CN210799868U

CN210799868U - Anti-seismic support of electromechanical equipment in building

Info

Publication number: CN210799868U
Application number: CN201921280057.6U
Authority: CN
Inventors: 沈艳萍; 陈策策
Original assignee: Shanghai Jicai Construction Technology Co ltd
Current assignee: Shanghai Jicai Construction Technology Co ltd
Priority date: 2019-08-08
Filing date: 2019-08-08
Publication date: 2020-06-19
Anticipated expiration: 2029-08-08

Abstract

The utility model discloses an anti-seismic support of electromechanical device inside building belongs to the support field of combatting earthquake, including mounting panel and four bottom plates, the top of mounting panel is fixed with electromechanical device, and the bottom surface of mounting panel is fixed with four buffering posts, four the settling hole has all been seted up at the top of bottom plate, and the inside in four settling holes all is equipped with removes the post, and removes and is equipped with the interval between the lateral wall in post and settling hole, removes the bottom of post and the bottom sliding connection in settling hole, four the buffering hole has all been seted up, four at the top of removal post the bottom of buffering post extends to the inside in four buffering holes respectively. The utility model discloses the structure pole is reasonable, and design benefit not only can carry out the shock attenuation to electromechanical device in vertical direction, can carry out diversified shock attenuation to electromechanical device in addition on the horizontal direction, has improved the antidetonation effect of whole device, has effectively avoided electromechanical device to receive the damage.

Description

Anti-seismic support of electromechanical equipment in building

Technical Field

The utility model relates to an antidetonation support field especially relates to an electromechanical device's in building antidetonation support.

Background

The electromechanical products refer to the sum of mechanical and electrical equipment, along with the progress of scientific technology, the varieties of the electromechanical products in the traditional sense are greatly developed, the electromechanical products in the general concept in modern technology and management refer to the mechanical products, electrical products, electronic products, electromechanical integrated products, parts, accessories and the like of the mechanical products, an anti-seismic support is often required to be fixedly supported in the use of the electromechanical equipment in a building, the anti-seismic support of the electromechanical equipment in the building, which is published by the patent number of CN201720599012.X, comprises a fixed ground mat, the periphery of the fixed ground mat is connected with the ground through fixing bolts, a support frame is arranged at the top of the fixed ground mat, four damping spring devices are arranged on the support frame, a reinforcing connecting rod is arranged between the support frames, a mounting seat is arranged at the top of the support frame, but the patent file intelligently damps the electromechanical equipment in the, however, seismic waves are not only longitudinal but also transverse, so that the defects in the prior art are overcome, and the application discloses an anti-seismic support for electromechanical equipment in the building.

Disclosure of Invention

The utility model provides a pair of building inside electromechanical device's antidetonation support has solved the antidetonation support of building inside electromechanical device among the prior art and can only carry out the absorbing problem to electromechanical device in the vertical direction.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an anti-seismic support of electromechanical equipment in a building comprises a mounting plate and four bottom plates, wherein the top of the mounting plate is fixed with the electromechanical equipment, the bottom surface of the mounting plate is fixed with four buffer columns, the tops of the four bottom plates are provided with mounting holes, moving columns are arranged in the four mounting holes, intervals are arranged between the moving columns and the side walls of the mounting holes, the bottoms of the moving columns are in sliding connection with the bottoms of the mounting holes, the tops of the four moving columns are provided with buffer holes, the bottoms of the four buffer columns respectively extend into the four buffer holes, one ends of the buffer columns, which are positioned in the buffer holes, are fixed with first springs, the other ends of the first springs are fixedly connected with the bottoms of the buffer holes, two sides of the four moving columns are fixed with first damping columns, two sides of the four mounting holes are provided with sliding grooves, and moving blocks are in sliding connection with the sliding blocks, the movable block is close to the one end of moving the post and has seted up first spring hole, the other end of first shock attenuation post extends to the inside in first spring hole, and the one end that first shock attenuation post is located first spring hole inside is fixed with the second spring, the other end and a lateral wall fixed connection in first spring hole of second spring, the second spring hole has all been seted up to the both sides of spout, and the both sides of movable block all are fixed with second shock attenuation post, and the other end of second shock attenuation post extends to the inside in second spring hole, and the one end that second shock attenuation post is located spring hole inside is fixed with the third spring, the other end and a lateral wall fixed connection in second spring hole of third spring.

Preferably, the bottom of the moving block is fixed with a limiting block, the bottom of the sliding groove is provided with a limiting groove, and one end of the limiting block extends to the inside of the limiting groove and is in sliding connection with the limiting groove.

Preferably, the two sides of the electromechanical device are both fixed with first connecting blocks, and the first connecting blocks are in threaded connection with the mounting plate through first bolts.

Preferably, the top of mounting panel is fixed with the shock pad, and the shock pad adopts the rubber preparation, and the shock pad is located electromechanical device's bottom.

Preferably, the top of spout has seted up the spread groove, and the width of spread groove is greater than the width of movable block, and the outside of spread groove is fixed with the apron, and the bottom of apron is fixed with the clamp plate, and the one end of clamp plate extends to the inside of spread groove.

Preferably, the cover plate is fixedly connected with the bottom plate through a second bolt.

Preferably, the two sides of the four bottom plates are fixed with second connecting blocks.

The utility model discloses in:

1. when the shock absorber vibrates in the vertical direction, the buffer column contracts in the buffer hole, and the impact force borne by the first spring is offset, so that the shock absorption purpose in the vertical direction is achieved;

2. when vibration occurs in the horizontal direction, the first damping column contracts in the first spring hole, and the second damping column contracts in the second spring hole, so that the damping effect can be achieved in four directions of the horizontal plane;

3. the arrangement of the connecting groove facilitates the installation of the moving block into the sliding groove, and the arrangement of the cover plate and the pressing plate can prevent the moving block from escaping from the connecting groove;

4. the limiting block is clamped inside the limiting groove, and the purpose that the moving block is fixed inside the sliding groove is achieved.

The utility model discloses the structure pole is reasonable, and design benefit not only can carry out the shock attenuation to electromechanical device in vertical direction, can carry out diversified shock attenuation to electromechanical device in addition on the horizontal direction, has improved the antidetonation effect of whole device, has effectively avoided electromechanical device to receive the damage.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is an enlarged view of a point a of the present invention.

Fig. 3 is a side view of the sliding chute and the moving block of the present invention.

Reference numbers in the figures: 1. mounting a plate; 2. an electromechanical device; 3. a shock pad; 4. a first connection block; 5. a first bolt; 6. a buffer column; 7. a cover plate; 8. a base plate; 9. moving the column; 10. a second connecting block; 11. a buffer hole; 12. a first spring; 13. placing the hole; 14. connecting grooves; 15 a first spring hole, 16, a moving block; 17. a limiting groove; 18. a limiting block; 19. a chute; 20. pressing a plate; 21. a first shock-absorbing post; 22. a second shock-absorbing post; 23. a second spring hole; 24 second bolt.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, an anti-seismic support for electromechanical equipment in a building comprises a mounting plate 1 and four bottom plates 8, wherein the top of the mounting plate 1 is fixed with electromechanical equipment 2, the bottom surface of the mounting plate 1 is fixed with four buffer columns 6, the tops of the four bottom plates 8 are all provided with placing holes 13, the interiors of the four placing holes 13 are all provided with moving columns 9, a space is arranged between the moving columns 9 and the side walls of the placing holes 13, the bottoms of the moving columns 9 are slidably connected with the bottoms of the placing holes 13, the tops of the four moving columns 9 are all provided with buffer holes 11, the bottoms of the four buffer columns 6 respectively extend into the four buffer holes 11, one end of each buffer column 6 positioned in each buffer hole 11 is fixed with a first spring 12, the other end of each first spring 12 is fixedly connected with the bottom of each buffer hole 11, two sides of each moving column 9 are all fixed with first damping columns 21, two sides of each placing hole 13 are all provided with chutes 19, the inside sliding connection of spout 19 has movable block 16, first spring hole 15 has been seted up to the one end that movable block 16 is close to removal post 9, the other end of first shock strut 21 extends to the inside of first spring hole 15, and first shock strut 21 is located the inside one end of first spring hole 15 and is fixed with the second spring, the other end of second spring and a lateral wall fixed connection of first spring hole 15, second spring hole 23 has all been seted up to the both sides of spout 19, the both sides of movable block 16 all are fixed with second shock strut 22, the other end of second shock strut 22 extends to the inside of second spring hole 23, and the one end that second shock strut 22 is located spring hole 23 is fixed with the third spring, the other end of third spring and a lateral wall fixed connection of second spring hole 23.

In this embodiment, when vibrations take place in the vertical direction, bumping post 6 contracts in buffering hole 11, and the impact force that first spring 12 will receive offsets to reach the purpose of absorbing shock in the vertical direction, when vibrations take place in the horizontal direction, first bumping post 21 contracts in first spring hole 15, and second bumping post 22 contracts in second spring hole 23, thereby can all reach absorbing effect in four directions of horizontal plane.

Specifically, a limiting block 18 is fixed at the bottom of the moving block 16, a limiting groove 17 is formed at the bottom of the sliding groove 19, and one end of the limiting block 18 extends into the limiting groove 17 and is connected with the limiting groove 17 in a sliding manner; the limiting block 18 is clamped inside the limiting groove 17, so that the moving block 16 is prevented from sliding out of the sliding groove 19.

Specifically, the two sides of the electromechanical device 2 are both fixed with first connecting blocks 4, and the first connecting blocks 4 are in threaded connection with the mounting plate 1 through first bolts 5; through the cooperation between first bolt 5 and the first connecting block 4, conveniently carry out the dismouting to electromechanical device 2.

Specifically, a damping pad 3 is fixed on the top of the mounting plate 1, the damping pad 3 is made of rubber, and the damping pad 3 is located at the bottom of the electromechanical device 2; the shock pad 3 is arranged to avoid over-excited collision between the electromechanical device 2 and the mounting plate.

Specifically, the top of the sliding groove 19 is provided with a connecting groove 14, the width of the connecting groove 14 is greater than that of the moving block 16, a cover plate 7 is fixed outside the connecting groove 14, a pressing plate 20 is fixed at the bottom of the cover plate 7, and one end of the pressing plate 20 extends into the connecting groove 14; the arrangement of the connecting groove 14 can facilitate the moving block 16 to be installed inside the sliding groove 19, and the arrangement of the cover plate 7 and the pressing plate 20 can prevent the moving block from escaping from the connecting groove 14.

Specifically, the cover plate 7 and the bottom plate 8 are fixedly connected through a second bolt 24; the second bolt 24 is arranged to facilitate the disassembly and assembly of the cover plate 7.

Specifically, the two sides of the four bottom plates 8 are fixed with second connecting blocks 10; the second connecting block 10 may be fixed to the ground, thereby fixing the base plate 8 to the ground.

The utility model discloses a theory of operation and use flow: when the vibration occurs in the vertical direction, the buffer column 6 contracts in the buffer hole 11, the impact force received by the first spring 12 is counteracted, and therefore the purpose of shock absorption in the vertical direction is achieved;

during assembly, the cover plate 7 is firstly taken away from the top of the connecting groove 14, then the moving block 16 is clamped into the sliding groove 19 along the connecting groove 14, and finally the cover plate 7 is covered outside the connecting groove 14, so that the moving block can be prevented from escaping from the connecting groove 14.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The anti-seismic support for the electromechanical equipment in the building comprises a mounting plate (1) and four bottom plates (8), and is characterized in that the electromechanical equipment (2) is fixed at the top of the mounting plate (1), four buffer columns (6) are fixed on the bottom surface of the mounting plate (1), four placement holes (13) are formed in the top of each bottom plate (8), a movable column (9) is arranged in each placement hole (13), a space is formed between each movable column (9) and the side wall of each placement hole (13), the bottom of each movable column (9) is in sliding connection with the bottom of each placement hole (13), the top of each movable column (9) is provided with a buffer hole (11), the bottom of each buffer column (6) extends into the corresponding buffer hole (11), and a first spring (12) is fixed at one end, located inside each buffer hole (11), of each buffer column (6), the other end of the first spring (12) is fixedly connected with the bottom of the buffer hole (11), first damping columns (21) are fixed on two sides of the four moving columns (9), sliding grooves (19) are formed in two sides of the four placing holes (13), a moving block (16) is connected to the inside of each sliding groove (19) in a sliding mode, a first spring hole (15) is formed in one end, close to the moving column (9), of the moving block (16), the other end of each first damping column (21) extends into the corresponding first spring hole (15), a second spring is fixed at one end, located inside the corresponding first spring hole (15), of each first damping column (21), the other end of each second spring is fixedly connected with one side wall of the corresponding first spring hole (15), second spring holes (23) are formed in two sides of each sliding groove (19), and second damping columns (22) are fixed on two sides of the moving block (16), the other end of the second shock absorption column (22) extends to the inside of the second spring hole (23), a third spring is fixed at one end, located inside the spring hole (23), of the second shock absorption column (22), and the other end of the third spring is fixedly connected with one side wall of the second spring hole (23).

2. The anti-seismic support for the electromechanical equipment in the building according to claim 1, wherein a limiting block (18) is fixed at the bottom of the moving block (16), a limiting groove (17) is formed at the bottom of the sliding groove (19), and one end of the limiting block (18) extends to the inside of the limiting groove (17) and is connected with the limiting groove (17) in a sliding manner.

3. An anti-seismic support for electromechanical equipment in a building according to claim 1, characterized in that a first connecting block (4) is fixed on each side of the electromechanical equipment (2), and the first connecting block (4) is in threaded connection with the mounting plate (1) through a first bolt (5).

4. An anti-seismic support for electromechanical equipment in a building according to claim 1, characterized in that a shock pad (3) is fixed on the top of the mounting plate (1), the shock pad (3) is made of rubber, and the shock pad (3) is located at the bottom of the electromechanical equipment (2).

5. The anti-seismic support for the electromechanical equipment in the building according to claim 1, wherein the top of the sliding groove (19) is provided with a connecting groove (14), the width of the connecting groove (14) is larger than that of the moving block (16), a cover plate (7) is fixed outside the connecting groove (14), a pressing plate (20) is fixed at the bottom of the cover plate (7), and one end of the pressing plate (20) extends to the inside of the connecting groove (14).

6. An anti-seismic support for electromechanical devices inside buildings according to claim 5, characterised in that said cover plate (7) is fixedly connected to the base plate (8) by means of second bolts (24).

7. An anti-seismic support for electromechanical devices inside buildings according to claim 5, characterised in that the four said base plates (8) are fixed on both sides with second connecting blocks (10).