CN216078624U

CN216078624U - Multi-pipeline-mounted anti-seismic support

Info

Publication number: CN216078624U
Application number: CN202122428175.0U
Authority: CN
Inventors: 陈建新; 王恒; 王海锋; 高�浩; 王权
Original assignee: Jiangsu Kafsman Electromechanical Technology Co ltd
Current assignee: Jiangsu Kafsman Electromechanical Technology Co ltd
Priority date: 2021-10-09
Filing date: 2021-10-09
Publication date: 2022-03-18
Anticipated expiration: 2031-10-09

Abstract

The utility model discloses a multi-pipeline-mounted anti-seismic bracket, which is arranged on the outer side surface of a wall body; the upper end and the lower end of the C-shaped channel steel are respectively provided with an anti-seismic connecting piece, the lower end of the C-shaped channel steel is connected with the bracket through the anti-seismic connecting piece, and the upper end of the C-shaped channel steel is connected with the bracket through the anti-seismic connecting piece; the method comprises the following steps: the bidirectional threaded rod is arranged below the bracket, the outer wall of the bidirectional threaded rod is connected with three groups of two second sliding blocks, and three groups of symmetrical clamping sleeves are fixed on the upper side of each second sliding block; a sliding groove is formed in the lower side of the support, and the lower part of the second sliding block is clamped in the sliding groove; the lower end of the conical gear set is sleeved at two ends of the bidirectional threaded rod; the lower end of the gear rod penetrates through the conical gear set. This antidetonation support of multi-channel installation is provided with two-way threaded rod, second slider, can carry out the centre gripping to the multi-channel simultaneously, can carry out the centre gripping to the pipeline of different diameters simultaneously, and the briquetting can be fixed the pipeline upside.

Description

Multi-pipeline-mounted anti-seismic support

Technical Field

The utility model relates to the technical field of pipeline installation, in particular to a multi-pipeline installed anti-seismic support.

Background

Pipeline installation indicates that to carry out scientific management and setting to the pipeline at the building in-process, pipeline installation is whether correct, directly influences the safety that people used in the life, pipeline installation used before is the gravity support, at present because people are more and more high to the requirement of safety, a lot of places all will use the antidetonation support to pipeline installation, the antidetonation support can play fine guard action to most vibrations in the life, in present antidetonation support use, some problems and not enough in addition, as follows:

the conventional multi-pipeline mounting bracket adopts a hoop structure, when pipelines are fixed, one hoop needs to be fixed by screws, time and labor are wasted, the device cannot be fixed at the same time, the hoop structure can only fix the pipelines with single diameter, the pipelines with different diameters cannot be clamped and fixed, and the use is inconvenient;

therefore, the multi-pipeline installation anti-seismic support can well solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an anti-seismic support for multi-pipeline installation, and aims to solve the problems that the conventional multi-pipeline installation support in the market provided by the background art adopts a hoop structure, when pipelines are fixed, one hoop needs to be screwed, time and labor are wasted, devices cannot be fixed simultaneously, the hoop structure can only be used for fixing the pipelines with a single diameter, the pipelines with different diameters cannot be clamped and fixed, and the use is inconvenient.

In order to achieve the purpose, the utility model provides the following technical scheme: a multi-pipeline installed anti-seismic bracket is arranged on the outer side surface of a wall body;

the upper end and the lower end of the C-shaped channel steel are respectively provided with an anti-seismic connecting piece, the lower end of the C-shaped channel steel is connected with the bracket through the anti-seismic connecting piece, and the upper end of the C-shaped channel steel is connected with the bracket through the anti-seismic connecting piece;

the method comprises the following steps:

the bidirectional threaded rod is arranged below the bracket, the outer wall of the bidirectional threaded rod is connected with three groups of two second sliding blocks, and three groups of symmetrical clamping sleeves are fixed on the upper side of each second sliding block; a sliding groove is formed in the lower side of the support, and the lower part of the second sliding block is clamped in the sliding groove;

the lower end of the conical gear set is sleeved at two ends of the bidirectional threaded rod;

the lower end of the gear rod penetrates through the conical gear set, the upper end of the gear rod is in threaded connection with two ends of the pressure rod, two ends of the pressure rod are installed on two sides of the support, and the lower side of the pressure rod is connected with the pressurizing mechanism; the pressurizing mechanism comprises a first sliding block, a spring and a pressing block;

the upper end of the first sliding block is mounted on the lower side of the pressing rod, the lower side of the first sliding block is connected with a spring, the spring is arranged in a cavity at the lower end of the first sliding block, the outer wall of the first sliding block is connected with a sleeve, and the lower end of the sleeve is connected with a pressing block;

preferably, the bidirectional threaded rod is in threaded connection with the second sliding block, and the thread directions of the second sliding blocks of two adjacent blocks are different.

Through above-mentioned structure, the second slider removes in opposite directions to can be simultaneously to the pipeline centre gripping.

Preferably, the lower sides of the second sliding blocks move in the sliding grooves, and the moving directions of the clamping sleeves at the upper ends of two adjacent second sliding blocks are opposite.

Through the structure, the clamping sleeve can move simultaneously, and the pipeline can be clamped conveniently.

Preferably, the bidirectional threaded rod drives the bevel gear set to rotate, and the rotation directions of the bidirectional threaded rod and the gear rod are different.

Through the structure, the pressing rod can move up and down conveniently, and the upper side of the pipeline can be extruded and fixed conveniently.

Preferably, the pressure rod and the pressurizing mechanism move up and down simultaneously, and the pressing block is in contact with the pipeline.

Through the structure, the pressing block can clamp and fix the pipeline conveniently.

Preferably, the sleeve is in sliding contact with the first slider.

Through above-mentioned structure, when the briquetting contacted the pipeline, can play the cushioning effect to the pipeline.

Compared with the prior art, the utility model has the beneficial effects that: the multi-channel mounted seismic support;

(1) the bidirectional threaded rod and the second sliding block are arranged, and when the bidirectional threaded rod rotates clockwise, the jacket on the second sliding block is driven to clamp the pipeline, so that one hoop is prevented from being fixed by screws, and the pipeline can be clamped and fixed at the same time;

(2) the clamping sleeve is arranged, when the bidirectional threaded rod rotates, the clamping sleeve can clamp pipelines with different diameters, and the phenomenon that the hoop can only fix the pipeline with the fixed diameter is avoided;

(3) be provided with bevel gear group, gear lever and depression bar, when two-way threaded rod rotated, drive gear lever through bevel gear group and rotate, the depression bar drives the briquetting and carries out upside extrusion fixed to the pipeline is fixed more stable.

Drawings

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

FIG. 2 is a schematic front view of the present invention;

FIG. 3 is a schematic view of the pressing mechanism according to the present invention;

FIG. 4 is an enlarged view of the structure at A in FIG. 1 according to the present invention;

FIG. 5 is an enlarged view of the structure at B in FIG. 1 according to the present invention.

In the figure: 1. a support; 2. c-shaped channel steel; 3. a bidirectional threaded rod; 4. a pressure lever; 5. a bevel gear set; 6. a jacket; 7. a pressurizing mechanism; 7.1, a first slide block; 7.2, a spring; 7.3, briquetting; 7.4, a sleeve; 8. a chute; 9. a second slider; 10. an anti-seismic connector; 11. a fixed block; 12. a gear lever.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a multi-pipeline installed anti-seismic bracket comprises a bracket 1, a support and a bracket body, wherein the bracket 1 is installed on the outer side surface of a wall body; the upper end and the lower end of the C-shaped channel steel 2 are both provided with anti-seismic connecting pieces 10, the lower end of the C-shaped channel steel 2 is connected with the bracket 1 through the anti-seismic connecting pieces 10, and the upper end of the C-shaped channel steel 2 is connected with the bracket 1 through the anti-seismic connecting pieces 10; the method comprises the following steps: the bidirectional threaded rod 3 is arranged below the bracket 1, the outer wall of the bidirectional threaded rod 3 is connected with three groups of two second sliding blocks 9, each group comprises two second sliding blocks, and the upper side of each second sliding block 9 is fixed with a jacket 6; a sliding groove 8 is formed in the lower side of the support 1, the lower side of each second sliding block 9 is clamped in the sliding groove 8, the two-way threaded rod 3 is in threaded connection with the second sliding blocks 9, the thread directions of the two adjacent second sliding blocks 9 are different, the lower sides of the second sliding blocks 9 move in the sliding groove 8, the moving directions of the clamping sleeves 6 at the upper ends of the two adjacent second sliding blocks 9 are opposite, the support 1 and the anti-seismic connecting piece 10 are fixed on the outer side of the wall through screws, then pipelines with the same diameter are placed on the fixing block 11, the handle of the two-way threaded rod 3 is manually rotated clockwise, the two adjacent second sliding blocks 9 simultaneously extrude the pipelines towards the inner side, meanwhile, the lower ends of the second sliding blocks 9 move towards the inner side, and the clamping sleeves 6 clamp and fix the pipelines;

the lower end of the conical gear set 5 is sleeved at two ends of the bidirectional threaded rod 3; the lower end of the gear rod 12 penetrates through the bevel gear set 5, the upper end of the gear rod 12 is in threaded connection with two ends of the pressure rod 4, two ends of the pressure rod 4 are installed on two sides of the support 1, and the lower side of the pressure rod 4 is connected with the pressurizing mechanism 7; the pressurizing mechanism 7 comprises a first slide block 7.1, a spring 7.2 and a pressing block 7.3, the bidirectional threaded rod 3 drives the bevel gear set 5 to rotate, the rotation direction of the bidirectional threaded rod 3 is different from that of the gear rod 12, the first slide block 7.1 is provided with an upper end arranged at the lower side of the pressing rod 4, the lower side of the first slide block 7.1 is connected with the spring 7.2, the spring 7.2 is arranged in a cavity at the lower end of the first slide block 7.1, the outer wall of the first slide block 7.1 is connected with a sleeve 7.4, the lower end of the sleeve 7.4 is connected with the pressing block 7.3, the pressing rod 4 and the pressurizing mechanism 7 move up and down simultaneously, the pressing block 7.3 is in contact with the pipeline, the sleeve 7.4 is in sliding contact with the first slide block 7.1, when the bidirectional threaded rod 3 drives the second slide block 9 to rotate, the bevel gear set 5 at two ends of the bidirectional threaded rod 3 simultaneously drives the gear rod 12 to rotate, the pressing rod 4 drives the pressing block 7.3 to move down, when the pressing block 7.3 is in contact with the outer side of the pipeline, the pressing block 7.3 slides up, therefore, the upper part of the pipeline can be fixed, and the pipeline is clamped completely.

The working principle is as follows: when the multi-pipeline-mounted anti-seismic support is used, firstly, the support 1 and the anti-seismic connecting piece 10 are fixed on the outer side of a wall body through screws, then pipelines with the same diameter are placed on the fixing block 11, then the handle of the bidirectional threaded rod 3 is manually rotated clockwise, two adjacent second sliding blocks 9 simultaneously extrude the pipelines towards the inner side, meanwhile, the lower ends of the second sliding blocks 9 move towards the inner side, and the clamping sleeves 6 clamp and fix the pipelines;

when the two-way threaded rod 3 drives the second slider 9 to rotate, the bevel gear sets 5 at two ends of the two-way threaded rod 3 drive the gear rod 12 to rotate, the pressing rod 4 drives the pressing block 7.3 to move downwards, when the pressing block 7.3 contacts the outer side of the pipeline, the sleeve 7.4 slides upwards, so that the upper part of the pipeline can be fixed, the pipeline is clamped, when the pipeline needs to be loosened, the two-way threaded rod 3 rotates anticlockwise, so that the second slider 9 moves outwards, the jacket 6 loosens the pipeline, meanwhile, the bevel gear sets 5 drive the pressing rod 4 to move upwards, the pressing block 7.3 loosens the pipeline, so that the pipeline can be taken out, and the pipeline is taken out after the operation is finished.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the utility model can be made, and equivalents and modifications of some features of the utility model can be made without departing from the spirit and scope of the utility model.

Claims

1. An anti-seismic support frame for multi-pipeline installation,

the bracket (1) is arranged on the outer side surface of the wall body;

the anti-seismic support is characterized by comprising C-shaped channel steel (2), anti-seismic connecting pieces (10) are mounted at the upper end and the lower end of the C-shaped channel steel (2), the lower end of the C-shaped channel steel (2) is connected with a support (1) through the anti-seismic connecting pieces (10), and the upper end of the C-shaped channel steel (2) is connected with the support (1) through the anti-seismic connecting pieces (10);

it is characterized by comprising:

the bidirectional threaded rod (3) is arranged below the bracket (1), the outer wall of the bidirectional threaded rod (3) is connected with three groups of second sliding blocks (9), each group comprises two sliding blocks, and a jacket (6) is fixed on the upper side of each second sliding block (9); a sliding groove (8) is formed in the lower side of the support (1), and the lower part of the second sliding block (9) is clamped in the sliding groove (8);

the lower end of the conical gear set (5) is sleeved at two ends of the bidirectional threaded rod (3);

the lower end of the gear rod (12) penetrates through the conical gear set (5), the upper end of the gear rod (12) is in threaded connection with two ends of the pressing rod (4), two ends of the pressing rod (4) are installed on two sides of the support (1), and the lower side of the pressing rod (4) is connected with the pressurizing mechanism (7); the pressurizing mechanism (7) comprises a first sliding block (7.1), a spring (7.2) and a pressing block (7.3);

the lower side at depression bar (4) is installed to first slider (7.1), upper end, the downside of first slider (7.1) is connected with spring (7.2), spring (7.2) set up in the cavity of first slider (7.1) lower extreme, the outer wall connection of first slider (7.1) has sleeve pipe (7.4), the lower extreme of sleeve pipe (7.4) is connected with briquetting (7.3).

2. A multi-pipe-installed seismic brace according to claim 1, wherein: the two-way threaded rod (3) is in threaded connection with the second sliding block (9), and the thread directions of the second sliding blocks (9) of two adjacent blocks are different.

3. A multi-pipe-installed seismic brace according to claim 1, wherein: the lower sides of the second sliding blocks (9) move in the sliding grooves (8), and the moving directions of the clamping sleeves (6) at the upper ends of the two adjacent second sliding blocks (9) are opposite.

4. A multi-pipe-installed seismic brace according to claim 1, wherein: the bidirectional threaded rod (3) drives the bevel gear set (5) to rotate, and the rotation directions of the bidirectional threaded rod (3) and the gear rod (12) are different.

5. A multi-pipe-installed seismic brace according to claim 1, wherein: the pressure lever (4) and the pressurizing mechanism (7) move up and down simultaneously, and the pressing block (7.3) is in contact with the pipeline.

6. A multi-pipe-installed seismic brace according to claim 1, wherein: the sleeve (7.4) is in sliding contact with the first slider (7.1).