KR102386704B1 - Seismic device for switchgear - Google Patents

Abstract

The present invention relates to a seismic device for a switchboard for seismic design, and more particularly, when an impact is applied to the switchboard, the support parts of both sides of the upper and lower bending plate springs spread or move in the left and right directions to prevent vibration caused by the impact applied to the switchboard. It relates to a switchgear seismic device for an earthquake-resistant design that acts as an offset.

Description

Seismic device for switchgear for seismic design

The present invention relates to a seismic device for a switchboard for seismic design, and more particularly, when an impact is applied to the switchboard, the support parts of both sides of the upper and lower bending plate springs spread or move in the left and right directions to prevent vibration caused by the impact applied to the switchboard. It relates to a switchgear seismic device for an earthquake-resistant design that acts as an offset.

It is a device that receives high-voltage or extra-high voltage electricity supplied by the power company, converts it into the voltage used by the consumer, and distributes it to the load facility. On the surface, this switchgear is a partition structure called cubicle, and inside the switchboard is electric power devices such as high-voltage switchgear, instrument current transformer, high-voltage circuit breaker, transformer, and low-voltage distribution circuit breaker, and electricity such as relays and instruments for protection and monitoring of the power system. Parts, etc. are mounted. In addition to power devices, busbars connecting power devices to each other according to the power system and wiring for measurement and monitoring of power devices are arranged inside the cubicle. There is a hole for the monitoring wiring and the load facility wiring between the two. If external vibrations or shocks due to seismic fluctuations occur due to the reason that the switchgear as described above is installed on the ground, the power devices inside the switchboard, the wiring interconnecting these power devices, and electrical components such as the protective relay are damaged or damaged. It is easy, and an interruption of the power supply may cause a fire or interruption of the power supply. Also, in general, a switchboard is a device used to monitor, control, and protect an electrical system when power transmitted from a power plant or substation is mainly distributed to a high-voltage receiver as one of electrical equipment that safely supplies industrial power to users.

The switchboard is composed of an assembly of electrical devices such as circuit breakers and protective relays and cables that connect and connect them inside the enclosure, and the enclosure is usually fixedly installed on the wall or ground of a building. Therefore, when an earthquake occurs, the vibration or shock causes damage to the enclosure as well as electric devices or cables installed therein, making it difficult to supply stable power.

In order to solve such a problem, as a technology combined with a seismic design, Korean Patent No. 1571557 (announced on November 24, 2015) discloses a 'seismic switchboard equipped with a vibration isolator housing'.

The main configuration of the invention is 'including a cube-shaped cubicle for accommodating a power receiving unit receiving power from a distribution line and electric devices of a power distribution unit distributing power supplied according to a predetermined control, and an earthquake occurs at the bottom edge of the cubicle A vibration isolator is installed to absorb seismic vibration when an earthquake occurs, and an insulating support in the shape of a long rod is installed inside the housing in the distribution unit, and the inner surface of the insulating support is not affected by the waves of the seismic wave when an earthquake occurs 3 It is fastened to a Z-shaped bus bar having a Z-shape for fixing the side, and the vibration isolator includes: a first seismic-resistant member having a plate-like shape and fastened to the bottom edge of the cubicle; a second earthquake-resistant member having a plate-like shape and fastened to the installation floor; and an elastic member installed therein in a cylindrical shape between the first earthquake-resistant member and the second earthquake-resistant member to prevent vibration or shock transmitted from the second earthquake-resistant member from being transmitted to the first earthquake-resistant member It includes a dustproof part.

The present invention provides a switchgear seismic device for seismic design, which acts to offset the vibration caused by the impact applied to the switchboard while the support parts of both sides of the upper and lower bending plate springs open or move in the left and right directions when an impact is applied to the switchboard. There is a purpose.

An object of the present invention is to provide a switchgear seismic device for seismic design that allows the installation to be performed by adjusting the elastic strength according to the load of the switchboard, and which allows the left and right flow to occur smoothly in the event of an earthquake.

The present invention is installed on the upper part of the lower plate frame 10' so that the upper and lower bending plate springs 20 and 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10', and the front and rear side walls A top plate frame 10 made of an 'H'-shaped side cross-section with the bottom formed at a certain height therebetween; It is installed in the lower part of the upper plate frame 10 so that upper and lower bending plate springs 20 and 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10', and the floor between the front and rear side walls The lower plate frame (10') made of an 'H'-shaped side cross-section formed at a certain height; Both fastening holes 24, 24' of the lower bending plate spring 20 so that the upper and lower bending plate springs 20, 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10' The flat support parts 29-1 and 29 on both sides of the upper bending plate spring 20' are coupled to the lower bending plate spring 20 in a state of being inserted into the upper plate spring 20' so as to be in close contact with the bottom of the lower plate frame 10'. '-1) is formed, and the convex part 28-1 bent in an arc shape between the support parts 29-1 and 29'-1 on both sides so as to be in close contact with the bottom of the pedestal 210 of the switchboard 200. is formed, and perforated holes 22-1 are formed in the support parts 29-1 and 29'-1 on both sides so that they can be fastened to the upper and lower plate frames 10, 10' and fixing bolts 40, 40'. , 22'-1) is formed in the upper bending plate spring (20'); Flat support parts 29 and 29' are formed on both sides of the lower bending plate spring 20 to be in close contact with the bottom of the upper plate frame 10, and to be in close contact with the bottom of the lower plate frame 10'. Concave portions 28 bent in an arc shape are formed between the support portions 29 and 29 ′ on both sides, and the upper and lower plate frames 10 and 10 ′ and the fixing bolts 40 and 40 ′ are formed so as to be fastened to the both sides. Cut-out holes 22 and 22' are formed in the support portions 29 and 29', and the upper bending plate spring 20' is inserted into the fastening holes 24 and 24' of the lower bending plate spring 20, · A lower bending plate spring (20) having fastening holes (24, 24') formed on both sides of the lower bending plate spring (20) so that the lower bending plate springs (20, 20') can be fixedly installed; and penetrating both through-holes 15 and 15' of the lower plate frame 10', and penetrating the cut-out holes 22-1 and 22'-1 of the upper bending plate spring 20' to the lower bushing ( 23, 23'), through both support springs 30 and 30', through the upper bushings 33, 33', and the cut-out holes 22 and 22' of the lower bending plate spring 20. The upper and lower bending plate springs ( 20, 20') is to offset the vibration caused by the impact applied to the switchboard 200 as the support portions 29, 29', 29', 29'-1 of the both sides spread or move in the left and right directions.

The present invention provides an action of canceling the vibration caused by the shock applied to the switchboard as the support parts of both sides of the upper and lower bending plate springs open or move in the left and right directions when an impact is applied to the switchboard because a plurality of them are attached to the bottom of the support of the switchboard. It has a useful effect.

In addition, the present invention is a very useful invention in which the elastic strength can be adjusted and installed according to the load of the switchboard, and the left and right flow is made smoothly in the event of an earthquake.

1 is a perspective view showing a switchboard seismic device for seismic design of the present invention.
Figure 2 is a perspective view showing a switchboard seismic device for seismic design of the present invention.
Figure 3 is a perspective view showing a switchboard seismic device for seismic design of the present invention.
Figure 4 is a perspective view showing a switchboard seismic device for seismic design of the present invention.
Figure 5 is a perspective view showing a switchboard seismic device for seismic design of the present invention.
Figure 6 is a cross-sectional view showing the switchboard seismic device for seismic design of the present invention.
Figure 7 is a cross-sectional view showing the switchboard seismic device for seismic design of the present invention.
Figure 8 is a cross-sectional view showing a switchboard seismic device for seismic design of the present invention.
9 is a state diagram showing an earthquake-resistant switchboard seismic device for an earthquake-resistant design of another embodiment of the present invention.

In the present invention, a plurality of pedestals 210 of the switchboard 200 are attached to the bottom surface of the switchboard 200 to offset vibrations caused by the impact applied to the switchboard 200 and to protect the switchboard 200 from earthquakes In an earthquake-resistant device, a top frame It is installed on the upper part of the lower plate frame 10' so that the upper and lower bending plate springs 20 and 20' can be fixedly installed between the 10 and the lower plate frame 10', and the floor is constant between the front and rear side walls. Top plate frame 10 made of a height formed 'H'-shaped side cross-section;

It is installed in the lower part of the upper plate frame 10 so that upper and lower bending plate springs 20 and 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10', and the floor between the front and rear side walls The lower plate frame (10') made of an 'H'-shaped side cross-section formed at a certain height;

Both fastening holes 24, 24' of the lower bending plate spring 20 so that the upper and lower bending plate springs 20, 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10' It is coupled with the lower bending plate spring 20 in a state of being inserted into the flat support parts 29-1, 29 on both sides of the upper bending plate spring 20' so as to be in close contact with the bottom of the lower plate frame 10'. '-1) is formed, and the convex part 28-1 bent in an arc shape between the support parts 29-1 and 29'-1 on both sides so that it can be closely attached to the bottom of the pedestal 210 of the switchboard 200. is formed, and perforated holes 22-1 are formed in the support parts 29-1 and 29'-1 on both sides so that they can be fastened to the upper and lower plate frames 10, 10' and the fixing bolts 40, 40'. , 22'-1) is formed in the upper bending plate spring (20');

Flat support parts 29 and 29' are formed on both sides of the lower bending plate spring 20 to be in close contact with the bottom of the upper plate frame 10, and to be in close contact with the bottom of the lower plate frame 10'. Concave portions 28 bent in an arc shape are formed between the support portions 29 and 29 ′ on both sides, and the upper and lower plate frames 10 and 10 ′ and the fixing bolts 40 and 40 ′ are formed so as to be fastened to the both sides. Cut-out holes 22 and 22' are formed in the support portions 29 and 29', and the upper bending plate spring 20' is inserted into the fastening holes 24 and 24' of the lower bending plate spring 20, · A lower bending plate spring (20) having fastening holes (24, 24') formed on both sides of the lower bending plate spring (20) so that the lower bending plate springs (20, 20') can be fixedly installed; and

The lower bushing 23 passes through both through-holes 15 and 15' of the lower plate frame 10', and penetrates the cut-out holes 22-1 and 22'-1 of the upper bending plate spring 20'. , 23'), through both support springs 30 and 30', through the upper bushings 33, 33', and cut-out holes 22 and 22' of the lower bending plate spring 20 It penetrates through both through-holes 15, 15' of the upper plate frame 10 and consists of fixing bolts 40 and 40' that are fastened to the fixing nuts 42, 42', so that the upper and lower bending plate springs 20 , 20') for earthquake-resistant design, characterized in that the both sides of the support (29, 29', 29', 29'-1) are spread or moved in the left and right directions to cancel the vibration caused by the impact applied to the switchboard 200 It relates to a switchboard seismic resistance device.

The seismic device of the present invention penetrates both through-holes 17 and 17' of the upper plate frame 10, penetrates the bottom of the pedestal 210 of the switchboard 200, and passes through the fixing bushings 63 and 63'. It is fixed to the bottom of the pedestal 210 of the switchboard 200 with fixing bolts 60, 60' fastened to the fixing nuts 62, 62', and through-holes 17 and 17' on both sides of the lower plate frame 10'. Penetrating through the fixing bushings (73, 73'), characterized in that it is fixed to the bottom surface with fixing bolts (70, 70') fastened to the fixing nuts (72, 72').

1 to 8, in the seismic device of the present invention, in the upper plate frame 10, upper and lower bending plate springs 20 and 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10'. It is installed on the upper part of the lower plate frame 10' so that the bottom is formed at a certain height between the front and rear side walls, and is made of an 'H'-shaped side cross-section, and the lower plate frame 10' is the upper plate frame 10 and the lower plate frame 10 ') is installed in the lower part of the upper plate frame 10 so that the upper and lower bending plate springs 20 and 20' can be fixedly installed between the When an impact is applied to the switchboard 200, the support parts 29, 29', 29', 29'-1 of both sides of the upper and lower bending plate springs 20, 20' are opened or moved in the left and right directions. It functions to cancel the vibration caused by the impact applied to the switchboard 200 .

1 to 8, in the seismic device of the present invention, the upper bending plate spring 20' is fixed between the upper plate frame 10 and the lower plate frame 10'. It is coupled to the lower bending plate spring 20 in a state of being inserted into both fastening holes 24 and 24' of the lower bending plate spring 20 so that it can be installed, and to be in close contact with the bottom of the lower plate frame 10'. Flat support portions 29-1 and 29'-1 are formed on both sides of the upper bending plate spring 20' to A convex portion 28-1 bent in an arc shape is formed between -1 and 29'-1), and can be fastened to the upper and lower plate frames 10, 10' and fixing bolts 40, 40'. Cut-out holes 22-1 and 22'-1 are formed in the support portions 29-1 and 29'-1 on both sides so that the lower bending plate spring 20 is in close contact with the bottom of the upper plate frame 10. Flat support parts 29 and 29' are formed on both sides of the lower bending plate spring 20 so that the A concave portion 28 bent by the 22, 22') are formed, and the upper bending plate spring 20' is inserted into the fastening holes 24 and 24' of the lower bending plate spring 20, and the upper and lower bending plate springs 20, 20' For this fixed installation, fastening holes 24 and 24' are formed on both sides of the lower bending plate spring 20, so that when an impact is applied to the switchboard 200, the upper and lower bending plate springs 20, 20' As the both sides of the supporting parts 29, 29', 29', 29'-1 of the switch are spread or moved in the left and right directions, they act to offset the vibration caused by the impact applied to the switchboard 200 .

1 to 8, the seismic device of the present invention penetrates both through-holes 15 and 15' of the lower plate frame 10', and cut-out holes 22-1 of the upper bending plate spring 20'. 22'-1) through the lower bushings 23 and 23', through both support springs 30 and 30', through the upper bushings 33 and 33', and the lower bending plate spring ( 20) through the cut-out holes 22, 22', through the both through-holes 15 and 15' of the upper plate frame 10, and fixing bolts 40 and 40' fastened to the fixing nuts 42 and 42'. ) so that when an impact is applied to the switchboard 200, the support parts 29, 29', 29', 29'-1 of both sides of the upper and lower bending plate springs 20, 20' are opened or moved in the left and right directions. It serves to offset the vibration caused by the impact applied to the switchboard 200 .

1 to 8, the earthquake-resistant device of the present invention penetrates through both through-holes 17 and 17' of the upper plate frame 10 and penetrates the bottom of the pedestal 210 of the switchboard 200, and the fixing bushing 63 . It penetrates the fixing bushings 73 and 73' through the holes 17 and 17', and is fixed to the bottom surface with fixing bolts 70 and 70' that are fastened to the fixing nuts 72 and 72', so that the switchboard ( 200), the support parts 29, 29', 29', 29'-1 of both sides of the upper and lower bending plate springs 20, 20' are spread or moved in the left and right directions to the switchboard 200. It works to cancel the vibration caused by the applied impact.

9 is another embodiment of the present invention in which the upper bending plate spring 20' and the lower bending plate spring 20 can be used where the load of the switchboard is large.

The upper bending plate spring 20 ′ and the lower bending plate spring 20 have the upper bending plate spring 20 ′ and the fastening holes 24 , 24 '24 ", 24"' of the lower bending plate spring 20 ) It is inserted into the upper and lower bending plate springs (20, 20') are characterized in that they are fastened to each other in a 'W' shape when they are fastened to each other.

The upper bending plate spring 20' includes flat support parts 29-1 and 29"-1 on both sides where long cut-out holes 22-1 and 22"-1 of the upper bending plate spring 20' are formed. , It is formed between the flat support parts (22-1, 29"-1) in the center of both sides, but consists of a central support part 29'-1 formed with a long cut-out hole 22'-1.

The upper bending plate spring 20' includes flat support parts 29-1 and 29"-1 on both sides where long cut-out holes 22-1 and 22"-1 of the upper bending plate spring 20' are formed. , formed between the flat support parts 22-1 and 29"-1 in the center of both sides, the central support part 29'-1 in which a long cut-out hole 22'-1 is formed, between the support parts in an arc shape Bent convex portions 28-1 and 28-3 are respectively formed, and the lower bending plate spring 20 has flat support portions ( 29, 29") and the central support part 29' formed between the flat support parts 22 and 29" in the center of the both sides, the central support part 29' having a long perforated hole 22', bent in an arc shape between the support parts Concave portions 28 were respectively formed and joined to form.

10: upper plate frame 10': lower plate frame
20: lower bending plate spring 20': upper bending plate spring

Claims (3)

A plurality of pedestals 210 of the switchboard 200 are attached to the bottom of the switchboard 200 to form an upper plate frame and a lower plate frame to offset the vibration caused by the shock applied to the switchboard 200, and a bending plate between the upper and lower plate frames In the earthquake-resistant device for protecting a switchboard by composing a spring to cushion the impact,
The earthquake-resistant device is installed on the upper part of the lower plate frame 10' so that the upper and lower bending plate springs 20 and 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10', and the front and rear A top plate frame 10 made of an 'H'-shaped side cross-section with a floor formed at a certain height between the side walls;
The upper and lower bending plate springs 20 and 20' are installed in the lower part of the upper plate frame 10 so that they can be fixedly installed between the upper plate frame 10 and the lower plate frame 10', and the floor between the front and rear side walls The lower plate frame (10') made of an 'H'-shaped side cross-section formed at a certain height;
Penetrating both through-holes 17, 17' of the upper plate frame 10, penetrating the bottom of the pedestal 210 of the switchboard 200, penetrating the fixing bushings 63, 63', the fixing nut 62, 62') is fixed to the bottom of the pedestal 210 of the switchboard 200 with fixing bolts 60, 60' fastened to the junction board 200, and is fixed through both through-holes 17 and 17' of the lower plate frame 10'. It penetrates the bushings (73, 73') and is formed to be fixed to the bottom surface with fixing bolts (70, 70') fastened to the fixing nuts (72, 72'),
Both fastening holes 24 and 24' of the lower bending plate spring 20 so that the upper and lower bending plate springs 20, 20' can be fixedly installed between the upper plate frame 10 and the lower plate frame 10' It is coupled with the lower bending plate spring 20 in a state of being inserted into the flat support parts 29-1, 29 on both sides of the upper bending plate spring 20' so as to be in close contact with the bottom of the lower plate frame 10'. '-1) is formed, and the convex part 28-1 bent in an arc shape between the support parts 29-1 and 29'-1 on both sides so that it can be closely attached to the bottom of the pedestal 210 of the switchboard 200. is formed, and perforated holes 22-1 are formed in the support parts 29-1 and 29'-1 on both sides so that they can be fastened to the upper and lower plate frames 10, 10' and the fixing bolts 40, 40'. , 22'-1) is formed in the upper bending plate spring (20');
Flat support parts 29 and 29' are formed on both sides of the lower bending plate spring 20 to be in close contact with the bottom of the upper plate frame 10, and to be in close contact with the bottom of the lower plate frame 10'. A concave portion 28 bent in an arc shape is formed between the support portions 29 and 29' on both sides, and the upper and lower plate frames 10, 10' and the fixing bolts 40, 40' can be used to fasten the concave portions 28 to both sides. Cut-out holes 22 and 22' are formed in the support portions 29 and 29', and the upper bending plate spring 20' is inserted into the fastening holes 24, 24' of the lower bending plate spring 20, · A lower bending plate spring (20) having fastening holes (24, 24') formed on both sides of the lower bending plate spring (20) so that the lower bending plate springs (20, 20') can be fixedly installed;
The lower bushing 23 passes through both through-holes 15 and 15' of the lower plate frame 10', and penetrates the cut-out holes 22-1 and 22'-1 of the upper bending plate spring 20'. , 23'), through both support springs 30 and 30', through the upper bushings 33, 33', and cut-out holes 22 and 22' of the lower bending plate spring 20 It penetrates through both through-holes 15 and 15' of the upper plate frame 10 and consists of fixing bolts 40 and 40' that are fastened to the fixing nuts 42 and 42', so that the upper and lower bending plate springs 20 , 20') for earthquake-resistant design, characterized in that the both sides of the support (29, 29', 29', 29'-1) are spread or moved in the left and right directions to cancel the vibration caused by the impact applied to the switchboard 200 switchboard seismic device.
delete According to claim 1, wherein the upper bending plate spring (20') and the lower bending plate spring (20)
When the upper bending plate spring (20') is inserted into the fastening holes (24, 24'24", 24"') of the lower bending plate spring 20 and the upper and lower bending plate springs 20, 20' are fastened to each other It is formed by fastening to each other in a 'W' shape,
The upper bending plate spring 20' is
Flat support parts 29-1 and 29"-1 on both sides of which long perforated holes 22-1 and 22"-1 of the upper bending plate spring 20' are formed, and flat support parts 22- at the center of both sides. 1,29"-1) formed between the central support part 29'-1 with a long perforated hole 22'-1, and the convex parts 28-1 and 28- which are bent in an arc shape between the support part. 3) is formed respectively,
The lower bending plate spring 20 is
It is formed between the flat support parts 29 and 29" on both sides where the long perforated holes 22 and 22" of the lower bending plate spring 20 are formed, and the flat support parts 22 and 29" in the center of the both sides, A seismic design switchboard seismic device for seismic design, characterized in that a central support part 29' having a long perforated hole 22' is formed and a concave part 28 bent in an arc shape is formed between the support part, respectively.

Images