A garment pattern printing device for producing windbreakers
By integrating heating, lifting, and printing modules into the printing worktable, and combining drive components and flattening frames, the problem of existing devices being unable to adapt to jackets of different thicknesses has been solved, achieving high-precision pattern printing and efficient printing results.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HEFEI INSPORT OUTDOOR TECH CO LTD
- Filing Date
- 2025-08-09
- Publication Date
- 2026-07-03
Smart Images

Figure CN224447195U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of clothing pattern printing device, and in particular to a clothing pattern printing device for producing windbreakers. Background Technology
[0002] With the rapid development of the garment industry, especially in the production of outdoor jackets, the demand for printing garment patterns is constantly increasing. This requires not only high-precision pattern transfer but also adaptation to different styles and thicknesses of outdoor jackets. This places higher demands on production equipment, particularly in the printing process. Ensuring the fabric is flat and securely fixed, while achieving uniform printing results on fabrics of varying thicknesses, has become a significant technological challenge.
[0003] For example, Chinese utility model patent application number 202421094487.X discloses a garment pattern printing device for producing outdoor jackets, including a support base, a fixed seat fixedly connected to one side of the support base, an mounting plate provided above the support base, a motion guide rod fixedly connected between the mounting plate and the support base, a linkage frame slidably connected to the outside of the motion guide rod, an ink storage box fixedly connected to one side of the linkage frame, a flat screen plate fixedly connected to the bottom inner wall of the ink storage box, an ink extrusion plate slidably connected to the inside of the ink storage box, a linkage adjustment seat slidably connected to the outside of the motion guide rod, and a limit rod fixedly connected to one side of the linkage adjustment seat. Through the cooperation of the linkage adjustment seat and positioning plate and other components, the worker can flatten and position the outdoor jacket in advance before printing the pattern, thereby avoiding wrinkles or other issues during the printing process and ensuring the printing effect of the outdoor jacket.
[0004] Existing equipment for printing patterns on rain jackets mostly uses a fixed-height clamping frame, which cannot be adjusted according to the thickness of the rain jacket. Therefore, during the printing process, especially when dealing with rain jackets of different thicknesses and textures, it is often impossible to achieve sufficient clamping, resulting in poor printing effects. In addition, existing equipment mostly relies on manual flattening, which is inefficient. Utility Model Content
[0005] The purpose of this utility model is to address the shortcomings of existing technologies by proposing a garment pattern printing device for the production of windbreakers.
[0006] To achieve the above objectives, the present invention adopts the following technical solution: a garment pattern printing device for producing windbreakers, comprising a printing operating table, a heater and a lifting frame fixedly installed on the top of the printing operating table, two guide rods fixedly connected to the inner top surface of the lifting frame, a moving block slidably connected to the outer walls of the two guide rods, a driving component capable of driving the moving block to move up and down provided on the top of the lifting frame, a flattening frame fixedly connected to one side of the moving block, a flattening groove and two limiting grooves respectively opened on the front of the flattening frame, two moving frames slidably connected inside the two limiting grooves, a moving component capable of driving the two moving frames to move relative to or away from each other provided on one side of the flattening frame, an adjusting component provided on the top of the moving frame, and a printing component provided on the top of the lifting frame.
[0007] The printing platform serves as the device's carrying platform, integrating core modules such as heating, lifting, and printing. It is made of stainless steel for corrosion resistance, and the heater has a built-in nickel-chromium alloy heating wire to provide a controllable heat source, accelerate ink curing, and prevent discoloration in low-temperature environments. The lifting frame and guide rods form a vertical guide frame, restricting the movement of the moving block to only move along the Z-axis. The flattening frame carries the bidirectional flattening mechanism, and flattening grooves and limiting grooves provide a movement track to ensure that the moving frame slides only horizontally without swaying.
[0008] As a further description of the above technical solution:
[0009] The drive assembly includes a drive motor fixedly installed on the top of the lifting frame. The output end of the drive motor rotates through the interior of the lifting frame and is fixedly connected to a threaded rod. The outer wall of the threaded rod is threadedly connected to the moving block.
[0010] The bottom end of the threaded rod is rotatably connected to the top of the printing operation table, and the drive motor drives the threaded rod to rotate, which is converted into the precise lifting and lowering of the moving block.
[0011] As a further description of the above technical solution:
[0012] The moving component includes a servo motor fixedly installed on one side of the leveling frame. The output end of the servo motor rotates through the leveling groove and is fixedly connected to a bidirectional lead screw.
[0013] One end of the bidirectional lead screw is rotatably connected to the inner wall of the leveling groove. The servo motor drives the bidirectional lead screw, causing the two threaded blocks to move towards or away from each other.
[0014] As a further description of the above technical solution:
[0015] The outer wall of the bidirectional lead screw has two threaded blocks.
[0016] The front of the threaded block is fixedly connected to the movable frame, and the outer wall of the threaded block slides along the leveling groove.
[0017] As a further description of the above technical solution:
[0018] The adjustment assembly includes an electric telescopic rod fixedly installed on the top of the mobile frame. The telescopic end of the electric telescopic rod passes through the mobile frame and is fixedly connected to a mounting base. A flat plate is detachably installed on the inner wall of the mounting base by bolts.
[0019] The electric telescopic rod pushes the flatbed to press the fabric vertically. The staff can control the extension and retraction length of the electric telescopic rod through the controller on the printing operation table. The pressure sensor is also installed on it to provide real-time feedback.
[0020] As a further description of the above technical solution:
[0021] The printing assembly includes two L-shaped plates fixedly installed on the top of the lifting frame, and a printer is fixedly installed on the front of the two L-shaped plates by a cylinder.
[0022] The cylinder pushes the printer downward to perform pattern transfer / printing, and the separation distance of the moving frame is greater than the width of the printer to avoid mechanical interference.
[0023] As a further description of the above technical solution:
[0024] A processing plate is fixedly mounted on the top of the heater.
[0025] The processing plate is made of high thermal conductivity aluminum alloy, which evenly transfers heat to the fabric of the jacket.
[0026] As a further description of the above technical solution:
[0027] A clamping frame is fixedly connected between the two sides of the inner wall of the flattening frame.
[0028] The fabric is pre-pressed but not completely locked, leaving room for the flattening mechanism to operate. Two flatbeds move inside the U-shaped structure of the pressing frame.
[0029] This utility model has the following beneficial effects:
[0030] 1. Compared with existing technologies, this garment pattern printing device for producing rain jackets, through the coordinated use of drive components, threaded rods, moving blocks, and flattening frames, allows workers to easily adjust the equipment to adapt to rain jackets of different thicknesses and types. It ensures that the pressing frame can press down in steps when in contact with the fabric to adapt to the thickness of the rain jacket, avoiding situations where the pressing is insufficient or excessive due to different thicknesses, and ensuring the fabric quality of the rain jacket during the printing process.
[0031] 2. Compared with existing technologies, this garment pattern printing device for producing rain jackets, through the coordinated use of structures such as moving components, adjusting components, printing components, and moving frames, can precisely flatten the rain jacket. Two threaded blocks can move precisely in different directions in the flattening groove. With the help of the limiting groove and adjusting components, it ensures that the fabric of the rain jacket is flat and wrinkle-free, thus providing a stable foundation for subsequent printing, improving the printing quality of the pattern. Furthermore, the heater can evenly heat the rain jacket during the printing process, accelerating the curing of ink or pattern and reducing waiting time. Attached Figure Description
[0032] Figure 1 This is a three-dimensional schematic diagram of the overall structure of a garment pattern printing device for producing windbreakers, as proposed in this utility model.
[0033] Figure 2 This is a three-dimensional schematic diagram of the drive component structure of a garment pattern printing device for producing windbreakers, as proposed in this utility model.
[0034] Figure 3 This is a three-dimensional schematic diagram of the printing device structure of a garment pattern printing device for producing windbreakers, as proposed in this utility model.
[0035] Figure 4 This is a three-dimensional schematic diagram of the adjustment component structure of a garment pattern printing device for producing windbreakers, as proposed in this utility model.
[0036] Legend:
[0037] 1. Printing worktable; 2. Heater; 3. Lifting frame; 4. Guide rod; 5. Moving block; 6. Flattening frame; 7. Flattening groove; 8. Restricting groove; 9. Moving frame; 10. Drive motor; 11. Threaded rod; 12. Servo motor; 13. Two-way lead screw; 14. Threaded block; 15. Electric telescopic rod; 16. Mounting base; 17. Flattening plate; 18. L-shaped plate; 19. Printer; 20. Processing plate; 21. Pressing frame. Detailed Implementation
[0038] 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.
[0039] Reference Figure 1-4This utility model provides a garment pattern printing device for producing windbreakers: It includes a printing workbench 1, a heater 2 and a lifting frame 3 fixedly mounted on the top of the printing workbench 1, two guide rods 4 fixedly connected to the inner top surface of the lifting frame 3, and a moving block 5 slidably connected to the outer walls of the two guide rods 4, a driving component capable of driving the moving block 5 to move up and down on the top of the lifting frame 3, a flattening frame 6 fixedly connected to one side of the moving block 5, a flattening groove 7 and two limiting grooves 8 respectively opened on the front of the flattening frame 6, two moving frames 9 slidably connected inside the two limiting grooves 8, a moving component capable of driving the two moving frames 9 to move relative to or away from each other on one side of the flattening frame 6, an adjusting component on the top of the moving frames 9, and a printing component on the top of the lifting frame 3. The printing workbench 1 serves as the device's support platform, integrating... The core modules, including heating, lifting, and printing, are made of corrosion-resistant stainless steel. The heater 2 has a built-in nickel-chromium alloy heating wire to provide a controllable heat source, accelerate ink curing, and prevent discoloration in low-temperature environments. The lifting frame 3 and guide rod 4 form a vertical guide frame, restricting the movement block 5 to move only along the Z-axis. The flattening frame 6 carries the bidirectional flattening mechanism and has flattening grooves 7 and limiting grooves 8 to provide a movement track, ensuring that the moving frame 9 slides only horizontally without swaying. Through the coordinated use of the drive assembly, threaded rod 11, moving block 5, and flattening frame 6, the equipment can be easily adjusted by the operator to accommodate different thicknesses and types of rain jackets. This ensures that the pressing frame 21 can press down in steps when in contact with the fabric to adapt to the thickness of the rain jacket, avoiding situations where the pressing is insufficient or excessive due to different thicknesses, and ensuring the fabric quality of the rain jacket during the printing process.
[0040] The drive assembly includes a drive motor 10 fixedly installed on the top of the lifting frame 3. The output end of the drive motor 10 rotates through the interior of the lifting frame 3 and is fixedly connected to a threaded rod 11. The outer wall of the threaded rod 11 is threadedly connected to the moving block 5. The bottom end of the threaded rod 11 is rotatably connected to the top of the printing operation table 1. The drive motor 10 drives the threaded rod 11 to rotate, which is converted into the precise lifting and lowering of the moving block 5.
[0041] The moving component includes a servo motor 12 fixedly mounted on one side of the leveling frame 6. The output end of the servo motor 12 rotates through the leveling groove 7 and is fixedly connected to a bidirectional lead screw 13. One end of the bidirectional lead screw 13 is rotatably connected to the inner wall of the leveling groove 7. The servo motor 12 drives the bidirectional lead screw 13, causing two threaded blocks 14 to move towards each other or away from each other. The outer wall of the bidirectional lead screw 13 is threadedly connected to two threaded blocks 14. The front of the threaded blocks 14 is fixedly connected to the moving frame 9, and the outer wall of the threaded blocks 14 slides along the leveling groove 7.
[0042] The adjustment assembly includes an electric telescopic rod 15 fixedly installed on the top of the mobile frame 9. The telescopic end of the electric telescopic rod 15 passes through the mobile frame 9 and is fixedly connected to a mounting base 16. A flat plate 17 is detachably installed on the inner wall of the mounting base 16 by bolts. The electric telescopic rod 15 pushes the flat plate 17 to vertically press the fabric. The operator can control the telescopic length of the electric telescopic rod 15 through the controller on the printing operation table 1. A pressure sensor is also installed on it to provide real-time feedback.
[0043] The printing assembly includes two L-shaped plates 18 fixedly mounted on the top of the lifting frame 3. The front of the two L-shaped plates 18 is fixedly mounted with a printer 19 by a cylinder. The cylinder pushes the printer 19 down to perform pattern transfer / printing. The separation distance of the moving frame 9 is greater than the width of the printer 19 to avoid mechanical interference.
[0044] A processing plate 20 is fixedly installed on the top of the heater 2. The processing plate 20 is a high thermal conductivity aluminum alloy plate that evenly transfers heat to the jacket fabric. A pressing frame 21 is fixedly connected between the two sides of the inner wall of the flattening frame 6 to pre-press the fabric but not completely lock it, leaving operating space for the flattening mechanism.
[0045] Working principle: First, connect the printing worktable 1 to an external power source. Then, place the jacket to be printed in the center of the processing plate 20. At this time, depending on the type and thickness of the jacket, the operator can start the drive motor 10, causing its output end to rotate, which in turn drives the threaded rod 11 to rotate. This allows the moving block 5 to move along the guide rod 4, thereby moving the flattening frame 6. The pressing frame 21 contacts the jacket but does not press it down. Then, the electric telescopic rod 15 is started, causing its telescopic end to extend and retract, which moves the mounting base 16, allowing the flattening plate 17 to contact the jacket and apply pressure. Then, the servo motor 12 is started, causing its output end to rotate, which drives the bidirectional lead screw 13 to rotate. This causes the two threaded blocks 14 to move relative to or away from each other along the flattening groove 7, and simultaneously drives the moving frame 9 to move along the limiting groove 8. This, in conjunction with the adjustment component, flattens the jacket, effectively improving the flatness of the fabric and ensuring the accuracy of the printed pattern.
[0046] At this point, the drive motor 10 is restarted to fully press the flattened jacket with the clamping frame 21. Then, the cylinder is activated, and the telescopic end moves the printer 19 downward to print on the jacket. It should be noted that during the printing process, the distance between the two moving frames 9 must be greater than the width of the printer 19. During the printing process, the heater 2 can also be activated to uniformly heat the jacket on the processing plate 20 with its internal heating wires, accelerating the curing process of the ink or pattern and thus improving production efficiency.
[0047] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present 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 the present utility model should be included within the protection scope of the present utility model.
Claims
1. A garment pattern printing device for producing a parka, comprising a printing worktable (1), characterized in that: A heater (2) and a lifting frame (3) are fixedly installed on the top of the printing worktable (1). Two guide rods (4) are fixedly connected to the inner top surface of the lifting frame (3). A moving block (5) is slidably connected to the outer wall of the two guide rods (4). A driving component capable of driving the moving block (5) to move up and down is provided on the top of the lifting frame (3). A flattening frame (6) is fixedly connected to one side of the moving block (5). A flattening groove (7) and two limiting grooves (8) are respectively opened on the front of the flattening frame (6). Two moving frames (9) are slidably connected inside the two limiting grooves (8). A moving component capable of driving the two moving frames (9) to move relative to each other or apart is provided on one side of the flattening frame (6). An adjustment component is provided on the top of the moving frame (9). A printing component is provided on the top of the lifting frame (3).
2. The garment pattern printing device for producing a combat jacket according to claim 1, wherein: The drive assembly includes a drive motor (10) fixedly installed on the top of the lifting frame (3). The output end of the drive motor (10) rotates through the interior of the lifting frame (3) and is fixedly connected to a threaded rod (11). The outer wall of the threaded rod (11) is threadedly connected to the moving block (5), and the bottom end of the threaded rod (11) is rotatably connected to the top of the printing operation table (1).
3. The garment pattern printing device for producing a combat jacket according to claim 1, wherein: The moving component includes a servo motor (12) fixedly installed on one side of the leveling frame (6). The output end of the servo motor (12) rotates through the leveling groove (7) and is fixedly connected to a bidirectional lead screw (13). One end of the bidirectional lead screw (13) is rotatably connected to the inner wall of the leveling groove (7).
4. The garment pattern printing device for producing a combat jacket according to claim 3, wherein: The outer wall of the bidirectional lead screw (13) is threaded with two threaded blocks (14). The front of the threaded blocks (14) is fixedly connected to the moving frame (9), and the outer wall of the threaded blocks (14) slides along the flattening groove (7).
5. The garment pattern printing device for producing a combat jacket according to claim 1, wherein: The adjustment assembly includes an electric telescopic rod (15) fixedly installed on the top of the movable frame (9). The telescopic end of the electric telescopic rod (15) passes through the movable frame (9) and is fixedly connected to a mounting base (16). A flat plate (17) is detachably installed on the inner wall of the mounting base (16) by bolts.
6. The garment pattern printing device for producing a combat jacket according to claim 1, wherein: The printing assembly includes two L-shaped plates (18) fixedly installed on the top of the lifting frame (3), and a printer (19) is fixedly installed on the front of the two L-shaped plates (18) by a cylinder.
7. The garment pattern printing device for producing a combat jacket according to claim 1, wherein: A processing plate (20) is fixedly installed on the top of the heater (2).
8. The garment pattern printing device for producing a combat jacket according to claim 1, wherein: A clamping frame (21) is fixedly connected between the two sides of the inner wall of the flattening frame (6).