboard is formed to have earthquake resistance. .

As described above, the flow and movement of the shock absorbing connecting member 20 and the bending of the shock absorbing member 27 are all performed within the radius of rotation within the circular space 15 of the housing.

Thus, the switchboard fixing device 10 of the present invention uses a buffer member 27 with high durability and uses a full weight member 27 that can withstand a weight of 100 kg compared to the weight of the installed switchboard 30, and uses a buffer member (27) uses an appropriate quantity according to the total weight of the switchboard.

In addition, the buffer member of the present invention is manufactured to have durability during up and down shaking and left and right shaking so that it can be operated according to seismic strength.

The present invention absorbs and buffers vibrations generated in a switchboard that manages a transformer in a substation, a power plant, or a building in a substation to receive and send electricity, and resists horizontal or vertical seismic force in the event of an earthquake and has a damping function to achieve an earthquake-resistant effect is to have

10: switchboard fixing device 11: housing
12: upper body 13: through hole
14: lower body 15: space
16: storage unit 17: fixed bracket
18: upper fastening bolt 19: lower fastening bolt
20: buffer connection member 21: hemispherical body
22: neck part 23: bolt part
24: groove portion 25: pressing contact surface
26: support bar 27: buffer member
28: bottom beam 29: fixed beam
30: switchboard

Claims (4)

a housing 11 installed on the fixing bracket 17;
a buffer member 27 installed inside the housing 11 to absorb vibration, shock and load;
a buffer connection member 20 connected to the upper end of the buffer member 27 and connected to a fixed section 29 installed on a lower surface of a transformer or switchboard;
The upper body 12 and the lower body 14 of the housing 11 are coupled with an upper fastening bolt 18, and the lower body 14 and the fixing bracket 17 are coupled with a lower fastening bolt 19,
The buffer connection member 20 has a hemispherical body 21 formed in a hemispherical shape, and a neck portion 22 and a bolt portion 23 integrally formed at the upper center of the hemispherical body 21,
The inner surface of the hemispherical body 21 is made of a concave groove portion 24, and the support rod 26 connected to the buffer member 27 is protruded downward from the central portion of the bottom surface groove portion 24 of the hemispherical body 21. A switchboard fixing device having an earthquake-resistant function. delete According to claim 1,
The housing 11 is made of a combination of an upper body 12 and a lower body 14, and a receiving portion 16 in which a buffer member 27 is installed is formed inside the lower body 14, and the lower body ( 14) and the upper body 12 are coupled to a switchboard fixing device having an earthquake-resistant function, characterized in that a circular space portion 15 is formed and a buffer connection member 20 is installed. According to claim 1,
The buffer member 27 corresponds to the pressing contact surface 25 forming the inner surface of the concave portion 24 formed on the bottom surface of the hemispherical body 21 of the buffer connection member 20 to uniformly compress the load transmitted from the top. A switchboard fixing device having an earthquake-resistant function, characterized in that.

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