An adhesive tape winding guide device for adhesive tape production

By linking the movable tube, extrusion block, and round rod on the positioning tube, the automatic alignment of the tape paper tube and the guide wheel is achieved, solving the problem of time-consuming paper tube positioning and improving production efficiency and winding quality.

CN122166587APending Publication Date: 2026-06-09HUIZHOU DEFUSHENG NEW MATERIAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
HUIZHOU DEFUSHENG NEW MATERIAL TECH CO LTD
Filing Date
2026-04-15
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In the tape production process, the positioning and centering adjustment of the paper tube is time-consuming, which affects production efficiency. Although the existing technology of alternating winding with dual air shafts has made some improvements, it has not completely solved the problem of low adjustment efficiency.

Method used

The system employs a linkage structure consisting of a movable tube on the positioning tube, an extrusion block, a round rod, and a spiral groove. This automatically drives the extrusion block to squeeze the tape paper tube and guide wheel from both sides, ensuring precise alignment. The limiting plane of the extrusion block forms a double fixation with the paper tube and guide wheel, ensuring winding stability.

Benefits of technology

It achieves automatic alignment of the tape tube and guide wheel, improves positioning efficiency, ensures winding regularity and product quality, optimizes the continuity of double-roller alternating winding operation, and improves overall production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a tape winding guide device for tape production, which comprises a base, a first air inflation shaft and a second air inflation shaft arranged in a slope on the top of the base, a plurality of positioning tubes arranged outside the first air inflation shaft and the second air inflation shaft, and the positioning tubes are used for supporting a guide wheel and a tape paper tube. The linkage of the movable tube, the extrusion block, the round rod and the spiral groove and other structures on the positioning tube is used, when the positioning tube is spliced and limited, the extrusion block is automatically driven to extrude the tape paper tube and the guide wheel from both sides, so that the tape paper tube and the guide wheel are accurately located in the middle of the installation area, automatic alignment is realized, the problem of high manual alignment accuracy and long time consumption is completely solved, and the positioning efficiency is greatly improved. Meanwhile, the limiting plane of the extrusion block realizes extrusion positioning, the arc abutting surface realizes inner wall tensioning, the antiskid effect of the rubber ring in the installation area is matched, double fixing is formed, the tape paper tube and the guide wheel do not rotate and move when winding, the winding regularity is guaranteed, and the product quality is improved.
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Description

Technical Field

[0001] This invention relates to the field of tape winding and guiding technology, and more particularly to a tape winding and guiding device for tape production. Background Technology

[0002] During the tape production process, appropriate guiding structures are usually required to guide the tape and ensure that it is neatly wound onto the winding paper roll. After a single roll of tape is wound, the finished tape must be removed and the paper roll reinstalled on the air shaft for the next winding operation.

[0003] Newly installed paper tubes require alignment adjustments to ensure precise alignment with guide wheels and other guiding mechanisms, guaranteeing neat tape winding afterwards. Due to the high precision requirements, manual adjustments are often time-consuming, impacting production efficiency. Existing technologies employ a dual-air-shaft alternating winding method, where one set completes winding before switching to the other. Workers can remove finished products, replace paper tubes, and complete adjustments at the standby station, improving overall production continuity. Even so, paper tube positioning and alignment still consume significant time, failing to fundamentally solve the problem of low adjustment efficiency.

[0004] Therefore, this application proposes a tape winding guide device for tape production. Summary of the Invention

[0005] The purpose of this invention is to solve the above-mentioned technical problems by providing a tape winding guide device for tape production.

[0006] To achieve the above objectives, the present invention adopts the following technical solution: A tape winding guide device for tape production includes a base, and a first air shaft and a second air shaft arranged at an angle are provided above the base. The first air shaft and the second air shaft are provided with a plurality of positioning tubes on their exteriors. The positioning tubes are used to support guide wheels and tape paper tubes. The positioning tube is provided with multiple storage slots distributed at both ends of the positioning tube. A movable tube is provided inside the storage slot and passes through the positioning tube. A pressing block is sleeved on the movable tube. A round rod is movably provided inside the movable tube. The two ends of the round rod are connected to the inner wall of the storage slot and the movable tube respectively through a first spring and a second spring. A sleeve is fixed inside the movable tube, and a protrusion is provided inside the sleeve. A guide rod is fixed on the round rod, and a spiral groove is provided on the outer surface of the guide rod to accommodate the protrusion. When the protrusion moves from one end of the spiral groove to the other end, the protrusion drives the sleeve and the movable tube to rotate 90°. The movable tube drives the extrusion block to rotate and extrudes the tape tube from both sides, so that the guide wheel is aligned with the tape tube.

[0007] Preferably, a bracket is fixed on the base, a coaxial first shaft is fixed to both ends of the first air shaft, a coaxial second shaft is fixed to both ends of the second air shaft, the first shaft and the second shaft are rotatably mounted on the bracket, a motor is mounted on the bracket, the output end of the motor is fixedly connected to the first shaft, and a support bearing is mounted on both the first shaft and the second shaft.

[0008] Preferably, the base is provided with a support mechanism for supporting the first shaft and the second shaft. The support mechanism includes a guide plate fixed on the base, a rail groove on the guide plate, a slide rail slidably connected in the rail groove, a lifting plate fixed on the slide rail, an arc-shaped groove for accommodating a support bearing on the upper end of the lifting plate, and a quick-release buckle on the upper end of the lifting plate, the buckle abutting against the upper end of the support bearing. An electric push rod is installed on the base, and a power rod is fixed to the output end of the electric push rod. A connecting block is fixed on the lifting plate, and the upper end of the power rod is fixed to the bottom of the connecting block.

[0009] Preferably, the outer walls of the first and second air shafts are fixed with retaining rings, and the outer surfaces of the first and second air shafts are provided with detachable clamping rings. The retaining rings and clamping rings are used to limit the positioning tube.

[0010] Preferably, the storage groove is located on the outer surface of the positioning tube and is recessed. The storage groove is distributed in a ring on the outer surface of the positioning tube and consists of two sets, with the two sets of storage grooves located at both ends of the positioning tube.

[0011] Preferably, the end of the positioning tube is provided with a through hole communicating with the storage groove, and the movable tube passes through the through hole and is slidably connected to it.

[0012] Preferably, a first limiting post is fixed on the round rod, a second limiting post is fixed on the inner wall of the receiving groove, and the first spring is sleeved on the outside of the first limiting post and the second limiting post.

[0013] Preferably, the inner wall of the movable tube is rotatably connected to a coaxial fixed bearing, and a second spring is fixed on the fixed bearing, the elastic force of the second spring being greater than that of the first spring.

[0014] Preferably, the extrusion block has an inclined surface, which is positioned opposite to the positioning tube.

[0015] Preferably, the outer surface of the positioning tube is fixed with an installation area, and a fixed rubber ring is sleeved on the positioning tube, the rubber ring being located within the installation area.

[0016] Compared with the prior art, the beneficial effects of this invention are as follows: 1. Through the linkage of the movable tube, extrusion block, round rod and spiral groove on the positioning tube, when the positioning tube is spliced ​​and limited, the extrusion block can automatically drive the extrusion block to extrude the tape paper tube and guide wheel from both sides, so that it is accurately positioned in the center of the installation area, realizing automatic alignment with the guide wheel. This solves the problem of high accuracy requirements and long time consumption for manual alignment, and greatly improves the paper tube positioning efficiency.

[0017] 2. The paper tube and guide wheel are doubly fixed to ensure winding stability. The limiting plane of the extrusion block can abut against the side wall of the paper tube and guide wheel to achieve extrusion positioning, while the arc-shaped pressing surface can abut against the inner wall of the paper tube and guide wheel to complete tensioning. Combined with the rubber ring in the installation area for initial anti-slip, the paper tube and guide wheel are not easy to rotate or deviate during the winding process, ensuring the regularity of tape winding and improving the quality of winding products.

[0018] 3. Optimize the continuity of the double-roller alternating winding operation and improve overall production efficiency; the device can retain the operation mode of the double air shaft alternating winding, and at the same time, it is equipped with a liftable support mechanism. The lifting plate can quickly disengage from the support bearing, which makes it convenient for the staff to quickly remove the finished tape and replace the new paper tube at the standby station; and the positioning and centering of the new paper tube is completed automatically without the need for additional time adjustment, which fundamentally solves the problem of low paper tube adjustment efficiency in the double-roller alternating winding, and further improves production continuity and overall production efficiency.

[0019] 4. The air shaft support structure is flexibly adjustable, balancing stability and ease of operation. The electric push rod on the base drives the lifting plate to rise and fall, providing stable horizontal support for the air shaft and ensuring structural stability during air shaft winding. At the same time, the quick-release buckle and the height-adjustable support structure make the disassembly and assembly of the air shaft and the removal of the finished tape more convenient, reducing the difficulty of operation for workers and reducing auxiliary work time.

[0020] 5. The positioning tubes are flexible in terms of disassembly, assembly, and limiting, adapting to different operational needs. The positioning tubes are fixed and limited by a fixing ring and a detachable clamping ring. The number of positioning tubes can be flexibly increased or decreased according to production needs. The positioning tubes are installed one by one in a splicing manner, making disassembly and assembly simple. At the same time, the splicing method of adjacent positioning tubes can trigger an automatic positioning structure, allowing the installation of positioning tubes and the positioning of paper tubes to be completed simultaneously, further simplifying the operation process.

[0021] In summary, this invention utilizes the linkage of the movable tube, extrusion block, round rod, and spiral groove on the positioning tube. During the splicing and limiting of the positioning tube, the extrusion block automatically drives the extrusion block to squeeze the tape tube and guide wheel from both sides, ensuring they are precisely positioned in the center of the installation area. This achieves automatic alignment, completely solving the problems of high precision and time-consuming manual alignment, and significantly improving positioning efficiency. Simultaneously, the limiting plane of the extrusion block achieves extrusion positioning, and the arc-shaped pressing surface achieves inner wall tension. Combined with the anti-slip effect of the rubber ring in the installation area, a double fixation is formed, ensuring that the tape tube and guide wheel do not rotate or shift during winding, guaranteeing winding regularity and improving product quality. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the structure of a tape winding guide device for tape production proposed in this invention; Figure 2 This is a left view of a tape winding guide device for tape production proposed in this invention. Figure 3 This is a right-side front view of a tape winding guide device for tape production proposed in this invention; Figure 4 This is a schematic diagram of the structure of the first air shaft and the positioning tube in a tape winding guide device for tape production proposed in this invention. Figure 5 This is a schematic diagram of the distribution of the receiving grooves on the positioning tube in a tape winding guide device for tape production proposed in this invention. Figure 6 This is a schematic diagram of the movable tube and extrusion block in a tape winding guide device for tape production proposed in this invention. Figure 7 This is a schematic diagram of the structure of the movable tube and the round rod in a tape winding guide device for tape production proposed in this invention. Figure 8 This is a schematic diagram of the disassembled movable tube and round rod in a tape winding guide device for tape production proposed in this invention; Figure 9 This is a schematic diagram of the structure of the sleeve and guide rod in a tape winding guide device for tape production proposed in this invention. Figure 10 This is a schematic diagram of the protrusion structure in a tape winding guide device for tape production proposed in this invention.

[0023] In the diagram: 1. Base, 2. Bracket, 3. Motor, 4. First shaft, 5. First air shaft, 6. Second air shaft, 7. Installation area, 8. Fixing ring, 9. Second shaft, 10. Clamping ring, 11. Electric push rod, 12. Buckle, 13. Connecting block, 14. Power rod, 15. Lifting plate, 16. Guide plate, 17. Slide rail, 18. Support bearing, 19. Rail groove, 20. Arc groove, 21. Positioning tube, 22. Storage groove, 23. Movable tube, 24. Round rod, 25. First limiting post, 26. Second limiting post, 27. First spring, 28. Fixed bearing, 29. Sleeve, 30. Guide rod, 31. Spiral groove, 32. Extrusion block, 33. Inclined surface, 34. Through hole, 35. Arc-shaped clamping surface, 36. Second spring, 37. Limiting plane, 38. Protrusion. Detailed Implementation

[0024] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0025] Reference Figures 1-10 A tape winding guide device for tape production includes a base 1. A first air shaft 5 and a second air shaft 6, arranged at an angle, are provided above the base 1. The height of the first air shaft 5 is greater than the height of the second air shaft 6. Further detailed explanation of the first and second air shafts: a bracket 2 is fixed on the base 1; a coaxial first shaft 4 is fixed to both ends of the first air shaft 5; and a coaxial second shaft 9 is fixed to both ends of the second air shaft 6. The first shaft 4 and the second shaft 9 are rotatably mounted on the bracket 2. A motor 3 is mounted on the bracket 2. The output end of the motor 3 is fixedly connected to the first shaft 4. The output end of the motor 3 drives the first shaft 4 to rotate, which in turn drives the first air shaft 5 to rotate, providing power for tape winding.

[0026] Support bearings 18 are installed on the other first shaft 4 and second shaft 9. The outer diameter of the support bearings 18 is smaller than the diameter of the first air shaft 5 and the second air shaft 6, so as to facilitate the installation and removal of the positioning tube 21.

[0027] To ensure the stability of the first air shaft 5 and the second air shaft 6, a support mechanism is provided on the base 1 to support the first shaft 4 and the second shaft 9. The support mechanism includes a guide plate 16 fixed on the base 1, a rail groove 19 on the guide plate 16, a slide rail 17 slidably connected in the rail groove 19, a lifting plate 15 fixed on the slide rail 17, an arc-shaped groove 20 at the upper end of the lifting plate 15 to accommodate the support bearing 18, and a quick-release buckle 12 at the upper end of the lifting plate 15. The buckle 12 abuts against the upper end of the support bearing 18 and is used to limit the position of the support bearing 18 to ensure its stability. The buckle 12 can be fixed by bolts.

[0028] An electric push rod 11 is installed on the base 1. A power rod 14 is fixed to the output end of the electric push rod 11. A connecting block 13 is fixed on the lifting plate 15. The upper end of the power rod 14 is fixed to the bottom of the connecting block 13. The electric push rod 11 drives the power rod 14 and the connecting block 13 to rise and fall, which can drive the lifting plate 15 to rise and fall. With the cooperation of the rail groove 19 and the slide rail 17, the lifting plate 15 can move up and down stably. The lifting plate 15 moves up and makes the arc groove 20 abut against the bottom of the support bearing 18, so as to support the support bearing 18, the first shaft 4 and the second shaft 9 at this end, and ensure that the first air shaft 5 and the second air shaft 6 remain horizontal.

[0029] Once the lifting plate 15 descends and disengages from the support bearing 18, the end of the shaft is no longer obstructed by the support structure, allowing the finished tape to be removed directly, making the operation convenient.

[0030] Both the first air shaft 5 and the second air shaft 6 are equipped with multiple positioning tubes 21 on their exteriors. These positioning tubes 21 are used to support the guide wheels and the tape / paper tube. Further detailed explanation follows: The positioning tubes 21 are arranged in an array on their outer surfaces along the axial direction of the first air shaft 5 and the second air shaft 6, with adjacent positioning tubes 21 abutting each other. To ensure the stability of the positioning tubes 21, a fixing ring 8 is fixed to the outer wall of the first air shaft 5 and the second air shaft 6, and a detachable clamping ring 10 is provided on the outer surface of the first air shaft 5 and the second air shaft 6. The fixing ring 8 and the clamping ring 10 are used to limit the positioning tubes 21. The innermost positioning tube 21 abuts against the end face of the fixing ring 8, and then the clamping ring 10 is installed so that the clamping ring 10 abuts against the end face of the outermost positioning tube 21. Then, the clamping ring 10 is pushed to move the positioning tubes 21 until each positioning tube 21 abuts against each other. Finally, the clamping ring 10 is fixed by bolts or buckles.

[0031] The positioning tube 21 has an installation area 7 fixed on its outer surface. A fixed rubber ring is fitted on the positioning tube 21 and is located in the installation area 7. This part is used to install and support the guide wheel and the tape tube. The rubber ring can be made of a bright color such as red to serve as a reminder for installation and positioning.

[0032] The positioning tube 21 is provided with multiple storage slots 22 distributed at both ends of the positioning tube 21. The storage slots 22 are located on the outer surface of the positioning tube 21 and are recessed. The storage slots 22 are arranged in a ring on the outer surface of the positioning tube 21 and there are two sets of them. The two sets of storage slots 22 are located at both ends of the positioning tube 21. Figure 5 As shown; each group of storage slots 22, arranged in a circular array, consists of at least three slots.

[0033] The storage groove 22 is provided with a movable tube 23. The end of the positioning tube 21 is provided with a through hole 34 communicating with the storage groove 22. The movable tube 23 passes through the through hole 34 and is slidably connected to it. A pressing block 32 is sleeved on the movable tube 23 and is fixedly connected to the movable tube 23. A round rod 24 is movably provided inside the movable tube 23. The two ends of the round rod 24 are connected to the inner wall of the storage groove 22 and the movable tube 23 respectively through a first spring 27 and a second spring 36. To ensure the stability of the first spring 27, a first limiting post 25 is fixed on the round rod 24, and a second limiting post 26 is fixed on the inner wall of the receiving groove 22. The first spring 27 is sleeved on the outside of the first limiting post 25 and the second limiting post 26 to prevent the first spring 27 from being twisted and deformed after being squeezed. A polygonal rod can be fixed on the first limiting post 25, and a polygonal groove can be provided on the second limiting post 26. The polygonal rod slides in the polygonal groove, so that the first spring 27 will not be subjected to torque and its stability during extension and retraction is ensured.

[0034] The inner wall of the movable tube 23 is rotatably connected to a coaxial fixed bearing 28, and a second spring 36 is fixed on the fixed bearing 28. The purpose of setting the fixed bearing 28 is to enable the second spring 36 to rotate with the round rod 24 without being twisted or deformed. The elastic force of the second spring 36 is greater than that of the first spring 27. That is to say, when this part of the structure is compressed, the first spring 27 is compressed first, until the first limiting post 25 and the second limiting post 26 abut against each other, and then the second spring 36 is compressed and contracted.

[0035] A sleeve 29 is fixed inside the movable tube 23. A protrusion 38 is provided inside the sleeve 29. A guide rod 30 is fixed on the round rod 24. The outer surface of the guide rod 30 is provided with a spiral groove 31 to accommodate the protrusion 38. The initial position of the protrusion 38 is located at the end of the spiral groove 31, which is close to the sleeve 29.

[0036] When the protrusion 38 moves from one end of the spiral groove 31 to the other end, the protrusion drives the sleeve 29 and the movable tube 23 to rotate 90°. The movable tube 23 drives the extrusion block 32 to rotate and extrudes the tape tube from both sides, so that the guide wheel is aligned with the tape tube.

[0037] The extrusion block 32 is provided with an inclined surface 33, which is opposite to the positioning tube 21. The end of the inclined surface 33 has a limiting plane 37, which is used to abut against the side wall of the guide wheel and the tape tube, and to limit the extrusion of the guide wheel and the tape tube. In addition, an arc-shaped abutting surface 35 is formed between the inclined surface 33 and the limiting plane 37. The arc-shaped abutting surface 35 protrudes from the inclined surface 33 and the limiting plane 37. When the limiting plane 37 abuts against the side of the guide wheel and the tape tube, the arc-shaped abutting surface 35 abuts against the inner wall of the guide wheel and the tape tube, and tensions them.

[0038] When adjacent positioning tubes 21 press against each other and squeeze the movable tube 23, the movable tube 23 moves, causing the second spring 36, the round rod 24 and the first limiting post 25 to move. At this time, the first spring 27 is compressed, and the movement of the movable tube 23 causes the squeezing block 32 to move, and the limiting plane 37 on the squeezing block 32 moves into place. When the movable tube 23 continues to move, the second spring 36 is squeezed and contracted, and relative sliding occurs between the movable tube 23 and the round rod 24. The movable tube 23 drives the sleeve 29 to move, and the sleeve 29 drives the protrusion 38 to move in the spiral groove 31, thereby driving the sleeve 29 and the movable tube 23 to rotate.

[0039] When the extrusion block 32 rotates, the inclined surface 33 first abuts against the side of the tape tube and the support guide wheel. As the extrusion block 32 continues to rotate, the extrusion blocks 32 on both sides will squeeze the tape tube and the support guide wheel towards the center, so that they are located in the middle position of the installation area. Finally, the limiting plane 37 abuts against the side of the guide wheel and the tape tube, squeezing and positioning the tape tube and the support guide wheel. The arc-shaped pressing surface 35 abuts against the inner wall of the guide wheel and the tape tube, tensioning them so that they are not easy to rotate, ensuring stability during use.

[0040] When using this invention, the tape tube and guide wheel are fitted onto the mounting area 7 of the positioning tube 21. The rubber ring in the mounting area 7 serves as an initial anti-slip and positioning reminder. Then, the positioning tubes 21 are fitted onto the first air shaft 5 and the second air shaft 6 one by one. The positioning tubes 21 near the fixing ring 8 abut against the fixing ring 8. Then, the clamping ring 10 is installed so that the positioning tubes 21 at the other end abut against each other. Then, the electric push rod 11 drives the power rod 14 and the connecting block 13 to move upward, which can drive the lifting plate 15 to move upward. With the cooperation of the rail groove 19 and the slide rail 17, the lifting plate 15 can move upward stably. The lifting plate 15 moves upward and makes the arc groove 20 abut against the bottom of the support bearing 18. In this way, the support bearing 18, the first shaft 4, and the second shaft 9 at this end can be supported, ensuring that the first air shaft 5 and the second air shaft 6 remain horizontal. Horizontal sensors can be installed at the ends of the first shaft 4 and the second shaft 9 for real-time monitoring and feedback to the electric push rod 11 to ensure that the first shaft 4 and the second shaft 9 are horizontally supported.

[0041] Next, the staff manually pushes the clamping ring 10 and drives the positioning tube 21 to move until multiple positioning tubes 21 abut against each other, and then the clamping ring 10 is fixed by bolts or buckles.

[0042] As the positioning tubes 21 move closer to each other, they will first squeeze the movable tube 23, causing the movable tube 23 to move. The movement of the movable tube 23 drives the second spring 36, the round rod 24 and the first limiting post 25 to move. At this time, the first spring 27 is compressed. The movement of the movable tube 23 drives the squeezing block 32 to move. At this time, the limiting plane 37 on the squeezing block 32 moves into place, and the first limiting post 25 and the second limiting post 26 abut against each other. As the movable tube 23 continues to be squeezed and moved, the second spring 36 is compressed, and relative sliding occurs between the movable tube 23 and the round rod 24. The movable tube 23 drives the sleeve 29 to move, and the sleeve 29 drives the protrusion 38 to move in the spiral groove 31, thereby driving the sleeve 29 and the movable tube 23 to rotate. When the squeezing block 32 rotates, the inclined surface 33 first abuts against the side of the tape tube and the support guide wheel. As the squeezing block 32 continues to rotate, the squeezing blocks 32 on both sides will squeeze the tape tube and the support guide wheel towards the center, so that they are located in the middle position of the installation area. Finally, the limiting plane 37 abuts against the side of the guide wheel and the tape tube, squeezing and positioning the tape tube and the support guide wheel. The arc-shaped pressing surface 35 abuts against the inner wall of the guide wheel and the tape tube, tensioning them so that they are not easy to rotate, ensuring stability during use.

[0043] This completes the tensioning and positioning, ensuring precise alignment between the tape roll and the guide wheel without the need for manual adjustment; The produced tape is tensioned by the existing tensioning mechanism, then wound around the support guide wheel, and finally wound by the tape paper tube to ensure the accuracy of tape winding.

[0044] This invention can retain the existing dual air shaft alternating winding operation method; After winding is complete, simply remove the retaining ring 10. Under the reset force of the first spring 27 and the second spring 36, all moving parts will reset synchronously, releasing the limit lock on the tape tube, and the finished tape can be easily removed.

[0045] The above description is only 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 tape winding guide device for tape production, comprising a base (1), characterized in that, The base (1) is provided with a first air shaft (5) and a second air shaft (6) arranged at an angle. Both the first air shaft (5) and the second air shaft (6) are provided with multiple positioning tubes (21) on their exteriors. The positioning tubes (21) are used to support the guide wheel and the tape paper tube. The positioning tube (21) is provided with multiple storage slots (22) and distributed at both ends of the positioning tube (21). The storage slots (22) are provided with movable tubes (23) that pass through the positioning tube (21). The movable tubes (23) are fitted with extrusion blocks (32). A round rod (24) is movably provided inside the movable tubes (23). The two ends of the round rod (24) are connected to the inner wall of the storage slots (22) and the movable tubes (23) respectively through a first spring (27) and a second spring (36). A sleeve (29) is fixed inside the movable tube (23). A protrusion (38) is provided inside the sleeve (29). A guide rod (30) is fixed on the round rod (24). A spiral groove (31) is provided on the outer surface of the guide rod (30) to accommodate the protrusion (38). When the protrusion (38) moves from one end to the other end of the spiral groove (31), the protrusion drives the sleeve (29) and the movable tube (23) to rotate 90°. The movable tube (23) drives the extrusion block (32) to rotate and extrudes the tape tube from both sides, so that the guide wheel is aligned with the tape tube.

2. The tape winding guide device for tape production according to claim 1, characterized in that, A bracket (2) is fixed on the base (1). A first shaft (4) is fixed at both ends of the first air shaft (5). A second shaft (9) is fixed at both ends of the second air shaft (6). The first shaft (4) and the second shaft (9) are rotatably mounted on the bracket (2). A motor (3) is installed on the bracket (2). The output end of the motor (3) is fixedly connected to the first shaft (4). Support bearings (18) are installed on the other first shaft (4) and the second shaft (9).

3. The tape winding guide device for tape production according to claim 1, characterized in that, The base (1) is provided with a support mechanism for supporting the first shaft (4) and the second shaft (9). The support mechanism includes a guide plate (16) fixed on the base (1). The guide plate (16) is provided with a rail groove (19). A slide rail (17) is slidably connected in the rail groove (19). A lifting plate (15) is fixed on the slide rail (17). The upper end of the lifting plate (15) is provided with an arc groove (20) for accommodating the support bearing (18). The upper end of the lifting plate (15) is provided with a quick-release buckle (12). The buckle (12) abuts against the upper end of the support bearing (18). An electric push rod (11) is installed on the base (1), and a power rod (14) is fixed to the output end of the electric push rod (11). A connecting block (13) is fixed on the lifting plate (15), and the upper end of the power rod (14) is fixed to the bottom of the connecting block (13).

4. The tape winding guide device for tape production according to claim 1, characterized in that, The outer walls of the first air shaft (5) and the second air shaft (6) are fixed with a fixing ring (8), and the outer surfaces of the first air shaft (5) and the second air shaft (6) are provided with a detachable clamping ring (10). The fixing ring (8) and the clamping ring (10) are used to limit the positioning tube (21).

5. A tape winding guide device for tape production according to claim 1, characterized in that, The storage groove (22) is located on the outer surface of the positioning tube (21) and is recessed. The storage groove (22) is distributed in a ring on the outer surface of the positioning tube (21), and two sets are provided, which are located at both ends of the positioning tube (21).

6. The tape winding guide device for tape production according to claim 1, characterized in that, The end of the positioning tube (21) is provided with a through hole (34) that communicates with the storage groove (22), and the movable tube (23) passes through the through hole (34) and is slidably connected to it.

7. The tape winding guide device for tape production according to claim 1, characterized in that, A first limiting post (25) is fixed on the round rod (24), and a second limiting post (26) is fixed on the inner wall of the storage groove (22). The first spring (27) is sleeved on the outside of the first limiting post (25) and the second limiting post (26).

8. A tape winding guide device for tape production according to claim 1, characterized in that, The inner wall of the movable tube (23) is rotatably connected to a coaxial fixed bearing (28), and a second spring (36) is fixed on the fixed bearing (28). The elastic force of the second spring (36) is greater than that of the first spring (27).

9. A tape winding guide device for tape production according to claim 1, characterized in that, The extrusion block (32) is provided with an inclined surface (33), which is arranged opposite to the positioning tube (21).

10. A tape winding guide device for tape production according to claim 1, characterized in that, The outer surface of the positioning tube (21) is fixed with an installation area (7), and a fixed rubber ring is fitted on the positioning tube (21), the rubber ring being located within the installation area (7).