A guidewire collection device

By introducing limiting and pressing structures into the bundling device, combined with adjusting components and a linkage gear ring, the problems of violent jumping and entanglement during guide wire traction are solved, thereby improving the stability and convenience of guide wire traction.

CN118727172BActive Publication Date: 2026-06-05福建省福地新材料股份有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
福建省福地新材料股份有限公司
Filing Date
2024-07-20
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

In existing bundling devices, the guide wire is prone to violent jumping due to strong tension during the guide wire traction process, which can lead to entanglement and affect the stability of subsequent processing.

Method used

The system employs a combination structure of a first limiting bar, a first pressing bar, and a second pressing bar. By limiting and pressing, it reduces the violent jumping of the guide wire. Combined with components such as adjusting parts and linkage gear rings, it adjusts the tension to meet the traction requirements of guide wires made of different materials.

Benefits of technology

It improves the stability of the guidewire traction process, reduces the possibility of entanglement, enhances the adaptability of the structure and ease of operation, and ensures that the guidewire remains taut when the machine is stopped.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN118727172B_ABST
    Figure CN118727172B_ABST
Patent Text Reader

Abstract

The application relates to the technical field of textile processing, and provides a guide yarn bundling device which comprises a bundling frame assembly and a plurality of guide rings. The bundling frame assembly is provided with a plurality of first limiting rods at the rear end of the guide rings, and a threading channel for threading guide yarns is formed between two adjacent first limiting rods. The bundling frame assembly is respectively provided with a first yarn pressing rod and a second yarn pressing rod. The first yarn pressing rod is slidingly installed at the front end of the bundling frame assembly located at the guide rings for pressing the guide yarns. The bundling frame assembly is provided with a first adjusting piece for adjusting the height of the first yarn pressing rod. The second yarn pressing rod is slidingly installed at the rear end of the bundling frame assembly located at the guide rings for pressing the guide yarns. The second yarn pressing rod is provided with two second yarn pressing rods which are respectively located at the front end of the threading channel and the rear end of the threading channel. The bundling frame assembly is provided with a second adjusting piece for adjusting the height of the second yarn pressing rod. The guide yarn bundling device can reduce the jumping amplitude in the guide yarn traction process.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application relates to the technical field of textile processing, and in particular to a yarn guiding and bundling device. Background Technology

[0002] A fiber guide bundler is a device used to gather and integrate multiple fiber guides together. This device is commonly used in industries such as textiles and synthetic fibers to further process or treat the fibers.

[0003] In the prior art, the bundling device includes a bundling frame and guide rings. Multiple guide rings are installed on the bundling frame and are provided to guide the guide yarns output from each front-end hopper to the bundling frame. The multiple guide yarns are respectively passed through different guide rings of the bundling frame, and then the multiple guide yarns are connected to a traction device. The traction device pulls the multiple guide yarns together to the next processing station for textile processing. The multiple guide rings can separate the multiple guide yarns, reduce the possibility of the multiple guide yarns getting tangled together during the traction process, and improve the stability of the guide yarn traction process.

[0004] However, in such bundled devices, although multiple guide rings can separate multiple guide wires and prevent them from tangling to some extent, when the traction speed of the guide wires by the rear traction device reaches a certain value, the guide wires are prone to violent jumping under the strong tension. The violent jumping causes multiple guide wires to entangle with each other during the traction process, which causes inconvenience to subsequent processing. Therefore, further improvements are needed. Summary of the Invention

[0005] To reduce the jumping amplitude during the guidewire traction process, this application provides a guidewire bundling device.

[0006] The guide wire bundling device provided in this application adopts the following technical solution:

[0007] A guide wire bundling device includes a bundling frame assembly and a plurality of guide rings mounted on the bundling frame assembly. The bundling frame assembly has a plurality of first limiting rods located at the rear end of the guide rings, arranged sequentially, with a passage channel formed between adjacent first limiting rods for the guide wire to pass through. The bundling frame assembly is respectively provided with a first pressure rod and a second pressure rod. The first pressure rod is slidably mounted on the front end of the bundling frame assembly located on the guide ring to press against the guide wire. The bundling frame assembly is provided with a first adjusting member for adjusting the height of the first pressure rod. The second pressure rod is slidably mounted on the rear end of the bundling frame assembly located on the guide ring to press against the guide wire. Two second pressure rods are provided, located at the front end and rear end of the passage channel, respectively. The bundling frame assembly is provided with a second adjusting member for adjusting the height of the second pressure rod.

[0008] By adopting the above technical solution, the guide wire output from the hopper is sequentially threaded through the guide ring and the threading channel via the first limiting bar, the first pressing bar, and the second pressing bar, and is used to connect to the traction device. The two adjacent first limiting bars can limit the guide wire in the horizontal direction, reducing the amplitude of violent jumping in the horizontal direction during the guide wire traction process. At the same time, during the guide wire traction process, the first pressing bar and the second pressing bar press the guide wire, thereby limiting the guide wire in the vertical direction and reducing the amplitude of violent jumping in the vertical direction during the guide wire traction process. This greatly improves the stability of the guide wire traction process and reduces the possibility of multiple guide wires becoming entangled. When it is necessary to adjust the tension of the guide wire traction, it is adjusted by the first adjusting member and the second adjusting member to adjust the height of the first pressing bar and the second pressing bar, thereby adjusting the tension of the guide wire during traction, adapting to the traction of guide wires of different materials, and improving the adaptability of the overall structure.

[0009] Optionally, the bundle frame assembly has two first mounting strips on the side wall at the front end of the guide ring, and multiple guide rings are located between the two first mounting strips. The first mounting strip has a first sliding groove, and the two ends of the first sliding groove extend along the height direction. The two ends of the first wire pressing rod are respectively slidably inserted into the first sliding grooves of the two first mounting strips. The first adjusting member includes two wing nuts, and the two wing nuts are respectively inserted into the two ends of the first wire pressing rod and threadedly connected to the first wire pressing rod.

[0010] By adopting the above technical solution, the first pressure bar is slidably installed on the bundle frame assembly through two first mounting strips by setting the wing nut, so that it can be raised and lowered. By tightening and loosening the wing nut, the height of the first pressure bar can be adjusted, thereby adjusting the clamping force on the guide wire. The wing nut makes it easy for the operator to tighten and loosen the first pressure bar without the need for wrenches or other auxiliary tools.

[0011] Optionally, the first adjusting component includes a drive gear, a drive rack, and a drive rod. The drive gear is rotatably mounted on the cluster frame assembly, and the drive rack is slidably mounted on the cluster frame assembly. The drive rack is connected to the first pressure bar and meshes with the drive gear for transmission. The cluster frame assembly has multiple memory holes on its side wall near the drive gear. The multiple memory holes are arranged at intervals around the central axis of the drive gear. The drive gear has through holes, and the drive rod passes through the through holes and memory holes in sequence and is threadedly connected to the through holes.

[0012] By adopting the above technical solution, through the configuration of the drive gear, drive rack, and drive rod, when adjusting the height of the first pressure bar, the drive rod is threaded into the through hole, and then the drive rod drives the drive gear to rotate. The drive gear drives the first pressure bar to slide through the drive rack, thereby adjusting the height of the first pressure bar and improving the convenience of adjusting the height of the first pressure bar. After the position of the first pressure bar is adjusted, the drive rod is rotated to insert the drive rod into the memory hole, thereby restricting the free rotation of the drive gear and fixing the position of the first pressure bar. By setting multiple memory holes, the drive rod can be inserted into different memory holes, allowing the first pressure bar to move to different heights. With the help of the position of the memory holes, the operator can quickly move the first pressure bar to the required height, greatly improving the operational convenience of the overall structure.

[0013] Optionally, the second pressure bar located at the front end of the threading channel presses against the upper surface of the guide wire, and the second pressure bar located at the rear end of the threading channel presses against the lower surface of the guide wire. The bundle frame assembly is rotatably mounted with a rotating disk, and both second pressure bars are connected to the rotating disk, with the two second pressure bars arranged at intervals around the central axis of the rotating disk. The second adjusting component includes a linkage gear ring and a linkage rack. The linkage gear ring is coaxially connected to the outer peripheral wall of the rotating disk, and the linkage rack is slidably mounted on the bundle frame assembly. The linkage rack and the linkage gear ring, as well as the linkage rack and the drive gear, are engaged for transmission.

[0014] By adopting the above technical solution, through the setting of the linkage gear ring and linkage rack, during the process of adjusting the height of the first pressure bar by the drive gear, the drive gear drives the linkage gear ring to rotate synchronously under the action of the linkage rack, thereby driving the rotating disk to rotate synchronously, so as to drive the two second pressure bars to rotate around the central axis of the rotating disk, thereby simultaneously adjusting the height of the two second pressure bars to adjust the tension of the guide wire, thereby reducing the possibility of violent jumping during the guide wire traction process and improving the overall ease of operation.

[0015] Optionally, the rotating disk has two rotating grooves, and the two rotating grooves are correspondingly arranged with two second pressure rods. One end of each second pressure rod passes through the corresponding rotating groove, and a bearing is provided between the second pressure rod and the inner wall of the corresponding rotating groove.

[0016] By adopting the above technical solution, through the setting of bearings, the guide wire passes through the second pressure bar located at the front end of the threading channel and then passes through the threading channel. After passing the first pressure bar located at the rear end of the threading channel, it is led to the traction device. When the traction device pulls the guide wire, the two pressure bars can rotate around their own central axis to reduce the friction between the second pressure bar and the guide wire, thereby reducing the resistance of the guide wire traction.

[0017] Optionally, the cluster frame assembly is rotatably mounted with multiple rotating disks, and the multiple rotating disks are correspondingly arranged with multiple first limiting rods. Each first limiting rod is vertically mounted on the corresponding rotating disk. Each rotating disk is vertically mounted with a second limiting rod. The first and second limiting rods are arranged at intervals around the rotation axis of the rotating disk. A rotating assembly is provided between the rotating disks and the multiple rotating disks. When the rotating disks rotate, the rotating assembly drives the multiple rotating disks to rotate synchronously to adjust the size of the passage.

[0018] By adopting the above technical solution, and by setting up a rotating disk and a second limiting bar, when the height of the two second pressure bars is adjusted by the rotating disk to adjust the clamping force on the guide wire, the rotating disk drives multiple rotating disks to rotate synchronously through the rotating assembly, so that the two adjacent first limiting bars move closer or further away from each other, and the two adjacent second limiting bars move closer or further away from each other, so as to simultaneously adjust the size of all the through-channels, thereby adjusting the limiting effect of the limiting bars on the guide wire in the horizontal direction, and adapting to guide wires of different materials passing through the through-channels.

[0019] Optionally, the cluster frame assembly is rotatably mounted with a rotating shaft. The rotating component includes a driven gear, a driven gear ring, and a rotating element. The driven gear is coaxially connected to the rotating shaft. Multiple driven gear rings are provided and correspondingly arranged with multiple rotating disks. Each driven gear ring is coaxially connected to the outer peripheral wall of the corresponding rotating disk. The driven gear rings of two adjacent rotating disks mesh and drive each other. The driven gear of the rotating shaft meshes and drives the driven gear ring of one of the rotating disks. The rotating element is disposed between the rotating disk and the rotating shaft to drive the rotating disk and the rotating shaft to rotate synchronously.

[0020] By adopting the above technical solution, through the setting of driven gear, driven gear ring and rotating parts, during the rotation of the rotating disk, the rotating disk drives the rotating shaft to rotate synchronously through the rotating parts, so as to drive the driven gear to rotate synchronously, and then under the action of the driven gear ring, drive all rotating disks to rotate synchronously, which greatly improves the convenience of adjusting the size of the passage.

[0021] Optionally, the first and second limiting rods are rotatably mounted on the corresponding rotating disks. The rotating shaft is provided with an anti-rotation component. When two adjacent first limiting rods or two adjacent second limiting rods approach each other and press against the guide wire, the anti-rotation component presses against the first and second limiting rods to restrict the free rotation of the first and second limiting rods.

[0022] By adopting the above technical solution, and through the setting of the anti-rotation component, the first and second limiting rods are rotatably installed on the corresponding rotating disks. When the guide wire is inserted into the insertion channel, and the guide wire contacts the first or second limiting rod, the first or second limiting rod can rotate under the action of the guide wire to reduce the resistance of the guide wire traction. When the machine is stopped (i.e., when the traction device stops traction on the guide wire), all rotating disks are driven to rotate synchronously, forcing two adjacent first limiting rods or two adjacent second limiting rods to approach each other and press against the guide wire to clamp it. At this time, the anti-rotation component can press against the first and second limiting rods to restrict their free rotation, so that the guide wire can be kept taut when the machine is stopped, avoiding the possibility of the guide wire becoming loose when the machine is stopped, so that the traction device can smoothly traction the guide wire when the machine is restarted next time.

[0023] Optionally, one end of the first limiting rod and the second limiting rod are both inserted through the rotating disk and extend to the bottom of the rotating disk. The anti-rotation assembly includes an abutment strip and a rotating screw. The abutment strip is slidably installed on the cluster frame assembly and located at the bottom of all rotating disks. The rotating screw is coaxially fixed to the rotating shaft. The rotating screw passes through the abutment strip and is threadedly connected to the abutment strip. When the rotating shaft rotates, forcing two adjacent first limiting rods or two adjacent second limiting rods to approach each other and press against the guide wire, the abutment strip simultaneously presses against all first limiting rods and all second limiting rods.

[0024] By adopting the above technical solution, through the setting of the abutment bar and the rotating screw, when the traction device stops, the rotating shaft drives all the rotating disks to rotate simultaneously, so as to force the two adjacent first limit bars or the two adjacent second limit bars to approach each other and abut against the guide wire. During the rotation of the rotating shaft, the rotating screw is driven to rotate synchronously, thereby forcing the abutment bar to rise, so as to abut against all the first limit bars and all the second limit bars at the same time, restricting the free rotation of the first limit bars and the second limit bars, so that the two adjacent first limit bars or the two adjacent second limit bars can better clamp the guide wire, so that the guide wire is in a taut state when the machine is stopped, so that the traction device can better pull the guide wire when it is restarted next time.

[0025] Optionally, the cluster frame assembly has a movable slot, with both ends of the movable slot extending horizontally. Each guide ring has a movable block on its outer side, and the movable block is slidably installed in the movable slot. The guide ring is slidably installed in the cluster frame assembly through the movable block.

[0026] In summary, this application includes at least one of the following beneficial technical effects:

[0027] 1. With the setting of the first limiting bar, the first pressing bar, and the second pressing bar, the guide wire output from the hopper is sequentially passed through the guide ring and the passing channel and used to connect to the traction device. The two adjacent first limiting bars can limit the guide wire in the horizontal direction, reducing the amplitude of violent jumping in the horizontal direction during the guide wire traction process. At the same time, during the guide wire traction process, the first pressing bar and the second pressing bar press the guide wire, thereby limiting the guide wire in the vertical direction, reducing the amplitude of violent jumping in the vertical direction during the guide wire traction process, greatly improving the stability of the guide wire traction process, and reducing the possibility of multiple guide wires getting tangled together. When it is necessary to adjust the tension of the guide wire traction, it is adjusted by the first adjusting member and the second adjusting member respectively, so as to adjust the height of the first pressing bar and the second pressing bar, thereby adjusting the tension of the guide wire during traction, adapting to the traction of guide wires of different materials, and improving the adaptability of the overall structure.

[0028] 2. By setting up a linkage gear ring and linkage rack, during the process of adjusting the height of the first pressure bar by the drive gear, the drive gear drives the linkage gear ring to rotate synchronously under the action of the linkage rack, thereby driving the rotating disk to rotate synchronously, so as to drive the two second pressure bars to rotate around the central axis of the rotating disk, thereby simultaneously adjusting the height of the two second pressure bars to adjust the tension of the guide wire, thereby reducing the possibility of violent jumping during the guide wire traction process and improving the overall ease of operation of the structure;

[0029] 3. By setting the anti-rotation component, both the first and second limiting rods are rotatably mounted on their respective rotating disks. When the guide wire is inserted into the insertion channel, and the guide wire contacts the first or second limiting rod, the first or second limiting rod can rotate under the action of the guide wire to reduce the resistance of the guide wire traction. When the machine is stopped (i.e., when the traction device stops traction on the guide wire), all rotating disks are driven to rotate synchronously, forcing two adjacent first limiting rods or two adjacent second limiting rods to approach each other and press against the guide wire to clamp it. At this time, the anti-rotation component can press against the first and second limiting rods to restrict their free rotation, so that the guide wire can be kept taut when the machine is stopped, avoiding the possibility of the guide wire becoming loose when the machine is stopped, so that the traction device can smoothly traction the guide wire when the machine is restarted. Attached Figure Description

[0030] Figure 1 This is a schematic diagram of the overall structure of Example 1;

[0031] Figure 2 This is a schematic diagram illustrating the structure of the guide ring in Example 1;

[0032] Figure 3 This is a schematic diagram illustrating the structure of the first adjusting member in Embodiment 1;

[0033] Figure 4 This is a partial cross-sectional view of Example 1 showing two second pressure rods;

[0034] Figure 5 This is a schematic diagram of the overall structure of Example 2;

[0035] Figure 6 yes Figure 5 Enlarged view of point A in the middle;

[0036] Figure 7 This is a partial cross-sectional view of the rotating disk in Embodiment 2;

[0037] Figure 8 This is a partial cross-sectional view of Embodiment 3 illustrating the rotating assembly and the anti-rotation assembly;

[0038] Figure 9 This is a partial cross-sectional view of the second limiting bar in Embodiment 3;

[0039] Figure 10 This is a partial cross-sectional view of Embodiment 3 showing two adjacent first limiting rods pressed against the guide wire.

[0040] Explanation of reference numerals in the attached drawings: 1. Bundle frame assembly; 11. First mounting strip; 111. First sliding groove; 12. Memory hole; 13. Rotating shaft; 14. Moving groove; 15. Second mounting strip; 151. Second sliding groove; 16. Mounting groove; 2. Guide ring; 21. Moving block; 3. First limiting rod; 31. Through-hole; 4. First pressure rod; 41. First adjusting component; 411. Wing nut; 412. Drive gear; 413. Drive rack; 414. Drive rod; 415. Through hole; 5. Second pressure bar; 51. Second adjusting component; 511. Linkage gear ring; 512. Linkage rack; 6. Rotating disk; 61. Bearing; 62. Rotating rod; 7. Rotating disk; 71. Second limit bar; 72. Rotating rod; 8. Rotating assembly; 81. Driven gear; 82. Driven gear ring; 83. First bevel gear; 84. Second bevel gear; 9. Anti-rotation assembly; 91. Abutment bar; 92. Rotating screw. Detailed Implementation

[0041] The following is in conjunction with the appendix Figure 1 -Appendix Figure 10 This application will be described in further detail.

[0042] Example 1:

[0043] This application discloses a guide wire bundling device.

[0044] Reference Figure 1 , Figure 2A wire bundling device includes a bundling frame assembly 1 and multiple guide rings 2. The multiple guide rings 2 are all installed on the bundling frame assembly 1. The guide wires output from the hopper are used to pass through the guide rings 2 and lead to the traction device (the hopper and traction device are not shown in the figure). The bundling frame assembly 1 has multiple moving slots 14, which are arranged at intervals along the height direction. Both ends of each moving slot 14 are extended in the horizontal direction. The multiple guide rings 2 are respectively installed in the multiple moving slots 14. A moving block 21 is fixedly installed on the outer peripheral wall of each guide ring 2. The moving block 21 is slidably installed on the corresponding moving slot 14 so that it can slide freely along the length direction of the moving slot 14. The guide ring 2 is slidably installed on the bundling frame assembly 1 through the moving block 21.

[0045] Reference Figure 1 The cluster frame assembly 1 is located at the rear end of the guide ring 2 (i.e., the side of the guide ring 2 near the traction device) and is equipped with multiple first limiting rods 3. The multiple first limiting rods 3 are all vertically arranged. In this embodiment, the lower end face of the first limiting rod 3 is fixedly installed on the cluster frame assembly 1. The multiple first limiting rods 3 are arranged in sequence, and adjacent two first limiting rods 3 are spaced apart to form a through-passing channel 31 for the guide wire to pass through. The multiple first limiting rods 3 form multiple through-passing channels 31.

[0046] Reference Figure 1 , Figure 3 Two first mounting strips 11 are fixedly installed on the side wall at the front end of the guide ring 2 (i.e., the side of the guide ring 2 away from the traction device). Both first mounting strips 11 are vertically arranged, and multiple guide rings 2 are located between the two first mounting strips 11. Each first mounting strip 11 has a first sliding groove 111. The two ends of the first sliding groove 111 extend along the height direction. Multiple first pressure rods 4 are slidably installed between the two first mounting strips 11. The number of first pressure rods 4 corresponds to the number of moving grooves 14. The first pressure rods 4 are horizontally arranged. The two ends of the first pressure rods 4 are slidably inserted into the first sliding grooves 111 of the two first mounting strips 11 so as to be able to rise and fall. The first pressure rods 4 are slidably installed on the front end of the bundle frame assembly 1 at the guide ring 2 through the two first mounting strips 11 to press the guide wire.

[0047] Reference Figure 1 , Figure 4Two second mounting strips 15 are fixedly installed at the rear end of the guide ring 2 in the bundle frame assembly 1. Both second mounting strips 15 are vertically arranged. Each second mounting strip 15 has a second sliding groove 151. The two ends of the second sliding groove 151 extend along the height direction. A second pressure rod 5 is installed between the two second mounting strips 15. The second pressure rod 5 is horizontally arranged. The two ends of the second pressure rod 5 slide through the second sliding grooves 151 of the two second mounting strips 15 to be able to rise and fall. The second pressure rod 5 is slidably installed at the rear end of the bundle frame assembly 1 at the guide ring 2 through the two second mounting strips 15 to press the guide wire.

[0048] In this embodiment, there are two second pressure rods 5, which are respectively distributed at the front end of the through-channel 31 (i.e., the side of the through-channel 31 close to the guide ring 2) and the rear end of the through-channel 31 (i.e., the side of the through-channel 31 away from the guide ring 2); the second pressure rod 5 located at the front end of the through-channel 31 presses against the upper surface of the guide wire, and the second pressure rod 5 located at the rear end of the through-channel 31 presses against the lower surface of the guide wire.

[0049] Reference Figure 1 , Figure 3 The bundle frame assembly 1 is provided with a first adjusting member 41 for adjusting the height of the first pressing rod 4 and a second adjusting member 51 for adjusting the height of the second pressing rod 5. In this embodiment, the structure of the first adjusting member 41 and the structure of the second adjusting member 51 are the same. The following description takes the structure of the first adjusting member 41 as an example. The structure of the second adjusting member 51 can be obtained in the same way. The first adjusting member 41 includes two wing nuts 411. The two wing nuts 411 are respectively inserted through both ends of the first pressing rod 4 and threadedly connected to the first pressing rod 4.

[0050] The implementation principle of Embodiment 1 of this application is as follows: the guide wire output from the hopper is sequentially passed through the guide ring 2 and the through channel 31 and used to connect the traction device. The two adjacent first limiting rods 3 can limit the guide wire in the horizontal direction, and the first pressure rod 4 and the second pressure rod 5 can limit the guide wire in the vertical direction, thereby reducing the amplitude of violent jumping during the guide wire traction process, greatly improving the stability of the guide wire traction process, and reducing the possibility of multiple guide wires getting tangled together.

[0051] The height of the first pressure bar 4 or the second pressure bar 5 can be adjusted by using the wing nut 411, thereby adjusting the tension during wire traction, adapting to wire traction of different materials, and improving the adaptability of the overall structure.

[0052] Example 2:

[0053] This application discloses a guide wire bundling device.

[0054] Reference Figure 5 , Figure 6 The difference between the guide wire bundling device disclosed in this application and Embodiment 1 is that:

[0055] In this embodiment, the first adjusting member 41 includes a driving gear 412, a driving rack 413, and a driving rod 414. The driving gear 412 is rotatably mounted on the side wall of the bundle frame assembly 1. The two ends of the driving rack 413 extend along the height direction. One end of all the first pressure rods 4 is fixedly connected to the driving rack 413. The driving rack 413 is slidably mounted on the bundle frame assembly 1 through multiple first pressure rods 4. The driving rack 413 and the driving gear 412 mesh and transmit power.

[0056] Reference Figure 5 , Figure 6 The cluster frame assembly 1 has multiple memory holes 12 on its side wall near the drive gear 412. The multiple memory holes 12 are arranged at intervals around the central axis of the drive gear 412. The drive gear 412 has a through hole 415. The drive rod 414 passes through the through hole 415 and the memory holes 12 in sequence and is threadedly connected to the through hole 415.

[0057] Reference Figure 5 , Figure 7 In this embodiment, the cluster frame assembly 1 is equipped with a rotating disk 6, which is located at the rear end of the guide ring 2. There are two rotating disks 6, and two second pressure rods 5 are located between the two rotating disks 6. Each rotating disk 6 is fixedly equipped with a rotating rod 62. One end of the rotating rod 62 is coaxially fixed to the corresponding rotating disk 6, and the other end is rotatably installed on the cluster frame assembly 1. The rotating disk 6 is rotatably installed on the cluster frame assembly 1 through the rotating rod 62. The two ends of the second pressure rod 5 are respectively connected to the two rotating disks 6. It should be noted that the two second pressure rods 5 are arranged at intervals around the central axis of the rotating disk 6.

[0058] Reference Figure 5 , Figure 7 The rotating disk 6 has two rotating grooves, which are corresponding to two second pressure rods 5. One end of the second pressure rod 5 passes through the corresponding rotating groove, and a bearing 61 is installed between the second pressure rod 5 and the inner wall of the corresponding rotating groove. This design allows the second pressure rod 5 to revolve around the central axis of the rotating rod 62 and rotate around its own central axis.

[0059] Reference Figure 5 , Figure 6In this embodiment, the second adjusting member 51 includes a linkage gear ring 511 and a linkage rack 512. The linkage gear ring 511 is coaxially fixed to the outer peripheral wall of one of the rotating disks 6. The linkage rack 512 is slidably installed on the bundle frame assembly 1. The two ends of the linkage rack 512 extend horizontally. The linkage rack 512 and the linkage gear ring 511 are meshed and transmitted, and the linkage rack 512 and the drive gear 412 are also meshed. The linkage rack 512 and the drive rack 413 are misaligned along the axial direction of the drive gear 412.

[0060] The implementation principle of Embodiment 2 of this application is as follows: the drive rod 414 is threaded to the through hole 415, and then the drive gear 412 is driven to rotate by the drive rod 414. The drive gear 412 drives the first pressure bar 4 to slide through the drive rack 413. During the rotation of the drive gear 412, under the action of the linkage gear ring 511 and the linkage rack 512, the rotating disk 6 rotates synchronously with the drive gear 412, thereby driving the two second pressure bars 5 to rotate around the central axis of the rotating rod 62, so as to synchronously adjust the height of the first pressure bar 4 and the two second pressure bars 5, thereby adjusting the tension during the guide wire traction process, reducing the possibility of violent jumping during the guide wire traction process, and improving the operational convenience of the overall structure.

[0061] By setting multiple memory holes 12, on the one hand, when the drive rod 414 is inserted into the memory hole 12, the drive rod 414 can be fixed, restricting the free rotation of the drive gear 412, thereby fixing the position of the first pressure rod 4 and the second pressure rod 5; on the other hand, when changing guide wires of different materials, different tension forces are required during the traction process of guide wires of different materials. The height of the first pressure rod 4 and the two second pressure rods 5 can be quickly adjusted through the memory holes 12, improving work efficiency.

[0062] Example 3:

[0063] This application discloses a guide wire bundling device.

[0064] Reference Figure 8 , Figure 9 The difference between the guide wire bundling device disclosed in this application and Embodiment 2 is that:

[0065] In this embodiment, the cluster frame assembly 1 has an installation groove 16, in which multiple rotating disks 7 are installed. The bottom wall of each rotating disk 7 is coaxially fixed with a rotating rod 72. The rotating rod 72 is rotatably installed on the bottom wall of the installation groove 16, and the rotating disk 7 is rotatably installed on the cluster frame assembly 1 through the rotating rod 72. The multiple rotating disks 7 are correspondingly arranged with multiple first limiting rods 3. Each first limiting rod 3 is vertically installed on the corresponding rotating disk 7, and the first limiting rod 3 is rotatably installed on the cluster frame assembly 1 through the rotating disk 7.

[0066] Reference Figure 8 , Figure 9 , Figure 10 Each rotating disk 7 is vertically mounted with a second limiting rod 71. The first limiting rod 3 and the second limiting rod 71 are arranged at intervals around the rotation axis of the rotating disk 7. A rotating assembly 8 is provided between the rotating disk 6 and the multiple rotating disks 7. When the rotating disk 6 rotates, the rotating assembly 8 drives the multiple rotating disks 7 to rotate synchronously to adjust the size of the passage 31.

[0067] Reference Figure 8 , Figure 9 A rotating shaft 13 is rotatably mounted on the bottom wall of the mounting groove 16. The rotating shaft 13 is vertically arranged. The rotating assembly 8 includes a driven gear 81, a driven gear ring 82, and a rotating component. The driven gear 81 is coaxially connected to the rotating shaft 13. Multiple driven gear rings 82 are provided, and multiple driven gear rings 82 are correspondingly arranged with multiple rotating disks 7. Each driven gear ring 82 is coaxially fixed to the outer peripheral wall of the corresponding rotating disk 7. The driven gear rings 82 of two adjacent rotating disks 7 mesh and drive each other. The driven gear 81 of the rotating shaft 13 meshes and drives one of the driven gear rings 82 of the rotating disk 7.

[0068] Reference Figure 8 A rotating component is disposed between the rotating disk 6 and the rotating shaft 13 to drive the rotating disk 6 and the rotating shaft 13 to rotate synchronously. The rotating component includes a first bevel gear 83 and a second bevel gear 84. The first bevel gear 83 is coaxially fixed to the outer peripheral wall of the rotating rod 62 of the rotating disk 6, and the second bevel gear 84 is coaxially fixed to the outer peripheral wall of one end of the rotating shaft 13. The first bevel gear 83 and the second bevel gear 84 mesh and transmit power.

[0069] Reference Figure 8 , Figure 9 , Figure 10 In this embodiment, the first limiting rod 3 and the second limiting rod 71 are both rotatably mounted on the corresponding rotating disk 7 (that is, the first limiting rod 3 can revolve around the central axis of the rotating rod 72 and rotate around its own central axis). The lower ends of the first limiting rod 3 and the second limiting rod 71 are both inserted through the rotating disk 7 and extend to the bottom of the rotating disk 7. The rotating shaft 13 is provided with an anti-rotation component 9. When two adjacent first limiting rods 3 or two adjacent second limiting rods 71 ​​approach each other and abut against the guide wire, the anti-rotation component 9 abuts against the first limiting rod 3 and the second limiting rod 71 to restrict the free rotation of the first limiting rod 3 and the second limiting rod 71.

[0070] Reference Figure 8 , Figure 9The anti-rotation assembly 9 includes an abutment strip 91 and a rotating screw 92. The abutment strip 91 is slidably installed on the cluster frame assembly 1 and located at the bottom of all rotating disks 7. The shape of the abutment strip 91 is adapted to the shape of the mounting groove 16. The abutment strip 91 has multiple clearance grooves for avoiding the rotating rod 72 (not shown in the figure). The upper end of the rotating screw 92 is coaxially fixed to the rotating shaft 13, and the lower end of the rotating screw 92 is rotatably installed on the bottom wall of the mounting groove 16. The rotating shaft 13 is rotatably installed in the mounting groove 16 through the rotating screw 92. The rotating screw 92 passes through the abutment strip 91 and is threadedly connected to the abutment strip 91 (the thread of the rotating screw 92 is not shown in the figure). When the rotating shaft 13 rotates, it forces two adjacent first limiting rods 3 or two adjacent second limiting rods 71 ​​to approach each other and press against the guide wire. At the same time, the abutment strip 91 presses against all the first limiting rods 3 and all the second limiting rods 71.

[0071] The implementation principle of Embodiment 3 of this application is as follows: the second pressure rod 5 is rotatably installed on the rotating disk 6, and the first limiting rod 3 and the second limiting rod 71 are rotatably installed on the rotating disk 7, so that during the traction process of the guide wire, the second pressure rod 5, the first limiting rod 3 and the second limiting rod 71 can all rotate around their own central axis, so as to reduce the friction during the traction process of the guide wire and improve the traction effect.

[0072] When changing to guide wires of different materials for traction, the drive gear 412 adjusts the height of the first pressure bar 4, and simultaneously drives the rotating disk 6 and all rotating disks 7 to rotate synchronously, thereby synchronously adjusting the positions of the first pressure bar 4, the second pressure bar 5 and the first limit bar 3, thereby adjusting the tension force during the traction process of the guide wire.

[0073] By setting the second limiting bar 71, when the machine is stopped (i.e., when the traction device stops traction on the guide wire), all rotating disks 7 are driven to rotate synchronously, forcing two adjacent first limiting bars 3 or two adjacent second limiting bars 71 to approach each other and press against the guide wire to clamp it. At this time, the abutting bar 91 can press against the first limiting bar 3 and the second limiting bar 71 to restrict the free rotation of the first limiting bar 3 and the second limiting bar 71, so that the guide wire can be kept in a taut state when the machine is stopped, avoiding the possibility of the guide wire becoming loose when the machine is stopped, so that the traction device can better pull the guide wire when the machine is started next time.

[0074] The above are preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made to the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A guide wire bundling device, characterized in that: The assembly includes a cluster frame assembly (1) and multiple guide rings (2) mounted on the cluster frame assembly (1). Multiple first limiting rods (3) are provided at the rear end of the guide rings (2) of the cluster frame assembly (1). The multiple first limiting rods (3) are arranged sequentially, and a passage (31) for the guide wire to pass through is formed between two adjacent first limiting rods (3). The cluster frame assembly (1) is respectively provided with a first pressing rod (4) and a second pressing rod (5). The first pressing rod (4) is slidably mounted on the front end of the cluster frame assembly (1) at the guide ring (2) to press against the guide wire. The cluster frame assembly (1) is provided with a first adjusting member (41) for adjusting the height of the first pressing rod (4). The second pressing rod (5) is slidably mounted on the cluster frame assembly. The first adjustment member (41) is located at the rear end of the guide ring (2) to press the guide wire. There are two second pressure rods (5), which are located at the front end and rear end of the through-channel (31) respectively. The bundle frame assembly (1) is provided with a second adjustment member (51) for adjusting the height of the second pressure rods (5). The first adjustment member (41) includes a drive gear (412), a drive rack (413) and a drive rod (414). The drive gear (412) is rotatably mounted on the bundle frame assembly (1), and the drive rack (413) is slidably mounted on the bundle frame assembly (1). The drive rack (413) is connected to the first pressure rod (4) and meshes with the drive gear (412) for transmission. The assembly (1) has multiple memory holes (12) on its side wall near the drive gear (412). The memory holes (12) are arranged at intervals around the central axis of the drive gear (412). The drive gear (412) has a through hole (415). The drive rod (414) passes through the through hole (415) and the memory hole (12) in sequence and is threaded to the through hole (415). The second pressure rod (5) located at the front end of the through channel (31) presses against the upper surface of the guide wire. The second pressure rod (5) located at the rear end of the through channel (31) presses against the lower surface of the guide wire. The bundle frame assembly (1) is rotatably mounted with a rotating disk (6). Both second pressure rods (5) are connected to the rotating disk (6), and both second pressure rods are connected to the rotating disk (6). The rods (5) are arranged at intervals around the central axis of the rotating disk (6); the second adjusting component (51) includes a linkage gear ring (511) and a linkage rack (512). The linkage gear ring (511) is coaxially connected to the outer peripheral wall of the rotating disk (6), and the linkage rack (512) is slidably installed on the bundle frame assembly (1). The linkage rack (512) and the linkage gear ring (511) are meshed and transmitted, and the linkage rack (512) and the drive gear (412) are also meshed and transmitted. The rotating disk (6) has two rotating slots, and the two rotating slots are correspondingly set with two second pressure rods (5). One end of each second pressure rod (5) passes through the corresponding rotating slot, and a bearing (61) is provided between the second pressure rod (5) and the inner wall of the corresponding rotating slot.The cluster frame assembly (1) is rotatably mounted with multiple rotating disks (7), and the multiple rotating disks (7) are correspondingly arranged with multiple first limiting rods (3). Each first limiting rod (3) is vertically mounted on the corresponding rotating disk (7). Each rotating disk (7) is vertically mounted with a second limiting rod (71). The first limiting rods (3) and the second limiting rods (71) are arranged at intervals around the rotation axis of the rotating disk (7). A rotating assembly (8) is provided between the rotating disk (6) and the multiple rotating disks (7). When the rotating disk (6) rotates, the rotating assembly (8) drives the multiple rotating disks (7) to rotate together. The step rotates to adjust the size of the threading channel (31); the cluster frame assembly (1) is rotatably mounted with a rotating shaft (13), and the first limiting rod (3) and the second limiting rod (71) are rotatably mounted on the corresponding rotating disk (7). The rotating shaft (13) is provided with an anti-rotation component (9). When two adjacent first limiting rods (3) or two adjacent second limiting rods (71) approach each other and abut against the guide wire, the anti-rotation component (9) abuts against the first limiting rod (3) and the second limiting rod (71) to restrict the free rotation of the first limiting rod (3) and the second limiting rod (71).

2. The guide wire bundling device according to claim 1, characterized in that: The bundle frame assembly (1) has two first mounting strips (11) on the side wall at the front end of the guide ring (2). The multiple guide rings (2) are located between the two first mounting strips (11). The first mounting strip (11) has a first sliding groove (111). The two ends of the first sliding groove (111) extend along the height direction. The two ends of the first pressure bar (4) slide through the first sliding groove (111) of the two first mounting strips (11). The first adjusting member (41) includes two wing nuts (411). The two wing nuts (411) are respectively inserted through the two ends of the first pressure bar (4) and threadedly connected to the first pressure bar (4).

3. The guide wire bundling device according to claim 1, characterized in that: The rotating assembly (8) includes a driven gear (81), a driven gear ring (82), and a rotating component. The driven gear (81) is coaxially connected to the rotating shaft (13). Multiple driven gear rings (82) are provided and are correspondingly provided to multiple rotating disks (7). Each driven gear ring (82) is coaxially connected to the outer peripheral wall of the corresponding rotating disk (7). The driven gear rings (82) of two adjacent rotating disks (7) mesh and drive each other. The driven gear (81) of the rotating shaft (13) meshes and drives the driven gear ring (82) of one of the rotating disks (7). The rotating component is provided between the rotating disk (6) and the rotating shaft (13) to drive the rotating disk (6) and the rotating shaft (13) to rotate synchronously.

4. The guide wire bundling device according to claim 1, characterized in that: One end of the first limiting rod (3) and the second limiting rod (71) are both inserted through the rotating disk (7) and extend to the bottom of the rotating disk (7). The anti-rotation assembly (9) includes an abutment strip (91) and a rotating screw (92). The abutment strip (91) is slidably installed on the bundle frame assembly (1) and located at the bottom of all rotating disks (7). The rotating screw (92) is coaxially fixed to the rotating shaft (13). The rotating screw (92) is inserted through the abutment strip (91) and threadedly connected to the abutment strip (91). When the rotating shaft (13) rotates, it forces two adjacent first limiting rods (3) or two adjacent second limiting rods (71) to approach each other and press against the guide wire. At the same time, the abutment strip (91) presses against all first limiting rods (3) and all second limiting rods (71).

5. The guide wire bundling device according to claim 1, characterized in that: The cluster frame assembly (1) has a moving groove (14) with both ends of the moving groove (14) extending horizontally. Each guide ring (2) has a moving block (21) on its outer side. The moving block (21) is slidably installed in the moving groove (14), and the guide ring (2) is slidably installed in the cluster frame assembly (1) through the moving block (21).