Automatic cloth cutting device

By coordinating the transmission, rotation, and drive components of the automatic fabric cutting device, the problem of cutting deviation caused by the deformation of the cutting tools is solved, achieving efficient and precise fabric cutting.

CN224478329UActive Publication Date: 2026-07-10DONGGUAN TINGYUXUAN GARMENT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN TINGYUXUAN GARMENT CO LTD
Filing Date
2025-07-07
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

When cutting fabrics of different materials or sizes, the existing cutting devices are prone to deformation of the cutting blades, causing deviation in the travel trajectory and affecting the cutting accuracy.

Method used

An automatic fabric cutting device is adopted, which includes a worktable, gantry frame, transmission component, rotating component, grinding component, drive component and cutting component. The transmission component drives the cutting component to move horizontally, the rotating component can rotate 0-360°, and the drive component lifts and lowers to ensure the precise positioning of the cutting blade.

Benefits of technology

It enables diagonal cutting at any angle, ensuring precise positioning during the cutting process, avoiding cutting deviations, and improving cutting accuracy and efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to cloth cutting technology field, concretely is a cloth automatic cutting device, including workstation, gantry, transmission assembly, rotating component, drive component and cutting assembly, drive component is located in rotating component, cutting assembly is located in drive component, and one end of drive component connects cutting assembly and lifts cutting, and through transmission assembly and rotating component drive cutting assembly rotation moves cutting, cutting assembly includes cutting positioning element and cutting blade, and drive component drives cutting positioning element and cutting blade and is oriented cloth positioning cutting of workstation, and through transmission assembly drive cutting assembly and shift along transmission guide rail, and rotating component realizes 0-360 degree free rotation, and cooperation drive component lift movement makes cutting blade can complete any angle's oblique line cutting, through the relative setting of cutting positioning element and cutting blade, ensure accurate positioning in the cutting process, effectively avoid cutting deviation, realize efficient, accurate cloth cutting operation.
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Description

Technical Field

[0001] This utility model relates to the field of fabric cutting technology, specifically to an automatic fabric cutting device. Background Technology

[0002] The garment industry is a highly competitive sector with strong growth momentum in my country's manufacturing industry, and it has become an indispensable part of the economic growth in the new era. With the increasing development of the garment industry, the requirements for tailoring techniques are also getting higher and higher.

[0003] Currently, as an automated fabric cutting device, the cutting machine is prone to deformation of the cutting tool due to differences in fabric size or material during the cutting process, causing the tool's travel trajectory to deviate; thus affecting the cutting accuracy. Utility Model Content

[0004] To address the aforementioned problems, this utility model provides an automatic fabric cutting device. This solves the problem that current cutting machines, as automated fabric cutting equipment, are prone to deformation of the cutting tools during the cutting process due to differences in fabric size or material, causing the tool's trajectory to deviate and thus affecting cutting accuracy.

[0005] The technical solution adopted by this utility model is: an automatic fabric cutting device, including a worktable, a gantry frame, a transmission component, a rotating component, a drive component, and a cutting component; the gantry frame is set on the worktable, the transmission component is set on the gantry frame, the rotating component is set on the transmission component, the drive component is set on the rotating component, and the cutting component is set on the drive component; one end of the drive component is connected to drive the cutting component to perform lifting and lowering cutting, and the transmission component and the rotating component drive the cutting component to rotate and move for cutting.

[0006] The cutting assembly includes a cutting positioning element and a cutting blade. The cutting positioning element and the cutting blade are disposed opposite to each other on the driving assembly. One end of the driving assembly drives the cutting positioning element and the cutting blade toward the fabric on the worktable for positioning and cutting.

[0007] A further improvement to the above solution is that a conveying component is provided on one side of the workbench, the conveying component is arranged opposite to the workbench, and the conveying component is used to convey the fabric toward the workbench; the side of the workbench facing the conveying component is an inclined surface.

[0008] A further improvement to the above solution is that the conveying assembly includes a conveying frame, a conveying motor, a conveying gear, and a conveyor belt. One end of the conveying motor is mounted on the conveying frame, one end of the conveying gear is mounted on the conveying motor, and the conveyor belt is fitted onto the conveying gear. One end of the conveying motor is connected to drive the conveying gear to move the conveyor belt on the conveying frame for conveying.

[0009] A further improvement to the above scheme is that an adjusting element is provided on the gantry frame, the adjusting element is sleeved on the gantry frame, and the adjusting element is used to adjust the length of the gantry frame.

[0010] A further improvement to the above scheme is that the transmission assembly includes a transmission frame, a transmission motor, a transmission guide rail, a transmission slider, and a transmission seat; the transmission frame is mounted on the gantry frame, the transmission motor is mounted on the transmission seat, two sets of transmission guide rails are provided, the two sets of transmission guide rails are located on both sides of the transmission frame, the transmission slider is movably mounted on the transmission guide rail, the transmission seat is mounted on the transmission frame, and the transmission motor is mounted on the transmission seat.

[0011] A further improvement to the above solution is that a transmission link is provided at one end of the transmission motor, a transmission gear is provided at one end of the transmission link, and transmission teeth are provided on the transmission gear near the upper part of the transmission frame; one end of the transmission motor is connected to drive the transmission gear on the transmission link to cooperate with the transmission gear for transmission, so as to drive the cutting component to perform straight cutting.

[0012] A further improvement to the above scheme is that one end of the transmission slider is provided with an oil inlet, and an oil injection element is provided on the oil inlet.

[0013] A further improvement to the above solution is that the rotating assembly includes a rotating motor, a rotating bracket, a rotating connecting rod, a coupling, a rotating wheel, and a mounting base; the rotating motor is mounted on the rotating bracket, one end of the rotating connecting rod is mounted on the rotating motor, one end of the coupling is sleeved on the rotating connecting rod, the rotating wheel is sleeved on the coupling, one end of the rotating connecting rod is mounted on the mounting base, and the driving assembly is mounted on the mounting base and connected to the rotating connecting rod; the rotating assembly drives the driving assembly to rotate, which is used to adjust the orientation of the cutting assembly.

[0014] A further improvement to the above solution is that the driving assembly includes a driving motor, a driving cam, and a driving mounting base. One end of the driving motor is connected to the driving cam, and the driving mounting base is sleeved on the driving cam. The cutting positioning element and the cutting blade are disposed opposite to each other on the driving mounting base. One end of the driving motor is connected to drive the driving cam to drive the cutting positioning element and the cutting blade to perform lifting and lowering cutting.

[0015] A further improvement to the above solution is that the cutting positioning element includes a cutting fixing rod and a cutting pressure plate. The cutting pressure plate is disposed on one side of the cutting fixing rod, and the cutting fixing rod is used to cut and fix the cutting pressure plate. The cutting pressure plate is provided with a cutting groove facing the cutting blade, and the cutting pressure plate performs cutting activities within the cutting groove.

[0016] The beneficial effects of this utility model are:

[0017] Compared to existing cutting devices, this invention uses a transmission component to drive the cutting component to translate along the transmission guide rail, while the rotating component achieves free rotation from 0 to 360°. Combined with the lifting motion of the drive component, this allows the cutting blades to complete diagonal cuts at any angle. The relative arrangement of the cutting positioning element and the cutting blades ensures precise positioning during the cutting process, effectively avoiding cutting deviations. Driven by the drive component, the cutting positioning element and the cutting blades can accurately position and cut the fabric on the worktable, achieving efficient and precise fabric cutting operations. Attached Figure Description

[0018] Figure 1 This is a perspective view of the automatic fabric cutting device of this utility model;

[0019] Figure 2 This is a perspective view of the automatic fabric cutting device of this utility model from another angle;

[0020] Figure 3 This is a schematic diagram of the automatic fabric cutting device of this utility model.

[0021] Explanation of reference numerals in the attached drawings: 10. Workbench; 11. Conveying assembly; 12. Conveying frame; 13. Conveying motor; 14. Conveying gear; 15. Conveying belt.

[0022] 20 gantry frame; 21 adjusting element;

[0023] Transmission assembly 30, transmission frame 31, transmission tooth 311, transmission motor 32, transmission connecting rod 321, transmission gear 322, transmission guide rail 33, transmission slider 34, oil inlet 341, oil inlet element 342, transmission seat 35;

[0024] Rotating assembly 40, rotating motor 41, rotating bracket 42, rotating connecting rod 43, coupling 44, rotating wheel 45, mounting base 46;

[0025] Drive assembly 50, drive motor 51, drive cam 52, drive mounting base 53;

[0026] Cutting assembly 60, cutting positioning element 61, cutting fixing rod 611, cutting pressing sheet 612, cutting shear blade 62. Detailed Implementation

[0027] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. Preferred embodiments of this utility model are shown in the drawings. However, this utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a more thorough and complete understanding of the disclosure of this utility model.

[0028] It should be noted that when a component is said to be "fixed to" another component, it can be directly attached to the other component or there may be an intervening component. When a component is said to be "connected to" another component, it can be directly connected to the other component or there may be an intervening component.

[0029] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

[0030] like Figure 1-3As shown in the embodiment of this utility model, an automatic fabric cutting device includes a worktable 10, a gantry frame 20, a transmission assembly 30, a rotating assembly 40, a drive assembly 50, and a cutting assembly 60. The gantry frame 20 is disposed on the worktable 10, the transmission assembly 30 is disposed on the gantry frame 20, the rotating assembly 40 is disposed on the transmission assembly 30, the drive assembly 50 is disposed on the rotating assembly 40, and the cutting assembly 60 is disposed on the drive assembly 50. One end of the drive assembly 50 is connected to drive the cutting assembly 60 to perform lifting and cutting, and drives the cutting assembly 60 to rotate and move for cutting through the transmission assembly 30 and the rotating assembly 40. The cutting assembly 60 includes a cutting positioning element 61 and a cutting blade 62. The cutting positioning element 61 and the cutting blade 62 are disposed opposite to each other on the drive assembly 50. One end of the drive assembly 50 drives the cutting positioning element 61 and the cutting blade 62 to position and cut the fabric on the worktable 10. In this embodiment, the transmission component 30 drives the cutting component to translate along the transmission guide rail 33, while the rotating component 40 achieves free rotation from 0 to 360°. In conjunction with the lifting and lowering motion of the drive component 50, the cutting blade 62 can complete diagonal cutting at any angle. The relative arrangement of the cutting positioning element 61 and the cutting blade 62 ensures accurate positioning during the cutting process and effectively avoids cutting deviation. Driven by the drive component 50, the cutting positioning element 61 and the cutting blade 62 can accurately position and cut the fabric on the worktable 10, realizing efficient and accurate fabric cutting operations.

[0031] like Figure 3 As shown, a conveying assembly 11 is provided on one side of the workbench 10. The conveying assembly 11 is positioned opposite to the workbench 10 and is used to convey the fabric toward the workbench 10. The side of the workbench 10 facing the conveying assembly 11 is inclined. In this embodiment, the conveying assembly 11 is cleverly configured on one side of the workbench 10 to ensure that the fabric is conveyed smoothly and accurately toward the workbench 10. This optimizes the fabric conveying path, reduces jamming and wrinkling during the conveying process, and greatly improves the fit between the fabric and the workbench 10, laying a solid foundation for subsequent cutting operations.

[0032] The conveying assembly 11 includes a conveying frame 12, a conveying motor 13, a conveying gear 14, and a conveyor belt 15. One end of the conveying motor 13 is mounted on the conveying frame 12, and one end of the conveying gear 14 is mounted on the conveying motor 13. The conveyor belt 15 is fitted onto the conveying gear 14. One end of the conveying motor 13 drives the conveying gear 14 to move the conveyor belt 15 on the conveying frame 12 for conveying. In this embodiment, the conveying frame 12 serves as a support structure, ensuring the stable operation of the entire assembly. The conveying motor 13, as a power source, has one end firmly mounted on the conveying frame 12, providing a stable and powerful power output. The precise connection between the conveying gear 14 and the conveying motor 13 accurately transmits the motor's driving force, thereby driving the conveyor belt 15. The conveyor belt 15, fitted onto the conveying gear 14, forms a smooth conveying path, allowing the fabric to move smoothly and continuously on the conveyor belt 15. The entire conveying process is highly automated, effectively improving the efficiency and accuracy of fabric cutting and providing strong support for the overall performance of the automatic fabric cutting device.

[0033] An adjusting element 21 is provided on the gantry frame 20. The adjusting element 21 is sleeved on the gantry frame 20 and is used to adjust the length of the gantry frame 20. In this embodiment, the adjusting element 21 cleverly provided on the gantry frame 20 brings significant flexibility and adaptability to the automatic fabric cutting device. By tightly sleeved on the gantry frame 20, the length of the gantry frame 20 can be easily and accurately adjusted through precise operation. This allows the device to adapt to the cutting needs of fabrics of different sizes and specifications, and also greatly improves work efficiency and cutting accuracy.

[0034] The transmission assembly 30 includes a transmission frame 31, a transmission motor 32, a transmission guide rail 33, a transmission slider 34, and a transmission seat 35. The transmission frame 31 is mounted on the gantry frame 20, the transmission motor 32 is mounted on the transmission seat 35, two sets of transmission guide rails 33 are provided on both sides of the transmission frame 31, the transmission slider 34 is movably mounted on the transmission guide rails 33, the transmission seat 35 is mounted on the transmission frame 31, and the transmission motor 32 is mounted on the transmission seat 35. In this embodiment, the transmission frame 31 is securely mounted on the gantry frame 20, ensuring the stability of the entire transmission system. The transmission motor 32 is cleverly positioned on the transmission seat 35, and precise displacement control is achieved by driving the transmission seat 35 to move on the transmission frame 31. Furthermore, two sets of transmission guide rails 33 are respectively positioned on both sides of the transmission frame 31, providing a smooth and precise movement path for the transmission slider 34. Through the movable setting of the transmission slider 34 on the transmission guide rails 33, the transmission seat 35 can perform linear motion smoothly, improving the cutting accuracy and enhancing the durability and reliability of the device.

[0035] like Figures 1 to 2 As shown, a transmission link 321 is provided at one end of the transmission motor 32, and a transmission gear 322 is provided at one end of the transmission link 321. The transmission gear 322 has transmission teeth 311 above it near the transmission frame 31. One end of the transmission motor 32 is connected to drive the transmission gear 322 on the transmission link 321 to cooperate with the transmission gear 322 for transmission, which is used by the transmission assembly 30 to drive the cutting assembly 60 to perform linear cutting. In this embodiment, the transmission link 321 is cleverly set at one end of the transmission motor 32, and the end of the link is equipped with a precision transmission gear 322 with fine transmission teeth 311, which ensures the stability and accuracy of the transmission. This allows the transmission motor 32 to smoothly drive the gear on the link and cooperate closely with the other transmission gear 322 to form a stable transmission system. This effectively drives the cutting assembly 60 to perform linear motion, realizing automatic and precise cutting of the fabric, and greatly improving cutting efficiency and quality.

[0036] One end of the transmission slider 34 is provided with an oil inlet 341, and an oil injection element 342 is provided on the oil inlet 341. In this embodiment, the oil injection element 342 can accurately deliver lubricant into the transmission slider 34, effectively reducing the friction and wear of the slider during movement; extending the service life of the transmission slider 34; and ensuring the overall stability and accuracy of the cutting device.

[0037] The rotating assembly 40 includes a rotating motor 41, a rotating bracket 42, a rotating connecting rod 43, a coupling 44, a rotating wheel 45, and a mounting base 46. The rotating motor 41 is mounted on the rotating bracket 42, one end of the rotating connecting rod 43 is mounted on the rotating motor 41, one end of the coupling 44 is sleeved on the rotating connecting rod 43, the rotating wheel 45 is sleeved on the coupling 44, one end of the rotating connecting rod 43 is mounted on the mounting base 46, and the driving assembly 50 is mounted on the mounting base 46 and connected to the rotating connecting rod 43. The rotating assembly 40 drives the driving assembly 50 to rotate, which is used to adjust the orientation of the cutting assembly 60. In this embodiment, a rotary motor 41 is mounted on a rotary bracket 42, and a rotary connecting rod 43 is tightly engaged with a coupling 44 to drive the rotary wheel 45 to rotate stably. One end of the rotary connecting rod 43 is cleverly fixed to the mounting base 46, ensuring the stability of the entire rotary assembly 40. The drive assembly 50 is connected to the rotary connecting rod 43, enabling the rotary assembly 40 to drive the drive assembly 50 to rotate, thereby precisely adjusting the position of the cutting assembly 60.

[0038] The drive assembly 50 includes a drive motor 51, a drive cam 52, and a drive mounting base 53. One end of the drive motor 51 is connected to the drive cam 52, and the drive mounting base 53 is sleeved on the drive cam 52. The cutting positioning element 61 and the cutting blade 62 are disposed opposite each other on the drive mounting base 53. One end of the drive motor 51 drives the drive cam 52 to drive the cutting positioning element 61 and the cutting blade 62 to perform lifting and lowering cutting. In this embodiment, the connection between the drive motor 51 and the drive cam 52 achieves efficient power transmission. The drive mounting base 53 is securely sleeved on the drive cam 52, ensuring the stability of the entire drive system. The arrangement of the cutting positioning element 61 and the cutting blade 62 opposite each other on the drive mounting base 53 makes the cutting process more precise and reliable. When the drive motor 51 starts, it drives the drive cam 52 to rotate, thereby driving the cutting positioning element 61 and the cutting blade 62 to perform lifting and lowering cutting actions. This improves cutting efficiency, ensures cutting quality, and enhances the overall level of production automation.

[0039] The cutting positioning element 61 includes a cutting fixing rod 611 and a cutting pressure plate 612. The cutting pressure plate 612 is disposed on one side of the cutting fixing rod 611, and the cutting fixing rod 611 is used to fix the cutting pressure plate 612 during cutting. The cutting pressure plate 612 has a cutting groove facing the cutting blade 62, and the cutting pressure plate 612 performs cutting activities within the cutting groove. In this embodiment, the cutting fixing rod 611 and the cutting pressure plate 612 work together to ensure the accuracy and stability of cutting. The cutting fixing rod 611 firmly supports the fabric, providing a stable reference for the cutting process; while the cutting pressure plate 612 is cleverly disposed on one side of the fixing rod, guiding the cutting blade 62 to perform precise cutting activities through the cutting groove on it. This improves cutting efficiency and greatly enhances cutting accuracy, making the fabric cutting neater and more standardized; it optimizes the performance of the automatic fabric cutting device and improves the overall cutting effect.

[0040] An automatic fabric cutting device includes a worktable 10, a gantry frame 20, a transmission assembly 30, a rotating assembly 40, a drive assembly 50, and a cutting assembly 60. The gantry frame 20 is mounted on the worktable 10, the transmission assembly 30 is mounted on the gantry frame 20, the rotating assembly 40 is mounted on the transmission assembly 30, the drive assembly 50 is mounted on the rotating assembly 40, and the cutting assembly 60 is mounted on the drive assembly 50. One end of the drive assembly 50 is connected to drive the cutting assembly 60 to perform lifting and cutting, and the transmission assembly 30 and the rotating assembly 40 drive the cutting assembly 60 to rotate and move for cutting. The cutting assembly 60 includes a cutting positioning element and a cutting blade 62. The cutting positioning element 61 and the cutting blade 62 are disposed opposite to each other on the drive assembly 50. One end of the drive assembly 50 drives the cutting positioning element 61 and the cutting blade 62 to position and cut the fabric on the worktable 10. In this embodiment, the transmission component 30 drives the cutting component to translate along the transmission guide rail 33, while the rotating component 40 achieves free rotation from 0 to 360°. In conjunction with the lifting and lowering motion of the drive component 50, the cutting blade 62 can complete diagonal cutting at any angle. The relative arrangement of the cutting positioning element 61 and the cutting blade 62 ensures accurate positioning during the cutting process and effectively avoids cutting deviation. Driven by the drive component 50, the cutting positioning element 61 and the cutting blade 62 can accurately position and cut the fabric on the worktable 10, realizing efficient and accurate fabric cutting operations.

[0041] The above embodiments only illustrate several implementation methods of this utility model, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.

Claims

1. An automatic fabric cutting device, characterized in that: It includes a worktable, a gantry frame, a transmission assembly, a rotating assembly, a drive assembly, and a cutting assembly; the gantry frame is mounted on the worktable, the transmission assembly is mounted on the gantry frame, the rotating assembly is mounted on the transmission assembly, the drive assembly is mounted on the rotating assembly, and the cutting assembly is mounted on the drive assembly. One end of the drive assembly is connected to drive the cutting assembly to perform lifting and lowering cutting, and the drive assembly and the rotating assembly drive the cutting assembly to rotate and move for cutting. The cutting assembly includes a cutting positioning element and a cutting blade. The cutting positioning element and the cutting blade are disposed opposite to each other on the driving assembly. One end of the driving assembly drives the cutting positioning element and the cutting blade toward the fabric on the worktable for positioning and cutting.

2. The automatic fabric cutting device according to claim 1, characterized in that: A conveying assembly is provided on one side of the workbench, and the conveying assembly is arranged opposite to the workbench. The conveying assembly is used to convey the fabric toward the workbench; the side of the workbench facing the conveying assembly is an inclined surface.

3. The automatic fabric cutting device according to claim 2, characterized in that: The conveying assembly includes a conveying frame, a conveying motor, a conveying gear, and a conveyor belt. One end of the conveying motor is mounted on the conveying frame, one end of the conveying gear is mounted on the conveying motor, and the conveyor belt is fitted onto the conveying gear. One end of the conveying motor is connected to drive the conveying gear to move the conveyor belt on the conveying frame for conveying.

4. The automatic fabric cutting device according to claim 1, characterized in that: The gantry frame is equipped with an adjustment element, which is sleeved on the gantry frame and is used to adjust the length of the gantry frame.

5. The automatic fabric cutting device according to claim 4, characterized in that: The transmission assembly includes a transmission frame, a transmission motor, transmission guide rails, a transmission slider, and a transmission base. The transmission frame is mounted on the gantry frame, the transmission motor is mounted on the transmission base, two sets of transmission guide rails are provided on both sides of the transmission frame, the transmission slider is movably mounted on the transmission guide rails, the transmission base is mounted on the transmission frame, and the transmission motor is mounted on the transmission base.

6. The automatic fabric cutting device according to claim 5, characterized in that: One end of the drive motor is provided with a drive linkage, and one end of the drive linkage is provided with a drive gear. The drive gear is provided with drive teeth near the upper part of the drive frame. One end of the drive motor is connected to drive the drive gear on the drive linkage to cooperate with the drive gear for transmission, so as to drive the cutting component to perform straight cutting.

7. The automatic fabric cutting device according to claim 6, characterized in that: One end of the transmission slider is provided with an oil inlet, and an oil injection element is provided on the oil inlet.

8. The automatic fabric cutting device according to claim 1, characterized in that: The rotating assembly includes a rotary motor, a rotating bracket, a rotating connecting rod, a coupling, a rotating wheel, and a mounting base. The rotary motor is mounted on the rotating bracket, one end of the rotating connecting rod is mounted on the rotary motor, one end of the coupling is sleeved on the rotating connecting rod, the rotating wheel is sleeved on the coupling, one end of the rotating connecting rod is mounted on the mounting base, and the drive assembly is mounted on the mounting base and connected to the rotating connecting rod. The rotating assembly drives the drive assembly to rotate, thereby adjusting the orientation of the cutting assembly.

9. The automatic fabric cutting device according to claim 8, characterized in that: The drive assembly includes a drive motor, a drive cam, and a drive mounting base. One end of the drive motor is connected to the drive cam, and the drive mounting base is sleeved on the drive cam. The cutting positioning element and the cutting blade are disposed opposite to each other on the drive mounting base. One end of the drive motor is connected to drive the drive cam to drive the cutting positioning element and the cutting blade to perform lifting and lowering cutting.

10. The automatic fabric cutting device according to claim 9, characterized in that: The cutting positioning element includes a cutting fixing rod and a cutting pressure plate. The cutting pressure plate is disposed on one side of the cutting fixing rod, and the cutting fixing rod is used to cut and fix the cutting pressure plate. The cutting pressure plate is provided with a cutting groove facing the cutting blade, and the cutting pressure plate performs cutting activities within the cutting groove.