A pier structure for pipe support
By combining the support rod with the irregular clamp, the problem of inconvenient airbag filling and unstable fixation in the existing technology is solved, realizing stable clamping and convenient disassembly of pipes of different diameters, and simplifying the pipe adjustment process.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- TIANJIN JIUWEI IND
- Filing Date
- 2025-06-24
- Publication Date
- 2026-07-07
AI Technical Summary
In existing pipeline support structures, the airbags are inconvenient to fill and are easily punctured, leading to unstable fixation. Furthermore, the entire support needs to be removed when adjusting the pipeline, which is inconvenient.
The design combines a support rod with a special-shaped clamp, and through threaded connection and sliding groove structure, it can stably clamp and easily disassemble pipes of different diameters. Rubber anti-slip pads are used to increase friction, and worm gear transmission facilitates pipe fixing and replacement.
It enables stable clamping and convenient disassembly of pipes of different diameters, improves the stability of pipe fixing, and simplifies the pipe adjustment process.
Smart Images

Figure CN224469820U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of pipeline support technology, specifically a support structure for pipeline support. Background Technology
[0002] During pipeline installation, the main function of pipeline supports is to support the pipeline and resist thrust, prevent displacement, settlement or deformation of the pipeline caused by its own weight, water pressure or external forces, thereby sharing the load and maintaining the stability of the pipeline system.
[0003] Application No. 202120796431.9 discloses a stabilizing structure for pipeline supports. It uses a hydraulic lifting column and a pipeline fixing ring. The mounting bracket at the lower end of the pipeline fixing ring is movably connected to the mounting plate at the upper end of the hydraulic lifting column through a bearing. The height and direction of the pipeline fixing ring can be changed. When adjusting the pipeline, it is not necessary to remove the entire pipeline support, which makes the adjustment of the pipeline more convenient.
[0004] In the aforementioned application, the arc radius of the flexible mounting base is fixed, and the filled airbag fits the pipe support. However, filling the airbag requires tools, which is inconvenient and it is easily punctured by sharp objects, resulting in unstable fixation. Utility Model Content
[0005] To address the shortcomings of existing technologies, this utility model provides a support structure for pipeline support, which solves the problems mentioned in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a support structure for pipe support, comprising a base and a pipe body. Two brackets are installed on each corresponding side of the top of the base. A support platform is installed on the top of each of the four brackets. A trapezoidal placement groove is formed inside the support platform. Sliding grooves are formed on each corresponding side of the trapezoidal placement groove inside the support platform. Support rods are slidably connected inside the sliding grooves. Support plates are fixedly connected to the bottom of two support rods. A positioning element is fitted onto one end of each of the two support rods. A shaped clamp is fixedly connected between the two positioning elements. A threaded rod is rotatably connected between the base and the support platform via a bearing. The threaded rod passes through the support plate and is threadedly connected to it. The bottom of the irregularly shaped clamp is rotatably connected to two first positioning blocks, the bottom of each of the two first positioning blocks is rotatably connected to two second positioning blocks, and the bottom of each of the two second positioning blocks is rotatably connected to two third positioning blocks. The irregularly shaped clamp, the first positioning blocks, and the second positioning blocks are respectively provided with two first convex sliding grooves, two second convex sliding grooves, and two third convex sliding grooves. The two first convex sliding grooves are each slidably connected to a first convex slider, the two second convex sliding grooves are each slidably connected to a second convex slider, and the two third convex sliding grooves are each slidably connected to a third convex slider. The first convex slider, the second convex slider, and the third convex slider are respectively fixedly connected to the first positioning block, the second positioning block, and the third positioning block.
[0007] Preferably, the structure of the support rod is a configuration.
[0008] Preferably, the positioning member has an insertion hole inside that mates with the support rod.
[0009] Preferably, the support platform has a groove inside and at the bottom of the trapezoidal placement slot. A rotating shaft and a worm are rotatably connected inside the groove. A worm wheel is installed on the outside of the rotating shaft. The worm wheel and the worm mesh with each other. A throttle is rotatably connected to one side of the support platform. The rotating shaft and the worm are fixedly connected to the threaded rod and the throttle, respectively.
[0010] Preferably, a rubber anti-slip pad is installed inside the trapezoidal placement groove.
[0011] Preferably, the first convex groove, the second convex groove, and the third convex groove are all arc-shaped.
[0012] This utility model provides a support structure for pipeline support, which has the following beneficial effects:
[0013] 1. The support structure for pipe support uses a threaded connection between the support plate at the bottom of the support rod and the threaded rod to facilitate the descent of the irregular clamp between the support rods. While clamping the pipe, the sliding structure between the first positioning block, the second positioning block and the third positioning block in the irregular clamp allows it to conform to the surface of pipes of different diameters. In conjunction with the trapezoidal placement groove in the support platform, it is beneficial to stably clamp and fix the pipe.
[0014] 2. The support structure for pipe support is formed by the insertion of the support rod and the positioning parts on both sides of the irregular clamp. The support rod has a hook-shaped structure, which allows the irregular clamp to slide against the pipe as the support rod slides. It can be directly disassembled for easy replacement. The trapezoidal placement groove is equipped with a rubber anti-slip pad, which helps to increase the stability of pipe clamping. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the structure of this utility model;
[0016] Figure 2 This utility model Figure 1 Enlarged view of point A in the middle;
[0017] Figure 3 This is a front view of the present utility model;
[0018] Figure 4 This is a partial structural diagram of the present invention.
[0019] In the diagram: 1. Base; 2. Pipe body; 3. Bracket; 4. Support platform; 5. Trapezoidal placement groove; 6. Sliding groove; 7. Support rod; 8. Support plate; 9. Positioning component; 10. Irregular clamp; 11. Threaded rod; 12. First convex sliding groove; 13. First convex slider; 14. First positioning block; 15. Second convex sliding groove; 16. Second convex slider; 17. Second positioning block; 18. Third convex sliding groove; 19. Third convex slider; 20. Third positioning block; 21. Insertion hole; 22. Rubber anti-slip pad; 23. Groove; 24. Shaft; 25. Worm gear; 26. Worm wheel; 27. Turning handle. Detailed Implementation
[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.
[0021] Please see Figures 1 to 4This utility model provides a technical solution: a support structure for pipe support, including a base 1 and a pipe body 2. Two brackets 3 are installed on each corresponding side of the top of the base 1. A support platform 4 is installed on the top of the four brackets 3. A trapezoidal placement groove 5 is formed inside the support platform 4. The inclined surface of the trapezoidal placement groove 5 facilitates automatic positioning of the pipe body 2 and limits the movement of the pipe body 2 on both sides, preventing lateral displacement. A rubber anti-slip pad 22 is installed inside the trapezoidal placement groove 5 to increase friction with the surface of the pipe body 2, making the clamping of the pipe body 2 more stable. Sliding grooves 6 are formed inside the support platform 4 on each corresponding side of the trapezoidal placement groove 5. Supports are slidably connected inside the sliding grooves 6. The support rods 7 are fixedly connected to the bottom of two support plates 8. Each support rod 7 has a positioning element 9 fitted at one end. A shaped clamp 10 is fixedly connected between the two positioning elements 9. The support rods 7 have a specific structure. The positioning element 9 has an insertion hole 21 that mates with the support rod 7, allowing one end of the support rod 7 to pass through the insertion hole 21 and press against the positioning element 9, thus driving the shaped clamp 10 to compress and fix the pipe body 2. This plug-in structure facilitates the disassembly and replacement of the shaped clamp 10. A threaded rod 11 is rotatably connected between the base 1 and the support platform 4 via a bearing. The threaded rod 11 passes through the support plate 8 and is threadedly connected to it. As the support plate 8 rotates with the threaded rod 11, it causes the two support rods 7 to rise and fall, and the shaped clamp 10 compresses the pipe body 2 accordingly. To facilitate clamping and fixing of the pipe body 2, the bottom of the irregular clamp 10 is rotatably connected to two first positioning blocks 14, the bottom of each of the two first positioning blocks 14 is rotatably connected to two second positioning blocks 17, and the bottom of each of the two second positioning blocks 17 is rotatably connected to two third positioning blocks 20. The irregular clamp 10, the first positioning blocks 14, and the second positioning blocks 17 each have two first convex sliding grooves 12, two second convex sliding grooves 15, and two third convex sliding grooves 18 respectively. The two first convex sliding grooves 12 each have a first convex slider 13 slidably connected inside, the two second convex sliding grooves 15 each have a second convex slider 16 slidably connected inside, and the two third convex sliding grooves 18 each have a third convex slider 19 slidably connected inside. Block 13, the second convex slider 16, and the third convex slider 19 are fixedly connected to the first positioning block 14, the second positioning block 17, and the third positioning block 20, respectively, and support the first positioning block 14, the second positioning block 17, and the third positioning block 20. As the irregularly shaped clamp 10 moves downward, the first positioning block 14, the second positioning block 17, and the third positioning block 20 compress the pipe body 2 and rotate automatically, which facilitates conforming to the surface of the pipe body 2. The structures of the first convex groove 12, the second convex groove 15, and the third convex groove 18 are all arc-shaped, allowing the third positioning block 20, the second positioning block 17, and the first positioning block 14 to slide along the trajectories of the first convex groove 12, the second convex groove 15, and the third convex groove 18, respectively, when compressed.A groove 23 is formed inside the support platform 4 at the bottom of the trapezoidal placement slot 5. A rotating shaft 24 and a worm gear 25 are rotatably connected inside the groove 23. A worm wheel 26 is installed on the outside of the rotating shaft 24, meshing with the worm gear 25. A handle 27 is rotatably connected to one side of the support platform 4. The rotating shaft 24 and the worm gear 25 are fixedly connected to the threaded rod 11 and the handle 27, respectively. Through the meshing between the worm wheel 26 and the worm gear 25, the handle 27 transmits power to the threaded rod 11, facilitating the rotation of the worm gear 25 and the threaded rod 11. The self-locking property of the worm gear 25 and the worm wheel 26 helps to lock the threaded rod 11. Dustproof protective sleeves are fitted on the outside of the threaded rod 11, both above and below the support plate 8. The threaded rod 11 is made of rust-resistant material.
[0022] In summary, when using this pipe support structure, the pipe body 2 is placed in the trapezoidal placement groove 5 on the support platform 4, and after it is in contact with the rubber anti-slip pad 22, the irregular clamp 10 is held by hand, and one end of each of the two support rods 7 is passed through the insertion holes 21 of the positioning parts 9 on both sides of the irregular clamp 10. At the same time, the handle 27 is rotated, and under the action of the meshing between the worm gear 25 and the worm wheel 26, and the threaded connection between the threaded rod 11 and the bottom support plate 8 of the two support rods 7, the threaded rod 11 rotates, driving the support plate 8 and the two support rods 7 to move down, so that the irregular clamp 10 descends and contacts the top of the pipe body 2. When squeezed by the pipe body 2, the multiple rotating first positioning blocks 14, second positioning blocks 17, and third positioning blocks 20 inside the irregular clamp 10 rotate accordingly and fit against the surface of the pipe body 2. Together with the trapezoidal placement groove 5, they clamp and fix the pipe body 2, and the irregular clamp 10 can be released. Similarly, when it is necessary to replace the irregular clamp 10, the reverse drive threaded rod 11 rotates, causing the two support rods 7 to rise. One end of the second positioning block 17 is then pulled out from the insertion hole 21 inside the positioning member 9. The support rod 7 separates from the positioning member 9, releasing the squeeze on the irregular clamp 10, and the irregular clamp 10 can be removed.
[0023] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.
Claims
1. A support structure for pipe support, comprising a base (1) and a pipe body (2), characterized in that: Two brackets (3) are installed on the top of the base (1) on both sides corresponding to the top of the base (1). A support platform (4) is installed on the top of the four brackets (3). A trapezoidal placement groove (5) is opened inside the support platform (4). A sliding groove (6) is opened inside the support platform (4) on both sides corresponding to the trapezoidal placement groove (5). A support rod (7) is slidably connected inside the sliding groove (6). A support plate (8) is fixedly connected to the bottom of the two support rods (7). A positioning piece (9) is sleeved on one end of the two support rods (7). A special-shaped clamp (10) is fixedly connected between the two positioning pieces (9). A threaded rod (11) is rotatably connected between the base (1) and the support platform (4) through a bearing. The threaded rod (11) passes through the support plate (8) and is threadedly connected to the support plate (8). Two first positioning blocks (14) are rotatably connected to the bottom of the special-shaped clamp (10). The bottom of block (14) is rotatably connected to two second positioning blocks (17), and the bottom of the two second positioning blocks (17) is rotatably connected to two third positioning blocks (20). The irregular clamp (10), the first positioning block (14), and the second positioning block (17) are respectively provided with two first convex sliding grooves (12), two second convex sliding grooves (15), and two third convex sliding grooves (18). The two first convex sliding grooves (12) are slidably connected to a first convex slider (13), the two second convex sliding grooves (15) are slidably connected to a second convex slider (16), and the two third convex sliding grooves (18) are slidably connected to a third convex slider (19). The first convex slider (13), the second convex slider (16), and the third convex slider (19) are fixedly connected to the first positioning block (14), the second positioning block (17), and the third positioning block (20), respectively.
2. The support structure for pipeline support according to claim 1, characterized in that: The structure of the support rod (7) is as follows.
3. The support structure for pipeline support according to claim 1, characterized in that: The positioning member (9) has an insertion hole (21) inside that mates with the support rod (7).
4. A support structure for pipeline support according to claim 1, characterized in that: The support platform (4) has a groove (23) at the bottom of the trapezoidal placement groove (5). A rotating shaft (24) and a worm (25) are rotatably connected inside the groove (23). A worm wheel (26) is installed on the outside of the rotating shaft (24). The worm wheel (26) and the worm (25) mesh with each other. A throttle (27) is rotatably connected to one side of the support platform (4). The rotating shaft (24) and the worm (25) are fixedly connected to the threaded rod (11) and the throttle (27) respectively.
5. A support structure for pipeline support according to claim 1, characterized in that: The trapezoidal placement groove (5) is equipped with a rubber anti-slip pad (22).
6. A support structure for pipeline support according to claim 1, characterized in that: The first convex groove (12), the second convex groove (15), and the third convex groove (18) all have arc-shaped structures.