CN219912200U - Anti-seismic bracket for building equipment pipeline - Google Patents

Abstract

The utility model discloses an anti-seismic bracket for a pipeline of building equipment, which comprises a clamp assembly sleeved on the outer side of the pipeline, wherein a first damping assembly is arranged between the clamp assembly and the pipeline; the main branch pipe is arranged above the clamp assembly and connected with the outer side of the clamp assembly through the second damping assembly, and one end of the main branch pipe, which is far away from the clamp assembly, is connected with the mounting seat. Compared with the prior art, the anti-seismic support for the building equipment pipeline can improve stability, firmness and anti-seismic performance of the anti-seismic support and reduce personnel damage and property loss.

Description

Anti-seismic bracket for building equipment pipeline

Technical Field

The utility model relates to the technical field of building construction, in particular to an anti-seismic bracket for a pipeline of building equipment.

Background

With the rapid development of national economy, urban construction is increasingly stressed, high-rise and super-high-rise buildings are continuously emerging like spring bamboo shoots after raining, building scale is continuously enlarged, meanwhile, pipeline supply areas of building equipment are also increasingly larger, required pipeline of the building equipment are increasingly larger, so that the larger the scale of a single pipeline and a comprehensive pipeline is, the larger the earthquake resistance of the pipeline of the building equipment is, the larger the earthquake resistance of a support and an attached structure is required during an earthquake, the larger the damage and influence are caused under the action of the earthquake, the casualties and facility equipment loss are larger in the earthquake, and the repair cost of the pipeline of the equipment is higher after the earthquake.

The anti-seismic support in the prior art has poor anti-seismic performance, and when an earthquake occurs, the pipeline is easy to damage during the earthquake due to the fact that the pipeline is fixed with a house through the anti-seismic support, and larger personnel damage and property loss are easy to cause.

Therefore, there is a need for an anti-seismic bracket for a building equipment pipeline that can improve stability, robustness and anti-seismic performance of the anti-seismic bracket, and reduce personnel damage and property loss.

Disclosure of Invention

In order to solve the technical problems, the utility model provides the anti-seismic bracket for the pipeline of the building equipment, which can improve the stability, the firmness and the anti-seismic performance of the anti-seismic bracket and reduce the problems of personnel damage and property loss.

The technical scheme provided by the utility model is as follows:

a shock-resistant bracket for a building equipment pipeline, comprising:

the clamp assembly is sleeved on the outer side of the pipeline, and a first damping assembly is arranged between the clamp assembly and the pipeline;

the main branch pipe is arranged above the clamp assembly and connected with the outer side of the clamp assembly through the second damping assembly, and one end of the main branch pipe, which is far away from the clamp assembly, is connected with the mounting seat.

Preferably, the method further comprises:

the auxiliary branch pipes are arranged on two sides of the main branch pipe, one end of each auxiliary branch pipe is hinged with the mounting seat, and one end, away from the mounting seat, of each auxiliary branch pipe is connected with the clamp assembly through the second damping assembly.

Preferably, the first shock absorbing assembly comprises:

an inner sleeve arranged between the pipeline and the clamp assembly, wherein the inner side of the inner sleeve is provided with an arc-shaped surface matched with the pipeline;

the elastic piece is arranged between the inner sleeve and the clamp assembly, the first end of the elastic piece is abutted with the inner sleeve, and the second end of the elastic piece is abutted with the inner wall of the clamp assembly.

Preferably, at least two elastic sheets are arranged, and the elastic sheets are arranged at intervals around the circumference of the inner sleeve.

Preferably, the elastic sheet is in an arc shape, and the first end and the second end are respectively disposed at two ends of the elastic sheet along the width direction of the elastic sheet.

Preferably, the first shock absorbing assembly further comprises:

the first sliding groove is arranged on the outer surface of the inner sleeve and matched with the first end for use;

the second sliding groove is arranged on the inner surface of the clamp assembly and matched with the second end for use.

Preferably, the first shock absorbing assembly further comprises:

the elastic damping blocks are arranged between the inner sleeve and the clamp assembly, and are provided with mounting holes at intervals, so that two sides of the second end of the elastic piece penetrate out respectively.

Preferably, the clip assembly comprises:

the clamp comprises a clamp body, wherein at least two clamp bodies are arranged, connecting pieces are arranged at two ends of the clamp body, and a space for accommodating a pipe fitting is formed between the clamp bodies;

the connecting pieces of the adjacent clamp bodies are connected through locking assemblies.

Preferably, the second shock absorbing assembly comprises:

the connecting rod is hinged with the clamp assembly, a first fixed block and a second fixed block are arranged on the connecting rod, and a first buffer assembly and a second buffer piece are arranged on the connecting rod;

the first fixing block is arranged in the main branch pipe, the first buffer component is arranged between the first fixing block and the end cover of the branch pipe, the second fixing block is arranged on the outer side of the main branch pipe, and the second buffer component is arranged between the end cover of the main branch pipe and the second fixing block.

Preferably, the first buffer assembly includes:

the third fixing block is arranged between the first fixing block and the end cover and fixedly connected with the main branch pipe;

elastic pieces are arranged between the first fixed block and the third fixed block and between the third fixed block and the end cover.

The utility model provides an anti-seismic bracket for a pipeline of building equipment, which is characterized in that a clamp assembly and a first damping assembly are arranged, wherein the clamp assembly is sleeved on the outer side of the pipeline, the pipeline is installed in the clamp assembly, the pipeline is installed and supported through the clamp assembly, the first damping assembly is arranged between the pipeline and the clamp assembly, and when an earthquake occurs, the pipeline is buffered and damped through the first damping assembly when the pipeline follows a house to vibrate. Secondly, still be provided with main branch pipe, second damper and mount pad, wherein, main branch pipe sets up in the top of clamp subassembly, links to each other through second damper between the outside of clamp subassembly and the main branch pipe, and the one end that clamp subassembly was kept away from to main branch pipe links to each other with the mount pad, and the mount pad setting is on construction equipment, through antidetonation leg joint construction equipment and pipeline to cushion the shock attenuation to the earthquake through first damper and second damper. Compared with the prior art, the anti-seismic support for the building equipment pipeline can improve stability, firmness and anti-seismic performance of the anti-seismic support and reduce personnel damage and property loss.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a construction of an anti-seismic bracket for a construction equipment pipeline according to an embodiment of the present utility model;

FIG. 2 is a schematic view of another construction of an anti-seismic bracket for a construction equipment pipeline according to an embodiment of the present utility model;

FIG. 3 is a schematic view of an embodiment of the present utility model in which an elastic sheet is installed between an inner sleeve and a clip body;

FIG. 4 is an enlarged view of a portion of FIG. 1 at A;

fig. 5 is a schematic structural view of a second shock absorbing assembly according to an embodiment of the present utility model.

Reference numerals: 1. a pipeline; 2. a clip assembly; 3. a first shock absorbing assembly; 4. a second shock absorbing assembly; 5. a main branch pipe; 6. a mounting base; 7. a sub-branch pipe; 21. a clamp body; 22. a connecting piece; 23. a locking assembly; 31. an inner sleeve; 32. an elastic sheet; 33. a first chute; 34. a second chute; 35. an elastic damping block; 41. a connecting rod; 42. a first fixed block; 43. a second fixed block; 44. a first cushioning assembly; 45. a second buffer member; 46. an end cap; 441. a third fixed block; 442. an elastic member.

Detailed Description

In order to enable those skilled in the art to better understand the technical solutions of the present utility model, the technical solutions of the embodiments of the present utility model will be clearly and completely described below, and it is obvious that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are merely for convenience in describing and simplifying the description based on the orientation or positional relationship shown in the drawings, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus are not to be construed as limiting the utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" or "a number" means two or more, unless specifically defined otherwise.

It should be understood that the structures, proportions, sizes, etc. shown in the drawings are for illustration purposes only and should not be construed as limiting the utility model to the extent that it can be practiced, since modifications, changes in the proportions, or adjustments of the sizes, which are otherwise, used in the practice of the utility model, are included in the spirit and scope of the utility model which is otherwise, without departing from the spirit or scope thereof.

The embodiment of the utility model is written in a progressive manner.

As shown in fig. 1 to 5, an embodiment of the present utility model provides an anti-seismic bracket for a construction equipment pipeline, comprising: the clamp assembly 2 is sleeved outside the pipeline 1, and a first damping assembly 3 is arranged between the clamp assembly 2 and the pipeline 1; the main branch pipe 5 is arranged above the clamp assembly 2 and connected with the outer side of the clamp assembly 2 through the second damping assembly 4, and one end, away from the clamp assembly 2, of the main branch pipe 5 is connected with the mounting seat 6.

The anti-seismic support in the prior art has poor anti-seismic performance, and when an earthquake occurs, the pipeline is easy to damage during the earthquake due to the fact that the pipeline is fixed with a house through the anti-seismic support, and larger personnel damage and property loss are easy to cause.

According to the anti-seismic bracket for the building equipment pipeline, firstly, the clamp assembly 2 and the first damping assembly 3 are arranged, wherein the clamp assembly 2 is sleeved on the outer side of the pipeline 1, the pipeline 1 is installed in the clamp assembly 2, the pipeline 1 is installed and supported through the clamp assembly 2, the first damping assembly 3 is arranged between the pipeline 1 and the clamp assembly 2, and when an earthquake occurs, the pipeline 1 is buffered through the first damping assembly 3 when following a house to vibrate. Secondly, still be provided with main branch pipe 5, second damper 4 and mount pad 6, wherein, main branch pipe 5 sets up in the top of clamp subassembly 2, links to each other through second damper 4 between the outside of clamp subassembly 2 and the main branch pipe 5, and the one end that clamp subassembly 2 was kept away from to main branch pipe 5 links to each other with mount pad 6, and mount pad 6 sets up on the construction equipment, connects construction equipment and pipeline 1 through antidetonation leg joint to cushion the vibrations of earthquake through first damper 3 and second damper 4. Compared with the prior art, the anti-seismic support for the building equipment pipeline can improve stability, firmness and anti-seismic performance of the anti-seismic support and reduce personnel damage and property loss.

Further, as one of the embodiments, the first damper assemblies 3 in the embodiment of the present utility model are provided with at least two groups, and the first damper assemblies are disposed at uniform circumferential intervals around the pipeline. Through setting up two at least groups of first damper, at the in-process of earthquake, whether the seismic effort that the pipeline received is pulling force or pressure, all can cushion through first damper.

Still further, the anti-seismic bracket for a pipeline of a building device according to the embodiment of the present utility model further includes two sub-branch pipes 7, wherein the sub-branch pipes 7 are respectively provided at two sides of the main branch pipe 5, one end of the sub-branch pipe 7 is hinged with the mounting seat 6, and one end of the sub-branch pipe 7, which is far from the mounting seat 6, is connected with the clamp assembly 2 through the second damping assembly 4. Owing to be provided with main branch pipe 5 and auxiliary branch pipe 7, link to each other main branch pipe 5 and auxiliary branch pipe 7 with shock-absorbing device's mount pad 6, be a triangular structure between main branch pipe 5 and the auxiliary branch pipe 7, utilize triangular structure's stability for it is fixed more stable to antidetonation support, and link to each other through second damper 4 between main branch pipe 5 and auxiliary branch pipe 7 and the clamp subassembly 2, when taking place the earthquake, cushion through second damper 4, can improve antidetonation support's stability, fastness and antidetonation support's antidetonation performance, reduce personnel damage and property damage.

Further, as one of the embodiments of the present utility model, the main branch pipe 5 is disposed along the vertical direction, the auxiliary branch pipe 7 is disposed at two sides of the main branch pipe 5, the auxiliary branch pipe 7 is disposed obliquely, the buffering force of the second damping component 4 disposed on the auxiliary branch pipe 7 can be decomposed into a first buffering force along the axis direction of the pipeline 1 and a second buffering force perpendicular to the axis direction of the pipeline 1, and the direction of the second buffering force is perpendicular to the extending direction of the main branch pipe 5, so that the pipeline 1 can buffer vibration in three directions under the action of the main branch pipe 5 and the auxiliary branch pipe, and stability, firmness and shock resistance of the shock-resistant bracket are further improved.

Further, as a specific implementation manner, the secondary branch pipe 7 and the mounting seat 6 in the embodiment of the utility model are hinged.

Further, as one of the embodiments, the first shock absorbing assembly 3 of the present utility model includes an inner sleeve 31 and an elastic piece 32, wherein the inner sleeve 31 is disposed between the pipeline 1 and the clamp assembly 2, an arc surface adapted to the pipeline 1 is disposed on the inner side of the inner sleeve 31, the elastic piece 32 is disposed between the inner sleeve 31 and the clamp assembly 2, a first end of the elastic piece 32 abuts against the inner sleeve 31, and a second end of the elastic piece 32 abuts against an inner wall of the clamp assembly 2. Due to the arrangement of the first damping component 3, when an earthquake occurs, the vibration of the pipeline 1 is relieved through the deformation of the elastic sheet 32, and the stability, the firmness and the shock resistance of the shock-resistant bracket are further improved.

In the above structure, as one embodiment, at least two elastic pieces 32 are provided in the embodiment of the present utility model, the elastic pieces 32 are disposed around the circumference of the pipeline 1 at intervals, the inner sleeve 31 is sleeved on the outer side of the pipeline 1, the clip assembly 2 is sleeved on the outer side of the inner sleeve 31, at least two elastic members 442 are disposed between the clip assembly 2 and the inner sleeve 31, and the elastic members 442 are disposed around the circumference of the pipeline 1 at intervals. In this way, the deformation of the pipeline 1 in all directions can be slowed down.

In the above structure, as one of the embodiments of the present utility model, the elastic piece 32 is specifically arc-shaped, the first end and the second end of the elastic piece 32 are respectively disposed at two sides of the width direction of the elastic piece 32, the elastic piece 32 is sleeved on the outer side of the inner sleeve 31, the first end of the elastic piece 32 is abutted with the outer wall of the inner sleeve 31, the second end of the elastic piece 32 is abutted with the inner wall of the clip assembly 2, the first end and the second end are respectively disposed at two sides of the elastic piece 32 along the width direction, when the pipeline 1 is impacted by an earthquake, the elastic piece 32 deforms along the length direction under the actions of the inner sleeve 31 and the clip assembly 2, and the impact of the earthquake is alleviated.

In the above structure, as one embodiment, the first shock absorbing assembly 3 in the embodiment of the present utility model further includes the first sliding groove 33 and the second sliding groove 34, where the first sliding groove 33 is disposed on the outer surface of the inner sleeve 31, the first sliding groove 33 is matched with the first end of the elastic piece 32, the second sliding groove 34 is disposed on the inner surface of the clip assembly 2, and the second sliding groove 34 is matched with the second end of the elastic piece 32, when the elastic piece 32 deforms under the action of external force, the first end of the elastic piece 32 slides in the first sliding groove 33, the second end of the elastic piece 32 slides in the second sliding groove 34, the direction of movement of the elastic piece 32 is restrained by the first sliding groove 33, and the direction of deformation of the elastic piece 32 is restrained by the second sliding groove 34.

In the above structure, in order to further improve the damping effect of the first damping component 3, as one embodiment, the first damping component 3 in the embodiment of the present utility model further includes an elastic damping block 35, where the elastic damping block 35 is disposed between the inner sleeve 31 and the clip component 2, mounting holes are disposed on the elastic damping block 35 at intervals, and two sides of the second end of the elastic sheet 32 respectively penetrate out of the mounting holes, and due to the provision of the elastic damping block 35, the impact effect of an earthquake is converted into deformation of the elastic sheet 32 and deformation of the elastic damping block 35, so that the impact effect of the earthquake is further slowed down.

In the above structure, as one embodiment, the clip assembly 2 in the embodiment of the present utility model includes at least two clip bodies 21, two ends of each clip body 21 are provided with the connecting pieces 22, and a receiving space for accommodating the pipe and the first damper assembly 3 is formed between the clip bodies 21, and the connecting pieces 22 of adjacent clip bodies 21 are connected by the locking assembly 23. Through setting up two at least clamp bodies 21, fix through connecting piece 22 between the adjacent clamp body 21, be convenient for install fixedly.

Furthermore, the number of the inner sleeves 31 in the embodiment of the utility model is one-to-one corresponding to the number of the clamp bodies 21, the inner sleeves 31 are sleeved on the outer sides of the pipelines 1, the clamp bodies 21 are sleeved on the outer sides of the inner sleeves 31, the connecting pieces 22 on the adjacent clamp bodies 21 are fixed through the locking assemblies 23, the elastic pieces 32 are arranged between the inner sleeves 31 and the clamp bodies 21, and under the action of the elastic pieces 32, the inner sleeves 31 are contacted with the outer surfaces of the pipelines 1, so that the pipelines 1 can be more conveniently installed and fixed.

More specifically, as one of the embodiments, two clamp bodies 21 are provided, a sleeve structure is formed between a first clamp and a second clamp, two ends of the first clamp are respectively provided with a first connecting piece, two ends of the second clamp are respectively provided with a second connecting piece, and the first connecting pieces and the second connecting pieces are connected through a locking assembly 23.

Furthermore, in the embodiment of the utility model, the first connecting piece and the second connecting piece are fastened and connected through bolts, when the anti-seismic bracket is installed, a worker installs the pipeline 1 in the inner sleeve 31, the elastic piece 32 is installed at the outer side of the inner sleeve 31, the clamp assembly 2 is installed at the outer side of the elastic piece 32, and the first clamp and the second clamp are fixedly connected through bolts, so that the inner sleeve 31 can firmly clamp the pipeline 1.

In the above structure, as one of the embodiments, the second damper assembly 4 of the present utility model includes the connecting rod 41, the connecting rod 41 is provided with the first fixing block 42 and the second fixing block 43, one end of the connecting rod 41 is hinged with the outer side of the clamp assembly 2, the connecting rod 41 is provided with the first damper assembly 44 and the second damper 45, wherein the first fixing block 42 is slidably disposed in the main branch 5, the first damper assembly 44 is disposed between the first fixing block 42 and the end cover 46 of the main branch 5, when the connecting rod 41 receives an external tensile force, the first fixing block 42 moves in a direction approaching the end cover 46, the first damper assembly 44 is compressed, the tensile force is converted into a compression deformation of the first damper assembly 44, the influence of the tensile force on the pipeline 1 is reduced, the second fixing block 43 is disposed outside the main branch 5, the second fixing block 43 is disposed near one end of the connecting rod 41 near the clamp assembly 2, the second damper 45 is disposed between the second fixing block 43 and the end cover 46, and when the square connecting rod 41 receives an external compressive force, the first fixing block 42 and the second fixing block 43 move in a direction approaching the end cover 46, the second damper assembly 45 is far from the direction of the pipeline 1, and the compression deformation is reduced.

Further, the connecting rod 41 and the first fixing block 42 and the connecting rod 41 and the second fixing block 43 are fixedly connected through threads in the embodiment of the utility model. The first fixed block 42 slides in the axial direction in the main branch pipe 5 by the link 41.

In the above-mentioned structure, as one of the embodiments, the first buffer assembly 44 according to the embodiment of the present utility model includes the third fixing block 441 and the elastic member 442, wherein the third fixing block 441 is disposed between the first fixing block 42 and the end cover 46, and the elastic member 442 is disposed between the first fixing block 42 and the third fixing block 441, and the influence of the pulling force on the pipeline 1 can be better reduced by disposing two sets of the elastic members 442 between the third fixing block 441 and the end cover 46.

In the above-mentioned structure, as one of the embodiments, the elastic member 442 is specifically a spring, and the spring is movably sleeved on the outer side of the connecting rod 41.

In the above-described structure, the third fixing block 441 in the embodiment of the present utility model is fixedly provided in the main branch pipe 5, and the end cap 46 is fixedly provided on the main branch pipe 5. Further, for ease of installation, the third fixing block 441 is detachably connected to the end cover 46.

Further, in the embodiment of the present utility model, the second damper assembly 4 is disposed between the main branch pipe 5 and the clamp assembly 2, and between the auxiliary branch pipe 7 and the clamp assembly 2, and the connection between the auxiliary branch pipe 7 and the second damper assembly 4 is the same as the connection between the main branch pipe and the second damper assembly 4, which will not be described herein.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. An anti-seismic bracket for a building equipment pipeline, comprising:

the clamp assembly (2) is sleeved on the outer side of the pipeline (1), and a first damping assembly (3) is arranged between the clamp assembly (2) and the pipeline (1);

the main branch pipe (5) is arranged above the clamp assembly (2) and connected with the outer side of the clamp assembly (2) through the second damping assembly (4), and one end, away from the clamp assembly (2), of the main branch pipe (5) is connected with the mounting seat (6).

2. An anti-seismic bracket for a building equipment pipeline according to claim 1, wherein,

further comprises:

the auxiliary branch pipes (7) are arranged on two sides of the main branch pipe (5), one end of each auxiliary branch pipe (7) is hinged to the corresponding mounting seat (6), and one end, away from the corresponding mounting seat (6), of each auxiliary branch pipe (7) is connected with the corresponding clamp assembly (2) through the corresponding second damping assembly (4).

3. An anti-seismic bracket for a building equipment pipeline according to claim 2, wherein,

the first shock-absorbing assembly (3) comprises:

an inner sleeve (31) arranged between the pipeline (1) and the clamp assembly (2), wherein the inner side of the inner sleeve (31) is provided with an arc-shaped surface matched with the pipeline (1);

the elastic piece (32) is arranged between the inner sleeve (31) and the clamp assembly (2), the first end of the elastic piece (32) is abutted with the inner sleeve (31), and the second end of the elastic piece (32) is abutted with the inner wall of the clamp assembly (2).

4. An anti-seismic bracket for a building equipment pipeline according to claim 3, wherein,

at least two elastic sheets (32) are arranged, and the elastic sheets (32) are arranged at intervals around the circumference of the inner sleeve (31).

5. An anti-seismic bracket for a building equipment pipeline according to claim 4, wherein,

the elastic sheet (32) is in an arc shape, and the first end and the second end are respectively arranged at two ends of the elastic sheet (32) along the width direction of the elastic sheet (32).

6. An anti-seismic bracket for a building equipment pipeline according to claim 4, wherein,

the first shock-absorbing assembly (3) further comprises:

the first sliding groove (33) is arranged on the outer surface of the inner sleeve (31) and matched with the first end for use;

and the second sliding groove (34) is arranged on the inner surface of the clamp assembly (2) and matched with the second end for use.

7. An anti-seismic bracket for a building equipment pipeline according to claim 6, wherein,

the first shock-absorbing assembly (3) further comprises:

elastic damping blocks (35) are arranged between the inner sleeve (31) and the clamp assembly (2), and mounting holes are formed in the elastic damping blocks (35) at intervals and respectively used for enabling two sides of the second end of the elastic sheet (32) to penetrate out.

8. An anti-seismic bracket for a construction equipment line according to any one of claims 1 to 7, characterized in that,

the clamp assembly (2) comprises:

the clamp comprises a clamp body (21), wherein at least two clamp bodies (21) are arranged, connecting pieces (22) are arranged at two ends of the clamp body (21), and a space for accommodating a pipe fitting is formed between the clamp bodies (21);

the connecting pieces (22) of the adjacent clamp bodies (21) are connected through locking assemblies (23).

9. An anti-seismic bracket for a building equipment pipeline according to claim 8, wherein,

the second shock-absorbing assembly (4) comprises:

the connecting rod (41) is hinged with the clamp assembly (2), a first fixed block (42) and a second fixed block (43) are arranged on the connecting rod (41), and a first buffer assembly (44) and a second buffer piece (45) are arranged on the connecting rod (41);

wherein, first fixed block (42) set up in main branch pipe (5), just first buffer assembly (44) set up first fixed block (42) with between end cover (46) of main branch pipe (5), second fixed block (43) set up in the outside of main branch pipe (5), second buffer (45) set up end cover (46) with between second fixed block (43).

10. An anti-seismic bracket for a building equipment pipeline according to claim 9, wherein,

the first cushioning assembly (44) includes:

the third fixed block (441) is arranged between the first fixed block (42) and the end cover (46) and fixedly connected with the main branch pipe (5);

elastic pieces (442) are arranged between the first fixed block (42) and the third fixed block (441) and between the third fixed block (441) and the end cover (46).