CN211550395U

CN211550395U - Anti-seismic support of electromechanical equipment in building

Info

Publication number: CN211550395U
Application number: CN201922282495.2U
Authority: CN
Inventors: 罗爱华
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-12-18
Filing date: 2019-12-18
Publication date: 2020-09-22
Anticipated expiration: 2029-12-18

Abstract

The utility model provides an inside electromechanical device's of building antidetonation support. The anti-seismic support of the electromechanical equipment in the building comprises a fixed base plate; the four damping springs are all fixedly arranged at the top of the fixed base plate and are distributed in a rectangular shape; the four buffer damping columns are respectively and fixedly arranged at the top ends of the four damping springs; the mounting support plate is fixedly mounted at the top ends of the four buffering shock absorption columns; the mounting thread blind holes are all formed in the top of the mounting support plate; four fixed blocks, four the fixed block all sets up the top of fixed baseplate, and four the fixed block is the rectangle and distributes. The utility model provides an inside electromechanical device's of building antidetonation support has the advantage that support intensity is high, shock-absorbing capacity is good.

Description

Anti-seismic support of electromechanical equipment in building

Technical Field

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

Background

Electromechanical equipment generally refers to machinery, electrical equipment and electrical automation equipment, more electromechanical equipment such as a fan, a pump body, a high-low voltage power distribution cabinet and the like can be used in a building, and in order to reduce the damage rate of the electromechanical equipment in the earthquake process, some electromechanical equipment needs to be supported and installed by using an anti-seismic support.

When supporting some great electromechanical device of quality, the support intensity of the support of considering antidetonation fully, however traditional antidetonation support's support intensity is not enough, and long time later, elastic support spare such as damping spring, rubber pad cause the support dynamics not enough because of long-time heavy burden or ageing factor, influence electromechanical device's normal use, have also reduced the antidetonation effect simultaneously.

Therefore, there is a need to provide a new anti-seismic support for electromechanical devices inside buildings to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem provide a support intensity height, the good antidetonation support of electromechanical device in building that shock-absorbing capacity is good.

For solving the technical problem, the utility model provides an inside electromechanical device's of building antidetonation support includes: fixing the substrate; the four damping springs are all fixedly arranged at the top of the fixed base plate and are distributed in a rectangular shape; the four buffer damping columns are respectively and fixedly arranged at the top ends of the four damping springs; the mounting support plate is fixedly mounted at the top ends of the four buffering shock absorption columns; the mounting thread blind holes are all formed in the top of the mounting support plate; the four fixed blocks are all arranged at the top of the fixed substrate and are distributed in a rectangular shape; the four arch-shaped supporting rods are fixedly arranged at the tops of the four fixing blocks respectively; the four L-shaped supporting blocks are fixedly arranged at the top ends of the four arch-shaped supporting rods respectively, and the bottom of the mounting carrier plate is in contact with the four L-shaped supporting blocks.

Preferably, four fixing and mounting holes are formed in the top of the fixing substrate, and the four fixing and mounting holes are distributed in a rectangular shape.

Preferably, the buffering shock absorption column comprises a plurality of metal wafers and a plurality of damping rubber wafers, the metal wafers and the damping rubber wafers are distributed in a staggered mode, and any damping rubber wafer is fixedly connected with two adjacent metal wafers.

Preferably, the arch-shaped supporting rod is made of copper, and the inside of the arch-shaped supporting rod is of a hollow structure.

Preferably, four caulking grooves are formed in the top of the fixing base plate and are distributed in a rectangular shape, four fixing blocks are slidably mounted in the four caulking grooves respectively, and fixing threaded blind holes are formed in the bottoms of the fixing blocks.

Preferably, four through holes are formed in the bottom of the fixing base plate and are distributed in a rectangular mode, the four through holes are communicated with the corresponding caulking grooves and are movably provided with fixing bolts, the top ends of the fixing bolts extend into the corresponding fixing thread blind holes, and the four fixing bolts are screwed with the corresponding inner walls of the fixing thread blind holes.

Compared with the prior art, the utility model provides an inside electromechanical device's of building antidetonation support has following beneficial effect:

the four damping springs and the four buffer columns can form main support for the fixed base plate, and meanwhile, the four fixed blocks, the four arched support rods and the four L-shaped support blocks also form support for the fixed base plate, so that the load of the damping springs and the buffer columns is reduced, the damping springs and the buffer columns are not easy to deform for a long time, and the normal placement state of the electromechanical equipment is ensured; through setting up the commonality bracing piece, not only can support and inject the installation support plate, and because the inside of arch bracing piece is hollow structure, and be the arch, when electromechanical device received vertical or horizontal impact force when too big, the arch bracing piece can be bent or the slope, absorb partly impact force, and simultaneously, damping spring and buffering column page or leaf cushion electromechanical device, reduce the impact force that electromechanical device received in the twinkling of an eye, damping rubber disk can absorb the energy, avoid damping spring to last vibrations, whole shock attenuation is effectual.

Drawings

Fig. 1 is a schematic structural view of a preferred embodiment of an anti-seismic support for electromechanical devices inside a building according to the present invention;

FIG. 2 is an enlarged schematic view of the structure at A shown in FIG. 1;

fig. 3 is a schematic structural view of the shock-absorbing strut shown in fig. 1.

Reference numbers in the figures: 1. the damping device comprises a fixed base plate, 2, a damping spring, 3, a buffering damping column, 4, an installation support plate, 5, an installation thread blind hole, 6, a fixed block, 7, an arched support rod, 8, an L-shaped support block, 9, a fixed installation hole, 10, an embedding groove, 11, a fixed thread blind hole, 12, a through hole, 13, a fixing bolt, 301, a metal wafer, 302 and a damping rubber wafer.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Please refer to fig. 1, fig. 2 and fig. 3 in combination, wherein fig. 1 is a schematic structural diagram of a preferred embodiment of an anti-seismic support for an electromechanical device inside a building according to the present invention; FIG. 2 is an enlarged schematic view of the structure at A shown in FIG. 1; fig. 3 is a schematic structural view of the shock-absorbing strut shown in fig. 1. The anti-seismic support of the electromechanical device inside the building comprises: a fixed substrate 1; the four damping springs 2 are all fixedly arranged at the top of the fixed base plate 1, and the four damping springs 2 are distributed in a rectangular shape; the four buffer damping columns 3 are respectively and fixedly arranged at the top ends of the four damping springs 2; the mounting support plate 4 is fixedly mounted at the top ends of the four buffering shock absorption columns 3; the mounting thread blind holes 5 are formed in the top of the mounting carrier plate 4; the four fixing blocks 6 are all arranged at the top of the fixed substrate 1, and the four fixing blocks 6 are distributed in a rectangular shape; the four arch-shaped support rods 7 are respectively and fixedly arranged at the tops of the four fixing blocks 6; the support device comprises four L-shaped support blocks 8, the four L-shaped support blocks 8 are fixedly arranged at the top ends of the four arch-shaped support rods 7 respectively, and the bottom of the installation support plate 4 is in contact with the four L-shaped support blocks 8.

Preferably, four fixing and mounting holes 9 are formed in the top of the fixing substrate 1, and the four fixing and mounting holes 9 are distributed in a rectangular shape.

Preferably, the damping column 3 comprises a plurality of metal disks 301 and a plurality of damping rubber disks 302, the plurality of metal disks 301 and the plurality of damping rubber disks 302 are distributed in a staggered manner, and any one damping rubber disk 302 is fixedly connected with two adjacent metal disks 301.

Preferably, the arch-shaped support rod 7 is made of copper, and the interior of the arch-shaped support rod 7 is of a hollow structure.

Preferably, four caulking grooves 10 are formed in the top of the fixing base plate 1, the four caulking grooves 10 are distributed in a rectangular shape, the four fixing blocks 6 are slidably mounted in the four caulking grooves 10 respectively, and fixing threaded blind holes 11 are formed in the bottoms of the fixing blocks 6.

Preferably, four through holes 12 are formed in the bottom of the fixing base plate 1, the four through holes 12 are distributed in a rectangular shape, the four through holes 12 are communicated with the corresponding caulking grooves 10, the four through holes 12 are movably provided with fixing bolts 13, the four fixing bolts 13 are movably arranged at the top ends of the fixing bolts 13 and extend into the corresponding fixing thread blind holes 11, and the four fixing bolts 13 are screwed with the corresponding inner walls of the fixing thread blind holes 11.

The utility model provides an inside electromechanical device's of building antidetonation support's theory of operation as follows:

when in use, the electromechanical equipment is arranged on the mounting support plate 4 and is fixed through the plurality of mounting thread blind holes 5;

four damping springs 2 and four buffer posts 3 form four groups of main supporting bodies to support the fixed substrate 1, and meanwhile, four fixed blocks 6, four arch-shaped supporting rods 7 and four L-shaped supporting blocks 8 form four groups of auxiliary supporting bodies to support the fixed substrate 1, so that the load of the damping springs 2 and the buffer posts 3 can be reduced, the damping springs 2 and the buffer posts 3 are not easy to deform, and the normal placement state of the electromechanical equipment is ensured;

when an earthquake occurs, the interior of the arched support rod 7 is of a hollow structure and is arched, so that when the electromechanical equipment is subjected to longitudinal and downward impact force, the arched support rod 7 can be further bent to absorb a part of the longitudinal impact force, meanwhile, the damping spring 2 and the damping column 3 buffer the electromechanical equipment, the impact force instantaneously applied to the electromechanical equipment is reduced, the damping rubber wafer 302 can absorb energy, and the damping spring 2 is prevented from continuously vibrating; in the process of receiving transverse impact force, the electromechanical device can rock left and right, the four L-shaped supporting blocks 8 can limit the position of the mounting support plate 4, the situation that the electromechanical device rocks too much is avoided, and the damping spring 2 and the buffer column 3 can be bent along with the rocking of the electromechanical device to form buffering.

the utility model provides an anti-seismic support for electromechanical equipment in a building, four damping springs 2 and four buffer posts 3 can form main support for a fixed substrate 1, and simultaneously, four fixed blocks 6, four arch-shaped support rods 7 and four L-shaped support blocks 8 also form support for the fixed substrate 1, so that the load of the damping springs 2 and the buffer posts 3 is reduced, the damping springs 2 and the buffer posts 3 are not easy to deform for a long time, and the normal placement state of the electromechanical equipment is ensured; through setting up commonality bracing piece 7, not only can support and prescribe a limit to installation support plate 4, and because the inside of arch bracing piece 7 is hollow structure, and be the arch, when electromechanical device received vertical or horizontal impact force too big, arch bracing piece 7 can be bent or slope, absorb partly impact force, and simultaneously, damping spring 2 and cushion column 3 page or leaf cushion electromechanical device, reduce the impact force that electromechanical device received in the twinkling of an eye, damping rubber disk 302 absorbable energy, avoid damping spring 2 to last vibrations, whole shock attenuation is effectual.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims

1. An anti-seismic support for electromechanical equipment within a building, comprising:

fixing the substrate;

the four damping springs are all fixedly arranged at the top of the fixed base plate and are distributed in a rectangular shape;

the four buffer damping columns are respectively and fixedly arranged at the top ends of the four damping springs;

the mounting support plate is fixedly mounted at the top ends of the four buffering shock absorption columns;

the mounting thread blind holes are all formed in the top of the mounting support plate;

the four fixed blocks are all arranged at the top of the fixed substrate and are distributed in a rectangular shape;

the four arch-shaped supporting rods are fixedly arranged at the tops of the four fixing blocks respectively;

the four L-shaped supporting blocks are fixedly arranged at the top ends of the four arch-shaped supporting rods respectively, and the bottom of the mounting carrier plate is in contact with the four L-shaped supporting blocks.

2. An anti-seismic support for electromechanical equipment in a building according to claim 1, wherein four fixing holes are formed in the top of the fixing base plate, and the four fixing holes are distributed in a rectangular shape.

3. An anti-seismic support for electromechanical devices inside buildings according to claim 1 wherein said shock absorbing column comprises a plurality of metal disks and a plurality of damping rubber disks, said plurality of metal disks and said plurality of damping rubber disks are staggered, and any one of said damping rubber disks is fixedly connected to two adjacent metal disks.

4. An anti-seismic support for electromechanical devices inside a building according to claim 1, wherein said arched support rods are made of copper, and the inside of said arched support rods is hollow.

5. An anti-seismic support for electromechanical equipment in a building according to claim 1, wherein four caulking grooves are formed in the top of the fixing base plate, the four caulking grooves are distributed in a rectangular shape, the four fixing blocks are slidably mounted in the four caulking grooves respectively, and fixing threaded blind holes are formed in the bottoms of the fixing blocks.

6. An anti-seismic support for electromechanical equipment inside a building according to claim 5, wherein four through holes are formed in the bottom of the fixing base plate, the four through holes are distributed in a rectangular shape, the four through holes are communicated with the corresponding caulking grooves, fixing bolts are movably mounted on the four through holes, the top ends of the four fixing bolts extend into the corresponding fixing thread blind holes, and the four fixing bolts are screwed with the inner walls of the corresponding fixing thread blind holes.