A PE communication pipe with an interface
The design of the ring-shaped locking block, screw thread connection, and compression ring enhances the stability of the PE communication pipe interface and solves the problem of easy loosening and falling off of traditional interfaces. At the same time, the inner wall reinforcing ribs and outer coating improve the structural strength and durability of the pipe.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- LANZHOU ZHONGREN PIPELINE ENG CO LTD
- Filing Date
- 2025-07-08
- Publication Date
- 2026-06-30
AI Technical Summary
Traditional PE communication pipes have problems with loose or detached interface connections, which affects the normal transmission of communication signals.
The system employs a ring-shaped locking block and a ferrule for engagement, combined with a threaded connection between the screw and the connecting block. The design of the compression ring and the elastic ferrule enhances the stability of the interface. The inner wall is equipped with spiral reinforcing ribs, and the outer side is coated with an anti-UV coating to enhance the pipe structure and protection.
It improves the stability of the interface, enabling it to withstand soil and fluid pressure, reducing the risk of loosening and falling off, and extending the service life of the pipeline.
Smart Images

Figure CN224438515U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of communication pipeline technology, specifically a PE communication pipeline with an interface. Background Technology
[0002] PE communication pipes are made of polyethylene resin and are primarily used for communication purposes. These pipes offer many advantages and are highly versatile, making them particularly suitable for laying cables, wires, and other wires during the construction of communication infrastructure. PE communication pipes are widely used to protect communication lines.
[0003] Traditional PE communication pipes have many problems in terms of interface connection. For example, the interface connection method is simple, often relying only on simple snap-fit or threaded connection. This connection method is prone to loosening and falling off when faced with external forces such as soil pressure, fluid pressure inside the pipe and external vibration, which will damage the communication line and affect the normal transmission of communication signals. Utility Model Content
[0004] The purpose of this invention is to provide a PE communication pipe with an interface to solve the problems mentioned in the background art.
[0005] To solve the above-mentioned technical problems, this utility model provides the following technical solution: a PE communication pipe with an interface, including a docking mechanism, wherein a fixing mechanism is provided on the left side of the docking mechanism;
[0006] The docking mechanism includes a first communication tube body, an annular locking block fixedly connected to the left side of the first communication tube body, a connecting shell fixedly connected to the left surface of the first communication tube body, an elastic sleeve fixedly connected to the left side of the connecting shell, and connecting blocks fixedly connected to both the front and rear ends of the outer side of the connecting shell.
[0007] The fixing mechanism includes a second communication tube body, an annular sleeve fixedly connected to the right side of the second communication tube body, a fixing shell fixedly connected to the right side surface of the second communication tube body, support blocks fixedly connected to both ends of the fixing shell, screws threadedly connected to both support blocks, a compression ring movably connected inside the fixing shell, and fixing blocks fixedly connected to both ends of the compression ring.
[0008] Preferably, the annular sleeve is engaged with the outside of the annular block.
[0009] Furthermore, the annular ferrule engages with the outer side of the annular ferrule, clarifying the cooperative relationship between these two components in the docking mechanism and the fixing mechanism.
[0010] Preferably, one end of each of the two screws passes through the two connecting blocks and extends to the right side of the connecting blocks, and the two screws are threadedly connected to the two connecting blocks respectively.
[0011] Furthermore, one end of each of the two screws passes through the two connecting blocks and extends to the right side of the connecting blocks, and the two screws are threadedly connected to the two connecting blocks respectively, further illustrating the connection structure between the fixing mechanism and the docking mechanism through the screws and connecting blocks.
[0012] Preferably, the two fixing blocks are respectively connected to the two screws.
[0013] Furthermore, the connection between the fixing block on the compression ring inside the fixed housing and the screw improves the connection structure of the internal components of the fixing mechanism.
[0014] Preferably, both the outer and inner sides of the first and second communication tube bodies are provided with reinforcement mechanisms.
[0015] Preferably, the reinforcement mechanism includes spiral reinforcing ribs and an anti-ultraviolet coating.
[0016] Preferably, the inner walls of both the first and second communication tube bodies are fixedly connected with spiral reinforcing ribs, and the outer sides of both the first and second communication tube bodies are coated with an anti-ultraviolet coating.
[0017] Furthermore, both the inner walls of the first and second communication tube bodies are fixedly connected with spiral reinforcing ribs, and both the outer sides of the first and second communication tube bodies are coated with an anti-ultraviolet coating.
[0018] Compared with the prior art, the beneficial effects achieved by this utility model are:
[0019] First, this utility model involves docking the first and second communication tube bodies. The annular locking block on the left side of the first communication tube body is aligned with the annular retaining sleeve on the right side of the second communication tube body. Since the annular retaining sleeve engages with the outside of the annular locking block, this design allows for quick positioning and initial locking during the initial docking, ensuring accurate docking and preventing misalignment during the docking process. This lays the foundation for a stable connection later. After initial locking, the connecting blocks at the front and rear ends of the connecting shell on the first communication tube body are connected to the screws on the support blocks at the front and rear ends of the fixing shell on the second communication tube body. Specifically, one end of each screw passes through the two connecting blocks and extends to the right side of the connecting blocks, with each screw threadedly connected to one of the two connecting blocks. By rotating the screws, the distance between the connecting blocks and the support blocks can be adjusted, further bringing the first and second communication tube bodies closer together for a tighter docking. Since the two fixing blocks are connected to the two screws respectively, when the screws are rotated... When the screw is rotated, it drives the fixed block to move. The fixed block is fixedly connected to the compression ring, so the compression ring moves within the fixed housing as the screw rotates. As the compression ring moves, it gradually approaches and compresses the elastic sleeve fixedly connected to the left side of the connecting housing. After being compressed by the compression ring, the elastic sleeve undergoes elastic deformation and fits tightly around the connection between the first and second communication pipe bodies, thereby enhancing the sealing and stability of the connection between the two communication pipe bodies. The engagement of the annular block and the annular sleeve provides initial fixation, preventing the two communication pipe bodies from easily separating after docking. The threaded connection between the screw and the connecting block, as well as the compression action of the compression ring on the elastic sleeve, further fixes the two communication pipe bodies from multiple directions. This multi-fixation method greatly enhances the stability of the entire communication pipeline interface, enabling it to withstand greater external forces, such as soil pressure and fluid pressure inside the pipeline, reducing the risk of loosening or falling off at the pipeline interface and ensuring the normal operation of the communication pipeline.
[0020] Secondly, the spiral reinforcing ribs in the reinforcement mechanism of this utility model are set on the inner walls of the first and second communication pipe bodies, which can enhance the internal structural strength of the pipe and prevent the pipe from deforming due to internal fluid pressure or external impact during long-term use. The anti-ultraviolet coating is applied to the outside of the pipe, which can effectively resist the corrosion of ultraviolet rays, slow down the aging rate of the pipe material, and extend the service life of the pipe in the outdoor environment. Attached Figure Description
[0021] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0022] Figure 2 This is a schematic diagram of the first three-dimensional structure of the present invention;
[0023] Figure 3 This is a schematic diagram of the second three-dimensional structure of the present invention;
[0024] Figure 4 This is a cross-sectional structural diagram of the present invention.
[0025] The components are as follows: 1. Docking mechanism; 101. First communication tube body; 102. Annular locking block; 103. Connecting shell; 104. Elastic sleeve; 105. Connecting block; 2. Fixing mechanism; 201. Second communication tube body; 202. Annular sleeve; 203. Fixing shell; 204. Support block; 205. Screw; 206. Extrusion ring; 207. Fixing block; 3. Reinforcing mechanism; 301. Spiral reinforcing rib. Detailed Implementation
[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0027] This utility model provides the following technical solution:
[0028] Example 1
[0029] Please see Figure 1 , Figure 2 , Figure 3 , Figure 4 A PE communication pipe with an interface includes a docking mechanism 1, and a fixing mechanism 2 is provided on the left side of the docking mechanism 1;
[0030] The docking mechanism 1 includes a first communication tube body 101, an annular locking block 102 is fixedly connected to the left side of the first communication tube body 101, a connecting shell 103 is fixedly connected to the left surface of the first communication tube body 101, an elastic sleeve 104 is fixedly connected to the left side of the connecting shell 103, and connecting blocks 105 are fixedly connected to both the front and rear ends of the outer side of the connecting shell 103.
[0031] The fixing mechanism 2 includes a second communication tube body 201. An annular sleeve 202 is fixedly connected to the right side of the second communication tube body 201. A fixing shell 203 is fixedly connected to the right surface of the second communication tube body 201. Support blocks 204 are fixedly connected to both the front and rear ends of the fixing shell 203. Screws 205 are threadedly connected to both support blocks 204. A compression ring 206 is movably connected inside the fixing shell 203. Fixing blocks 207 are fixedly connected to both the front and rear ends of the compression ring 206.
[0032] Specifically, the annular sleeve 202 is engaged and connected to the outside of the annular block 102.
[0033] Specifically, one end of each of the two screws 205 passes through the two connecting blocks 105 and extends to the right side of the connecting blocks 105, and the two screws 205 are threadedly connected to the two connecting blocks 105 respectively.
[0034] Specifically, the two fixing blocks 207 are connected to the two screws 205 respectively.
[0035] Through the above technical solution, the first communication tube body 101 and the second communication tube body 201 are docked. The annular locking block 102 on the left side of the first communication tube body 101 is aligned with the annular retaining sleeve 202 on the right side of the second communication tube body 201. Since the annular retaining sleeve 202 is engaged with the outside of the annular locking block 102, this design allows the two communication tube bodies to be quickly positioned and initially engaged during the initial docking, ensuring accurate docking position and preventing displacement during the docking process. This lays the foundation for a stable connection later. After the initial engagement, the front of the connecting shell 103 on the first communication tube body 101 is... The connecting blocks 105 at both ends are connected to the screws 205 on the support blocks 204 at both ends of the fixing shell 203 on the second communication tube body 201. Specifically, one end of each screw 205 passes through the two connecting blocks 105 and extends to the right side of the connecting block 105, and the two screws 205 are threadedly connected to the two connecting blocks 105 respectively. By rotating the screws 205, the distance between the connecting blocks 105 and the support blocks 204 can be adjusted, thereby further bringing the first communication tube body 101 and the second communication tube body 201 closer together, making their connection tighter. Since the two fixing blocks 207 are respectively connected to the two screws... The screw 205 is connected to the fixed block 207. When the screw 205 is rotated, it will drive the fixed block 207 to move. The fixed block 207 is fixedly connected to the compression ring 206. Therefore, the compression ring 206 will move within the fixed shell 203 with the rotation of the screw 205. As the compression ring 206 moves, it will gradually approach and compress the elastic sleeve 104 fixedly connected to the left side of the connecting shell 103. After being compressed by the compression ring 206, the elastic sleeve 104 will undergo elastic deformation and fit tightly around the connection part of the first communication tube body 101 and the second communication tube body 201, thereby strengthening the two communication tube bodies. The sealing and stability of the connection between the two communication pipe bodies are ensured by the engagement of the annular locking block 102 and the annular sleeve 202, which provides initial fixation and prevents the two communication pipe bodies from easily separating after docking. The threaded connection between the screw 205 and the connecting block 105, as well as the squeezing action of the compression ring 206 on the elastic sleeve 104, further fix the two communication pipe bodies from multiple directions. This multi-fixing method greatly enhances the stability of the entire communication pipeline interface, enabling it to withstand greater external forces, such as soil pressure and fluid pressure inside the pipeline, reducing the risk of loosening or falling off at the pipeline interface and ensuring the normal operation of the communication pipeline.
[0036] Example 2
[0037] Please see Figure 1 , Figure 2 , Figure 3 , Figure 4 Furthermore, based on Embodiment 1, the following is further obtained: both the outer and inner sides of the first communication tube body 101 and the second communication tube body 201 are provided with reinforcement mechanisms 3.
[0038] Specifically, the reinforcement mechanism 3 includes a spiral reinforcing rib 301 and an anti-ultraviolet coating.
[0039] Specifically, the inner walls of the first communication tube body 101 and the second communication tube body 201 are both fixedly connected with spiral reinforcing ribs 301, and the outer sides of the first communication tube body 101 and the second communication tube body 201 are both coated with an anti-ultraviolet coating.
[0040] Through the above technical solution, the spiral reinforcing ribs 301 in the reinforcement mechanism 3 are set on the inner walls of the first communication pipe body 101 and the second communication pipe body 201, which can enhance the internal structural strength of the pipe and prevent the pipe from deforming due to internal fluid pressure or external impact during long-term use. The anti-ultraviolet coating is applied to the outside of the pipe, which can effectively resist the corrosion of ultraviolet rays, slow down the aging rate of the pipe material, and extend the service life of the pipe in the outdoor environment.
[0041] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations may be made to these embodiments without departing from the principles and spirit, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A PE communication conduit with an interface, comprising a docking mechanism (1), characterized in that: A fixing mechanism (2) is provided on the left side of the docking mechanism (1); The docking mechanism (1) includes a first communication tube body (101), a ring-shaped locking block (102) is fixedly connected to the left side of the first communication tube body (101), a connecting shell (103) is fixedly connected to the left surface of the first communication tube body (101), an elastic sleeve (104) is fixedly connected to the left side of the connecting shell (103), and connecting blocks (105) are fixedly connected to both the front and rear ends of the outer side of the connecting shell (103). The fixing mechanism (2) includes a second communication tube body (201), a ring sleeve (202) is fixedly connected to the right side of the second communication tube body (201), a fixing shell (203) is fixedly connected to the right surface of the second communication tube body (201), a support block (204) is fixedly connected to both the front and rear ends of the fixing shell (203), a screw (205) is threaded onto both of the support blocks (204), a compression ring (206) is movably connected inside the fixing shell (203), and a fixing block (207) is fixedly connected to both the front and rear ends of the compression ring (206).
2. The PE communication pipe with an interface according to claim 1, characterized in that: The annular sleeve (202) is engaged with the outside of the annular block (102).
3. A PE communication pipe with an interface according to claim 1, characterized in that: One end of each of the two screws (205) passes through the two connecting blocks (105) and extends to the right side of the connecting blocks (105), and the two screws (205) are threadedly connected to the two connecting blocks (105) respectively.
4. A PE communication pipe with an interface according to claim 1, characterized in that: The two fixing blocks (207) are respectively connected to the two screws (205).
5. A PE communication pipe with an interface according to claim 1, characterized in that: The first communication tube body (101) and the second communication tube body (201) are both provided with reinforcement mechanisms (3) on the outer and inner sides.
6. A PE communication pipe with an interface according to claim 5, characterized in that: The reinforcement mechanism (3) includes a spiral reinforcing rib (301) and an anti-ultraviolet coating.
7. A PE communication pipe with an interface according to claim 5, characterized in that: The inner walls of the first communication tube body (101) and the second communication tube body (201) are both fixedly connected with spiral reinforcing ribs (301), and the outer sides of the first communication tube body (101) and the second communication tube body (201) are both coated with an anti-ultraviolet coating.