Multifunctional cutting machine for glass fiber reinforced plastic pipe
By designing a multi-angle adjustment mechanism and a drive mechanism, the multi-functional fiberglass pipe cutting machine solves the problem that traditional cutting machines cannot meet the requirements of multi-angle cutting, achieving precise and flexible cutting results and adapting to the cutting needs of complex shapes and high precision.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINJIANG XINYE COMPOSITE MATERIAL CO LTD
- Filing Date
- 2025-06-25
- Publication Date
- 2026-06-05
AI Technical Summary
Traditional fiberglass pipe cutting machines, due to their fixed material settings, limit the application range of the equipment, making it difficult to meet the needs of multi-angle cutting and reducing operational flexibility.
A multi-functional fiberglass pipe cutting machine was designed, which includes a multi-angle adjustment mechanism and a drive mechanism. Through the linkage of the moving table, limit slider, first rotating shaft and cutting platform, the cutting angle and position can be flexibly adjusted. Combined with the mechanical transmission of motor and gear rack, the precise movement and rotation of the cutting platform are ensured.
It enables precise cutting of fiberglass pipes, improves operational flexibility and cutting quality, can adapt to complex shapes and high-precision cutting tasks, and enhances the ease of operation and cutting efficiency of the equipment.
Smart Images

Figure CN224323197U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of fiberglass pipe cutting technology, specifically relating to a multi-functional fiberglass pipe cutting machine. Background Technology
[0002] A multi-functional fiberglass pipe cutting machine is a mechanical device specifically designed for cutting fiberglass pipes. Fiberglass (Glass Fiber Reinforced Plastics, abbreviated as GFRP) pipes are widely used in industries such as chemical, petroleum, natural gas, and water supply and drainage due to their excellent corrosion resistance, lightweight and high strength, and long service life. However, the special properties of fiberglass materials also place higher demands on cutting and processing.
[0003] In the existing technology, traditional FRP pipe cutting machines, due to their fixed material settings, limit the application range of the equipment and make it difficult to meet the needs of some tasks that require multi-angle cutting, thus reducing their operational flexibility.
[0004] The aforementioned patents can solve this problem, but they have certain drawbacks in their application. Utility Model Content
[0005] The purpose of this utility model is to provide a multi-functional fiberglass pipe cutting machine, which aims to solve the problem that the traditional fiberglass pipe cutting machine in the prior art uses a fixed material setting, which limits the application range of the equipment and makes it difficult to meet the needs of some tasks that require multi-angle cutting, thereby reducing its operational flexibility.
[0006] To achieve the above objectives, this utility model provides the following technical solution:
[0007] A multi-functional fiberglass pipe cutting machine, comprising:
[0008] Work platform;
[0009] A multi-angle adjustment mechanism is provided on the upper side of the work platform. The multi-angle adjustment mechanism includes a moving stage, a limiting slider, a first rotating shaft, and a cutting platform. The moving stage is slidably connected to the work platform. The two limiting sliders are respectively fixedly connected to both ends of the moving stage. Both limiting sliders are slidably connected to the work platform. The first rotating shaft is fixedly connected to the upper end of the moving stage. The cutting platform is rotatably connected to the circumferential surface of the first rotating shaft.
[0010] A drive mechanism is located on the underside of the moving platform.
[0011] In a preferred embodiment of this utility model, the driving mechanism includes a first motor, a gear, and a rack. The first motor is fixedly connected inside the moving platform, the gear is fixedly connected to the lower end of the first motor, and the rack is fixedly connected to the lower end of the working platform. The gear and the rack mesh with each other.
[0012] In a preferred embodiment of this utility model, two first retainers are fixedly connected to one end of each rack, and two first retainers are fixedly connected to the lower end of each working platform.
[0013] In a preferred embodiment of this utility model, two grippers are fixedly connected to the upper end of the cutting platform, two locking blocks are slidably connected inside each of the two grippers, and two threaded rods are threadedly rotatably connected inside each of the grippers and locking blocks. Two first handles are fixedly connected to both ends of the cutting platform.
[0014] As a preferred embodiment of this utility model, the upper end of the work platform is fixedly connected to a mounting frame, and two second fixtures are fixedly connected to both ends of the mounting frame. A second rotating shaft is rotatably connected inside each of the two second fixtures, and a cutting machine is fixedly connected to the circumferential surface of the second rotating shaft.
[0015] In a preferred embodiment of this utility model, a second motor is fixedly connected to one end of the cutting machine, a cutting blade is rotatably connected inside the cutting machine, and a second handle is fixedly connected to the upper end of the cutting machine.
[0016] Compared with the prior art, the beneficial effects of this utility model are:
[0017] I. In this solution, the present invention ensures more precise cutting lines by accurately controlling the position and angle of the material. This is especially important when dealing with complex shapes or cutting tasks that require high precision. At the same time, it also allows the operator to approach the workpiece more conveniently from different angles and positions to adapt to various complex cutting needs, such as grooving and chamfering.
[0018] II. In this scheme, the drive mechanism consists of a first motor, a gear, and a rack. This mechanism drives the moving platform through the linkage between the motor and the mechanical transmission components. In actual operation, the first motor is fixed inside the moving platform as a power source. Its output shaft extends downward and is rigidly connected to the gear. The gear meshes with the rack fixed at the bottom of the working platform. When the first motor is powered on, it drives the gear to rotate. Since the rack is fixed, the gear rolls on its tooth surface, thereby driving the entire moving platform to reciprocate linearly along the working platform. Attached Figure Description
[0019] The accompanying drawings are provided to further illustrate the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention, but do not constitute a limitation thereof. In the drawings:
[0020] Figure 1 This is a first side perspective view of the present invention;
[0021] Figure 2 This is a bottom perspective view of the present invention;
[0022] Figure 3 This is a second side perspective view of the present invention;
[0023] Figure 4 This is an exploded perspective view of the present invention;
[0024] In the diagram: 1. Working platform; 2. Moving table; 3. Limiting slider; 4. First rotating shaft; 5. Cutting platform; 6. First motor; 7. Gear; 8. Rack; 9. First retainer; 10. Clamp; 11. Locking block; 12. Threaded rod; 13. First handle; 14. Mounting bracket; 15. Second retainer; 16. Second rotating shaft; 17. Cutting machine; 18. Second motor; 19. Cutting disc; 20. Second handle. Detailed Implementation
[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0026] Example
[0027] Please see Figures 1-4 The present invention provides the following technical solution:
[0028] A multi-functional fiberglass pipe cutting machine, comprising:
[0029] Work platform 1;
[0030] A multi-angle adjustment mechanism is located on the upper side of the work platform 1. The multi-angle adjustment mechanism includes a moving stage 2, a limiting slider 3, a first rotating shaft 4, and a cutting platform 5. The moving stage 2 is slidably connected to the work platform 1. The two limiting sliders 3 are respectively fixedly connected to the two ends of the moving stage 2. Both limiting sliders 3 are slidably connected to the work platform 1. The first rotating shaft 4 is fixedly connected to the upper end of the moving stage 2. The cutting platform 5 is rotatably connected to the circumferential surface of the first rotating shaft 4.
[0031] The drive mechanism is located on the lower side of the moving platform 2.
[0032] In a specific embodiment of this utility model, the multi-angle adjustment mechanism in the multi-functional fiberglass pipe cutting machine achieves flexible adjustment of the cutting angle and position through the linkage between multiple components. Its core structure includes a moving table 2, a limiting slider 3, a first rotating shaft 4, and a cutting platform 5. These components form a sliding and rotating cooperation relationship with the working platform 1. In actual operation, the drive mechanism is installed below the moving table 2, providing power to make the moving table 2 slide horizontally along a direction set inside the working platform 1. This sliding process drives the limiting slider 3, which is fixedly connected to it, to move synchronously. The limiting slider 3 is embedded in the working platform 1 and slides along its guide rail, playing a guiding and limiting role, ensuring smooth operation and accurate positioning during movement. At the same time, the first rotating shaft 4 is fixed to the upper end of the moving table 2, and the cutting platform 5 is rotatably connected to the circumferential surface of the first rotating shaft 4 through bearings or similar structures, so that the cutting platform 5 can rotate and adjust around the first rotating shaft 4, thereby changing the cutting angle of the material to be processed. This design not only realizes the degree of freedom of movement of the cutting platform 5 in the horizontal direction, but also has the degree of freedom of rotation around the central axis, which greatly improves the flexibility of the equipment in operation. It allows users to quickly adjust the cutting position and angle according to the fiberglass pipes of different shapes and sizes, thereby meeting the processing needs under complex working conditions. At the same time, since the mechanical linkage between the components ensures the stability of the movement process and the repeatability of the positioning accuracy, it helps to improve the cutting quality and work efficiency.
[0033] Please refer to the details. Figures 1-4 The drive mechanism includes a first motor 6, a gear 7 and a rack 8. The first motor 6 is fixedly connected inside the moving platform 2, the gear 7 is fixedly connected to the lower end of the first motor 6, and the rack 8 is fixedly connected to the lower end of the working platform 1. The gear 7 and the rack 8 mesh with each other.
[0034] In this embodiment, the drive mechanism consists of a first motor 6, a gear 7, and a rack 8. This mechanism drives the moving platform 2 through the linkage between the motor and the mechanical transmission components. In actual operation, the first motor 6 is fixed inside the moving platform 2 as a power source. Its output axis extends downward and is rigidly connected to the gear 7. The gear 7 is meshed with the rack 8 fixed at the bottom of the working platform 1. When the first motor 6 is powered on, it drives the gear 7 to rotate. Since the rack 8 is fixed, the gear 7 rolls on its tooth surface, thereby driving the entire moving platform 2 to perform linear reciprocating motion along the working platform 1.
[0035] Please refer to the details. Figures 1-4 Two first retainers 9 are fixedly connected to one end of each rack 8, and two first retainers 9 are fixedly connected to the lower end of each working platform 1.
[0036] In this embodiment: During equipment operation, the first fixture 9 serves as a connecting and supporting component, rigidly fixing the rack 8 to the working platform 1, so that the rack 8 can be stably installed at the bottom of the working platform 1, and ensuring that the meshing transmission between it and the gear 7 maintains the correct alignment. By fixing the two ends of the rack 8 with the two first fixtures 9, the overall structural rigidity and transmission stability of the rack 8 can be effectively enhanced, avoiding meshing deviation or movement jamming caused by uneven force or loosening, thereby ensuring that the drive mechanism has higher precision and stability when driving the moving table 2 to slide, and also helping to improve the reliability and durability of the entire cutting machine in long-term use.
[0037] Please refer to the details. Figures 1-4 Two grippers 10 are fixedly connected to the upper end of the cutting platform 5. Two locking blocks 11 are slidably connected inside each gripper 10. Two threaded rods 12 are threadedly rotatably connected inside each gripper 10 and locking block 11. Two first handles 13 are fixedly connected to both ends of the cutting platform 5.
[0038] In this embodiment: In actual operation, the locking block 11 is moved in a straight line inside the clamp 10 by rotating the threaded rod 12, thereby clamping or releasing the fiberglass pipe placed between the clamps 10. The clamp 10 serves as a support and installation base, providing guidance for the locking block 11, enabling it to slide stably and maintain a uniform distribution of clamping force. The threaded rod 12 converts the rotational motion into linear displacement through threaded transmission, thereby precisely controlling the clamping force and position. This structural design allows the material to be firmly fixed during the cutting process, preventing positional displacement caused by vibration or external force. It also facilitates quick adjustment to adapt to pipes of different diameters, improving the applicability and cutting stability of the equipment.
[0039] Please refer to the details. Figures 1-4 The upper end of the work platform 1 is fixedly connected to a mounting bracket 14. Two second fixtures 15 are fixedly connected to both ends of the mounting bracket 14. A second rotating shaft 16 is rotatably connected inside each of the two second fixtures 15. A cutting machine 17 is fixedly connected to the circumferential surface of the second rotating shaft 16.
[0040] In this embodiment: During equipment operation, the second fixture 15 serves as a support component, providing a pivot point for the second rotating shaft 16, enabling the cutting machine 17 to adjust its angle and rotate via the second rotating shaft 16. Through this structure, the cutting machine 17 can rotate around the axis in cooperation with the second fixture 15 and the second rotating shaft 16, thereby adjusting the cutting angle to meet the processing requirements of fiberglass pipes of different shapes or sizes, while ensuring stability and positioning accuracy during the cutting process, and improving the operational flexibility and cutting efficiency of the equipment.
[0041] Please refer to the details. Figures 1-4 A second motor 18 is fixedly connected to one end of the cutting machine 17, a cutting blade 19 is rotatably connected inside the cutting machine 17, and a second handle 20 is fixedly connected to the upper end of the cutting machine 17.
[0042] In this embodiment: the second motor 18 serves as a power source to drive the cutting blade 19 to rotate at high speed, thereby realizing the cutting operation of the fiberglass pipe. At the same time, the cutting blade 19 is rotatably connected to the cutting machine 17 through a bearing or similar structure to ensure that it maintains a stable rotation state during operation. The second handle 20 is used by the operator to control the overall movement and angle adjustment of the cutting machine 17, making the cutting action more precise and controllable. This structure achieves an efficient and stable cutting process by driving the cutting blade 19 to rotate through the motor, and the second handle 20 assists in adjusting the cutting position, improving the ease of operation and cutting accuracy of the equipment.
[0043] The working principle and usage process of this utility model are as follows: First, the fiberglass pipe is placed between the two clamps 10 on the cutting platform 5. The locking block 11 slides within the clamps 10 by rotating the threaded rod 12, thus clamping and fixing the pipe. Then, the cutting platform 5 is adjusted according to the required cutting angle, rotating around the first rotating shaft 4 to a suitable position. The sliding engagement of the moving table 2 within the working platform 1 drives the limiting slider 3 to move along the guide rail, achieving overall position adjustment of the cutting platform 5. After the first motor 6 in the drive mechanism starts, it drives the gear 7 to rotate. The gear 7 meshes with the rack 8 fixed at the lower end of the working platform 1, causing the moving table 2 and the cutting platform 5 to move stably together to the desired position. The operator controls the cutting machine 17 mounted on the second rotating shaft 16 via the second handle 20. The second rotating shaft 16 rotates within the second fixture 15, adjusting the cutting angle. After the second motor 18 starts, it drives the cutting blade 19 to rotate at high speed, completing the precise cutting of the fiberglass pipe. Throughout the process, all components work together to ensure the stability, flexibility, and accuracy of the cutting operation. This invention ensures a more precise cutting line by accurately controlling the position and angle of the material, which is especially important when dealing with complex shapes or high-precision cutting tasks. At the same time, it also allows the operator to more easily approach the workpiece from different angles and positions to adapt to various complex cutting needs, such as grooving and chamfering.
[0044] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A multi-functional cutting machine for fiberglass pipes, characterized in that... include: Work platform (1); A multi-angle adjustment mechanism is provided on the upper side of the working platform (1). The multi-angle adjustment mechanism includes a moving stage (2), a limiting slider (3), a first rotating shaft (4), and a cutting platform (5). The moving stage (2) is slidably connected to the working platform (1). The two limiting sliders (3) are respectively fixedly connected to the two ends of the moving stage (2). The two limiting sliders (3) are slidably connected to the working platform (1). The first rotating shaft (4) is fixedly connected to the upper end of the moving stage (2). The cutting platform (5) is rotatably connected to the circumferential surface of the first rotating shaft (4). A drive mechanism is located on the underside of the moving platform (2).
2. The multi-functional fiberglass pipe cutting machine according to claim 1, characterized in that: The drive mechanism includes a first motor (6), a gear (7) and a rack (8). The first motor (6) is fixedly connected to the moving platform (2). The gear (7) is fixedly connected to the lower end of the first motor (6). The rack (8) is fixedly connected to the lower end of the working platform (1). The gear (7) and the rack (8) mesh with each other.
3. The multi-functional fiberglass pipe cutting machine according to claim 2, characterized in that: Two first retainers (9) are fixedly connected to one end of each rack (8), and two first retainers (9) are fixedly connected to the lower end of each working platform (1).
4. A multi-functional fiberglass pipe cutting machine according to claim 3, characterized in that: The upper end of the cutting platform (5) is fixedly connected to two clamps (10), and two locking blocks (11) are slidably connected in the two clamps (10). Two threaded rods (12) are threadedly connected in the clamps (10) and locking blocks (11). Two first handles (13) are fixedly connected to both ends of the cutting platform (5).
5. A multi-functional fiberglass pipe cutting machine according to claim 4, characterized in that: The upper end of the working platform (1) is fixedly connected to a mounting frame (14), and two second fixtures (15) are fixedly connected to both ends of the mounting frame (14). A second rotating shaft (16) is rotatably connected inside each of the two second fixtures (15), and a cutting machine (17) is fixedly connected to the circumferential surface of the second rotating shaft (16).
6. A multi-functional fiberglass pipe cutting machine according to claim 5, characterized in that: A second motor (18) is fixedly connected to one end of the cutting machine (17), a cutting blade (19) is rotatably connected inside the cutting machine (17), and a second handle (20) is fixedly connected to the upper end of the cutting machine (17).