CN215763030U

CN215763030U - Electromechanical anti-seismic support and hanger for building

Info

Publication number: CN215763030U
Application number: CN202120967598.7U
Authority: CN
Inventors: 彭瑞; 刘运成; 季华卫; 马龙
Original assignee: First Construction Co Ltd of China Construction Eighth Engineering Division Co Ltd
Current assignee: First Construction Co Ltd of China Construction Eighth Engineering Division Co Ltd
Priority date: 2021-05-07
Filing date: 2021-05-07
Publication date: 2022-02-08
Anticipated expiration: 2031-05-07

Abstract

The utility model provides an electromechanical earthquake-resistant support and hanger for a building, and belongs to the technical field of building construction. The technical scheme is as follows: the utility model provides a building electromechanical antidetonation gallows, including the damping piece, with the mounting that the damping device top is connected, just is used for connecting the ceiling, for the holder of centre gripping pipe fitting, and set up damping device bottom with the connecting rod between the holder top. This electromechanical antidetonation gallows of building's simple structure prevents that the high strength stand from leading to the bolt under the stand not hard up that the ceiling fitment caused the shake after fixed, prevents that the fixture from dropping, and pounces the staff that passes by and cause danger, blows off the dust of deposit on the fixture through the shake in-process.

Description

Electromechanical anti-seismic support and hanger for building

Technical Field

The utility model relates to the technical field of building construction, in particular to an electromechanical earthquake-resistant support and hanger for a building.

Background

At present, in the process of a construction site, temporary cables need to be erected due to temporary needs in engineering, particularly in the process of erecting the cables, the cables need to be dismantled after operation, so that the arrangement of the cables is generally not standardized, square timber or other insulating objects can be found temporarily and erected and hung on the construction site with strict requirements, but the cables are not attractive and firm, and the cables are directly placed on the operation surface under most actual conditions on the site.

How to solve the problems in the prior art described above is a problem to be faced by the present invention.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an electromechanical earthquake-resistant support and hanger for a building, which can effectively solve the problems.

The utility model is realized by the following measures: an electromechanical earthquake-resistant support hanger for a building is characterized by comprising a damping piece, a fixing piece, a clamping piece and a connecting rod, wherein the fixing piece is connected with the top end of the damping device and is used for being connected with a ceiling;

wherein, the shock attenuation piece include: the axis of the shock-absorbing cylinder is collinear with the axis of the connecting rod; the two support columns are correspondingly arranged at the upper end and the lower end of the shock-absorbing cylinder body along the radial direction of the shock-absorbing cylinder body; the pressure-relieving component is positioned in the middle of the interior of the damping cylinder body and is clamped and matched with the side wall of the damping cylinder body; the two U-shaped rods are correspondingly positioned at two ends in the damping cylinder body and are respectively clamped and matched with the supporting columns at the same end; the two extrusion components are correspondingly positioned at two ends in the damping cylinder body, one end of each extrusion component is fixedly connected with the U-shaped rod at the corresponding end, and the other end of each extrusion component is fixedly connected with the corresponding end of the pressure-relieving component; the bottom end of the fixing piece penetrates through the top wall of the damping cylinder body and is connected with the corresponding U-shaped rod, and the top end of the connecting rod penetrates through the bottom wall of the damping cylinder body and is connected with the corresponding U-shaped rod.

Furthermore, the support column both ends run through the shock attenuation barrel lateral wall, the shock attenuation piece is still including setting up support column both ends department circumference side with the blotter between the shock attenuation barrel lateral wall.

Further, the compression assembly includes: the damping cylinder comprises two extrusion plates which are oppositely arranged and a spring which is arranged between the two extrusion plates along the axial direction of the damping cylinder, wherein one extrusion plate is fixedly connected with the corresponding U-shaped rod, and the other extrusion plate is matched with the corresponding end part of the pressure-relieving component. Can enough extrude the slow-pressing subassembly effectively, in whole pressurization process, adjust the extrusion force, can pass through the characteristic of spring again for whole device has possessed the function of energy dissipation.

The utility model is particularly characterized in that four through grooves are uniformly arranged at the middle position of the damping cylinder body along the circumferential direction of the damping cylinder body, and the pressure-relieving assembly comprises: the pressure relieving part comprises a pressure relieving cylinder with the axis collinear with the axis of the damping cylinder body and four hollow clamping parts which are uniformly arranged along the circumferential direction of the pressure relieving cylinder and are arranged on the circumferential side surface of the pressure relieving cylinder, four through holes which are respectively communicated with the four clamping parts are formed in the side wall of the pressure relieving cylinder, air holes are formed in the clamping parts, and the clamping parts and the through grooves are in one-to-one correspondence; the buffer box is hollow and positioned in the pressure buffering piece, four side surfaces of the buffer box are respectively clamped and matched with four through holes of the pressure buffering piece, and the buffer box is communicated with the corresponding through holes through air guide ports formed in the side surfaces; the top and bottom surfaces of the buffer box are respectively matched with the corresponding extrusion plates.

Preferably, the pressing plate near one end of the buffer box can be specifically adjusted according to the shape of the buffer box, so that the pressing plate can more efficiently press the buffer box.

Furthermore, the bleeder vent sets up the bottom of card and portion, just be equipped with in the card and portion with bleeder vent matched with filter screen.

Furthermore, a flared opening which expands outwards is arranged on the outer side of the air guide opening.

Furthermore, the buffer box is also provided with a wind guide machine which is positioned at the wind guide opening and used for accelerating the air flow rate.

Only the small fan with the rotating shaft and the fan blades mainly utilizes the extrusion of air flow to enable the wind guide machine to rotate to provide wind power under the condition of autorotation, and the wind is guided through the radian of the fan blades.

Can form atmospheric pressure through vibration extrusion buffering box, when outwards discharging through atmospheric pressure, drive the air guide machine and rotate, blow off the dust that covers on the stand and be convenient for clean, the air guide machine carries out normal running fit's relation with inside atmospheric pressure.

The utility model fixes a fixed object on a ceiling by using an electromechanical anti-seismic support and hanger of a building, and then enables a fixing ring to drive a damping device on a connecting frame to damp in the construction shaking process, so that the bolt is prevented from loosening due to vibration, and an extrusion plate in the device extrudes an extrusion box to blow out gas to remove dust from the fixed object in the damping process.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a front cross-sectional view of the shock absorbing device of the present invention;

FIG. 3 is a side cross-sectional view of the shock absorbing device of the present invention;

FIG. 4 is a schematic view of a pressure relief member according to the present invention;

FIG. 5 is a front view of the crush box of the present invention;

wherein the figures are identified as: 1. a fixing member; 2. a shock absorbing member; 21. a shock-absorbing cylinder; 22. a support pillar; 23. a pressure relief assembly; 231. a pressure relief piece; 2311. air holes are formed; 232. a buffer box; 2321. a wind guide opening; 24. an extrusion assembly; 241. a pressing plate; 242. a spring; 25. a U-shaped rod; 26. a cushion pad; 3. a connecting rod; 4. a clamping member; 5. a filter screen; 6. a bell mouth; 7. a wind guide fan; 8. a gas hood; 9. link, 10, spacing bolt.

Detailed Description

In order to clearly illustrate the technical features of the present solution, the present solution is explained below by way of specific embodiments.

Referring to fig. 1 to 5, the present invention is: an electromechanical earthquake-resistant support hanger for a building is characterized by comprising a damping piece 2, a fixing piece 1 connected with the top end of the damping device and used for being connected with a ceiling, a clamping piece 4 used for clamping a pipe fitting, and a connecting rod 3 arranged between the bottom end of the damping device and the top end of the clamping piece;

wherein, the shock attenuation piece include: a shock-absorbing cylinder 21 whose axis is collinear with the axis of the connecting rod; two supporting columns 22, which are correspondingly arranged at the upper end and the lower end of the shock-absorbing cylinder body along the radial direction of the shock-absorbing cylinder body; the pressure-relieving component 23 is positioned in the middle of the interior of the damping cylinder body and is clamped and matched with the side wall of the damping cylinder body; the two U-shaped rods 25 are correspondingly positioned at two ends in the damping cylinder body and are respectively clamped and matched with the supporting columns at the same end; the two extrusion components 24 are correspondingly positioned at two ends in the damping cylinder body, one end of each extrusion component is fixedly connected with the U-shaped rod at the corresponding end, and the other end of each extrusion component is fixedly connected with the corresponding end of the pressure-relieving component; the bottom end of the fixing part 1 penetrates through the top wall of the damping cylinder 21 and is connected with the corresponding U-shaped rod 25, and the top end of the connecting rod 3 penetrates through the bottom wall of the damping cylinder and is connected with the corresponding U-shaped rod.

Preferably, the fixing member may be configured as a connection bolt, one end of which is fixedly connected to the ceiling, and the other end of which is connected to the top end of the shock-absorbing cylinder, and the fixing member belongs to the prior art and is not described in too much.

Preferably, the clamping member may be configured as a support hanger pipe clamp, mainly used for connecting pipes and the like, and since the clamping member belongs to the prior art, it is not described too much.

Preferably, the electromechanical earthquake-resistant support and hanger for the building further comprises a connecting frame 9 arranged at the joint of the fixing member and the damping member and arranged at the joint of the connecting rod and the damping member, so as to further enhance the stability of the whole device.

Preferably, the fixing piece and the connecting piece can be further provided with a limiting bolt 10, so that the whole damping piece can absorb energy and damp in specific amplitude, and the stability of the whole device is further improved.

Furthermore, the two ends of the supporting column penetrate through the side wall of the shock-absorbing cylinder body, and the shock-absorbing piece further comprises cushion pads 26 arranged between the circumferential side surfaces at the two ends of the supporting column and the side wall of the shock-absorbing cylinder body. Further achieve the purpose of buffering, reduce the loss of spare part in the device, and then improve the life of whole device.

Further, the compression assembly includes: the damping cylinder comprises two extrusion plates 241 arranged oppositely and a spring 242 arranged between the two extrusion plates along the axial direction of the damping cylinder, wherein one extrusion plate is fixedly connected with the corresponding U-shaped rod, and the other extrusion plate is matched with the corresponding end part of the pressure-relieving component. Can enough extrude the slow-pressing subassembly effectively, in whole pressurization process, adjust the extrusion force, can pass through the characteristic of spring again for whole device has possessed the function of energy dissipation.

The utility model is particularly characterized in that four through grooves are uniformly arranged at the middle position of the damping cylinder body along the circumferential direction of the damping cylinder body, and the pressure-relieving assembly comprises: the slowly pressing part 231 comprises a slowly pressing barrel with the axis collinear with the axis of the damping barrel body and four hollow clamping parts which are uniformly arranged along the circumferential direction of the slowly pressing barrel and are arranged on the circumferential side surface of the slowly pressing barrel, four through holes which are respectively communicated with the four clamping parts are formed in the side wall of the slowly pressing barrel, air holes are formed in the clamping parts, and the clamping parts and the through grooves are in one-to-one correspondence; the buffer box 232 is hollow and positioned in the pressure relief piece, four side surfaces of the buffer box are respectively clamped and matched with four through holes of the pressure relief piece, and the buffer box is communicated with the corresponding through holes through air guide openings 2321 formed in the side surfaces; the top and bottom surfaces of the buffer box are respectively matched with the corresponding extrusion plates.

Further, the air holes 2311 are formed in the bottom of the clamping portion, and a filter screen 5 matched with the air holes is arranged in the clamping portion.

Further, a flared bell mouth 6 which expands outwards is arranged outside the air guide opening 2321.

Further, the buffer box is further provided with an air guide machine 7 which is located at the air guide opening 2321 and used for accelerating the air flow rate.

The technical features of the present invention which are not described in the above embodiments may be implemented by or using the prior art, and are not described herein again, of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and variations, modifications, additions or substitutions which may be made by those skilled in the art within the spirit and scope of the present invention should also fall within the protection scope of the present invention.

Claims

1. An electromechanical earthquake-resistant support and hanger for buildings is characterized by comprising a damping piece (2), a fixing piece (1) connected with the top end of the damping piece and used for connecting a ceiling, a clamping piece (4) used for clamping a pipe fitting, and a connecting rod (3) arranged between the bottom end of the damping piece and the top end of the clamping piece;

wherein, the shock attenuation piece include: a shock-absorbing cylinder (21) whose axis is collinear with the axis of the connecting rod;

two supporting columns (22) which are correspondingly arranged at the upper end and the lower end of the shock-absorbing cylinder body along the radial direction of the shock-absorbing cylinder body;

the pressure relief assembly (23) is positioned in the middle of the interior of the damping cylinder body and is clamped and matched with the side wall of the damping cylinder body;

the two U-shaped rods (25) are correspondingly positioned at two ends in the damping cylinder body and are respectively clamped and matched with the supporting columns at the same end;

two extrusion components (24) which are correspondingly positioned at two ends in the damping cylinder body, one end of each extrusion component is fixedly connected with the U-shaped rod at the corresponding end, and the other end of each extrusion component is fixedly connected with the corresponding end of the pressure-relieving component;

the bottom end of the fixing piece (1) penetrates through the top wall of the damping cylinder body (21) and is connected with the corresponding U-shaped rod (25), and the top end of the connecting rod (3) penetrates through the bottom wall of the damping cylinder body and is connected with the corresponding U-shaped rod.

2. An electromechanical earthquake-resistant support and hanger for buildings according to claim 1, characterized in that: the shock attenuation barrel lateral wall is run through at support column both ends, the buffer pad (26) between the shock attenuation barrel lateral wall is still including setting up at support column both ends department circumference side with.

3. A building electromechanical earthquake resistant support and hanger as claimed in claim 2, wherein said extrusion assembly comprises: the damping cylinder comprises two extrusion plates (241) which are oppositely arranged and a spring (242) which is arranged between the two extrusion plates along the axial direction of the damping cylinder body, wherein one extrusion plate is fixedly connected with the corresponding U-shaped rod, and the other extrusion plate is matched with the corresponding end part of the pressure-relieving assembly.

4. A building electromechanical anti-seismic support and hanger frame according to claim 3, wherein four through grooves are uniformly arranged at the middle position of the shock absorption cylinder body along the circumferential direction of the shock absorption cylinder body, and the pressure-relieving assembly comprises:

the pressure relieving part (231) comprises a pressure relieving cylinder with the axis collinear with the axis of the damping cylinder body and four hollow clamping parts which are uniformly arranged along the circumferential direction of the pressure relieving cylinder and are arranged on the circumferential side surface of the pressure relieving cylinder, four through holes which are respectively communicated with the four clamping parts are formed in the side wall of the pressure relieving cylinder, air holes are formed in the clamping parts, and the clamping parts and the through grooves are in one-to-one correspondence;

and the buffer box (232) is hollow in the pressure relief piece, four side faces of the buffer box are respectively clamped and matched with the four through holes of the pressure relief piece, and the buffer box is communicated with the corresponding through holes through air guide openings (2321) formed in the side faces.

5. A building electromechanical earthquake-resistant support and hanger as claimed in claim 4, wherein: the air holes (2311) are formed in the bottom of the clamping portion, and a filter screen (5) matched with the air holes is arranged in the clamping portion.

6. A building electromechanical earthquake-resistant support and hanger as claimed in claim 5, wherein: and a flared bell mouth (6) which expands outwards is arranged on the outer side of the air guide opening (2321).

7. A building electromechanical earthquake-resistant support and hanger as claimed in claim 6, wherein: the buffer box is also provided with a wind guide machine (7) which is positioned at the wind guide opening (2321) and used for accelerating the air flow rate.