CN118009105A

CN118009105A - Building construction pipeline support with pipeline fixing effect

Info

Publication number: CN118009105A
Application number: CN202410407258.7A
Authority: CN
Inventors: 李力广; 师卫锋; 任发亮; 李昀春; 梁胖胖; 闫靖宇; 赵建峰; 王文亭; 宋剑; 韩斐; 董亚强
Original assignee: Shanxi Construction Engineering Group Co Ltd
Current assignee: Shanxi Construction Engineering Group Co Ltd
Priority date: 2024-04-07
Filing date: 2024-04-07
Publication date: 2024-05-10

Abstract

The invention relates to a building construction pipeline bracket with a pipeline fixing function, belonging to the technical field of building construction; the device comprises a bracket, wherein a conveying roller is rotationally arranged in the bracket, a squeeze roller and a jacking roller are slidably arranged in the bracket, the squeeze roller and the conveying roller are arranged in parallel, and the squeeze roller and the conveying roller are mutually close to or far away from each other when sliding; the squeeze roller and the jacking roller are connected through a transmission rod, and synchronous sliding of the squeeze roller and the jacking roller is realized through the transmission rod; a rebound mechanism is arranged at the top end of the inside of the bracket and is connected with the squeeze roller, the rebound mechanism gives a rebound force to the squeeze roller towards the conveying roller, a clamping mechanism is arranged between the conveying roller and the squeeze roller, and when the conveying roller and the squeeze roller are close to each other, the conveying roller and the squeeze roller are mutually clamped through the clamping mechanism; the problem that the existing pipeline bracket cannot limit the pipeline which is not required to be pulled out is solved.

Description

Building construction pipeline support with pipeline fixing effect

Technical Field

The invention belongs to the technical field of building construction, and particularly relates to a building construction pipeline bracket with a pipeline fixing function.

Background

In building construction, in order to ensure normal operation of construction equipment, pipelines such as air pipes, water pipes and the like are usually required to be arranged on a construction site, wherein some pipelines are generally pulled out from pipeline rolls, so that brackets for placing the pipelines are arranged to prevent the pipelines from falling down or falling on the ground, but some pipelines still fall down or falling on the ground due to the action of gravity or due to the fact that the released pipelines are longer, and when the pipelines fall down in slurry, the pipelines are polluted; and because the length of the pipeline to be pulled out is uncertain during construction, the pipeline is pulled out more under the condition that the pipeline is dropped, and the construction is inconvenient.

Disclosure of Invention

The invention overcomes the defects of the prior art and provides a building construction pipeline bracket with a pipeline fixing function; the problem that the existing pipeline bracket cannot limit the pipeline which is not required to be pulled out is solved.

In order to achieve the above purpose, the present invention is realized by the following technical scheme.

The utility model provides a construction pipeline support with pipeline fixed action, includes the support, rotates in the support inside and is provided with the conveying roller, slides in the support inside and is provided with squeeze roll and jacking roller, squeeze roll and conveying roller parallel arrangement, squeeze roll and conveying roller are close to each other or keep away from each other when sliding; the squeeze roller and the jacking roller are connected through a transmission rod, and synchronous sliding of the squeeze roller and the jacking roller is realized through the transmission rod; a rebound mechanism is arranged at the top end of the inside of the support and connected with the squeeze roller, the squeeze roller is provided with a rebound force towards the conveying roller through the rebound mechanism, a clamping mechanism is arranged between the conveying roller and the squeeze roller, and when the conveying roller and the squeeze roller are close to each other, the conveying roller and the squeeze roller are clamped with each other through the clamping mechanism.

Further, the support is of a door-shaped structure and comprises two vertical plates and a horizontal plate, and the upper end edges of the two vertical plates are fixedly connected with the left end edge and the right end edge of the horizontal plate respectively.

Further, be provided with in the inside front side below of support the jacking roller, the fixed first bull stick that is provided with in axis department of jacking roller is provided with a vertical first lift hole respectively on two vertical boards of support, and the both ends of first bull stick stretch into respectively in two first lift holes of support.

Further, the conveying roller is arranged in the middle of the rear side of the inside of the bracket, and two ends of the conveying roller are respectively connected with two vertical plates of the bracket in a rotating way.

Further, the extrusion roller is arranged above the rear side of the inside of the bracket, the extrusion roller is positioned above the conveying roller, a second rotating rod is fixedly arranged at the axis of the extrusion roller, two vertical plates of the bracket are respectively provided with a vertical second lifting hole, and two ends of the second rotating rod respectively extend into the two second lifting holes of the bracket; two ends of the second rotating rod are respectively fixedly provided with a waist-shaped block, the waist-shaped blocks are of long round structures, the two waist-shaped blocks are respectively positioned inside the two second lifting holes, and two side planes of the waist-shaped blocks are respectively contacted with two side inner walls of the second lifting holes.

Further, the number of the transmission rods is two, the transmission rods are respectively arranged at the left side and the right side of the squeeze roller and the jacking roller, and the two transmission rods are positioned at the inner side of the bracket; two ends of the transmission rod are respectively provided with a first rotating hole, and the two first rotating holes at two ends of the transmission rod are respectively sleeved on the outer sides of the first rotating rod and the second rotating rod.

Further, the rebound mechanism comprises a sliding block, an extrusion spring and an extrusion rod; a sliding groove is formed in the lower end face of the horizontal plate of the bracket, a sliding block is arranged in the sliding groove in a sliding manner along the front-back direction, and the sliding block is positioned above the front side of the extrusion roller; the inside of the sliding groove is provided with an extrusion spring, the front end of the extrusion spring is fixedly connected with the inner wall of the front side of the sliding groove, and the rear end of the extrusion spring is fixedly connected with the end face of the front side of the sliding block; two hinging seats which are bilaterally symmetrical are fixedly arranged on the lower end surface of the sliding block; the number of the extrusion rods is two, the two extrusion rods are respectively arranged on the left side and the right side of the extrusion roller, a second rotating hole is respectively formed in two ends of each extrusion rod, the second rotating hole at the upper end of each extrusion rod is hinged with the hinged seat on the same side through a pin shaft, and the second rotating hole at the lower end of each extrusion rod is sleeved on the outer side of the second rotating rod.

Further, a sliding hole which is communicated from front to back is formed in the middle of the sliding block, a front-to-back horizontal fixing rod is fixedly arranged in the sliding groove, the sliding hole of the sliding block is sleeved on the outer side of the fixing rod in a sliding mode, and the extrusion spring is sleeved on the outer side of the fixing rod in a sleeved mode.

Further, the middle parts of the cylindrical surfaces of the outer sides of the jacking roller, the conveying roller and the extruding roller are respectively provided with a circle of annular arc grooves, the outer walls of the pipelines are positioned through the arc grooves, and rubber pads are fixedly arranged in the arc grooves of the jacking roller, the conveying roller and the extruding roller.

Further, the clamping mechanism comprises a clamping groove and a clamping block; two groups of clamping grooves in circular arrays are fixedly arranged on the outer cylindrical surface of the conveying roller, and the two groups of clamping grooves are symmetrically arranged relative to the circular arc grooves of the conveying roller; two groups of circular array clamping blocks are fixedly arranged on the outer cylindrical surface of the squeeze roller, and the two groups of clamping blocks are symmetrically arranged relative to the circular arc groove of the squeeze roller; the fixture block is the triangle setting with the draw-in groove, conveniently with the fixture block card inside the draw-in groove.

Compared with the prior art, the invention has the following beneficial effects:

When the pipeline lifting device is used, the lifting roller can be lifted by directly pulling the pipeline, and the lifting roller drives the extrusion roller to synchronously lift through the transmission rod, so that the extrusion roller and the conveying roller do not extrude the pipeline any more, and the pipeline can be normally pulled out; when the pipeline is not required to be pulled out, the pipeline is loosened, the jacking roller can immediately descend, the jacking roller drives the squeeze roller to synchronously descend through the transmission rod, when the squeeze roller is contacted with the pipeline, the squeeze roller controls the conveying roller to stop rotating through the clamping mechanism, and simultaneously the pipeline is clamped through the squeeze roller and the conveying roller, so that the pipeline cannot be pulled out continuously, the squeeze roller is controlled to not ascend through the rebound mechanism, the squeeze roller and the conveying roller are always clamped, and the pipeline is further prevented from falling down.

Drawings

The invention is described in further detail below with reference to the accompanying drawings:

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic diagram of the whole structure of the present invention;

FIG. 3 is a schematic view of the structure of the present invention after the stent is semi-sectioned;

FIG. 4 is a schematic view of a partial explosion of the present invention;

Wherein 1 is a bracket; 2 is a conveying roller; 3 is a jacking roller; 4 is a squeeze roll; 5 is a first rotating rod; 6 is a first lifting hole; 7 is a second rotating rod; 8 is a second lifting hole; 9 is a transmission rod; 10 is a first rotating hole; 11 is a waist-shaped block; 12 is a chute; 13 is a slide block; 14 is an extrusion rod; 15 is a second rotary hole; 16 is an extrusion spring; 17 is a slide hole; 18 is a fixed rod; 19 is a clamping groove; 20 is a clamping block; 21 is a fixing frame; and 22 is a rubber pad.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the invention is further described in detail by combining the embodiments and the drawings. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention. The following describes the technical scheme of the present invention in detail with reference to examples and drawings, but the scope of protection is not limited thereto.

As shown in fig. 1 to 4, the invention provides a construction pipeline bracket with a pipeline fixing function, which comprises a bracket 1, wherein a conveying roller 2 is rotatably arranged in the bracket 1, a squeeze roller 4 and a jacking roller 3 are slidably arranged in the bracket 1, the squeeze roller 4 is parallel to the conveying roller 2, and the squeeze roller 4 and the conveying roller 2 are mutually close to or far away from each other when sliding; the squeeze roller 4 is connected with the jacking roller 3 through a transmission rod 9, and synchronous sliding of the squeeze roller 4 and the jacking roller 3 is realized through the transmission rod 9; the inside top at support 1 is provided with the resilience mechanism, and the resilience mechanism is connected with squeeze roll 4, gives squeeze roll 4a resilience force towards conveying roller 2 through the resilience mechanism, is provided with joint mechanism between conveying roller 2 and squeeze roll 4, and through joint mechanism and joint each other when conveying roller 2 and squeeze roll 4 are close to each other.

The support 1 is of a door-shaped structure and comprises two vertical plates and a horizontal plate, wherein the upper end edges of the two vertical plates are fixedly connected with the left end edge and the right end edge of the horizontal plate respectively.

The lifting roller 3 is arranged below the front side of the inside of the bracket 1, a first rotating rod 5 is fixedly arranged at the axis of the lifting roller 3, and the first rotating rod 5 is horizontally arranged along the left-right direction. Two vertical plates of the support 1 are respectively provided with a vertical first lifting hole 6, the two first lifting holes 6 are symmetrically arranged, two ends of the first rotating rod 5 extend into the two first lifting holes 6 of the support 1 respectively, the outer walls of the first rotating rod 5 are in close contact with the inner walls of two sides of the first lifting holes 6, and therefore the first rotating rod 5 is guaranteed not to shake back and forth when lifting in the first lifting holes 6. A group of anti-slip rings are fixedly arranged at two ends of the first rotating rod 5 respectively, and the two groups of anti-slip rings are respectively arranged to be contacted with the outer walls of two sides of two vertical plates of the bracket 1, so that the first rotating rod 5 is prevented from shaking left and right in the bracket 1. When the first rotating rod 5 and the jacking roller 3 slide in the first lifting hole 6, the jacking roller 3 can rotate along with the first rotating rod 5.

The conveying roller 2 is arranged in the middle of the rear side of the inside of the support 1, the axis of the conveying roller 2 is horizontally arranged along the left-right direction, and two ends of the conveying roller 2 are respectively connected with two vertical plates of the support 1 in a rotating mode, so that the conveying roller 2 rotates in the inside of the support 1.

The extrusion roller 4 is arranged above the rear side of the inside of the bracket 1, the extrusion roller 4 is positioned above the conveying roller 2, a second rotating rod 7 is fixedly arranged at the axis of the extrusion roller 4, and the second rotating rod 7 is horizontally arranged along the left-right direction. Two vertical plates of the bracket 1 are respectively provided with a vertical second lifting hole 8, the two second lifting holes 8 are symmetrically arranged, and two ends of the second rotating rod 7 respectively extend into the two second lifting holes 8 of the bracket 1. The two ends of the second rotating rod 7 are respectively fixedly provided with a waist-shaped block 11, the waist-shaped blocks 11 are of long round structures, the two waist-shaped blocks 11 are respectively positioned inside the two second lifting holes 8, and the two side planes of the waist-shaped blocks 11 are respectively contacted with the two side inner walls of the second lifting holes 8, so that the waist-shaped blocks 11 can only lift inside the second lifting holes 8 and cannot rotate, and further, the squeeze roller 4 and the second rotating rod 7 can only lift and cannot rotate. A group of anti-slip rings are fixedly arranged at two ends of the second rotating rod 7 respectively, and the two groups of anti-slip rings are respectively contacted with the outer walls of two sides of two vertical plates of the bracket 1, so that the second rotating rod 7 is prevented from shaking left and right in the bracket 1.

The number of the transmission rods 9 is two, the two transmission rods 9 are respectively arranged on the left side and the right side of the squeeze roller 4 and the jacking roller 3, and the two transmission rods 9 are both positioned on the inner side of the bracket 1. Two ends of the transmission rod 9 are respectively provided with a first rotating hole 10, and the two first rotating holes 10 at two ends of the transmission rod 9 are respectively sleeved on the outer sides of the first rotating rod 5 and the second rotating rod 7, so that the first rotating rod 5 and the second rotating rod 7 can rotate in the first rotating holes 10 of the transmission rod 9.

The rebound mechanism comprises a sliding block 13, a compression spring 16 and a compression rod 14.

A chute 12 is arranged on the lower end face of the horizontal plate of the bracket 1, and the chute 12 is a T-shaped chute with an opening at the lower end. A slide block 13 is slidably disposed in the slide groove 12 along the front-rear direction, the slide block 13 has a T-block structure, and the slide block 13 is located above the front side of the squeeze roller 4. An extrusion spring 16 is arranged in the chute 12, the extrusion spring 16 is horizontally arranged along the front-back direction, the front end of the extrusion spring 16 is fixedly connected with the front inner wall of the chute 12, and the rear end of the extrusion spring 16 is fixedly connected with the front end face of the sliding block 13. Two bilaterally symmetrical hinge seats are fixedly arranged on the lower end surface of the sliding block 13. The number of the extrusion rods 14 is two, the two extrusion rods 14 are respectively arranged on the left side and the right side of the extrusion roller 4, two second rotating holes 15 are respectively formed in two ends of the extrusion rods 14, the second rotating holes 15 at the upper ends of the extrusion rods 14 are hinged with hinge seats on the same side through pin shafts, and the second rotating holes 15 at the lower ends of the extrusion rods 14 are sleeved on the outer sides of the second rotating rods 7.

A slide hole 17 penetrating through the slide block 13 from front to back is arranged in the middle of the slide block, a fixing rod 18 which is horizontal from front to back is fixedly arranged in the slide groove 12, and the front end and the rear end of the fixing rod 18 are respectively fixedly connected with the inner walls of the front side and the rear side of the slide groove 12. The sliding hole 17 of the sliding block 13 is sleeved on the outer side of the fixed rod 18 in a sliding manner, and the inner wall of the sliding hole 17 is in contact with the outer wall of the fixed rod 18, so that the sliding block 13 is stable when sliding forwards and backwards, the extrusion spring 16 is sleeved on the outer side of the fixed rod 18, and the extrusion spring 16 is prevented from bending when stretching.

A fixing frame 21 is fixedly arranged on the outer side of the vertical plate on one side of the bracket 1, and the fixing frame 21 is connected with a wall body through bolts, so that the whole pipeline bracket is fixed with the wall body.

The middle parts of the outer cylindrical surfaces of the jacking roller 3, the conveying roller 2 and the extruding roller 4 are respectively provided with a circle of annular arc grooves, and the outer walls of the pipelines are positioned through the arc grooves. Rubber pads 22 are fixedly arranged in circular arc grooves of the jacking roller 3, the conveying roller 2 and the extruding roller 4, friction force in the contact process of the pipeline and the jacking roller 3, the conveying roller 2 and the extruding roller 4 is improved, and the fixing effect of the conveying roller 2 and the extruding roller 4 on the pipeline is improved.

The clamping mechanism comprises a clamping groove 19 and a clamping block 20. Two groups of clamping grooves 19 in circular arrays are fixedly arranged on the outer cylindrical surface of the conveying roller 2, and the two groups of clamping grooves 19 are symmetrically arranged relative to the circular arc grooves of the conveying roller 2; two groups of clamping blocks 20 in circular arrays are fixedly arranged on the outer cylindrical surface of the squeeze roller 4, and the two groups of clamping blocks 20 are symmetrically arranged relative to the circular arc groove of the squeeze roller 4. The clamping block 20 and the clamping groove 19 are arranged in a triangular mode, and the clamping block 20 is conveniently clamped inside the clamping groove 19.

The working principle of the invention is as follows:

When the line support is in use, the line is passed forward between the squeeze roller 4 and the transfer roller 2 and then around the jacking roller 3 from below.

When the line is not pulled and paid out, the line does not apply force to the jacking roller 3, the jacking roller 3 is located at the lowest position due to self-weight, at this time, the first rotating rod 5 is located at the lowest point of the first lifting hole 6, and the first rotating rod 5 pulls the second rotating rod 7 downwards through the transmission rod 9, so that the second rotating rod 7 is located at the lowest point of the second lifting hole 8. At this time, the pressing spring 16 is in a free stretching state, the pressing spring 16 pushes the sliding block 13 to the rearmost side of the sliding groove 12, and the sliding block 13 pushes the second rotating rod 7 downwards through the pressing rod 14, so that the second rotating rod 7 is always located at the lowest point of the second lifting hole 8. Because squeeze roller 4 is in the lowest position to make squeeze roller 4 and conveying roller 2 extrude the pipeline together, guarantee that the pipeline can not continue to draw, thereby make pipeline and pipeline support wholly fixed mutually.

When the pipeline is pulled and paid off, the pipeline is in a straightening state, the pipeline gives an upward acting force to the jacking roller 3, the jacking roller 3 is jacked up, the jacking roller 3 drives the first rotating rod 5 to slide upwards in the first lifting hole 6, and the jacking roller 3 and the pipeline are rubbed with each other in the lifting process, so that the jacking roller 3 always rotates in the lifting process. When the jacking roller 3 ascends, the transmission rod 9 drives the second rotating rod 7 to slide upwards, the waist-shaped blocks 11 at two ends of the second rotating rod 7 slide upwards in the second lifting hole 8, the second rotating rod 7 drives the extrusion roller 4 to ascend, the extrusion roller 4 is separated from a pipeline, the extrusion roller 4 and the conveying roller 2 are not clamped by the pipeline, the pipeline can be pulled, and therefore the pipeline can be pulled out of the pipeline bracket smoothly. In the process of lifting the second rotating rod 7, the pressing rod 14 drives the sliding block 13 to slide forwards, and the pressing spring 16 is compressed by the sliding block 13.

When the pipeline is not pulled and paid out any more, the pipeline bends under the action of gravity, the pipeline does not apply acting force to the jacking roller 3, the jacking roller 3 descends due to self-weight, the first rotating rod 5 descends synchronously with the jacking roller 3, the first rotating rod 5 pulls the second rotating rod 7 downwards through the transmission rod 9, so that the second rotating rod 7 also starts to descend, the compressed compression spring 16 also pushes the sliding block 13 backwards, and the sliding block 13 pushes the second rotating rod 7 downwards through the compression rod 14, so that stable descending of the compression roller 4 is ensured. When the squeeze roller 4 descends to be in contact with the pipeline, the clamping blocks 20 at the two ends of the squeeze roller 4 are clamped inside the clamping grooves 19 at the two ends of the conveying roller 2 and are used for controlling the conveying roller 2 not to rotate continuously, and meanwhile, the squeeze roller 4 clamps the pipeline together with the conveying roller 2 to ensure that the pipeline cannot be pulled continuously, so that the pipeline is fixed with the pipeline support integrally, and the pipeline is prevented from being excessively bent or even falling on the ground during conveying. Due to the resilience force of the extrusion spring 16, the sliding block 13 is ensured not to slide forward, so that the second rotating rod 7 is always in the current state and cannot slide upwards, and the driving clamping block 20 is clamped inside the clamping grooves 19 at the two ends of the conveying roller 2, so that the positions of the pipelines are further fixed.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a construction pipeline support with pipeline fixed action which characterized in that: the device comprises a bracket (1), wherein a conveying roller (2) is rotationally arranged in the bracket (1), a squeeze roller (4) and a jacking roller (3) are slidably arranged in the bracket (1), the squeeze roller (4) and the conveying roller (2) are arranged in parallel, and the squeeze roller (4) and the conveying roller (2) are mutually close to or far away from each other when sliding; the squeeze roller (4) is connected with the jacking roller (3) through a transmission rod (9), and synchronous sliding of the squeeze roller (4) and the jacking roller (3) is realized through the transmission rod (9); the inside top at support (1) is provided with the resilience mechanism, and the resilience mechanism is connected with squeeze roll (4), gives squeeze roll (4) a resilience force towards conveying roller (2) through the resilience mechanism, is provided with joint mechanism between conveying roller (2) and squeeze roll (4), and through joint mechanism and each other joint when conveying roller (2) and squeeze roll (4) are close to each other.

2. A construction pipeline bracket having a pipeline fixing effect according to claim 1, wherein: the support (1) is of a door-shaped structure and comprises two vertical plates and a horizontal plate, and the upper end edges of the two vertical plates are fixedly connected with the left end edge and the right end edge of the horizontal plate respectively.

3. A construction pipeline bracket having a pipeline fixing effect according to claim 2, wherein: the lifting roller (3) is arranged below the front side of the inside of the support (1), a first rotating rod (5) is fixedly arranged at the axis of the lifting roller (3), two vertical lifting holes (6) are respectively formed in two vertical plates of the support (1), and two ends of the first rotating rod (5) respectively extend into the two first lifting holes (6) of the support (1).

4. A construction pipeline bracket having a pipeline fixing effect according to claim 2, wherein: the middle part of the rear side inside the bracket (1) is provided with the conveying roller (2), and two ends of the conveying roller (2) are respectively connected with two vertical plates of the bracket (1) in a rotating way.

5. A construction line support having a line fixing effect according to claim 3, wherein: the extrusion roller (4) is arranged above the rear side of the inside of the bracket (1), the extrusion roller (4) is positioned above the conveying roller (2), a second rotating rod (7) is fixedly arranged at the axis of the extrusion roller (4), two vertical plates of the bracket (1) are respectively provided with a vertical second lifting hole (8), and two ends of the second rotating rod (7) respectively extend into the two second lifting holes (8) of the bracket (1); two ends of the second rotating rod (7) are respectively fixedly provided with a waist-shaped block (11), the waist-shaped blocks (11) are of long round structures, the two waist-shaped blocks (11) are respectively positioned inside the two second lifting holes (8), and two side planes of the waist-shaped blocks (11) are respectively contacted with two side inner walls of the second lifting holes (8).

6. A construction pipeline bracket having a pipeline fixing effect according to claim 5, wherein: the two transmission rods (9) are respectively arranged at the left side and the right side of the squeeze roller (4) and the jacking roller (3), and the two transmission rods (9) are positioned at the inner side of the bracket (1); two ends of the transmission rod (9) are respectively provided with a first rotating hole (10), and the two first rotating holes (10) at two ends of the transmission rod (9) are respectively sleeved on the outer sides of the first rotating rod (5) and the second rotating rod (7).

7. A construction pipeline bracket having a pipeline fixing effect according to claim 5, wherein: the rebound mechanism comprises a sliding block (13), an extrusion spring (16) and an extrusion rod (14); a sliding groove (12) is formed in the lower end face of the horizontal plate of the bracket (1), a sliding block (13) is slidably arranged in the sliding groove (12) along the front-back direction, and the sliding block (13) is positioned above the front side of the extrusion roller (4); an extrusion spring (16) is arranged in the sliding groove (12), the front end of the extrusion spring (16) is fixedly connected with the inner wall of the front side of the sliding groove (12), and the rear end of the extrusion spring (16) is fixedly connected with the end face of the front side of the sliding block (13); two bilaterally symmetrical hinging seats are fixedly arranged on the lower end surface of the sliding block (13); the number of the extrusion rods (14) is two, the two extrusion rods (14) are respectively arranged on the left side and the right side of the extrusion roller (4), a second rotating hole (15) is respectively formed in two ends of each extrusion rod (14), the second rotating hole (15) at the upper end of each extrusion rod (14) is hinged with a hinge seat at the same side through a pin shaft, and the second rotating hole (15) at the lower end of each extrusion rod (14) is sleeved on the outer side of the second rotating rod (7).

8. A construction pipeline bracket having a pipeline fixing effect according to claim 7, wherein: the middle part of the sliding block (13) is provided with a sliding hole (17) which is penetrated from front to back, a front-back horizontal fixing rod (18) is fixedly arranged in the sliding groove (12), the sliding hole (17) of the sliding block (13) is sleeved on the outer side of the fixing rod (18) in a sliding way, and the extrusion spring (16) is sleeved on the outer side of the fixing rod (18).

9. A construction pipeline bracket having a pipeline fixing effect according to claim 1, wherein: the outer cylindrical surfaces of the jacking roller (3), the conveying roller (2) and the extruding roller (4) are provided with annular circular arc grooves, the outer walls of pipelines are positioned through the circular arc grooves, and rubber pads (22) are fixedly arranged in the circular arc grooves of the jacking roller (3), the conveying roller (2) and the extruding roller (4).

10. A construction pipeline bracket having a pipeline fixing effect according to claim 9, wherein: the clamping mechanism comprises a clamping groove (19) and a clamping block (20); two groups of clamping grooves (19) in a circular array are fixedly arranged on the outer cylindrical surface of the conveying roller (2), and the two groups of clamping grooves (19) are symmetrically arranged relative to the circular arc grooves of the conveying roller (2); two groups of circular array clamping blocks (20) are fixedly arranged on the outer cylindrical surface of the squeeze roller (4), and the two groups of clamping blocks (20) are symmetrically arranged relative to the arc groove of the squeeze roller (4); the clamping block (20) and the clamping groove (19) are arranged in a triangular mode, and the clamping block (20) is conveniently clamped inside the clamping groove (19).