CN221257959U - Angle self-adaptive anti-seismic bracket - Google Patents

Abstract

The utility model belongs to the technical field of anti-seismic brackets, and particularly provides an angle-adaptive anti-seismic bracket which comprises a bracket body and a boom assembly, wherein a pipe hoop assembly is arranged on the bracket body; one end of the boom assembly is rotationally connected with the bracket body; the support body with jib subassembly junction is equipped with the control the jib subassembly rotation angle's locking mechanism. The angle-adaptive anti-seismic bracket provided by the utility model can adjust the angle between the support and the suspender according to the pipeline installation angle requirement, and can meet the pipeline installation under different inclination requirements. In addition, the anti-seismic bracket provided by the utility model can be further designed in a refinement manner through the locking mechanism, the telescopic boom assembly, the rotating seat and the like, is suitable for different pipeline installation directions, provides buffer support for the pipeline, and greatly provides adaptability and safety for use of the device.

Description

Angle self-adaptive anti-seismic bracket

Technical Field

The utility model belongs to the technical field of anti-seismic supports, and particularly relates to an angle-adaptive anti-seismic support.

Background

In the engineering construction process, pipeline laying is often required for conveying tap water, fire water, natural gas and the like. If the pipelines are directly fixed on the wall, falling easily occurs when an earthquake occurs, so that safety accidents are caused, and therefore, the support body for fixing the pipelines needs to have better shock resistance.

The anti-seismic bracket needs to be fixed on a wall body first and then the pipeline is fixed on the bracket body, but the existing anti-seismic bracket structure is mainly used for horizontal pipeline installation, in some scenes with height differences, the pipeline is provided with inclined parts so as to adapt to the height differences at two ends, at the moment, the anti-seismic bracket cannot effectively support the inclined pipeline, the adaptability is low, and the pipeline installation safety is poor.

Disclosure of utility model

The utility model aims to solve the problems that an anti-seismic bracket in the prior art cannot effectively support an inclined pipeline, the adaptability is low, and the pipeline installation safety is poor.

The utility model provides an angle self-adaptive anti-seismic bracket, which comprises a bracket body and a boom assembly, wherein the bracket body is provided with a pipe hoop assembly; one end of the boom assembly is rotationally connected with the bracket body; the support body with jib subassembly junction is equipped with the control the jib subassembly rotation angle's locking mechanism.

Specifically, the bracket body is provided with a rotating shaft; one end of the boom assembly is provided with a rotary supporting frame; one end of the rotating shaft is connected with the support body, and the other end of the rotating shaft penetrates through the rotating support frame and is connected with the rotating support frame in a rotating mode.

Specifically, the locking mechanism comprises a locking sleeve and a positioning tooth holder; the locking sleeve is sleeved on the rotating shaft in a sliding manner and is positioned at one side of the rotating support frame, which is away from the support body; the positioning tooth seat is fixed on one side of the rotary support frame facing the locking sleeve; and the locking sleeve and the positioning tooth seat are respectively provided with clamping teeth which are mutually clamped.

Specifically, a baffle is arranged at one end of the rotating shaft far away from the bracket body; the locking mechanism further comprises a compression spring sleeved outside the rotating shaft; one end of the compression spring is connected with the baffle plate, and the other end of the compression spring is connected with the locking sleeve.

Specifically, the boom assembly comprises a telescopic rod and a fixed plate rotatably arranged at one end of the telescopic rod; one end of the telescopic rod, which is far away from the fixed plate, is rotationally connected with the bracket body.

Specifically, the telescopic rod comprises an outer sleeve rod, an inner lining rod and an adjusting bolt; the fixed plate is rotatably arranged at the top of the outer sleeve rod; one end of the lining rod is slidably arranged in the outer sleeve rod, and the other end of the lining rod extends out of the outer sleeve rod and is rotationally connected with the bracket body; the outer sleeve rod is provided with an adjusting hole matched with the adjusting bolt; one end of the adjusting bolt penetrates through the adjusting hole to be connected with the lining rod.

Specifically, a support plate is arranged in the bracket body; the support plate is movably connected with the bracket body through a guide bolt; the pipe clamp assembly is mounted on the support plate.

Specifically, a buffer pad is arranged between the support plate and the support body.

Specifically, a rotating seat is arranged on the supporting plate; the pipe hoop component is installed on the rotating seat.

Specifically, the angle-adaptive anti-seismic bracket comprises two groups of suspender components; the two groups of boom components are symmetrically connected to the two sides of the bracket body.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

1. The angle-adaptive anti-seismic bracket provided by the utility model can adjust the angle between the support and the suspender according to the pipeline installation angle requirement, so that the inclined installation of the pipeline is satisfied. In addition, through locking sleeve, location toothholder and compression spring constitution's locking mechanism setting, stir at the locking sleeve and leave the location toothholder, can adjust the support body and produce every single move rotation, adaptation pipeline supporting angle, and the back loose locking sleeve of unblanking, with the location toothholder card die under compression spring's promotion, thereby make the rotation of support body receive the restriction of locking sleeve, can provide buffer elasticity for the every single move change of support body with the help of compression spring this moment, and then for the pipeline improves effectual shock protection, great adaptability and the security that provide the device to use.

2. The boom component of the angle-adaptive anti-seismic bracket provided by the utility model can be accurately installed with a wall surface according to the requirement, the installation direction of the boom component is adjusted by utilizing the rotation of the fixed plate and the outer sleeve rod, and the telescopic lengths of the outer sleeve rod and the inner lining rod are adjusted so as to adapt to different installation walls. In addition, the blotter that sets up between backup pad and the supporting seat also can provide vertical buffering support to the pipeline, simultaneously, also can rotate the orientation that the seat was rotated in the adjustment and adjust the ferrule subassembly to adapt to more pipeline installation direction, very big improvement practicality and the convenience of device.

The present utility model will be described in further detail with reference to the accompanying drawings.

Drawings

Fig. 1 is a schematic structural view of an angle-adaptive anti-seismic bracket provided by the utility model.

Fig. 2 is an installation side view of the angle-adaptive anti-seismic bracket provided by the utility model.

FIG. 3 is an enlarged view of the attachment of the boom assembly to the support base of the angle-adaptive anti-shock bracket.

Fig. 4 is a schematic view of the lock sleeve separation state of the angle-adaptive anti-seismic bracket.

Reference numerals illustrate: 1. a bracket body; 11. a rotating shaft; 111. a baffle; 12. a support plate; 121. a guide bolt; 13. a cushion pad; 14. a rotating seat; 2. a boom assembly; 21. an outer sleeve rod; 22. a lining rod; 23. a fixing plate; 24. an adjusting bolt; 25. an adjustment aperture; 3. a pipe clamp assembly; 4. rotating the support frame; 5. a locking sleeve; 6. a compression spring; 7. positioning a tooth holder; 8. a pipeline.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but 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.

In the description of the present utility model, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

Referring to fig. 1-2, the utility model provides an angle-adaptive anti-seismic bracket, which comprises a bracket body 1 and a boom assembly 2, wherein a pipe hoop assembly 3 is arranged on the bracket body 1; one end of the boom assembly 2 is rotatably connected with the bracket body 1; the support body 1 with jib subassembly 2 junction is equipped with the control the locking mechanism of jib subassembly 2 rotation angle. During the in-service use, jib subassembly 2 can be as required with the accurate installation of wall, and pipeline 8 is fixed in ferrule subassembly 3, adjusts the contained angle between support body 1 and the jib subassembly 2, adjusts pipeline 8 to suitable position, and is fixed with the contained angle between support body 1 and the jib subassembly 2 through locking mechanism at last, can accomplish pipeline 8 installation.

Specifically, a rotating shaft 11 is arranged on the bracket body 1; one end of the boom assembly 2 is provided with a rotary supporting frame 4; one end of the rotating shaft 11 is connected with the bracket body 1, and the other end of the rotating shaft penetrates through the rotating support frame 4 and is in rotating connection with the rotating support frame 4. The rotation of the rotation support frame 4 relative to the rotation shaft 11 realizes the rotation connection between the suspender component 2 and the bracket body 1.

Further, as shown in fig. 3-4, the locking mechanism comprises a locking sleeve 5 and a positioning tooth holder 7; the locking sleeve 5 is sleeved on the rotating shaft 11 in a sliding manner and is positioned at one side of the rotating support frame 4, which is away from the support body 1; the positioning tooth seat 7 is fixed on one side of the rotary support frame 4 facing the locking sleeve 5; and the locking sleeve 5 and the positioning tooth seat 7 are respectively provided with clamping teeth which are mutually clamped. When the hanger rod assembly is used, the locking sleeve 5 is firstly separated from the clamping teeth on the positioning tooth holder 7, so that the included angle between the hanger rod assembly 2 and the support body 1 is adjusted to a proper angle, and then the locking sleeve 5 is loosened, so that the locking sleeve 5 is clamped with the clamping teeth on the positioning tooth holder 7, the rotation of the support body 1 is limited by the locking sleeve 5, and the included angle between the hanger rod assembly 2 and the support body 1 is fixed at the angle.

In order to improve the shock-resistant protection of the pipeline 8, a baffle 111 is arranged at one end of the rotating shaft 11, which is far away from the bracket body 1; the locking mechanism further comprises a compression spring 6 sleeved outside the rotating shaft 11; one end of the compression spring 6 is connected with the baffle 111, and the other end is connected with the locking sleeve 5. The locking sleeve 5 is shifted away from the positioning tooth seat 7, so that the bracket body 1 can be adjusted to generate pitching rotation, and the support angle of the pipeline 8 is adapted. And then the locking sleeve 5 is released, and under the pushing of the compression spring 6, the locking sleeve 5 and the positioning tooth seat 7 are locked, so that the rotation of the bracket body 1 is limited by the locking sleeve 5, and at the moment, the damping elastic force can be provided for the pitching variation of the bracket body 1 by means of the torsion of the compression spring 6.

Further, the boom assembly 2 comprises a telescopic rod and a fixed plate 23 rotatably mounted at one end of the telescopic rod; one end of the telescopic rod far away from the fixed plate 23 is rotatably connected with the bracket body 1. During the use, install the antidetonation support through fixed plate 23 and fix on the wall, the length of telescopic link is adjusted according to pipeline 8 installation demand. Since the fixing plate 23 is rotatably installed at the end of the telescopic rod, the installation angle of the boom assembly 2 can be freely selected.

Specifically, the telescopic rod comprises an outer sleeve rod 21, an inner lining rod 22 and an adjusting bolt 24; the fixed plate 23 is rotatably arranged on the top of the outer sleeve rod 21; one end of the lining rod 22 is slidably arranged in the outer sleeve rod 21, and the other end of the lining rod extends out of the outer sleeve rod 21 and is rotationally connected with the bracket body 1; the outer sleeve rod 21 is provided with an adjusting hole 25 matched with the adjusting bolt 24; the adjusting bolt 24 is connected to the lining rod 22 at one end thereof through the adjusting hole 25. The adjusting hole 25 is generally a long hole, and when the length of the telescopic rod needs to be adjusted, the adjusting bolt 24 is unscrewed to slide the lining rod 22 to a required position, and then the adjusting bolt 24 is screwed to fix the lining rod 22 and the outer sleeve rod 21, so that the telescopic rod is adjusted to a proper length.

In a refined embodiment, a support plate 12 is arranged in the bracket body 1; the support plate 12 is movably connected with the bracket body 1 through a guide bolt 121; the pipe clamp assembly 3 is mounted on the support plate 12. The guide bolts 121 improve the accuracy of the installation between the pipe 8 and the bracket body 1.

Preferably, a cushion pad 13 is arranged between the support plate 12 and the support body 1, and the cushion pad 13 can be a rubber pad structure, so that the buffering capacity of the device is improved.

Further, a rotating seat 14 is mounted on the supporting plate 12; the pipe clamp assembly 3 is mounted on the rotary seat 14. The rotating seat 14 is generally connected with the supporting plate 12 through a set screw, and the orientation of the pipe hoop assembly 3 is adjusted through the rotating seat 14, so that the pipe hoop assembly is suitable for more installation directions of the pipeline 8, and the practicability of the device is improved.

Optionally, the angle-adaptive anti-seismic bracket comprises two sets of boom assemblies 2; the two groups of suspender components 2 are symmetrically connected to the two sides of the bracket body 1, so that the connection stability between the bracket body 1 and the wall surface is improved.

Embodiment one:

The embodiment provides an angle self-adaptive anti-seismic bracket, which comprises a pipe hoop assembly 3, a bracket body 1, two groups of boom assemblies 2 and two groups of locking mechanisms;

The support plate 12 is mounted on the upper surface of the bracket body 1 through a guide bolt 121; a rubber buffer pad 13 is arranged between the support plate 12 and the bracket body 1; the support plate 12 is rotatably provided with a rotating seat 14; the pipe hoop assembly 3 is fixed on the rotating seat 14;

The boom assembly 2 comprises a telescopic rod, a fixed plate 23 and a rotary support frame 4; the telescopic rod comprises an outer sleeve rod 21, an inner lining rod 22 and an adjusting bolt 24; the fixed plate 23 is rotatably arranged on the top of the outer sleeve rod 21; one end of the lining rod 22 is slidably arranged in the outer sleeve rod 21, and the other end of the lining rod extends out of the outer sleeve rod 21 and is fixedly connected with the rotary support frame 4; the outer sleeve rod 21 is provided with an adjusting hole 25 matched with the adjusting bolt 24; one end of an adjusting bolt 24 is connected with the lining rod 22 through the adjusting hole 25;

The locking mechanism comprises a locking sleeve 5, a positioning tooth seat 7 and a compression spring 6; the locking sleeve 5 and the positioning tooth seat 7 are respectively provided with clamping teeth which are mutually clamped;

Both ends of the bracket body 1 are provided with rotating shafts 11; one end of the rotating shaft 11 is connected with the bracket body 1, and the other end penetrates through the rotating support frame 4; a baffle 111 is arranged at one end of the rotating shaft 11 far away from the bracket body 1; the positioning tooth seat 7 is fixed on one side surface of the rotary support frame 4, which is away from the support body 1; the locking sleeve 5 is sleeved outside the rotating shaft 11 in a sliding manner and is positioned between the baffle 111 and the positioning tooth seat 7; the compression spring 6 is sleeved outside the rotating shaft 11, one end of the compression spring is connected with the locking sleeve 5, and the other end of the compression spring is connected with the baffle 111.

During actual use, the boom assembly 2 is accurately installed with the wall surface through the fixing plate 23 as required, the installation direction of the boom assembly 2 is adjusted by utilizing the rotation of the fixing plate 23 and the outer sleeve rod 21, and then the telescopic lengths of the outer sleeve rod 21 and the lining rod 22 are adjusted to adapt to different installation walls. The locking sleeve 5 is shifted away from the positioning tooth seat 7, so that the bracket body 1 generates angle offset relative to the rotary supporting frame 4 and adapts to the pitching supporting angle of the supported pipeline 8. And then release the locking sleeve 5, under the promotion of compression spring 6, locking sleeve 5 and location toothholder 7 card are dead to make the rotation of support body 1 receive the restriction of locking sleeve 5, with the help of compression spring 6's torsion this moment, for the every single move change of support body 1 provides buffering elasticity, and then for pipeline 8 provides effectual antidetonation protection. The pipeline 8 is fixedly connected with the anti-seismic support through the pipe hoop assembly 3, vertical buffer support is provided for the pipeline 8 under the support of the buffer cushion 13, and meanwhile, the direction of the pipe hoop assembly 3 can be adjusted through the rotating seat 14, so that the installation direction of more pipelines 8 is adapted.

The foregoing examples are merely illustrative of the present utility model and are not intended to limit the scope of the present utility model, and all designs that are the same or similar to the present utility model are within the scope of the present utility model.

Claims (10)

1. The utility model provides an angle self-adaptation's antidetonation support, includes support body (1) and jib subassembly (2), its characterized in that: a pipe hoop assembly (3) is arranged on the bracket body (1); one end of the boom assembly (2) is rotationally connected with the bracket body (1); the support body (1) with jib subassembly (2) junction is equipped with the control jib subassembly (2) rotation angle's locking mechanism.

2. The angle-adaptive anti-seismic bracket of claim 1, wherein: a rotating shaft (11) is arranged on the bracket body (1); one end of the boom assembly (2) is provided with a rotary supporting frame (4); one end of the rotating shaft (11) is connected with the bracket body (1), and the other end of the rotating shaft penetrates through the rotating support frame (4) and is rotationally connected with the rotating support frame (4).

3. The angle-adaptive anti-seismic bracket of claim 2, wherein: the locking mechanism comprises a locking sleeve (5) and a positioning tooth holder (7); the locking sleeve (5) is sleeved on the rotating shaft (11) in a sliding manner and is positioned at one side of the rotating support frame (4) away from the support body (1); the positioning tooth seat (7) is fixed on one side of the rotary support frame (4) facing the locking sleeve (5); and the locking sleeve (5) and the positioning tooth seat (7) are respectively provided with clamping teeth which are mutually clamped.

4. An angularly adaptive anti-seismic cradle according to claim 3, characterized in that: one end of the rotating shaft (11) far away from the bracket body (1) is provided with a baffle (111); the locking mechanism also comprises a compression spring (6) sleeved on the rotating shaft (11); one end of the compression spring (6) is connected with the baffle (111), and the other end of the compression spring is connected with the locking sleeve (5).

5. The angle-adaptive anti-seismic bracket of claim 1, wherein: the boom assembly (2) comprises a telescopic rod and a fixed plate (23) rotatably arranged at one end of the telescopic rod; one end of the telescopic rod, which is far away from the fixed plate (23), is rotationally connected with the bracket body (1).

6. The angle-adaptive anti-seismic bracket of claim 5, wherein: the telescopic rod comprises an outer sleeve rod (21), an inner lining rod (22) and an adjusting bolt (24); the fixed plate (23) is rotatably arranged at the top of the outer sleeve rod (21); one end of the lining rod (22) is slidably arranged in the outer sleeve rod (21), and the other end of the lining rod extends out of the outer sleeve rod (21) and is rotationally connected with the bracket body (1); an adjusting hole (25) matched with the adjusting bolt (24) is formed in the outer sleeve rod (21); one end of the adjusting bolt (24) passes through the adjusting hole (25) to be connected with the lining rod (22).

7. The angle-adaptive anti-seismic bracket of claim 1, wherein: a support plate (12) is arranged in the support body (1); the support plate (12) is movably connected with the bracket body (1) through a guide bolt (121); the pipe hoop assembly (3) is mounted on the support plate (12).

8. The angle-adaptive anti-seismic bracket of claim 7, wherein: a buffer cushion (13) is arranged between the supporting plate (12) and the bracket body (1).

9. The angle-adaptive anti-seismic bracket of claim 7, wherein: a rotating seat (14) is arranged on the supporting plate (12); the pipe hoop assembly (3) is mounted on the rotating seat (14).

10. The angle-adaptive anti-seismic bracket of claim 1, wherein: comprises two groups of boom components (2); the two groups of boom components (2) are symmetrically connected to the two sides of the bracket body (1).