Fine yarn connection yarn pipe cross-platform transmission structure

By designing a cross-platform transmission structure for fine-loop yarn tubes, the problem of manual intervention required by existing yarn tube conveying devices was solved, realizing automated and rapid conveying of yarn tubes and improving efficiency.

CN224492705UActive Publication Date: 2026-07-14FUJIAN CHANGLE CITY CHANGYUAN TEXTILE

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
FUJIAN CHANGLE CITY CHANGYUAN TEXTILE
Filing Date
2025-07-11
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing yarn tube conveying devices require manual intervention in yarn tube placement, resulting in a large workload, high labor costs, and low conveying efficiency, which cannot meet the needs of automated production.

Method used

A cross-platform transmission structure for fine yarn tubes was designed, including a fixed frame, a conveyor belt, an unloading module, a material distribution mechanism, and a lifting component. The unloading module unloads the yarn tubes, the material distribution mechanism accurately conveys them one by one, and the lifting component transports the yarn tubes to the collection box, thus realizing automated conveying.

Benefits of technology

It enables rapid and stable conveying of yarn tubes, meets the needs of automated production, improves conveying efficiency, and reduces manual intervention.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of fine yarn association bobbin cross-platform transmission structure, it is related to yarn tube conveying technical field, including fixing frame, the fixed frame is equipped with conveyor belt one, the fixed frame is equipped with guide rail, the conveyor belt one is equipped in guide rail, the fixed connection pipe seat of transportation is fixed on the conveyor belt one, the pipe seat upper end fixed connection fixed link, the outer end of the fixed link is equipped with fine yarn bobbin, the side of fixed frame one end is equipped with blanking groove, the blanking groove is equipped with distribution mechanism, the blanking groove connects lifting component, the guide rail is equipped with unloading module;Fine yarn bobbin can be unloaded in the process of conveying by unloading module, reduces the time of conveying;Fine yarn bobbin is accurately conveyed one by one by distribution mechanism, transmission is reasonable, stable;Fine yarn bobbin is transported into collection box by lifting component again, to realize the rapid conveying of fine yarn bobbin, satisfy the demand of automation, improve conveying efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of yarn tube conveying technology, specifically a cross-platform transmission structure for finely wound yarn tubes. Background Technology

[0002] In the spinning process, the yarn bobbin primarily serves a transport function, and its quality is closely related to the yarn produced. Positioned on a high-speed spinning spindle, the yarn bobbin is spun from roving into fine yarn and collected on the bobbin via a series of drafting components on the spinning frame. The spinning process then transports the collected yarn bobbin to the downstream spinning process, where a winding machine collects it onto bobbins, forming larger yarn cones for easier transport and customer use. Finally, the yarn bobbin is collected by the downstream spinning process and transported back to the spinning process for reuse.

[0003] Existing yarn tube conveying devices require conveying yarn tubes one by one onto the conveyor belt. However, sometimes the yarn tubes are not placed in the correct position, requiring manual placement before conveying. This process is labor-intensive, has high labor costs, and low conveying efficiency, failing to meet the needs of automated production.

[0004] Based on this, a cross-platform transmission structure for fine yarn connecting tubes is now provided, which can eliminate the drawbacks of existing devices. Utility Model Content

[0005] The purpose of this invention is to provide a cross-platform transmission structure for fine yarn connecting tubes to solve the problems in the background art.

[0006] To achieve the above objectives, this utility model provides the following technical solution:

[0007] A cross-platform transmission structure for fine yarn bobbins includes a fixed frame, a conveyor belt on the fixed frame, a guide rail on the fixed frame, the conveyor belt inside the guide rail, a tube carrier fixedly connected to the conveyor belt, a fixed rod fixedly connected to the upper end of the tube carrier, a fine yarn bobbin at the outer end of the fixed rod, a material discharge chute on the side of one end of the fixed frame, a material distribution mechanism in the material discharge chute, a lifting component connected to the material discharge chute, and a material unloading module on the guide rail.

[0008] Based on the above technical solutions, this utility model also provides the following optional technical solutions:

[0009] In one alternative embodiment: the unloading module includes a first unloading plate and a second unloading plate. The first unloading plate is fixedly connected to the guide rail on the side near the discharge chute, and the second unloading plate is fixedly connected to the guide rail on the side away from the discharge chute. The upper ends of the first and second unloading plates are inclined slopes, and the upper end surface of the second unloading plate is higher than the upper end surface of the first unloading plate.

[0010] In one alternative embodiment: the material distribution mechanism includes a material distribution roller, which is rotatably connected to a material discharge trough. The outer end of the material distribution roller is provided with four material distribution slots. One end of the material distribution roller is fixedly connected to a rotating disk. The rotating disk is provided with four evenly distributed transmission slots. A push rod is connected in the transmission slots. The push rod is fixedly connected to a connecting rod. The connecting rod is fixedly connected to a rotating wheel. The rotating wheel is fixedly connected to the output shaft of a motor. The motor is fixedly connected to the outer end of the material discharge trough.

[0011] In one alternative: the lifting component includes a lifting frame, on which a second conveyor belt is provided, and on which a plurality of lifting buckets are provided. One end of the second conveyor belt is located at the lower end of the distributing roller, and a guide pipe is provided at the other end of the second conveyor belt. A collection box is provided at the end of the guide pipe away from the second conveyor belt.

[0012] In one alternative: a controller is fixedly connected to the mounting frame, and the controller is electrically connected to motor one, conveyor belt one, and conveyor belt two respectively.

[0013] In one alternative: the four dispensing troughs are arranged in a circumferential array at the outer end of the dispensing roller.

[0014] In one alternative: the lifting bucket is provided with an elastic sponge.

[0015] In one alternative: multiple lifting buckets are evenly arranged on conveyor belt two.

[0016] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0017] This invention uses an unloading module to unload the yarn bobbins during transport, reducing transport time; a separating mechanism accurately transports each yarn bobbin individually, ensuring a reasonable and stable transmission; and a lifting component transports the yarn bobbins to a collection box, thus achieving rapid transport of the yarn bobbins, meeting automation requirements, and improving transport efficiency. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the structure of this utility model.

[0019] Figure 2 This is a schematic diagram of the structure of the pipe seat of this utility model.

[0020] Figure 3 This is a schematic diagram of the structure of the material discharge trough of this utility model.

[0021] Figure 4 This is a schematic diagram of the rotating wheel of this utility model.

[0022] Figure reference numerals: 100, fixed frame; 101, conveyor belt one; 102, guide rail; 103, conveying tube seat; 104, fixed rod; 200, fine yarn bobbin; 300, material dropper; 401, material stripper plate one; 402, material stripper plate two; 501, material distribution roller; 502, material distribution trough; 503, rotating disc; 504, transmission groove; 505, push rod; 506, connecting rod; 507, rotating wheel; 508, motor one; 601, lifting frame; 602, conveyor belt two; 603, lifting bucket; 604, guide pipe; 605, collection box; 700, controller; 800, elastic sponge. Detailed Implementation

[0023] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments.

[0024] In one embodiment, such as Figures 1-4 As shown, a cross-platform transmission structure for fine yarn bobbins includes a fixed frame 100, a conveyor belt 101 mounted on the fixed frame 100, a guide rail 102 mounted on the fixed frame 100, the conveyor belt 101 disposed within the guide rail 102, a tube carrier 103 fixedly connected to the conveyor belt 101, a fixed rod 104 fixedly connected to the upper end of the tube carrier 103, a fine yarn bobbin 200 mounted on the outer end of the fixed rod 104, and a material dropper 300 provided on the side of one end of the fixed frame 100. The material dropper 300 contains... The material distribution mechanism includes a material drop trough 300 connected to a lifting component, a material unloading module on the guide rail 102, a conveyor belt 101 driving the tube carrier 103 to move, the tube carrier 103 driving the fixed rod 104 to move, and the fixed rod 104 driving the yarn bobbin 200 to move. The material unloading module unloads the yarn bobbin 200 into the material drop trough 300. The material distribution mechanism accurately conveys the yarn bobbins one by one, and the lifting component stably transports the yarn bobbins 200, thereby achieving rapid conveying of the yarn bobbins 200, meeting automation requirements, and improving conveying efficiency.

[0025] In this embodiment, as Figure 2As shown, the unloading module includes a first unloading plate 401 and a second unloading plate 402. The first unloading plate 401 is fixedly connected to the guide rail 102 on the side near the discharge chute 300, and the second unloading plate 402 is fixedly connected to the guide rail 102 on the side away from the discharge chute 300. The upper ends of the first unloading plate 401 and the second unloading plate 402 are inclined slopes. The upper end surface of the second unloading plate 402 is higher than the upper end surface of the first unloading plate 401. A fixing rod 104... The outer end of the fine yarn bobbin 200 moves with the conveyor belt 101. When the fine yarn bobbin 200 moves to the stripper plate 401 and stripper plate 402, the inclined surface causes the fine yarn bobbin 200 to move upward and detach from the fixing rod 104. Since the upper end of the stripper plate 402 is higher than the upper end of the stripper plate 401, the fine yarn bobbin 200 tilts to one side of the drop trough 300, causing the fine yarn bobbin 200 to fall into the drop trough 300.

[0026] In one embodiment, such as Figure 3 and Figure 4 As shown, the material distribution mechanism includes a material distribution roller 501, which is rotatably connected to a material discharge trough 300. Four material distribution grooves 502 are provided at the outer end of the material distribution roller 501. One end of the material distribution roller 501 is fixedly connected to a rotating disk 503. The rotating disk 503 has four evenly distributed transmission grooves 504, in which a push rod 505 is connected. The push rod 505 is fixedly connected to a connecting rod 506. The connecting rod 506 is fixedly connected to a rotating wheel 507, and the rotating wheel 507 is fixedly connected to a motor. The output shaft of motor 508 is fixedly connected to the outer end of the feed chute 300. Motor 508 drives the rotating wheel 507 to rotate, the rotating wheel 507 drives the connecting rod 506 to rotate, the connecting rod 506 drives the push rod 505 to rotate, the push rod 505 cooperates with the transmission groove 504, and intermittently drives the rotating disk 503 to rotate, rotating 90° at a time. The rotating disk 503 drives the distributing roller 501 to rotate, and the fine yarn bobbins 200 that fall into the feed chute 300 enter the distributing groove 502. As the distributing roller 501 rotates, they are accurately conveyed one by one.

[0027] In one embodiment, such as Figure 1As shown, the lifting component includes a lifting frame 601, a second conveyor belt 602 on the lifting frame 601, and multiple lifting buckets 603 on the second conveyor belt 602. One end of the second conveyor belt 602 is located at the lower end of the distributing roller 501, and the other end of the second conveyor belt 602 is provided with a guide pipe 604. The end of the guide pipe 604 away from the second conveyor belt 602 is provided with a collection box 605. The fine yarn bobbins 200 in the distributing trough 502 fall into the lifting buckets 603. The second conveyor belt 602 drives the lifting buckets 603 to move, and the fine yarn bobbins 200 in the lifting buckets 603 then enter the guide pipe 604 and fall into the collection box 605 through the guide pipe 604, which facilitates transportation by workers.

[0028] In one embodiment, such as Figure 1 As shown, a controller 700 is fixedly connected to the fixed frame 100. The controller 700 is electrically connected to the motor 508, the conveyor belt 101, and the conveyor belt 602 respectively. The controller 700 ensures the coordination between the devices and the normal operation of the devices.

[0029] In one embodiment, such as Figure 3 As shown, the four material distribution grooves 502 are arranged in a circumferential array on the outer end of the material distribution roller 501. When the material distribution roller 501 rotates, the four material distribution grooves 502 sequentially grab, transfer and release the yarn bobbin 200 at fixed angles of 90° to ensure the stability of transportation.

[0030] In one embodiment, such as Figure 3 As shown, the lifting bucket 603 is provided with an elastic sponge 800. The elastic sponge 800 has a certain elastic buffering effect and can fit the outer surface of the yarn bobbin 200, increasing the stability of the yarn bobbin 200 during transportation.

[0031] In one embodiment, such as Figure 1 As shown, multiple lifting buckets 603 are evenly arranged on the second conveyor belt 602. The evenly arranged lifting buckets 603 can maintain a constant filling rate of the yarn bobbin 200 during the conveying process, prevent the second conveyor belt 602 from being overloaded or blocked due to local accumulation, and avoid material interruption caused by uneven spacing, thus ensuring the continuous and stable operation of the conveyor line.

[0032] The above embodiment discloses a cross-platform transmission structure for fine yarn bobbins, wherein the fine yarn bobbin 200 at the outer end of the fixed rod 104 moves with the conveyor belt 101. When the fine yarn bobbin 200 moves to the stripper plate 401 and stripper plate 402, due to the inclined surface, the fine yarn bobbin 200 moves upward and detaches from the fixed rod 104. Since the upper end surface of stripper plate 402 is higher than the upper end surface of stripper plate 401, the fine yarn bobbin 200 tilts towards one side of the drop trough 300, causing the fine yarn bobbin 200 to fall into the drop trough 300. The motor 508 drives the rotating wheel 507 to rotate, and the rotating wheel 507 drives the connecting rod 506 to rotate. The connecting rod 506 drives the push rod 505 to rotate. The push rod 505 cooperates with the transmission groove 504 to intermittently drive the rotating disk 503 to rotate. Each rotation is 90°. The rotating disk 503 drives the distribution roller 501 to rotate. The yarn bobbins 200 that fall into the drop trough 300 enter the distribution trough 502. As the distribution roller 501 rotates, they are accurately conveyed one by one. The yarn bobbins 200 in the distribution trough 502 fall into the lifting bucket 603. The conveyor belt 602 drives the lifting bucket 603 to move. The yarn bobbins 200 in the lifting bucket 603 then enter the guide pipe 604 and fall into the collection box 605 through the guide pipe 604, which facilitates transportation by the staff.

[0033] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this application should be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. A cross-platform transmission structure for fine yarn-connecting tubes, comprising a fixing frame (100), characterized in that, The fixed frame (100) is provided with a first conveyor belt (101) and a guide rail (102). The first conveyor belt (101) is located inside the guide rail (102). A conveyor tube seat (103) is fixedly connected to the first conveyor belt (101). A fixed rod (104) is fixedly connected to the upper end of the conveyor tube seat (103). A fine yarn bobbin (200) is provided at the outer end of the fixed rod (104). A material drop chute (300) is provided on the side of one end of the fixed frame (100). A material distribution mechanism is provided in the material drop chute (300). The material drop chute (300) is connected to a lifting component. A material unloading module is provided on the guide rail (102).

2. The cross-platform transmission structure for finely wound yarn tubes according to claim 1, characterized in that, The unloading module includes a first unloading plate (401) and a second unloading plate (402). The first unloading plate (401) is fixedly connected to the guide rail (102) on the side near the discharge chute (300). The second unloading plate (402) is fixedly connected to the guide rail (102) on the side away from the discharge chute (300). The upper ends of the first unloading plate (401) and the second unloading plate (402) are inclined slopes. The upper end surface of the second unloading plate (402) is higher than the upper end surface of the first unloading plate (401).

3. The cross-platform transmission structure for finely wound yarn tubes according to claim 1, characterized in that, The material distribution mechanism includes a material distribution roller (501), which is rotatably connected in the material drop trough (300). The outer end of the material distribution roller (501) is provided with four material distribution grooves (502). One end of the material distribution roller (501) is fixedly connected to a rotating disk (503). The rotating disk (503) is provided with four evenly distributed transmission grooves (504). A push rod (505) is connected in the transmission groove (504). The push rod (505) is fixedly connected to a connecting rod (506). The connecting rod (506) is fixedly connected to a rotating wheel (507). The rotating wheel (507) is fixedly connected to the output shaft of a motor (508). The motor (508) is fixedly connected to the outer end of the material drop trough (300).

4. The cross-platform transmission structure for finely wound yarn tubes according to claim 1, characterized in that, The lifting component includes a lifting frame (601), on which a second conveyor belt (602) is provided, and on which a plurality of lifting buckets (603) are provided. One end of the second conveyor belt (602) is located at the lower end of the distributing roller (501), and at the other end of the second conveyor belt (602) is a guide pipe (604). At the end of the guide pipe (604) away from the second conveyor belt (602) is a collection box (605).

5. The cross-platform transmission structure for finely wound yarn tubes according to claim 1, characterized in that, A controller (700) is fixedly connected to the fixed frame (100), and the controller (700) is electrically connected to the motor (508), the conveyor belt (101), and the conveyor belt (602).

6. The cross-platform transmission structure for finely wound yarn tubes according to claim 3, characterized in that, The four distributing troughs (502) are arranged in a circumferential array at the outer end of the distributing roller (501).

7. The cross-platform transmission structure for finely wound yarn tubes according to claim 4, characterized in that, The lifting bucket (603) is provided with an elastic sponge (800).

8. The cross-platform transmission structure for finely wound yarn tubes according to claim 4, characterized in that, Multiple lifting buckets (603) are evenly arranged on conveyor belt two (602).