A glass fiber reinforced plastic winding guide device

By introducing a support base, guide rail, and translation mechanism into the fiberglass winding device, combined with a telescopic structure and transmission components, a single drive motor is used to achieve multi-directional movement of the loading vehicle, solving the problems of high power supply pressure and high cost in existing technologies and improving production efficiency.

CN224335127UActive Publication Date: 2026-06-09SHANGHAI TANGSHENG ENVIRONMENTAL PROTECTION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI TANGSHENG ENVIRONMENTAL PROTECTION TECH CO LTD
Filing Date
2025-06-12
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In existing fiberglass winding equipment, parallel winding and spiral winding methods require independent high-power motors, resulting in high power supply pressure, high cost, and hindering rapid production.

Method used

The system employs a support base, guide rails, a translation frame, and a translation mechanism, combined with a telescopic structure and transmission components. A single drive motor enables the lateral movement and telescopic motion of the loading vehicle. The power transmission is automatically switched by using a limit rail to guide the movement of the sliding block, thus simplifying the drive structure.

Benefits of technology

This technology enables the use of a single drive motor to meet the multi-directional movement requirements of the loading vehicle, reducing energy consumption and costs while improving production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a glass fiber reinforced plastic winding guide device relates to glass fiber reinforced plastic winding technical field, including support base, support base is located in the core mould rotation module side, be equipped with two guide rails on the support base, guide rail and translation car frame sliding connection, be equipped with the feeding trolley on translation car frame, be equipped with the translation mechanism on the support base, the translation mechanism includes first screw rod, first screw rod screw connection translation car frame, change the tightness of first belt or second belt through the use of adjusting wheel movement, realize and utilize one drive motor to satisfy the feeding trolley transverse movement operation and telescopic movement operation, simple structure, compared with traditional scheme, save resources, be convenient for maintenance, through the limit rail guide sliding block movement, make one side adjusting wheel when pressurizing first belt or second belt, the adjusting wheel of other side automatic decline, disconnect power transmission, switch to different operation automatically, accelerate work efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of fiberglass winding technology, specifically a fiberglass winding guide device. Background Technology

[0002] The fiberglass winding process begins with preparing fiberglass material according to product specifications and mixing the curing agent. Then, the fiberglass is spread out on the wire feeding frame and impregnated with resin. Next, the impregnated fiber is wound onto a rotating mandrel according to a predetermined procedure. Finally, the fiberglass product is demolded and removed. There are two operation methods in this process: parallel winding and spiral winding. Both operation methods require an independent moving mechanism for driving.

[0003] Its technical solution has inherent limitations: In the existing solution, whether it is parallel winding or spiral winding, the position of the wire feeding frame needs to be adjusted according to the progress of the operation. It usually requires two movement paths, namely parallel to the core mold movement and perpendicular to the core mold movement. The usual solution for these two movement paths is to equip an independent high-power motor for transmission. However, long-term use has the problems of high power supply pressure and high cost.

[0004] Independent drives require separate management of their moving structures, which is not conducive to rapid production.

[0005] Based on this, a fiberglass winding guide device is now provided, which can eliminate the drawbacks of existing devices. Utility Model Content

[0006] The purpose of this invention is to provide a fiberglass winding guide device to solve the problems in the background art.

[0007] To achieve the above objectives, this utility model provides the following technical solution:

[0008] A fiberglass winding guide device includes a support base located on the side of a core mold rotating module. Two guide rails are provided on the support base and slidably connected to a translation frame. A loading trolley is mounted on the translation frame. A translation mechanism is provided on the support base. The translation mechanism includes a first lead screw threadedly connected to the translation frame, with a fixed block rotatably connected to the end of the first lead screw. A telescopic structure is provided on the translation frame.

[0009] Based on the above technical solutions, this utility model also provides the following optional technical solutions:

[0010] In one alternative: the telescopic structure includes a rotating roller, which is rotatably connected to a fixed block. A transmission block is provided on the surface of the rotating roller. The rotating roller is slidably connected to a sliding sleeve. The rotating roller drives the sliding sleeve to rotate through the transmission block. Several sliding sleeves are rotatably connected to the translation frame. A transmission component is provided on the sliding sleeve.

[0011] In one alternative embodiment: the transmission assembly includes a worm gear, the worm gear is provided in the middle of the sliding sleeve, the upper side of the worm gear meshes with a worm wheel for transmission, the worm wheel is connected to a transmission shaft, the transmission shaft is rotatably connected to a rotating seat, the rotating seat is fixedly connected to the translation frame, and the transmission shaft is connected to a sliding element.

[0012] In one alternative embodiment: the sliding element includes a second lead screw, which is connected to a drive shaft and rotatably connected to a translation frame. The second lead screw is provided with a plurality of translation stages, which mesh with the second lead screw for transmission. The upper end of the translation stages is connected to a fixed plate, and the upper end of the fixed plate is connected to a loading trolley. The upper end of the support base is provided with a dual control unit.

[0013] In one alternative embodiment: the dual control unit includes a drive motor, the fixed end of which is connected to the upper end of the support base, the output end of which is connected to a transmission roller, the surface of which is provided with a first pulley, the side of which is provided with a second pulley, the surface of which is provided with a third pulley, and the surface of which is provided with a fourth pulley. The first pulley and the third pulley are driven by a first belt, and the second pulley and the fourth pulley are driven by a second belt. The first pulley is rotatably connected to a rotating frame, and the side of which is provided with a switching device.

[0014] In one alternative: the switching device includes a telescopic cylinder, the fixed end of which is connected to a support base, the output end of which is connected to a transmission rod, the transmission rod being connected to a sliding seat, a limiting rail being provided on each side of the sliding seat, the sliding seat being slidably connected to the limiting rail, and a lifting device being slidably provided inside the sliding seat.

[0015] In one alternative: the lifting device includes sliding blocks, two sliding blocks are slidably connected to a sliding seat, the surface of the sliding blocks is provided with a limiting roller, the surface of the limiting frame is provided with a limiting rail, the limiting roller is slidably connected to the limiting rail, and the limiting roller is connected to an adjusting wheel.

[0016] In one alternative: the loading vehicle is equipped with a scraper.

[0017] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0018] 1. This utility model uses the movement of adjusting wheels to change the tension of the first or second belt, so that a single drive motor can be used to meet the lateral movement and telescopic movement of the loading vehicle. The structure is simple, saves resources and is easy to maintain compared with traditional solutions.

[0019] 2. This utility model guides the movement of the sliding block through the limiting rail, so that when the adjusting wheel on one side is pressurized by the first belt or the second belt, the adjusting wheel on the other side automatically descends, disconnects the power transmission, and automatically switches between different operations, thus speeding up work efficiency. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the structure of this utility model.

[0021] Figure 2 This is a schematic diagram of the structure of the support base of this utility model.

[0022] Figure 3 This is a schematic diagram of the loading vehicle of this utility model.

[0023] Figure 4 This is a schematic diagram of the structure of the fixing plate of this utility model.

[0024] Figure 5 This is a schematic diagram of the structure of the third pulley of this utility model.

[0025] Figure 6 This is a schematic diagram of the telescopic cylinder of this utility model.

[0026] Figure 7 This is a schematic diagram of the limiting rail of this utility model.

[0027] Figure 8 This is a schematic diagram of the sliding seat of this utility model.

[0028] Figure reference numerals: 101. Core mold rotating module; 102. Loading trolley; 103. Support base; 104. First lead screw; 105. Translation frame; 106. Guide rail; 107. Fixing block; 201. Rotating roller; 202. Transmission block; 203. Sliding sleeve; 204. Worm gear; 205. Worm wheel; 301. Transmission shaft; 302. Rotating seat; 303. Second lead screw; 304. Translation stage; 305. Fixing block. Plate, 401. Drive motor, 402. Transmission roller, 403. First pulley, 404. Second pulley, 405. Rotating frame, 406. Third pulley, 407. First belt, 408. Fourth pulley, 409. Second belt, 501. Telescopic cylinder, 502. Transmission rod, 503. Sliding seat, 504. Limiting frame, 505. Limiting rail, 601. Sliding block, 602. Limiting roller, 603. Adjusting wheel. Detailed Implementation

[0029] 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.

[0030] In one embodiment, such as Figures 1-3 As shown, a fiberglass winding guide device includes a support base 103, which is disposed on the side of a core mold rotating module 101. Two guide rails 106 are provided on the support base 103, and the guide rails 106 are slidably connected to a translation frame 105. A loading trolley 102 is provided on the translation frame 105. A translation mechanism is provided on the support base 103, and the translation mechanism includes a first lead screw 104, which is threadedly connected to the translation frame 105. The end of the first lead screw 104 is rotatably connected to a fixing block 10. 7. The translation frame 105 is equipped with a telescopic structure. The first lead screw 104 rotates to drive the translation frame 105 to move along the guide rail 106, changing the position of the loading carriage 102. After the loading carriage 102 moves to the position, the loading carriage 102 contacts the trigger block with the core mold rotation module 101 through telescopic movement. The core mold rotation module 101 drives the core mold to rotate and roll the raw material onto the surface of the core mold. The loading carriage 102 is equipped with a curing agent and a scraper. After the raw material is soaked in the curing agent, the scraper removes the excess curing agent, which facilitates the bonding of the raw material.

[0031] In one embodiment, such as Figure 2 and Figure 3 As shown, the telescopic structure includes a rotating roller 201, which is rotatably connected to a fixed block 107. A transmission block 202 is provided on the surface of the rotating roller 201. The rotating roller 201 is slidably connected to a sliding sleeve 203. The rotating roller 201 drives the sliding sleeve 203 to rotate through the transmission block 202. Several sliding sleeves 203 are rotatably connected to the translation frame 105. A transmission component is provided on the sliding sleeve 203. The rotating roller 201 slidably connects to the sliding sleeve 203. When the translation frame 105 is translating, the rotating roller 201 does not interfere with the movement of the translation frame 105. The rotation of the rotating roller 201 drives the transmission block 202 to move, and the transmission block 202 drives the sliding sleeve 203 to rotate, providing power for the extension and retraction of the loading trolley 102.

[0032] In one embodiment, such as Figure 2 and Figure 3As shown, the transmission assembly includes a worm gear 204, with the worm gear 204 located in the middle of the sliding sleeve 203. The upper side of the worm gear 204 meshes with a worm wheel 205 for transmission. The worm wheel 205 is connected to a transmission shaft 301, which is rotatably connected to a rotating seat 302. The rotating seat 302 is fixedly connected to a translation frame 105. The transmission shaft 301 is connected to a sliding element, which drives the sliding sleeve 203 to rotate via the transmission block 202. The sliding sleeve 203 drives the worm gear 204 to slide, and the worm gear 204 drives the worm wheel 205 to rotate, thus providing conditions for power transmission.

[0033] In one embodiment, such as Figure 2 and Figure 3 As shown, the sliding element includes a second lead screw 303, which is connected to a transmission shaft 301. The second lead screw 303 is rotatably connected to a translation frame 105. The second lead screw 303 is provided with several translation stages 304, which mesh with the second lead screw 303 for transmission. The upper end of the translation stage 304 is connected to a fixed plate 305, and the upper end of the fixed plate 305 is connected to a loading trolley 102. The upper end of the support base 103 is provided with a dual control unit, which drives the transmission shaft 301 to rotate through the rotation of the worm gear 205. The transmission shaft 301 drives the second lead screw 303 to rotate, and the second lead screw 303 drives the several translation stages 304 to move synchronously. The translation stages 304 drive the fixed plate 305 to move, and the fixed plate 305 drives the loading trolley 102 to extend and retract, so as to facilitate the contact of the trigger block with the core mold rotation module 101.

[0034] In one embodiment, such as Figure 4 and Figure 5 As shown, the dual-control unit includes a drive motor 401. The fixed end of the drive motor 401 is connected to the upper end of the support base 103. The output end of the drive motor 401 is connected to a transmission roller 402. A first pulley 403 is provided on the surface of the transmission roller 402. A second pulley 404 is provided on the side of the first pulley 403. A third pulley 406 is provided on the surface of the first lead screw 104. A fourth pulley 408 is provided on the surface of the rotating roller 201. The first pulley 403 and the third pulley 406 are driven by a first belt 407, and the second pulley 404 and the fourth pulley 408 are driven by a second belt 407. The belt 409 drives the first pulley 403 to rotate the rotating frame 405. The rotating frame 405 is equipped with a switching device on its side. The drive motor 401 provides power and drives the transmission roller 402 to rotate. The transmission roller 402 drives the first pulley 403 and the second pulley 404 to rotate. When the first belt 407 is taut, the first pulley 403 drives the third pulley 406. When the second belt 409 is taut, the second pulley 404 drives the fourth pulley 408. The rotation of the third pulley 406 and the fourth pulley 408 is controlled to facilitate the adjustment of the position of the loading car 102.

[0035] In one embodiment, such as Figure 5 and Figure 6 As shown, the switching device includes a telescopic cylinder 501. The fixed end of the telescopic cylinder 501 is connected to the support base 103, and the output end of the telescopic cylinder 501 is connected to the transmission rod 502. The transmission rod 502 is connected to the sliding seat 503. A limit rail 505 is provided on each side of the sliding seat 503. The sliding seat 503 is slidably connected to the limit rail 505. A lifting device is slidably provided inside the sliding seat 503. The telescopic cylinder 501 drives the transmission rod 502 to move, and the transmission rod 502 drives the sliding seat 503 to move, providing power for the movement of the sliding seat 503.

[0036] In one embodiment, such as Figure 5 and Figure 6 As shown, the lifting device includes a sliding block 601, two sliding blocks 601 are slidably connected to a sliding seat 503, a limiting roller 602 is provided on the surface of the sliding block 601, a limiting rail 505 is provided on the surface of the limiting frame 504, the limiting roller 602 is slidably connected to the limiting rail 505, the limiting roller 602 is connected to an adjusting wheel 603, the sliding seat 503 moves by translation, the sliding seat 503 drives the sliding block 601 and the limiting roller 602 to move, the sliding seat 503 guides the limiting roller 602 to move, the sliding block 601 provides the conditions for the limiting roller 602 to move, during the displacement of the limiting roller 602, the adjusting wheel 603 is driven to lift upward or move downward, providing conditions for tightening the first belt 407 or the second belt 409.

[0037] The above embodiment discloses a fiberglass winding guide device, wherein the rotation of the first lead screw 104 drives the translational carriage 105 to move along the guide rail 106, changing the position of the loading carriage 102. After the loading carriage 102 moves to the position, it extends and retracts to contact the trigger block with the core mold rotation module 101. The core mold rotation module 101 drives the core mold to rotate, winding and attaching the raw material to the surface of the core mold. The loading carriage 102 contains a curing agent and a scraper. After the raw material is soaked in the curing agent, the scraper removes excess curing agent, facilitating the bonding of the raw material. A sliding sleeve is slidably connected by a rotating roller 201. 203. When the translation frame 105 is translating, the rotating roller 201 does not interfere with the movement of the translation frame 105. The rotation of the rotating roller 201 drives the transmission block 202 to move, and the transmission block 202 drives the sliding sleeve 203 to rotate, providing power for the extension and retraction of the loading car 102. The transmission block 202 drives the sliding sleeve 203 to rotate, and the sliding sleeve 203 drives the worm gear 204 to slide. The worm gear 204 drives the worm wheel 205 to rotate, providing conditions for power transmission. The rotation of the worm wheel 205 drives the transmission shaft 301 to rotate, and the transmission shaft 301 drives the second lead screw 303 to rotate. The second lead screw 303 drives several translation tables 304 to move forward. The synchronous displacement is achieved by the translation stage 304 driving the fixed plate 305 to move, which in turn drives the loading trolley 102 to extend and retract, facilitating the contact of the trigger block with the core mold rotation module 101. The telescopic cylinder 501 drives the transmission rod 502, which in turn drives the sliding seat 503, providing power for its movement. The sliding seat 503 translates, driving the sliding block 601 and the limiting roller 602 to move. The sliding seat 503 guides the limiting roller 602 to move, while the sliding block 601 provides the necessary conditions for its displacement. During the movement, the adjusting wheel 603 is driven to lift or move downward, providing conditions for tightening the first belt 407 or the second belt 409. Power is provided by the drive motor 401, which drives the transmission roller 402 to rotate. The transmission roller 402 drives the first pulley 403 and the second pulley 404 to rotate. When the first belt 407 is tightened, the first pulley 403 drives the third pulley 406. When the second belt 409 is tightened, the second pulley 404 drives the fourth pulley 408. By controlling the rotation of the third pulley 406 and the fourth pulley 408, the position of the loading car 102 can be easily adjusted.

[0038] 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 fiberglass winding guide device, comprising a support base (103), the support base (103) being disposed on the side of a core mold rotating module (101), the support base (103) being provided with two guide rails (106), the guide rails (106) being slidably connected to a translational frame (105), the translational frame (105) being provided with a loading trolley (102), characterized in that, The support base (103) is provided with a translation mechanism, which includes a first lead screw (104), the first lead screw (104) is threadedly connected to the translation frame (105), the end of the first lead screw (104) is rotatably connected to a fixing block (107), and the translation frame (105) is provided with a telescopic structure.

2. The fiberglass winding guide device according to claim 1, characterized in that, The telescopic structure includes a rotating roller (201), which is rotatably connected to a fixed block (107). A transmission block (202) is provided on the surface of the rotating roller (201). The rotating roller (201) is slidably connected to a sliding sleeve (203). The rotating roller (201) drives the sliding sleeve (203) to rotate through the transmission block (202). Several sliding sleeves (203) are rotatably connected to the translation frame (105). A transmission component is provided on the sliding sleeve (203).

3. The fiberglass winding guide device according to claim 2, characterized in that, The transmission assembly includes a worm (204), and the worm (204) is provided in the middle of the sliding sleeve (203). The upper side of the worm (204) meshes with the worm wheel (205) for transmission. The worm wheel (205) is connected to the transmission shaft (301). The transmission shaft (301) is rotatably connected to the rotating seat (302). The rotating seat (302) is fixedly connected to the translation frame (105). The transmission shaft (301) is connected to the sliding element.

4. The fiberglass winding guide device according to claim 3, characterized in that, The sliding element includes a second lead screw (303), which is connected to a drive shaft (301). The second lead screw (303) is rotatably connected to a translation frame (105). The second lead screw (303) is provided with a plurality of translation stages (304). The translation stages (304) mesh with the second lead screw (303) for transmission. The upper end of the translation stage (304) is connected to a fixed plate (305). The upper end of the fixed plate (305) is connected to a loading trolley (102). The upper end of the support base (103) is provided with a dual control unit.

5. A fiberglass winding guide device according to claim 4, characterized in that, The dual control unit includes a drive motor (401), the fixed end of which is connected to the upper end of the support base (103), the output end of which is connected to a transmission roller (402), the transmission roller (402) has a first pulley (403) on its surface, a second pulley (404) on the side of the first pulley (403), a third pulley (406) on the surface of the first lead screw (104), and a fourth pulley (408) on the surface of the rotating roller (201). The first pulley (403) and the third pulley (406) are driven by a first belt (407), and the second pulley (404) and the fourth pulley (408) are driven by a second belt (409). The first pulley (403) is rotatably connected to a rotating frame (405), and a switching device is provided on the side of the rotating frame (405).

6. A fiberglass winding guide device according to claim 5, characterized in that, The switching device includes a telescopic cylinder (501), the fixed end of which is connected to a support base (103), and the output end of which is connected to a transmission rod (502). The transmission rod (502) is connected to a sliding seat (503). A limiting rail (505) is provided on each side of the sliding seat (503). The sliding seat (503) is slidably connected to the limiting rail (505). A lifting device is slidably provided inside the sliding seat (503).

7. A fiberglass winding guide device according to claim 6, characterized in that, The lifting device includes a sliding block (601), two sliding blocks (601) are slidably connected to a sliding seat (503), the surface of the sliding block (601) is provided with a limiting roller (602), the surface of the limiting frame (504) is provided with a limiting rail (505), the limiting roller (602) is slidably connected to the limiting rail (505), and the limiting roller (602) is connected to an adjusting wheel (603).

8. A fiberglass winding guide device according to claim 1, characterized in that, The loading trolley (102) is equipped with a scraper.