Glass fiber reinforced plastic fixed-length cutting device

CN224476260UActive Publication Date: 2026-07-10JIANGSU XINLANRUI MATERIAL TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU XINLANRUI MATERIAL TECHNOLOGY CO LTD
Filing Date
2025-05-29
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing fiberglass cutting equipment requires manual removal of the pipes after cutting, resulting in low production efficiency.

Method used

A fiberglass fixed-length cutting device was designed, which includes a conveyor seat, a fixed-length seat and a cutting mechanism. The pipe is fixed by a fixing component, the cutting machine is driven by a telescopic cylinder, and the pipe is automatically unloaded by tilting the unloading surface.

Benefits of technology

The system enables automated feeding of fiberglass pipes, reducing the labor intensity of workers and improving production efficiency.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224476260U_ABST
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Abstract

The utility model provides a kind of glass steel fixed-length cutting device, including conveying seat, its top is provided with conveying surface, the top of conveying surface is equipped with fixed component;Fixed-length seat is located at one end of conveying seat, and cutting gap is left between conveying seat, the top of fixed-length seat is provided with blanking surface, blanking surface is inclined to one side of fixed-length seat, the top of fixed-length seat is equipped with fixed-length component, for changing the cutting length of glass steel pipe material;Cutting mechanism includes first telescopic cylinder and cutting machine, the telescopic shaft end of first telescopic cylinder is upwards and is connected with cutting machine, cutting machine is provided with cutting knife, cutting knife is located above cutting gap.The utility model in, pipe material is cut off immediately along the inclination direction of blanking surface natural roll off blanking surface, realize the automatic blanking of pipe material, without worker, both can reduce the labor intensity of worker, can also improve pipe material transfer efficiency, pipe material is cut off immediately can continue to convey subsequent pipe material, improve production efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of fiberglass processing technology, specifically to a fiberglass fixed-length cutting device. Background Technology

[0002] Fiberglass pipe products are usually quite long during production. Depending on the usage requirements, cutting devices are used to cut the fiberglass products to the required length.

[0003] Chinese patent CN221968208U discloses a fixed-length cutting device for a fiberglass pultrusion machine. The clamping device on the top of the machine body serves to clamp the fiberglass, making it easier for operators to fix the position of the fiberglass when cutting, and preventing cutting errors caused by the fiberglass not being fixed in position during the cutting process.

[0004] However, after the aforementioned device cuts the fiberglass, it is still necessary to manually remove the cut fiberglass, which delays subsequent cutting processes and results in low production efficiency. Utility Model Content

[0005] In view of the shortcomings of the existing technology, this utility model proposes a fiberglass fixed-length cutting device to solve the above problems.

[0006] The objective of this utility model is achieved through the following technical solution:

[0007] This utility model provides a fiberglass fixed-length cutting device, comprising:

[0008] A conveyor seat, with a conveying surface on its top, and a fixing component installed on the top of the conveying surface for fixing the fiberglass pipe on the conveying surface;

[0009] A length-fixing seat is located at one end of the conveyor seat and has a cutting gap between it and the conveyor seat. The top of the length-fixing seat is provided with a feeding surface, which is inclined towards one side of the length-fixing seat. A length-fixing component is installed on the top of the length-fixing seat to change the cutting length of the fiberglass pipe.

[0010] A cutting mechanism includes a first telescopic cylinder and a cutting machine. The telescopic shaft end of the first telescopic cylinder faces upward and is connected to the cutting machine. The cutting machine is equipped with a cutting blade, which is located above the cutting gap.

[0011] Furthermore, the middle of the conveying surface is V-shaped and recessed, and its two sides form side surfaces that slope inwards. The feeding surface is flush with the surface of one of the side surfaces.

[0012] Furthermore, a side groove is provided on the side of the fixed-length seat that is inclined away from the material feeding surface. A sliding groove is provided in the fixed-length seat, with both ends extending to the material feeding surface and the side groove. A support plate is slidably inserted in the sliding groove, and the upper surface of the support plate is flush with the surface of the other side surface. One end of the support plate extends out of the side groove and is connected to the side groove by a spring to provide elastic force so that the other end of the support plate extends out of the material feeding surface. A gear set is installed in the side groove. A first rack is provided on the support plate to mesh with the gear set. A second rack is installed on the cutting machine to mesh with the gear set. When the second rack moves down to mesh with the gear set, it can drive the first rack to move through the gear set so that the end of the support plate extending out of the material feeding surface is retracted into the sliding groove.

[0013] Furthermore, the fixing component includes a bracket and a second telescopic cylinder. The bracket is mounted on the top of the conveyor seat, and the second telescopic cylinder is mounted on the bracket and located above the conveying surface, with its telescopic shaft end facing downward and fitted with a clamping block.

[0014] Furthermore, the length-fixing component includes a guide groove, a threaded rod, a motor, and a positioning block. The guide groove is opened on the unloading surface, the threaded rod is rotatably installed in the guide groove, the motor is installed on the length-fixing base and drivenly connected to the threaded rod, the positioning block is slidably installed in the guide groove along the direction close to or away from the conveyor base and threadedly connected to the threaded rod, and a baffle is provided on the side of the positioning block close to the conveyor base.

[0015] Furthermore, a scale is provided on the feeding surface next to the guide groove.

[0016] Furthermore, a conveyor belt is provided on the side of the fixed-length seat located in the inclined direction of the unloading surface, and a protective plate is provided on the side of the conveyor belt away from the fixed-length seat, with a buffer layer provided on the inner side of the protective plate.

[0017] As can be seen from the above technical solution, this utility model provides a fiberglass fixed-length cutting device:

[0018] The pipe is fixed to the conveyor seat by a fixing component. The cutting machine is started and driven to move down by the first telescopic cylinder, so that the cutting blade cuts the pipe and penetrates into the cutting gap to complete the cutting of the fiberglass pipe. After the pipe is cut, it will roll naturally away from the feeding surface along the inclined direction of the feeding surface, realizing automatic feeding of the pipe. There is no need for workers to move it, which can reduce the labor intensity of workers and improve the efficiency of pipe transfer. After the pipe is cut, the subsequent pipe can be conveyed immediately, which improves the production efficiency. Attached Figure Description

[0019] To more clearly illustrate the specific embodiments of this utility model, the accompanying drawings used in the specific embodiments will be briefly described below. In all the drawings, the elements or parts are not necessarily drawn to scale.

[0020] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0021] Figure 2 This is a cross-sectional view of the side structural schematic diagram of this utility model;

[0022] Figure 3 for Figure 2 A magnified view of a section at point A in the middle;

[0023] Figure label:

[0024] Conveying seat 1, conveying surface 11, side contact surface 111, fixing component 12, bracket 121, second telescopic cylinder 122, pressing block 123;

[0025] 2. Length-fixed seat, 21. Cutting gap, 22. Material feeding surface, 221. Scale, 221. Length-fixed assembly, 23. Guide groove, 231. Threaded rod, 232. Motor, 233. Positioning block, 234. Baffle, 235. Side groove, 24. Sliding groove, 25. Support plate, 26. Spring, 261. First rack, 262. Gear set, 27. Conveyor belt, 28. Protective plate, 281. Buffer layer, 282.

[0026] The cutting mechanism 3 includes a first telescopic cylinder 31, a cutting machine 32, a cutting blade 321, and a second rack 322. Detailed Implementation

[0027] To further illustrate the technical means and effects adopted by this utility model in order to achieve the intended utility model purpose, the following detailed description of the specific implementation methods, structure, features and effects of this utility model is provided in conjunction with the accompanying drawings and preferred embodiments.

[0028] like Figure 1-3 As shown, this embodiment provides a fiberglass fixed-length cutting device, which includes a conveying seat 1, a fixed-length seat 2, and a cutting mechanism 3.

[0029] The top of the conveyor seat 1 is provided with a conveying surface 11 for carrying and conveying the fiberglass pipe to be cut. A fixing component 12 is installed on the top of the conveying surface 11 to fix the fiberglass pipe on the conveying surface 11 to prevent the fiberglass from shifting during cutting.

[0030] Specifically, the fixing component 12 includes a bracket 121 and a second telescopic cylinder 122. The bracket 121 is installed on the top of the conveying seat 1, and the second telescopic cylinder 122 is installed on the bracket 121 and located above the conveying surface 11. Its telescopic shaft end faces downward and is equipped with a clamping block 123. The second telescopic cylinder 122 can be a hydraulic cylinder. By driving the clamping block 123 downward through the second telescopic cylinder 122, the fiberglass can be clamped between the clamping block 123 and the conveying surface 11, thereby fixing the fiberglass pipe before cutting.

[0031] The length-fixing seat 2 is located at one end of the conveyor seat 1, and a cutting gap 21 is left between them. The top of the length-fixing seat 2 is provided with a feeding surface 22, which is inclined towards one side of the length-fixing seat 2 so that the height of one side is lower than the height of the other side. The top of the length-fixing seat 2 is equipped with a length-fixing component 23, which is used to change the cutting length of the fiberglass pipe.

[0032] Specifically, the length-fixing component 23 includes a guide groove 231, a threaded rod 232, a motor 233, and a positioning block 234. The guide groove 231 is opened on the unloading surface 22 and extends along the conveying direction of the fiberglass pipe. The threaded rod 232 is rotatably installed in the guide groove 231 and is parallel to the length direction of the guide groove 231. The motor 233 is installed on the length-fixing seat 2 and is drivenly connected to the threaded rod 232. Specifically, the output shaft end of the motor is coaxially connected to one end of the threaded rod 232. The positioning block 234 is slidably installed in the guide groove 231 in the direction of approaching or away from the conveying seat 1 and is threadedly connected to the threaded rod 232. A baffle 235 is provided on the side of the positioning block 234 near the conveying seat 1. The screw rod 232 is driven to rotate by the motor 233, which can drive the positioning block 234 to move, thereby changing the distance between the baffle 235 and the cutting gap 21. Whenever the fiberglass pipe is conveyed to the baffle 235, the conveying can be stopped, and the pipe can be cut, thereby realizing the adjustment of the cutting length of the fiberglass pipe.

[0033] Preferably, a scale 221 is provided on the unloading surface 22 next to the guide groove 231 so that workers can measure the distance between the baffle 235 and the cutting gap 21, which helps to make the processing precise.

[0034] The cutting mechanism 3 includes a first telescopic cylinder 31 and a cutting machine 32. The first telescopic cylinder 31 can be a hydraulic cylinder, with its telescopic shaft end facing upwards and connected to the cutting machine 32. The cutting machine 32 is equipped with a cutting blade 321, which is located above the cutting gap 21. It should be noted that the cutting machine 32 can be a conventional cutting device, therefore its specific structure will not be described in detail. Figure 1 As shown, the cutting machine 32 in this device is a chainsaw, and the cutting blade 321 is a chainsaw blade. Of course, this utility model does not limit the structure of the cutting machine 32, and conventional cutting equipment has a cutting blade 321. According to actual use needs, other types of cutting equipment can still be selected as the cutting machine 32 in this utility model.

[0035] In practical use, the cutting length of the fiberglass pipe is first determined as needed, and the distance between the baffle 235 and the cutting gap 21 is adjusted by the length-fixing component 23. Then, the produced fiberglass pipe is transported to the conveying surface 11 of the conveying seat 1 by the conveying equipment. The pipe continues to move until its end abuts against the baffle 235. Then, the pipe is fixed to the conveying seat 1 by the fixing component 12. The cutting machine 32 is started and driven to move down by the first telescopic cylinder 31, so that the cutting blade 321 cuts the pipe and penetrates into the cutting gap 21 to complete the cutting of the fiberglass pipe. After the pipe is cut, it will roll naturally away from the feeding surface 22 along the inclined direction of the feeding surface 22, realizing the automatic feeding of the pipe without the need for workers to move it. This can reduce the labor intensity of workers and improve the efficiency of pipe transfer. After the pipe is cut, the subsequent pipes can be transported immediately, which improves the production efficiency.

[0036] Preferably, a conveyor belt 28 is provided on one side of the fixed length seat 2 in the inclined direction of the unloading surface 22. The top surface of the conveyor belt 28 is slightly lower than the height of the lowest side of the unloading surface 22 to receive the FRP pipes rolling off the unloading surface 22. A protective plate 281 is provided on the side of the conveyor belt 28 away from the fixed length seat 2 to prevent the pipes from rolling out of the conveyor belt 28. Furthermore, a buffer layer 282 is provided on the inner side of the protective plate 281. The buffer layer 282 is a rubber layer or a sponge layer, which helps to prevent the pipes from being damaged by hard collision with the protective plate 281.

[0037] In one embodiment, the middle of the conveying surface 11 is V-shaped and recessed, and the two sides form side-facing surfaces 111 that slope inward. When the fiberglass pipe is conveyed on the conveying surface 11, it can always be at the bottom of the V-shaped section of the conveying surface 11, which can effectively prevent the pipe from shifting during conveying. The unloading surface 22 is flush with the surface of one of the side-facing surfaces 111. When the pipe is not cut by the cutting mechanism 3, the unloading surface 22 can provide a certain support for the pipe, preventing the pipe from being suspended and bent in the area of ​​the fixed length seat 2. When the pipe is cut, it can roll away along the inclined direction of the unloading surface 22.

[0038] Furthermore, a side groove 24 is provided on the side of the fixed-length seat 2 away from the material feeding surface 22 in an inclined direction. A sliding groove 25 is provided inside the fixed-length seat 2, with both ends extending through the material feeding surface 22 and the side groove 24. A support plate 26 slides through the sliding groove 25, and the upper surface of the support plate 26 is flush with the surface of the other side contact surface 111. One end of the support plate 26 extends out of the side groove 24 and is connected to the side groove 24 by a spring 261. Specifically, the end of the support plate 26 extending out of the side groove 24 is bent laterally and connected to the side groove 24 by a spring 261. A spring 261 is connected between the side grooves 24 to provide elastic force so that the other end of the support plate 26 passes through the unloading surface 22. A gear set 27 is installed in the side groove 24. Specifically, the gear set 27 consists of two meshing gears. A first rack 262 that meshes with the gear set 27 is provided on the support plate 26. A second rack 322 that can mesh with the gear set 27 is installed on the cutting machine 32. Specifically, the first rack 262 meshes with one of the gears, and the second rack 322 meshes with the other gear.

[0039] Under the tension of spring 261, support plate 26 protrudes from the unloading surface 22. Since the unloading surface 22 and support plate 26 are flush with the two side contact surfaces 111 respectively, the fiberglass pipe can be smoothly moved from the conveyor seat 1 to the fixed length seat 2, and the part of the pipe to be cut can be supported by the unloading surface 22 and support plate 26. When the cutting machine 32 moves down to cut the fiberglass pipe, it will synchronously drive the second rack 322 to move down, so that the second rack 322 continuously approaches the gear set 27. When the cutting machine 32 cuts the pipe with the cutting blade 321... Then, the second rack 322 moves down to mesh with the gear set 27, and can drive the first rack 262 to move through the gear set 27, so that the end of the support plate 26 that protrudes from the unloading surface 22 is retracted into the sliding groove 25. The support plate 26 then releases its support for the pipe, and the cut pipe will naturally roll down the slope of the unloading surface 22. When the cutting machine 32 returns upward, the second rack 322 will drive the first rack 262 to move in the opposite direction through the gear set 27, so that the support plate 26 re-protrudes from the unloading surface 22 to support the pipe to be transferred later. Through this structure, the support plate 26 can support the pipe before the cutting machine 32 cuts it, preventing the pipe from bending or shifting. After the cutting machine 32 cuts the pipe, the support plate 26 can be driven into the sliding groove 25 through the first rack 262, the gear set 27, and the second gear 322, realizing automatic unloading of the pipe and improving processing efficiency.

[0040] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any way. Although the present utility model has been disclosed above with reference to a preferred embodiment, it is not intended to limit the present utility model. Any person skilled in the art can make some modifications or alterations to the above-disclosed technical content to create equivalent embodiments without departing from the scope of the present utility model. Any simple modifications, equivalent changes and alterations made to the above embodiments based on the technical essence of the present utility model without departing from the scope of the present utility model shall still fall within the scope of the present utility model.

Claims

1. A fiberglass fixed-length cutting device, characterized in that, include: A conveyor seat, with a conveying surface on its top, and a fixing component installed on the top of the conveying surface for fixing the fiberglass pipe on the conveying surface; A length-fixing seat is located at one end of the conveyor seat and has a cutting gap between it and the conveyor seat. The top of the length-fixing seat is provided with a feeding surface, which is inclined towards one side of the length-fixing seat. A length-fixing component is installed on the top of the length-fixing seat to change the cutting length of the fiberglass pipe. A cutting mechanism includes a first telescopic cylinder and a cutting machine. The telescopic shaft end of the first telescopic cylinder faces upward and is connected to the cutting machine. The cutting machine is equipped with a cutting blade, which is located above the cutting gap.

2. The fiberglass fixed-length cutting device according to claim 1, wherein the middle part of the conveying surface is V-shaped and recessed, and the two sides thereare inclined side surfaces, and the feeding surface is flush with the surface of one of the side surfaces.

3. The fiberglass fixed-length cutting device according to claim 2, wherein a side groove is provided on the side of the fixed-length seat away from the material feeding surface, and a sliding groove is provided in the fixed-length seat with both ends extending to the material feeding surface and the side groove, a support plate is slidably inserted in the sliding groove, and the upper surface of the support plate is flush with the surface of the other side surface, one end of the support plate extends out of the side groove and is connected to the side groove by a spring to provide elastic force so that the other end of the support plate extends out of the material feeding surface, a gear set is installed in the side groove, a first rack is provided on the support plate to mesh with the gear set, and a second rack is installed on the cutting machine to mesh with the gear set. When the second rack moves down to mesh with the gear set, the first rack can be driven to move through the gear set so that the end of the support plate extending out of the material feeding surface is retracted into the sliding groove.

4. The fiberglass fixed-length cutting device according to claim 1, wherein the fixing component includes a bracket and a second telescopic cylinder, the bracket is installed on the top of the conveying seat, the second telescopic cylinder is installed on the bracket and located above the conveying surface, and its telescopic shaft end faces downward and is equipped with a clamping block.

5. The fiberglass fixed-length cutting device according to claim 1, wherein the fixed-length component includes a guide groove, a threaded rod, a motor and a positioning block, the guide groove is opened on the unloading surface, the threaded rod is rotatably installed in the guide groove, the motor is installed on the fixed-length seat and drivenly connected to the threaded rod, the positioning block is slidably installed in the guide groove along the direction close to or away from the conveyor seat and threadedly connected to the threaded rod, and a baffle is provided on the side of the positioning block close to the conveyor seat.

6. The fiberglass fixed-length cutting device according to claim 5, wherein a scale is provided on the unloading surface next to the guide groove.

7. The fiberglass fixed-length cutting device according to claim 1, wherein a conveyor belt is provided on the side of the fixed-length seat located in the inclined direction of the feeding surface, a protective plate is provided on the side of the conveyor belt away from the fixed-length seat, and a buffer layer is provided on the inner side of the protective plate.