A netted braided cable harness

By setting annular rings and rotating grooves at both ends of the cable mesh sleeve, combined with rotatable connectors and clamping components, the problems of fixed cable mesh sleeve length and inconvenient maintenance are solved, enabling rapid docking and stable fixation, and improving the flexibility and adaptability of cable protection.

CN224383986UActive Publication Date: 2026-06-19JIANFENG SLING

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANFENG SLING
Filing Date
2025-06-27
Publication Date
2026-06-19

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Abstract

This utility model provides a cable braided rigging system. By incorporating annular rings and recessed rotating grooves at both ends of the cable braid, along with rotatably mounted first and second connectors, the system allows the first and second connectors to rotate relative to the cable braid during connection. This enables rapid connection between multiple cable braids without rotating the braid, improving on-site assembly flexibility and work efficiency, and is particularly suitable for space-constrained construction environments. Furthermore, the combination of the spherical shape and the rotating grooves ensures stable installation of the connectors while providing a certain degree of freedom of movement, which helps mitigate impact loads during traction and enhances the overall reliability of the rigging. Moreover, the annular ring corresponding to the second connector is equipped with a clamping component, which effectively clamps and secures the covered cable or steel rope, preventing slippage or loosening during traction or suspension, thus enhancing safety and stability during use.
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Description

Technical Field

[0001] This utility model relates to the technical field of cable auxiliary equipment, specifically a cable braided rigging. Background Technology

[0002] Cable braided rigging is a sleeve-like structure formed by interlacing several steel wire ropes, primarily used for covering and protecting cables or other strip-shaped objects. In power construction, communication line laying, or hoisting operations, this type of rigging is commonly used for pulling or positioning cables and other components. When in use, the braided rigging is placed over the outer surface of the cable being dragged or pulled to effectively buffer friction and external impacts, preventing damage to the cable surface, and improving service life and construction safety.

[0003] However, most existing cable braided rigging systems are integrally braided with fixed lengths and lack modular and detachable designs. If a section is damaged, the entire cable braided rigging system usually needs to be replaced, resulting in significant material waste. Therefore, it is necessary to provide a cable braided rigging system that is structurally reliable, securely connected, and easy to assemble and replace, to solve the problems of material waste and inconvenient maintenance in existing technologies, and to improve the overall adaptability and performance of the rigging system. Utility Model Content

[0004] To address the shortcomings of existing technologies, this utility model provides a cable braided rigging system that effectively improves upon some traditional cable braided rigging systems, which have fixed lengths, cannot adapt to cables of different lengths, and suffer from inconvenient maintenance and weak connections.

[0005] A cable braided rigging includes several detachably connected cable nets woven from steel wire rope and steel wire rope knots detachably disposed at the ends of the cable nets. Each cable net has an annular ring at both ends, and a rotating groove is recessed from the side of the annular ring away from the cable net towards the side closer to the cable net. A first connector and a second connector are rotatably mounted on the annular rings at both ends of the cable net. The first connector includes a first connector body with a through hole in the middle. Multiple spherical bodies are disposed at the end of the first connector body near the annular ring via a connecting post. The spherical bodies are rotatably disposed within the rotating groove. The connector body has an annular groove recessed from the inner sidewall to the outer sidewall. The first connector body is provided with a locking member. The end of the first connector body away from the annular ring and the end closer to the annular ring are provided with a plug interface that connects to the annular groove. The second connector body includes a second connector body with a through hole in the middle. The end of the second connector body near the annular ring is provided with a plurality of spherical bodies through a connecting post. The spherical bodies are rotatably disposed in the rotating groove. The middle of the outer sidewall of the second connector body is provided with a plurality of connecting rods and a groove that cooperates with the locking member. A clamping component is provided on the annular ring connected to the second connector.

[0006] Preferably, the locking member includes a telescopic shaft, a spherical locking block, and a damping spring. The first connecting member body has a plurality of mounting holes recessed from its inner sidewall to its outer sidewall. The telescopic shaft is connected to the side of the mounting holes near the outer sidewall of the first connecting member body. The spherical locking block is connected to the other end of the telescopic shaft. The spherical locking block protrudes from the mounting holes. The damping spring is sleeved on the outside of the telescopic shaft.

[0007] Furthermore, the diameter of the mounting hole is smaller than the diameter of the spherical block.

[0008] Preferably, the clamping assembly includes a pair of opposing arc-shaped retaining rings, which are fitted into a through hole in the middle of the annular ring. The annular ring has multiple threaded holes, and a tightening bolt is installed in each threaded hole. One end of the tightening bolt connected to the arc-shaped retaining ring is a circular piece. A mounting seat is provided on the side of the arc-shaped retaining ring near the annular ring, and a rotating groove is provided on the mounting seat. The circular piece is rotatably connected to the rotating groove.

[0009] Furthermore, a rubber pad is provided on the side of the arc-shaped retaining ring away from the annular ring.

[0010] Preferably, the steel cable joint includes a mounting lug and a third connector disposed on the mounting lug. The third connector is a columnar connector, and the middle of the outer side wall of the third connector is provided with a plurality of connecting rods and a groove that mates with the locking member.

[0011] Preferably, both the first connector body and the second connector are hollow cylindrical connectors, and the diameter of the through hole in the middle of the hollow cylindrical connector is larger than the diameter of the cable.

[0012] Preferably, the diameter of the through hole in the center of the annular ring is larger than the diameter of the cable.

[0013] Compared with the prior art, the present invention has the following beneficial effects:

[0014] This utility model provides a cable braided rigging system. By incorporating annular rings and recessed rotating grooves at both ends of the cable braid, along with rotatably mounted first and second connectors, the system allows the first and second connectors to rotate relative to the cable braid during connection. This enables rapid connection between multiple cable braids without rotating the braid, improving on-site assembly flexibility and efficiency, and is particularly suitable for construction environments with limited space or complex cable routing paths. Furthermore, the annular rings corresponding to the second connectors are equipped with clamping components, which effectively clamp and fix the cable or steel rope when the cable braid is wrapped, preventing slippage or loosening during traction or suspension, thus enhancing safety and stability during use. Therefore, this cable braided rigging system effectively protects cables, steel ropes, or other strip-shaped objects. Simultaneously, its modular design allows for quick assembly and disassembly of the cable braids through standardized structures, facilitating flexible adjustment of the combined length on-site to meet diverse requirements for cable length and traction force in different projects. This further enhances the system's adaptability and engineering practicality, and allows for timely replacement in case of damage. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of the cable braided rigging described in this utility model;

[0016] Figure 2 This is a schematic diagram of the cross-sectional structure of the first connector and the second connector described in this utility model;

[0017] Figure 3 This is a schematic diagram of the split cross-sectional structure of the first connector and the second connector described in this utility model;

[0018] Figure 4 This is a top view of the first connecting member of this utility model;

[0019] Figure 5 This is a top view of the annular ring described in this utility model.

[0020] Figure 6 This is a schematic diagram of the cross-sectional structure of the annular ring described in this utility model.

[0021] in:

[0022] 10-Cable mesh sleeve, 20-Steel rope knot, 11-Annular ring, 12-Rotating groove, 13-First connector, 14-Second connector, 15-Spherical body, 18-Annular groove, 19-Locking component, 21-Plug-in interface, 22-Connecting rod, 23-Groove, 24-Clamping assembly, 25-Telescopic shaft, 26-Spherical locking block, 27-Damping spring, 28-Mounting hole, 29-Arc-shaped retaining ring, 30-Tightening bolt, 31-Circular piece, 32-Mounting base, 33-Rotating groove. Detailed Implementation

[0023] The embodiments described below are merely some embodiments of this utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without inventive effort are within the scope of protection of this utility model.

[0024] See Figures 1-6 This embodiment provides a cable mesh braiding rigging, including a plurality of detachably connected cable mesh sleeves 10 woven from steel wire rope and steel wire rope knots 20 detachably disposed at the ends of the cable mesh sleeves 10.

[0025] Specifically, each end of the cable mesh sleeve 10 is provided with an annular ring 11. A rotating groove 12 is recessed from the side of the annular ring 11 away from the cable mesh sleeve 10 towards the side closer to the cable mesh sleeve 10. A first connector 13 and a second connector 14 are rotatably mounted on the annular rings 11 at both ends of the cable mesh sleeve 10, respectively. The first connector 13 includes a body with a through hole in the middle. Multiple spherical bodies 15 are provided at the end of the first connector 13 body near the annular ring 11 via a connecting post. The spherical bodies 15 are rotatably disposed within the rotating groove 12. An annular groove 18 is recessed from the inner sidewall towards the outer sidewall of the first connector 13 body. The body of the first connector 13 is provided with a locking member 19. The end of the first connector 13 away from the annular ring 11 and the end closer to the annular ring 11 are provided with an insertion interface 21 that connects to the annular groove 18. The second connector 14 includes a body of the second connector 14 with a through hole in the middle. The end of the body of the second connector 14 close to the annular ring 11 is provided with a plurality of spherical bodies 15 through a connecting post. The spherical bodies 15 are rotatably disposed in the rotating groove 12 of the annular ring 11. The middle of the outer side wall of the body of the second connector 14 is provided with a plurality of connecting rods 22 and a groove 23 that cooperates with the locking member 19. The annular ring 11 connected to the second connector 14 is provided with a clamping assembly 24.

[0026] It should be noted that during use, the cable is inserted from the second connector 14 side of the cable mesh sleeve 10 and exits through the first connector 13 side. Then, several cable mesh sleeves 10 are inserted into the cable as needed to complete the overall coverage. During this process, the first connector 13 and the second connector 14 of two adjacent cable mesh sleeves 10 are connected, and the connecting rod 22 on the outside of the second connector 14 is inserted through the insertion interface 21 of the first connector 13 to reach the annular groove 18. At the same time, since the spherical body 15 can rotate and engage within the rotating groove 12, the first connector 13 and the second connector 14 can rotate. This allows for the connection operation between multiple mesh sleeves without rotating the entire cable mesh sleeve 10 during assembly. Through the rotation of the first connector 13 and the second connector 14, the connecting rod 22 rotates to the middle position of the annular groove 18, that is, no longer directly facing the insertion interface 21. At the same time, the locking member 19 set inside the body of the first connector 13 engages with the groove 23 on the second connector 14, further achieving a quick and secure mechanical connection. After installation, the cable is clamped and locked by the clamping assembly 24 on the annular ring 11 on one side of the second connector 14 to prevent the cable mesh sleeve 10 from slipping or loosening during use. After the cable mesh sleeve 10 is completed, the steel cable knot 20 is connected to the cable mesh sleeve 10 at the end.

[0027] Preferably, the locking member 19 includes a telescopic shaft 25, a spherical locking block 26, and a damping spring 27. The first connecting member 13 body has a plurality of mounting holes 28 recessed from its inner sidewall to its outer sidewall. The telescopic shaft 25 is connected to the side of the mounting hole 28 near the outer sidewall of the first connecting member 13 body. The spherical locking block 26 is connected to the other end of the telescopic shaft 25. The spherical locking block 26 protrudes from the mounting hole 28. The damping spring 27 is sleeved on the outer side of the telescopic shaft 25. When the first connecting member 13 and the second connecting member 14 are mated, the plurality of connecting rods 22 on the outer sidewall of the second connecting member 14 body first penetrate into the insertion interface 21 provided in the first connecting member 13 body, and further reach the annular groove 18. During this process, the annular groove 18 is squeezed into the mounting hole 28. Next, as the first connector 13 and the second connector 14 rotate, the connecting rod 22 on the second connector 14 gradually rotates into the center of the annular groove 18. Simultaneously, when the groove 23 on the second connector 14 aligns with the locking element 19 in the first connector 13, the spherical locking block 26 in the mounting hole 28 automatically pops out under the action of the damping spring 27. Its protruding portion fits perfectly into the groove 23 of the second connector 14, achieving a limiting and locking engagement of the connecting rod 22. Because the shape of the spherical locking block 26 matches the groove 23, the fit is tight, thus achieving a reliable connection between the two connectors and preventing accidental loosening. When it is necessary to disassemble the cable sleeve 10 or replace a section of the sleeve assembly, the first connector 13 and the second connector 14 can be rotated in opposite directions. At this time, the spherical locking block 26 overcomes the elastic force of the damping spring 27 and is pressed into the mounting hole 28, disengaging from the groove 23 of the second connector 14. When the connecting rod 22 is rotated to align with the insertion interface 21, the connecting rod 22 on the second connector 14 can be pulled out along the direction of the insertion interface 21, thereby separating the first connector 13 from the second connector 14 and achieving a quick disassembly operation.

[0028] Alternatively, the locking member 19 may include a threaded insertion hole on the body of the first connector 13 and a locking screw threadedly connected to the threaded insertion hole. In use, the locking screw is screwed into the threaded insertion hole, thereby causing the end of the locking screw to be pushed into the groove 23, thus achieving a reliable connection between the first connector 13 and the second connector 14. Of course, when this structure is configured, both the first connector 13 and the second connector 14 are provided with scales. When the scales are aligned, it means that the groove 23 and the threaded insertion hole are aligned. At this time, screwing in the locking screw can achieve the connection between the locking screw and the groove 23.

[0029] Furthermore, the diameter of the mounting hole 28 is smaller than the diameter of the spherical locking block 26, which can prevent the spherical locking block 26 from dislodging from the mounting hole 28 under force without affecting the elastic extension of the spherical locking block 26, thus ensuring the stability and safety of the locking structure.

[0030] Preferably, the clamping assembly 24 includes a pair of opposing arc-shaped retaining rings 29. The arc-shaped retaining rings 29 are fitted into a through hole in the center of the annular ring 11. The annular ring 11 has multiple threaded holes, and a tightening bolt 30 is installed in each threaded hole. One end of the tightening bolt 30 connected to the arc-shaped retaining ring 29 is a circular piece 31. A mounting base 32 is provided on the side of the arc-shaped retaining ring 29 closest to the annular ring 11. The mounting base 32 has a rotating groove 33, and the circular piece 31 is rotatably connected to the rotating groove 33. In use, when the tightening bolt 30 is tightened, the circular piece 31 rotates within the rotating groove 33 and applies a force to the arc-shaped retaining rings 29 towards the cable, thereby causing the arc-shaped retaining rings 29 at both ends to clamp the cable, thus achieving reliable cable fixation. It should be noted that each arc-shaped retaining ring 29 has a corresponding mounting base 32 at both ends. Furthermore, a rubber pad is provided on the side of the arc-shaped clamping ring 29 away from the annular ring 11 to increase friction and provide flexible protection for the cable surface. The clamping assembly 24 is not only flexible in adjustment but also effectively prevents axial slippage or loosening of the cable during traction, lifting, or vibration, improving safety and reliability during use. It is suitable for fixing cables of various diameters and possesses good versatility and engineering practicality. Most importantly, when only a section of the cable mesh sleeve 10 needs to be connected to the cable, the arc-shaped clamping ring 29, in conjunction with the tightening bolt 30, provides local clamping, achieving stable fixation of the cable to the end of the cable mesh sleeve 10.

[0031] Preferably, the steel cable joint 20 includes a mounting lug and a third connector disposed on the mounting lug. The third connector is a columnar connector, and a plurality of connecting rods 22 and a groove 23 that mates with the locking member 19 are disposed in the middle of the outer side wall of the third connector. When the third connector mates with the second connector 14, the plurality of connecting rods 22 on the third connector can be inserted through the insertion interface 21 provided in the body of the second connector 14. After insertion, the connecting rods 22 are located in the inner groove 23 area of ​​the body of the second connector 14. Subsequently, by rotating the third connector and the second connector 14 relative to each other, the connecting rods 22 are disengaged from the insertion interface 21 and rotated to the middle area of ​​the annular groove 18. At this time, the locking member 19 provided inside the second connector 14 automatically pops out under the action of the damping spring 27, and the spherical locking block 26 is embedded in the groove 23 on the connecting rod 22 of the third connector, thereby completing the locking operation and realizing a stable mechanical connection between the third connector and the second connector 14. The connecting cable joint facilitates dragging and traction operations.

[0032] Preferably, both the first connector 13 and the second connector 14 are hollow cylindrical connectors, and the diameter of the through hole in the middle of the hollow cylindrical connector is larger than the diameter of the cable. Preferably, the diameter of the through hole in the middle of the annular ring 11 is larger than the diameter of the cable. Further, the through hole of the hollow cylindrical connector and the through hole of the annular ring 11 are coaxially aligned, allowing the cable to smoothly pass through one cable sleeve 10 and multiple sleeves without jamming, improving the convenience and continuity of the overall assembly. Since the diameters of the through holes and through holes are larger than the diameter of the cable body, there is a large installation margin during cable installation, which not only facilitates the adaptation of cables with different diameter ranges but also allows for rapid cable threading operations when site conditions are limited or time is tight. In addition, during use, it can reduce the frictional resistance between the cable surface and the inner wall of the cable sleeve 10, reducing losses and wear risks during installation, and further improving the service life and reliability of the cable braided rigging.

[0033] This utility model provides a cable braided rigging system. By providing annular rings 11 and recessed rotating grooves 12 at both ends of the cable braid 10, and cooperating with rotatably mounted first and second connectors 13 and 14, the first and second connectors 13 and 14 can rotate relative to the cable braid 10 during connection. This allows for rapid connection between multiple cable braids 10 without rotating the cable braid 10, improving the flexibility and efficiency of on-site assembly, and is particularly suitable for construction environments with limited space or complex cable routing paths. Furthermore, the annular ring 11 corresponding to the second connector 14 is provided with a clamping component 24, which effectively clamps and fixes the cable or steel rope when the cable braid 10 is wrapped, preventing slippage or loosening during traction or suspension, thus enhancing safety and stability during use. Therefore, this cable braided rigging can protect cables, steel ropes, or other strip-shaped objects. At the same time, the cable braided rigging adopts a modular design, and the cable braids 10 can be quickly assembled and disassembled through a standardized structure, which facilitates flexible adjustment of the combined length on site and meets the diverse needs of different projects for cable length and traction force. This further enhances the adaptability and engineering practicality of the system, and can also be replaced in time when damaged.

[0034] The above-disclosed embodiments are merely some preferred embodiments of the present utility model, and should not be construed as limiting the scope of the present utility model. Therefore, any equivalent changes made in accordance with the scope of the present utility model patent application shall still fall within the scope of the present utility model.

Claims

1. A cable braided rigging system, comprising a plurality of detachably connected cable mesh sleeves woven from steel wire rope and steel wire rope knots detachably disposed at the ends of the cable mesh sleeves, characterized in that, Both ends of the cable mesh sleeve are provided with an annular ring. A rotating groove is recessed on the side of each annular ring away from the cable mesh sleeve, towards the side closer to the cable mesh sleeve. A first connector and a second connector are rotatably mounted on each of the annular rings at both ends of the cable mesh sleeve. The first connector includes a first connector body with a through hole in the middle. Multiple spherical bodies are provided at the end of the first connector body near the annular ring via a connecting post. The spherical bodies are rotatably disposed within the rotating groove. An annular groove is recessed from the inner sidewall to the outer sidewall of the first connector body. The connector body is provided with a locking member. The first connector body has an insertion interface that connects to the annular groove at the end away from the annular ring and the end closer to the annular ring. The second connector body includes a second connector body with a through hole in the middle. At the end of the second connector body near the annular ring, a plurality of spherical bodies are provided through a connecting post. The spherical bodies are rotatably disposed in the rotating groove. The middle of the outer side wall of the second connector body is provided with a plurality of connecting rods and a groove that cooperates with the locking member. A clamping component is provided on the annular ring connected to the second connector.

2. The cable braided rigging as described in claim 1, characterized in that, The locking component includes a telescopic shaft, a spherical locking block, and a damping spring. The first connecting component body has several mounting holes recessed from its inner sidewall to its outer sidewall. The telescopic shaft is connected to one side of the mounting holes near the outer sidewall of the first connecting component body. The spherical locking block is connected to the other end of the telescopic shaft. The spherical locking block protrudes from the mounting holes. The damping spring is sleeved on the outside of the telescopic shaft.

3. The cable braided rigging as described in claim 2, characterized in that, The diameter of the mounting hole is smaller than the diameter of the spherical block.

4. The cable braided rigging as described in claim 1, characterized in that, The clamping assembly includes a pair of opposing arc-shaped retaining rings. The arc-shaped retaining rings are fitted into a through hole in the middle of the annular ring. The annular ring has multiple threaded holes, and a tightening bolt is installed in each threaded hole. One end of the tightening bolt connected to the arc-shaped retaining ring is a circular piece. A mounting base is provided on the side of the arc-shaped retaining ring near the annular ring. The mounting base has a rotating groove, and the circular piece is rotatably connected to the rotating groove.

5. The braided cable rigging as described in claim 4, characterized in that, A rubber pad is provided on the side of the arc-shaped retaining ring away from the annular ring.

6. The braided cable rigging as described in claim 1, characterized in that, The steel cable joint includes a mounting lug and a third connector disposed on the mounting lug. The third connector is a columnar connector, and a plurality of connecting rods and a groove that mates with the locking member are provided in the middle of the outer side wall of the third connector.

7. The cable braided rigging as described in claim 1, characterized in that, Both the first connector body and the second connector are hollow cylindrical connectors, and the diameter of the through hole in the middle of the hollow cylindrical connector is larger than the diameter of the cable.

8. The braided cable rigging as described in claim 1, characterized in that, The diameter of the through hole in the center of the annular ring is larger than the diameter of the cable.