Rubber tube anti-twist shaping support
The anti-twist shaping bracket, composed of a support plate, L-shaped clamp, electric slide rail, and fixing block, solves the problem of loosening and twisting of rubber tubes under vibration, achieving stable shaping and reliable clamping of the rubber tubes, and improving the flow capacity and service life of the pipeline.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINYU KAIGUANG RUBBER CO LTD
- Filing Date
- 2025-09-29
- Publication Date
- 2026-06-23
Smart Images

Figure CN224397320U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of rubber tube support technology, and in particular to a rubber tube anti-twist and shaping support. Background Technology
[0002] Rubber hoses are widely used in industrial equipment, hydraulic systems, and pneumatic devices for the transmission of liquid or gas media. Their installation route, bending radius, and fixation stability directly affect not only the smoothness of the fluid passage and pressure stability, but also the overall operational safety and service life of the equipment. If excessive bending, twisting, or uneven stress occurs during the pipe laying process, it can easily lead to concavity of the pipe wall, reduction of the flow cross section, and local stress concentration, which can then cause malfunctions such as leakage, pipe bursting, or loose joints. Especially under conditions of long-term operation or frequent vibration, if the rubber hose lacks effective shaping and fixation, it is more prone to axial displacement, circumferential rotation, wear, or even breakage, which may lead to downtime accidents or safety hazards in severe cases.
[0003] Currently, traditional rubber hose fixing methods mostly use cable ties, clamps, or simple supports, which generally suffer from problems such as insufficient clamping force, non-adjustable position, and lack of directional limiting. Such structures are difficult to provide stable constraints for the rubber hose, and the hose is prone to loosening or deformation under vibration. In long-term use, the inability to effectively prevent torsion and displacement can lead to inner wall collapse, reduced flow capacity, and accelerated fatigue damage. These problems seriously affect the reliability and maintenance cycle of the system, making it difficult to meet the technical requirements of high-reliability pipeline systems for precise pipe laying, long-term fixation, and anti-torsion shaping.
[0004] Therefore, it is necessary to design a rubber tube anti-torsion shaping bracket to solve the above-mentioned technical problems. Utility Model Content
[0005] To overcome the shortcomings of traditional rubber hose fixing methods, such as insecure clamping, lack of adjustability, and no directional limit, which easily lead to loosening, twisting, and deformation under vibration, and long-term use causing collapse, blockage, and fatigue damage, making it difficult to meet the precise shaping requirements of high-reliability pipelines, this utility model provides a rubber hose anti-twist shaping bracket.
[0006] The technical solution is as follows: A rubber tube anti-twist shaping bracket includes a bracket plate, an L-shaped locking block, an electric slide rail, a slider, a first fixing block, and a second fixing block. An L-shaped locking block is fixedly connected to the rear of the bracket plate. Electric slide rails are symmetrically installed on the left and right sides of the front of the bracket plate. A slider is slidably connected to each electric slide rail. The top of the two lower sliders is fixedly connected to the first fixing block, and the bottom of the two upper sliders is fixedly connected to the second fixing block. The first fixing block and the second fixing block on the same side are arranged vertically opposite each other.
[0007] As a further preferred option, both the first fixing block and the second fixing block are made of aluminum alloy.
[0008] As a further preferred embodiment, it also includes bolts, with bolts symmetrically threaded on both the front and rear sides of the top of the two first fixing blocks, and threaded holes symmetrically provided on both the front and rear sides of the bottom of the two second fixing blocks.
[0009] As a further preferred embodiment, it also includes an electric push rod, with an electric push rod installed inside each slider. The telescopic rod of each electric push rod extends vertically and is connected to the corresponding first and second fixing blocks.
[0010] As a further preferred embodiment, it also includes locking teeth, with multiple locking teeth evenly arranged on the inner sidewalls of each first fixing block and second fixing block facing each other, the locking teeth having a sawtooth structure.
[0011] As a further preferred option, it also includes a magnetic block, with the front face of the L-shaped card block having a magnetic block made of a strong magnetic material.
[0012] The present invention has the following advantages: 1. The present invention clamps the rubber tube with the first fixing block and the second fixing block facing each other from top to bottom, and adjusts the position with the electric slide rail to achieve stable shaping, effectively prevent the tube body from twisting and deforming, maintain the integrity of the flow section, and improve the standardization and safety of the pipeline layout.
[0013] 2. This utility model uses an electric push rod to drive the first fixing block and the second fixing block to automatically clamp together, and then locks them together with bolts and threaded holes to achieve stable and reliable clamping force control, improve clamping efficiency and consistency, and is suitable for the shaping needs of rubber tubes in frequently disassembled or automated pipeline systems.
[0014] 3. This utility model uses serrated teeth on the inner sidewalls of the first and second fixing blocks to increase the friction with the surface of the rubber tube, effectively preventing the tube from sliding or twisting; combined with the magnetic block at the front end of the L-shaped locking block, it enables quick positioning and secure installation of the bracket, improving the overall ease of use and stability. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the structure of this utility model.
[0016] Figure 2 This is a structural schematic diagram of the first fixing block, the second fixing block, and bolts of this utility model.
[0017] Figure 3 This is a cross-sectional view of the slider of this utility model.
[0018] Figure 4 This is a cross-sectional view of the L-shaped card block of this utility model.
[0019] Among them: 1-bracket plate, 2-L-shaped locking block, 3-electric slide rail, 301-slider, 4-first fixing block, 5-second fixing block, 6-bolt, 7-threaded hole, 8-electric push rod, 9-locking tooth, 10-magnetic block. Detailed Implementation
[0020] Example: A rubber tube anti-torsion shaping bracket, such as Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, it includes a support plate 1, an L-shaped locking block 2, an electric slide rail 3, a slider 301, a first fixing block 4, and a second fixing block 5. The L-shaped locking block 2 is installed on the rear of the support plate 1 by screws. The electric slide rails 3 are symmetrically installed on the left and right sides of the front of the support plate 1. Each electric slide rail 3 is slidably connected to a slider 301. The top of the two lower sliders 301 is installed with a first fixing block 4 by screws, and the bottom of the two upper sliders 301 is installed with a second fixing block 5 by screws. The first fixing block 4 and the second fixing block 5 on the same side are arranged vertically opposite each other. The first fixing block 4 and the second fixing block 5 are both made of aluminum alloy.
[0021] like Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, it also includes bolts 6, electric push rods 8, locking teeth 9, and magnetic blocks 10. The top front and rear sides of the two first fixing blocks 4 are symmetrically connected with bolts 6. The bottom front and rear sides of the two second fixing blocks 5 are symmetrically provided with threaded holes 7. Each slider 301 is equipped with an electric push rod 8. The telescopic rod of each electric push rod 8 extends vertically and is connected to the corresponding first fixing block 4 and second fixing block 5. Multiple locking teeth 9 are evenly arranged on the inner sidewalls of each first fixing block 4 and second fixing block 5 facing each other. The locking teeth 9 have a sawtooth structure. The front end face of the L-shaped locking block 2 is provided with a magnetic block 10, which is made of a strong magnetic material.
[0022] When this device is needed, first, fix the bracket plate 1 to the equipment or support structure using the L-shaped clip 2. The magnetic block 10 set on the front end of the L-shaped clip 2 uses the adsorption force generated by the strong magnetic material to quickly and stably adsorb the entire bracket onto the metal surface, realizing screwless quick installation and making it easy to flexibly adjust the position according to actual needs.
[0023] Subsequently, the rubber tube to be shaped is placed horizontally between the first fixing block 4 and the second fixing block 5 on the same side, with the two facing each other vertically to form a clamping space. At this time, the electric slide rail 3 is activated, and the sliders 301 on the left and right sides move synchronously in the horizontal direction under the drive of the electric slide rail 3, which drives the first fixing block 4 and the second fixing block 5 to adjust laterally as a whole, so that the clamping position is accurately aligned with the curved section of the rubber tube, ensuring that the shaping path conforms to the design direction and preventing uneven force on the tube body due to eccentric clamping.
[0024] Once the clamping position is determined, the electric push rod 8 is activated, and its telescopic rod moves vertically, pushing the first fixing block 4 upward and the second fixing block 5 downward to clamp the rubber tube. The bolt 6 on the top of the first fixing block 4 and the threaded hole 7 at the bottom of the second fixing block 5 cooperate, allowing for further manual or automatic tightening after the electric push rod 8 has initially clamped the rubber tube, thereby enhancing clamping stability and ensuring that the rubber tube does not shift or loosen during operation.
[0025] During the clamping process, multiple serrated teeth 9 on the inner sidewalls of the first fixing block 4 and the second fixing block 5, which face each other, closely contact the outer wall of the rubber tube. The teeth 9 can effectively increase the friction of the contact surface and prevent the rubber tube from sliding axially or twisting circumferentially under vibration or pressure changes, thereby avoiding failures such as inner wall collapse and reduced flow cross-section caused by twisting. The first fixing block 4 and the second fixing block 5, made of aluminum alloy, reduce weight while ensuring strength, thus improving the overall response speed and flexibility of the equipment.
Claims
1. A rubber tube anti-torsion shaping bracket, characterized in that: It includes a support plate (1), an L-shaped locking block (2), an electric slide rail (3), a slider (301), a first fixing block (4), and a second fixing block (5). The L-shaped locking block (2) is fixedly connected to the rear of the support plate (1). Electric slide rails (3) are symmetrically installed on the left and right sides of the front of the support plate (1). A slider (301) is slidably connected to each electric slide rail (3). The top of the two sliders (301) on the lower side is fixedly connected to the first fixing block (4), and the bottom of the two sliders (301) on the upper side is fixedly connected to the second fixing block (5). The first fixing block (4) and the second fixing block (5) on the same side are arranged vertically opposite each other.
2. The rubber tube anti-torsion shaping bracket as described in claim 1, characterized in that: Both the first fixing block (4) and the second fixing block (5) are made of aluminum alloy.
3. The rubber tube anti-torsion shaping bracket as described in claim 2, characterized in that: It also includes bolts (6), and the two first fixing blocks (4) are symmetrically connected to the bolts (6) on the front and back sides of the top, and the two second fixing blocks (5) are symmetrically provided with threaded holes (7) on the front and back sides of the bottom.
4. The rubber tube anti-torsion shaping bracket as described in claim 3, characterized in that: It also includes an electric push rod (8), and each slider (301) is equipped with an electric push rod (8). The telescopic rod of each electric push rod (8) extends vertically and is connected to the corresponding first fixing block (4) and second fixing block (5).
5. The rubber tube anti-torsion shaping bracket as described in claim 4, characterized in that: It also includes locking teeth (9), and multiple locking teeth (9) are evenly arranged on the inner sidewalls of each first fixing block (4) and second fixing block (5) facing each other. The locking teeth (9) are serrated structures.
6. The rubber tube anti-torsion shaping bracket as described in claim 5, characterized in that: It also includes a magnetic block (10), and the front end of the L-shaped card block (2) is provided with a magnetic block (10), which is made of a strong magnetic material.