A jet ring cable lacing device for replacing optical cable lacing
By combining the protective cover, spray pump, and drive components, the problem of uneven material surface during interruption in the spray ring cable binding device is solved, achieving uniformity of the spray ring cable binding surface and convenient insertion of optical cables, thus improving utilization and efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SHANTOU HIGH TECH ZONE AOXING OPTICAL COMM EQUIP
- Filing Date
- 2022-11-10
- Publication Date
- 2026-07-14
AI Technical Summary
Existing alternative fiber optic cable bundling devices often result in uneven cut surfaces during the bundling process, requiring additional grinding, increasing work difficulty and procedures, and reducing utilization.
The design incorporates a combination of a protective cover, a spray pump, a material guiding and cutting component, and a drive component. The rotation and position adjustment of the pressure ring are controlled by an electric telescopic rod, a motor, and a gear system, ensuring the neatness of the spray ring cable binding surface and providing convenience during optical cable insertion.
This ensures the uniformity of the surface of the sprayed ring-tied cable, avoids additional grinding, reduces processes, and improves utilization and efficiency.
Smart Images

Figure CN115648669B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of cable binding technology, specifically to a spray ring cable binding device that can replace optical cable binding yarn. Background Technology
[0002] With the advancement of technology, making optical cables "lighter" and "more refined" has become the main direction for research and development and production. Currently, optical cables with "lighter" and "more refined" characteristics generally adopt a dry core structure. Compared with the traditional grease-filled optical cable structure, which uses binding yarn and water-blocking grease, dry structure optical cables use water-blocking binding yarn. The weight of water-blocking binding yarn is lighter, which in turn makes the dry structure optical cable lighter. Moreover, dry structure optical cables do not have water-blocking grease, and the sheath layer of dry structure optical cables is more tightly wrapped with the core. Dry structure optical cables not only meet the water-blocking performance requirements of optical cables, but also effectively save the time of cleaning the joints after stripping the optical cable during construction, improving construction efficiency and being more environmentally friendly.
[0003] Optical cable core stranding typically employs SZ stranding or unidirectional stranding. SZ stranding, also known as left-right stranding, is prone to loosening at the point of left-right switching, requiring re-tying at the exchange point. However, existing re-tying processes are inefficient and costly. To improve efficiency and reduce costs, a replacement for optical cable re-tying devices using spray rings has emerged (see patent number: 202020341459.9). Its features include: an optical cable, a spray ring re-tying mold, and a cooling module. The spray ring re-tying mold includes a mold base and an annular nozzle. The mold base has a horizontal placement hole, with a retaining ring at one end and a cooling module at the other. The annular nozzle passes through the placement hole. Fixed on the mold base, the annular nozzle consists of two symmetrically placed discs. Each disc has a conical protrusion on the side pointing towards the other disc. A spraying gap is provided at the junction of the conical protrusions on the two discs. The outer surfaces of the two conical protrusions and the inner wall of the placement hole form an annular injection cavity. The center of each of the two conical protrusions is provided with a horizontal spray ring hole for passing through the optical cable, and the two horizontal spray ring holes are concentric. The cooling module is provided with a clearance hole concentric with the horizontal spray ring hole. The diameters of the horizontal spray ring hole and the clearance hole are both larger than the outer diameter of the optical cable. A spraying conveying pipe is provided above the mold base. The lower end of the spraying conveying pipe is connected to the annular injection cavity. A pulse control valve is provided on the spraying conveying pipe.
[0004] However, existing alternative fiber optic cable bundling devices often result in uneven cutting surfaces during the bundling process (leading to pulling and unevenness). This necessitates additional grinding of the bundling area after the cable is removed from the equipment, which increases the difficulty of the work, prolongs the process, and reduces the utilization rate. Summary of the Invention
[0005] The purpose of this invention is to solve the problem that existing spray ring binding devices for optical cable binding often result in uneven cutting surfaces during the spray ring binding process, requiring additional grinding of the spray ring binding area after exiting the equipment. This increases the difficulty of the work, prolongs the process, and reduces the utilization rate. The invention provides an alternative spray ring binding device for optical cable binding.
[0006] To achieve the above objectives, the present invention provides the following technical solution: a replacement device for optical cable binding with spray rings, comprising:
[0007] The protective cover is used to protect the cable during the spraying and tying process and to provide corresponding operating space for the spraying and tying of cables.
[0008] The optical cable is located inside the protective shield;
[0009] The spray pump is located on one side of the top of the protective cover;
[0010] The material guiding and cutting component is located inside the protective cover;
[0011] The drive assembly is located inside the protective cover and below the material guiding and cutting assembly;
[0012] The number of the material guiding and cutting components is four, and each of the four material guiding and cutting components includes a spray pipe. The top of the spray pipe is provided with a telescopic tube, and an electric telescopic rod is installed on one side of each telescopic tube. The top of each electric telescopic rod is provided with a connecting rod, and the connecting rod is of a "Z" shape. A pressure ring is provided below each spray pipe. The top of each pressure ring is provided with an arc-shaped groove. A material hole extending to the top of the pressure ring is provided at the middle position inside the arc-shaped groove. Multiple sets of toothed grooves are evenly provided at the bottom of the pressure ring. Each pressure ring includes an upper half and a lower half. Arc-shaped limiting grooves are provided at the top and bottom of both sides of the pressure ring. A sliding block is provided at one end of the top of each arc-shaped groove, and an elastic element is provided at one end of each sliding block.
[0013] As a further embodiment of the present invention: the protective cover has a mold groove inside, and movable plates are provided at the top and bottom of the mold groove. Electric push rods are installed at the four corners of the top of one set of movable plates and the four corners of the bottom of another set of movable plates. The electric push rods are fixedly connected to the top and bottom of the mold groove, respectively. A transverse insertion hole extending to the other side is provided on one side of the adjacent end face of the two sets of movable plates, and the transverse insertion hole is composed of two semi-arcs. A longitudinal insertion hole extending to the top of both the top of the transverse insertion hole and the top of the mold groove is provided. Multiple sets of annular limiting grooves are evenly provided inside the transverse insertion hole, and the annular limiting grooves are all located directly below the longitudinal insertion holes. An arc-shaped protrusion matching the arc groove is provided at the upper rear position inside the annular limiting groove. Multiple sets of limiting blocks matching the arc limiting groove are evenly provided at the top and bottom of both sides of the annular limiting groove. A movable groove is provided below the annular limiting groove, and an installation groove is provided on one side of the movable groove.
[0014] As a further embodiment of the present invention: the driving component includes a motor, the output end of the motor is provided with a first gear, a rotating rod is rotatably connected above the motor, a second gear is sleeved on one side of the rotating rod, the second gear and the motor are both located inside the mounting groove, and the second gear is meshed with the first gear, a rotating disk is provided on the other side of the rotating rod, and multiple sets of locking teeth are evenly arranged on the top of the rotating disk, the rotating disk and the locking teeth are both located inside the movable groove, and the locking teeth are meshed with the tooth groove.
[0015] As a further embodiment of the present invention: both sides of the rotating rod are provided with bearing seats, and bearings are provided inside the bearing seats. Both sides of the rotating rod are rotatably connected to the inner walls of the movable groove and the mounting groove respectively through the mutual cooperation of the bearing seats and the bearings.
[0016] As a further embodiment of the present invention: the top and bottom of the elastic element are both welded to the adjacent end faces of the sliding block and the arc groove via welding blocks.
[0017] As a further embodiment of the present invention: each of the bottom ends of one side of the connecting rod is provided with a docking hole, and the spray pipe is connected to the connecting rod through the docking hole.
[0018] As a further embodiment of the present invention: the top end of one side of the telescopic tube is connected to the output end of the spray pump.
[0019] Compared with the prior art, the beneficial effects of the present invention are:
[0020] 1. The system comprises a protective cover, optical cable, spray pump, material guiding and cutting assembly, and drive assembly. During use, the output end of the electric telescopic rod shortens under electric power, carrying the connecting rod and spray pipe downwards along the longitudinal insertion hole until the discharge end of the spray pipe abuts against the material hole position inside the arc-shaped groove on the pressure ring and adheres to it. Simultaneously, the optical cable extends to the right through the transverse insertion hole, moving the cable tie position to the inner side of the pressure ring. Then, the input end of the spray pump draws the liquid material sequentially through the telescopic tube, spray pipe, and material hole extension inside the pressure ring, filling the end face adjacent to the optical cable in a ring shape (and securing it to the outside of the optical cable in a ring shape). After filling, the motor output end rotates clockwise under electric power, driving the first gear to rotate. Since the first gear meshes with the second gear, the second gear carries the rotating rod, rotating disk, and locking teeth to rotate counterclockwise. Then, due to the locking teeth engaging with the pressure ring... The toothed grooves on the pressure ring engage, generating a pushing force on the pressure ring, causing it to rotate clockwise. Simultaneously, the outlet of the spray pipe is misaligned with the material hole on the pressure ring. The spray pipe then exerts a forward pushing force on the sliding block on the clockwise rotating pressure ring, causing the sliding block to slide along the arc groove and exert a squeezing force on the elastic element, deforming it under stress. At the same time, the arc groove on the rotating pressure ring moves along the outer side of the arc protrusion, thus using the arc protrusion to block the material hole on the inner side of the arc groove on the rotating pressure ring. This prevents the liquid material to be formed inside the pressure ring from seeping out from the end face of the arc groove. This achieves both material cutting and ensures the neatness of the spray ring cable binding surface formed on the inner side of the pressure ring. Therefore, after exiting the equipment, it is not necessary to grind the spray ring cable binding position separately, which reduces the difficulty of the work, reduces the number of processes, and improves the utilization rate.
[0021] 2. Through the setting of the pressure ring, locking teeth, tooth groove, arc-shaped limiting groove, and limiting block, when the locking teeth located outside the rotating disk separate from the tooth groove (the position outside the rotating disk where there are no locking teeth is in contact with the tooth groove), the pressure ring resets under the action of the elastic element. This allows the material hole in the arc-shaped groove on the pressure ring to move back to the end face of the spray pipe outlet and align with it. When the liquid material solidifies, the electric push rod located at the bottom of the mold cavity shortens under the action of electricity and carries the lower movable plate downward. This causes the lower half of the pressure ring to move downward under the action of the limiting block and the arc-shaped limiting groove located on the side of the lower half of the pressure ring. At the same time, the electric push rod located at the top of the mold cavity shortens under the action of electricity. The short, movable plate located at the top moves upward, causing the upper half of the pressure ring to move upward under the action of the limiting block and the arc-shaped limiting groove on the side of the upper half of the pressure ring. This creates a certain gap between the upper and lower halves of the pressure ring, providing sufficient space for the optical cable to be inserted. The optical cable can then move along the transverse insertion hole under the traction of the traction device. At the same time, the lower half of the pressure ring is limited and supported by the arc-shaped limiting groove on its side and the limiting block on the bottom side inside the annular limiting groove, which facilitates the disassembly of the lower half of the pressure ring from the upper half of the pressure ring. This facilitates the separation of the optical cable after the pressure ring and the spray ring are tied together, thereby improving the utilization rate. Attached Figure Description
[0022] Figure 1 This is a schematic diagram of the structure of the present invention;
[0023] Figure 2 This is a partial perspective view of the present invention;
[0024] Figure 3 This is a partial structural diagram of the present invention;
[0025] Figure 4 This is a partial structural schematic diagram of the protective cover of the present invention;
[0026] Figure 5 For the present invention Figure 1 A magnified view of A in the middle.
[0027] In the diagram: 1. Protective cover; 101. Horizontal insertion hole; 102. Annular limiting groove; 103. Arc-shaped protrusion; 104. Movable groove; 105. Mounting groove; 106. Longitudinal insertion hole; 107. Limiting block; 108. Mold groove; 109. Movable plate; 1010. Electric push rod; 2. Optical cable; 3. Spray pump; 4. Material guiding and cutting assembly; 401. Spray pipe; 402. Telescopic pipe; 403. Electric telescopic rod; 404. Connecting rod; 405. Pressure ring; 406. Arc-shaped groove; 407. Sliding block; 408. Elastic element; 409. Gear groove; 4010. Arc-shaped limiting groove; 5. Drive assembly; 501. Motor; 502. First gear; 503. Rotating rod; 504. Second gear; 505. Rotating disk; 506. Clamping tooth. Detailed Implementation
[0028] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0029] In the description of this invention, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicating orientation or positional relationships, are based on the orientation or positional relationships shown in the accompanying drawings and are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance. In the description of this invention, it should be noted that unless otherwise explicitly specified and limited, the terms "installed," "connected," "linked," and "set up" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal communication of two components. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances. The following describes embodiments of the invention based on its overall structure.
[0030] Please see Figures 1-5 In this embodiment of the invention, a replacement for optical cable binding with a spray ring includes:
[0031] Protective cover 1 is used to protect the cable-binding process and provide corresponding operating space for the cable-binding process.
[0032] Optical cable 2 is located inside protective cover 1;
[0033] The spray pump 3 is located on one side of the top of the protective cover 1;
[0034] The material guiding and cutting component 4 is located inside the protective cover 1;
[0035] The drive component 5 is located inside the protective cover 1 and below the material guiding and cutting component 4;
[0036] There are four sets of material guiding and cutting components 4, and each set of material guiding and cutting components 4 includes a spray pipe 401. The top of the spray pipe 401 is provided with a telescopic pipe 402. An electric telescopic rod 403 is installed on one side of each telescopic pipe 402. The top of each electric telescopic rod 403 is provided with a connecting rod 404. The connecting rod 404 is in a "Z" shape. A pressure ring 405 is provided below each spray pipe 401. The top of each pressure ring 405 is provided with an arc shape. The groove 406 has a material hole extending to the top of the pressure ring 405 at the middle position inside the arc-shaped groove 406. The bottom of the pressure ring 405 is evenly provided with multiple sets of toothed grooves 409. The pressure ring 405 includes an upper half and a lower half. The top and bottom of both sides of the pressure ring 405 are provided with arc-shaped limiting grooves 4010. A sliding block 407 is provided at one end of the top of the arc-shaped groove 406. An elastic element 408 is provided at one end of the sliding block 407.
[0037] Please refer to this carefully. Figure 1 and 4The protective cover 1 has a mold groove 108 inside. Movable plates 109 are provided at the top and bottom of the mold groove 108. Electric push rods 1010 are installed at the four corners of the top of one set of movable plates 109 and the four corners of the bottom of the other set of movable plates 109. The electric push rods 1010 are fixedly connected to the top and bottom of the mold groove 108, respectively. A transverse insertion hole 101 extending to the other side is provided on one side of the adjacent end faces of the two sets of movable plates 109. The transverse insertion hole 101 is composed of two semi-circular shapes. A longitudinal insertion hole 106 extending to the top of both the transverse insertion hole 101 and the mold groove 108 is provided. Multiple sets of annular limiting grooves 102 are evenly arranged inside the transverse insertion hole 101. The slots 102 are all located directly below the longitudinal insertion holes 106. An arc-shaped protrusion 103 matching the arc-shaped groove 406 is provided at the upper rear position inside the annular limiting groove 102. Multiple sets of limiting blocks 107 matching the arc-shaped limiting groove 4010 are evenly provided at the top and bottom of both sides inside the annular limiting groove 102. A movable groove 104 is provided below the annular limiting groove 102. An installation groove 105 is provided on one side of the movable groove 104. A damping pad is provided on the inner side of the arc-shaped limiting groove 4010, located at the contact surface adjacent to the limiting block 107 and the arc-shaped limiting groove 4010, thereby increasing the damping force it receives when sliding, and at the same time ensuring that the pressure ring 405 can only move under the action of external force (elastic element 408 and motor 501 driving force).
[0038] Please refer to this carefully. Figure 1 , 2 5. The drive assembly 5 includes a motor 501. The output end of the motor 501 is provided with a first gear 502. A rotating rod 503 is rotatably connected above the motor 501. A second gear 504 is sleeved on one side of the rotating rod 503. The second gear 504 and the motor 501 are both located inside the mounting groove 105, and the second gear 504 is meshed with the first gear 502. A rotating disk 505 is provided on the other side of the rotating rod 503. Multiple sets of locking teeth 506 are evenly arranged on the top of the rotating disk 505. The rotating disk 505 and the locking teeth 506 are both located inside the movable groove 104, and the locking teeth 506 are meshed with the tooth groove 409.
[0039] Please refer to this carefully. Figure 1 , 2 Both sides of the rotating rod 503 are provided with bearing seats, and bearings are provided inside the bearing seats. Both sides of the rotating rod 503 are rotatably connected to the inner walls of the movable groove 104 and the mounting groove 105 respectively through the mutual cooperation of the bearing seats and bearings.
[0040] Please refer to this carefully. Figure 2 and 3The top and bottom of the elastic element 408 are welded to the adjacent end faces of the sliding block 407 and the arc groove 406 respectively through welding blocks.
[0041] Please refer to this carefully. Figure 1 and 2 Each of the bottom ends of one side of the connecting rod 404 is provided with a docking hole, and the spray pipe 401 is connected to the connecting rod 404 through the docking hole.
[0042] Please refer to this carefully. Figure 1 and 2 The top end of one side of the telescopic tube 402 is connected to the output end of the spray pump 3.
[0043] The working principle of this invention is as follows: During use, the output end of the electric telescopic rod 403 shortens under electric power, carrying the connecting rod 404 and the spray pipe 401 downwards along the longitudinal insertion hole 106 until the discharge end of the spray pipe 401 abuts against the material hole position inside the arc-shaped groove 406 on the pressure ring 405 and fits against it. Simultaneously, the optical cable 2 extends to the right through the transverse insertion hole 101, moving the cable tie position to the inner side of the pressure ring 405. Then, the input end of the spray pump 3 draws the liquid material sequentially through the telescopic tube 402, the spray pipe 401, and the inner side of the pressure ring 405 in the material hole extension, filling the end face of the pressure ring 405 adjacent to the optical cable 2 in a ring shape (and tying it to the outside of the optical cable 2 in a ring shape). After filling is complete, the motor 501... The output end rotates clockwise under the action of electricity, driving the first gear 502 to rotate. Since the first gear 502 is meshed with the second gear 504, the second gear 504 can carry the rotating rod 503, the rotating disk 505 and the retaining tooth 506 to rotate counterclockwise. Then, since the retaining tooth 506 is meshed with the tooth groove 409 on the pressure ring 405, it can generate a pushing force on the pressure ring 405, causing the pressure ring 405 to rotate clockwise. At the same time, the outlet of the spray pipe 401 is misaligned with the material hole on the pressure ring 405. Then, the spray pipe 401 generates a forward pressing force on the sliding block 407 on the clockwise rotating pressure ring 405, causing the sliding block 407 to slide along the arc groove 406 and squeeze the elastic element 408. The force causes it to deform under stress. Simultaneously, the arc-shaped groove 406 on the rotating pressure ring 405 moves along the outer side of the arc-shaped protrusion 103. This allows the arc-shaped protrusion 103 to block the material hole inside the arc-shaped groove 406 on the rotating pressure ring 405, preventing the molten material inside the pressure ring 405 from seeping out from the end face of the arc-shaped groove 406. This achieves both material cutting and ensures the neatness of the spray ring and cable-binding surface formed inside the pressure ring 405. Therefore, after exiting the equipment, it is not necessary to grind the spray ring and cable-binding position separately, reducing the difficulty of the work, decreasing the number of processes, and improving utilization. Furthermore, when the locking teeth 506 located outside the rotating disk 505 and the tooth groove 409 are separated... After separation (the position where the locking teeth 506 are not located on the outside of the rotating disk 505 is in contact with the tooth groove 409), the pressure ring 405 resets under the action of the elastic element 408, thereby allowing the material hole in the arc groove 406 on the pressure ring 405 to move back to the end face of the outlet of the spray pipe 401 and align with it. When the locking teeth 506 located on the outside of the rotating disk 505 separate from the tooth groove 409 (the position where the locking teeth 506 are not located on the outside of the rotating disk 505 is in contact with the tooth groove 409), the pressure ring 405 resets under the action of the elastic element 408, thereby allowing the material hole in the arc groove 406 on the pressure ring 405 to move back to the end face of the outlet of the spray pipe 401 and align with it. After the liquid solidifies...The electric push rod 1010, located at the bottom of the mold groove 108, shortens under the action of electricity, carrying the lower movable plate 109 downward. This causes the lower half of the pressing ring 405 to move downward under the action of the limiting block 107 and the arc-shaped limiting groove 4010 on the side of the lower half of the pressing ring 405. Simultaneously, the electric push rod 1010, located at the top of the mold groove 108, shortens under the action of electricity, carrying the upper movable plate 109 upward. This causes the upper half of the pressing ring 405 to move upward under the action of the limiting block 107 and the arc-shaped limiting groove 4010 on the side of the upper half of the pressing ring 405. The upper half of the pressure ring 405 moves upward, creating a gap between the upper and lower halves, providing sufficient space for the insertion of the optical cable 2. The optical cable 2 can then move along the transverse insertion hole 101 under the traction of the traction device. Simultaneously, the lower half of the pressure ring 405 is limited and supported by the arc-shaped limiting groove 4010 on its side and the bottom limiting block 107 located inside the annular limiting groove 102, facilitating its disassembly from the upper half of the pressure ring 405. This facilitates the subsequent separation of the pressure ring 405 from the optical cable 2 after the cable is bundled with the spray ring, thereby improving utilization.
[0044] The above description is merely a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.
Claims
1. A replacement for optical cable binding with spray rings, comprising: The protective cover (1) is used to protect the cable-binding process and to provide the corresponding operating space for the cable-binding process. The optical cable (2) is located inside the protective cover (1); The spray pump (3) is located on one side of the top of the protective cover (1); The material guiding and cutting component (4) is located inside the protective cover (1); The drive assembly (5) is located inside the protective cover (1) and below the material guiding and cutting assembly (4); characterized in that the number of the material guiding and cutting assembly (4) is four sets, and each of the four sets of the material guiding and cutting assembly (4) includes a spray pipe (401), the top of the spray pipe (401) is provided with a telescopic pipe (402), one side of the telescopic pipe (402) is equipped with an electric telescopic rod (403), the top of the electric telescopic rod (403) is provided with a connecting rod (404), the connecting rod (404) is in a "Z" shape, and the bottom of the spray pipe (401) is provided with a pressure ring ( 405), the top of each of the pressing rings (405) is provided with an arc-shaped groove (406), and a material hole extending to the top of the pressing ring (405) is provided at the middle position inside the arc-shaped groove (406). The bottom of the pressing ring (405) is provided with multiple sets of toothed grooves (409). Each pressing ring (405) includes an upper half and a lower half. The top and bottom of both sides of the pressing ring (405) are provided with arc-shaped limiting grooves (4010). One end of the top of each arc-shaped groove (406) is provided with a sliding block (407), and one end of each sliding block (407) is provided with an elastic element (408). A transverse insertion hole (101) extending to the other side is provided at the middle position of one side of the protective cover (1). The top of the transverse insertion hole (101) is provided with a longitudinal insertion hole (106) extending to the top of the protective cover (1). Multiple sets of annular limiting grooves (102) are uniformly arranged inside the transverse insertion hole (101), and the annular limiting grooves (102) are all located directly below the longitudinal insertion hole (106). An arc-shaped protrusion (103) matching the arc groove (406) is provided at the upper rear position inside the annular limiting groove (102). Multiple sets of limiting blocks (107) matching the arc limiting groove (4010) are uniformly arranged at the top and bottom of both sides of the annular limiting groove (102).
2. The alternative optical cable binding ring device according to claim 1, characterized in that, A movable groove (104) is provided below the annular limiting groove (102), and an installation groove (105) is provided on one side of the movable groove (104).
3. The alternative optical cable binding ring device according to claim 1, characterized in that, The drive assembly (5) includes a motor (501), and a first gear (502) is provided at the output end of each motor (501). A rotating rod (503) is rotatably connected above each motor (501). A second gear (504) is sleeved on one side of the rotating rod (503). The second gear (504) and the motor (501) are both located inside the mounting groove (105), and the second gear (504) meshes with the first gear (502). A rotating disk (505) is provided on the other side of the rotating rod (503).
4. The alternative optical cable binding ring device according to claim 3, characterized in that, The top of the rotating disk (505) is uniformly provided with multiple sets of locking teeth (506). The rotating disk (505) and the locking teeth (506) are both located inside the movable groove (104). The locking teeth (506) are all engaged with the tooth groove (409).
5. The alternative optical cable binding ring device according to claim 3, characterized in that, Both sides of the rotating rod (503) are provided with bearing seats, and the bearing seats are provided with bearings. Both sides of the rotating rod (503) are rotatably connected to the inner walls of the movable groove (104) and the mounting groove (105) respectively through the mutual cooperation of the bearing seats and bearings.
6. The alternative optical cable binding ring device according to claim 1, characterized in that, The top and bottom of the elastic element (408) are welded to the adjacent end faces of the sliding block (407) and the arc groove (406) respectively by welding blocks.
7. The alternative optical cable binding ring device according to claim 1, characterized in that, Each of the connecting rods (404) has a docking hole at the bottom of one side, and the spray pipe (401) is connected to the connecting rod (404) through the docking hole.
8. The alternative optical cable binding ring device according to claim 1, characterized in that, The top end of one side of the telescopic tube (402) is connected to the output end of the spray pump (3).