Dot wave machine embossing device
By utilizing the centrifugal fan suction and multi-layer filtration system of the embossing device of the dotted wave lace machine, the problem of dust on the material surface affecting the embossing quality is solved, achieving material cleaning and improving product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONG GUAN DO HEARTS TECH CO LTD
- Filing Date
- 2025-06-26
- Publication Date
- 2026-06-16
Smart Images

Figure CN224363066U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of lace machines, and in particular to an embossing device for a dotted wavy lace machine. Background Technology
[0002] In industries such as textiles and decorative materials, the demand for polka dot wavy lace is growing. Traditional lace production methods are inefficient and have limited patterns. The polka dot wavy lace embossing device has emerged to meet this need. It can quickly and accurately emboss polka dot wavy lace on materials, improving production efficiency and product diversity, and meeting the diverse needs of the market.
[0003] In existing technologies, common lace machines often expose materials to complex environments during the production process. From raw material storage to transportation, and then to the preparation stage before entering the embossing device, each step may cause dust to adhere to the surface of the material. When the material surface is contaminated with dust, direct embossing will seriously interfere with the normal formation of the embossed pattern. This not only destroys the overall aesthetics of the lace pattern and reduces the visual effect of the product, but also affects the physical properties of the lace, such as causing the lace edges to be uneven and prone to unraveling, thus significantly shortening the product's service life. Therefore, it is necessary to improve the embossing device of the dotted wave pattern lace machine to solve the above problems. Utility Model Content
[0004] In order to overcome the problem that directly embossing materials with dust on their surface will affect the quality of the finished product and even the subsequent use of the materials.
[0005] The technical solution of this utility model is as follows: a dotted wave pattern lace embossing device, including a device body, a first sliding plate and a feeding mechanism, a support leg fixedly connected to the device body, a feeding mechanism provided on the device body, a first sliding plate slidably connected to the device body, an air intake port fixedly connected to the first sliding plate, a first connecting pipe fixedly connected to the air intake port, a fixed box fixedly connected to the device body, a second connecting pipe fixedly connected to the fixed box, a connecting hose fixedly connected between the second connecting pipe and the first connecting pipe, a centrifugal fan body for providing suction fixedly connected to the fixed box, a sliding frame slidably connected to the fixed box, a pre-filter plate body for filtering impurities provided on the sliding frame, a dust filter plate body for filtering dust provided on the sliding frame, and an activated carbon filter plate body for filtering fine particles provided on the sliding frame.
[0006] Preferably, the fixed box has a groove at the relative position of the sliding frame, and the sliding frame is slidably connected to the groove.
[0007] Preferably, a first motor is fixedly connected to the fixed box, and a cam is fixedly connected to the output end of the first motor. A first connecting plate is fixedly connected to the sliding frame, and a second fixed plate is fixedly connected to the fixed box. A second spring is fixedly connected between the second fixed plate and the first connecting plate. A fixed rod is fixedly connected to the first connecting plate. The cam and the fixed rod cooperate to drive the first connecting plate to reciprocate. A dust collection box for collecting dust is slidably connected to the fixed box. A second motor is fixedly connected to the fixed box, and a bidirectional threaded rod is fixedly connected to the output end of the second motor. A second sliding plate is threadedly connected to the bidirectional threaded rod. The second sliding plate is slidably connected to the fixed box, and an opening and closing plate is fixedly connected to one end of the second sliding plate. A first threaded rod for driving the first sliding plate to slide is rotatably connected to the main body of the device, and a first knob is fixedly connected to one end of the first threaded rod.
[0008] Preferably, the fixed box has a guide groove at the relative position of the second sliding plate, and the second sliding plate is slidably connected to the groove.
[0009] Preferably, the main body of the device has a limiting groove at the relative position of the first threaded rod, and the first threaded rod is rotatably connected to the groove.
[0010] Preferably, the feeding mechanism includes a fixed bracket fixedly connected to the main body of the device, a guide rod for guiding the material fixedly connected to the fixed bracket, a material roll roller for placing the material roll on the fixed bracket, a first pressure roller for pressing the material on the main body of the device, a second pressure roller for pressing the material on the main body of the device, an embossing roller body for embossing on the main body of the device, a third motor fixedly connected to the main body of the device, a conveyor roller for conveying the material forward fixedly connected to the output end of the third motor, the conveyor roller being rotatably connected to the main body of the device, a sprocket fixedly connected to the conveyor roller, a chain meshing on the sprocket, a second threaded rod rotatably connected to the main body of the device, a second knob fixedly connected to one end of the second threaded rod, a first sliding seat threadedly connected to the second threaded rod, the first sliding seat being slidably connected to the main body of the device, and a limiting roller for pressing the material forward being rotatably connected to the first sliding seat.
[0011] Preferably, the main body of the device has a rotating groove at the relative position of the second threaded rod, and the second threaded rod is rotatably connected to the rotating groove.
[0012] The beneficial effects of this utility model are:
[0013] 1. During use, the centrifugal fan provides suction to draw dust and air into the fixed box, so as to avoid dust affecting the subsequent embossing work. When the dust is drawn in, it is fully filtered by the pre-filter plate, the dust filter plate and the activated carbon filter plate before being discharged, so as to avoid dust being discharged directly and causing harm to the surrounding staff and environment, and to avoid the problem of dust adhering to the materials and causing pollution.
[0014] 2. The first motor drives the cam to rotate, and the connected components enable the reciprocating movement of the first connecting plate and the sliding frame, which in turn moves the filter plate to shake off dust, increasing the service life of the filter plate. The shaken-off dust is collected in a dust collection box, so that the staff can centrally process the dust and other impurities, greatly reducing the burden of maintenance and cleaning.
[0015] 3. The second motor drives the connected components to work, thereby controlling the opening and closing of the opening and closing plate. When dust removal is performed, the opening and closing plate opens, allowing the dust shaken off the filter plate to enter the dust collection box for centralized storage. When vacuuming is performed, the opening and closing plate closes, sealing the dust collection box to prevent the suction force generated by the centrifugal fan from sucking out and discharging the dust stored inside the dust collection box, thus avoiding the impact on the surrounding environment and personnel, and preventing dust from falling onto the material surface again and causing infection. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of one embodiment of the embossing device for the dotted wave pattern lace machine of this utility model;
[0017] Figure 2 This utility model Figure 1 A rear view structural schematic diagram of the main body of the device and its connected components;
[0018] Figure 3 This is a schematic diagram of the air intake and its connected components of the present invention;
[0019] Figure 4 This is a structural schematic diagram of the fixing box and its connected components of this utility model;
[0020] Figure 5 This is a structural schematic diagram of the sliding frame and its connected components of this utility model;
[0021] Figure 6 This is a schematic diagram of the structure of the first motor and its connected components according to this utility model;
[0022] Figure 7 This is a schematic diagram of the structure of the second motor and its connected components according to this utility model;
[0023] Figure 8This is a schematic diagram of the conveying mechanism of this utility model;
[0024] Figure 9 This is a schematic diagram of the structure of the third motor and its connected components according to this utility model.
[0025] Explanation of reference numerals in the attached drawings: 1. Main body of the device; 21. First sliding plate; 22. Air inlet; 23. First connecting pipe; 24. Fixing box; 25. Second connecting pipe; 26. Connecting hose; 27. Centrifugal fan body; 28. Sliding frame; 29. Pre-filter plate body; 210. Dust filter plate body; 211. Activated carbon filter plate body; 212. First motor; 213. Cam; 214. First connecting plate; 215. Second fixing plate; 216. Second spring; 217. Fixing rod; 218. Dust collection. Box; 219. Second motor; 220. Bidirectional threaded rod; 221. Second sliding plate; 222. Opening and closing plate; 223. First threaded rod; 224. First knob; 31. Fixed bracket; 32. Guide rod; 33. Material roll roller; 34. First pressure roller; 35. Second pressure roller; 36. Embossing roller body; 37. Third motor; 38. Conveying roller; 39. Sprocket; 310. Chain; 311. Second threaded rod; 312. Second knob; 313. First sliding seat; 314. Limiting roller; 4. Support leg. Detailed Implementation
[0026] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0027] Please see Figure 1 - Figure 5This utility model provides an embodiment of a dotted wave pattern lace embossing device, including a device body 1, a first sliding plate 21, and a feeding mechanism. A support leg 4 is fixedly connected to the device body 1. The device body 1 is equipped with a feeding mechanism. The first sliding plate 21 is slidably connected to the device body 1. An air intake port 22 is fixedly connected to the first sliding plate 21. A first connecting pipe 23 is fixedly connected to the air intake port 22. A fixed box 24 is fixedly connected to the device body 1. A second connecting pipe 25 is fixedly connected to the fixed box 24. A connecting hose 26 is fixedly connected between the second connecting pipe 25 and the first connecting pipe 23. A centrifugal fan body 27 for providing suction is fixedly connected to the fixed box 24. A sliding frame 28 is slidably connected to the fixed box 24. A pre-filter plate body 29 for filtering impurities is provided on the sliding frame 28. The sliding frame 28 is equipped with a dust filter plate body 210 for dust filtration and an activated carbon filter plate body 211 for fine particle filtration. During use, the material is smoothly conveyed forward by the feeding mechanism. When the material passes through the air intake 22, the centrifugal fan body 27 provides suction, causing the dust on the surface of the material to be sucked into the fixed box 24 through the air intake 22, the first connecting pipe 23, the second connecting pipe 25 and the connecting hose 26. When the material passes through the sliding frame 28 inside the fixed box 24, the impurities in the gas are filtered by the pre-filter plate body 29, the dust is filtered by the dust filter plate body 210, and the smaller particles are filtered by the activated carbon filter plate body 211. Thus, the intake air is fully filtered before being discharged. The material after dust suction continues to move forward for embossing.
[0028] Please see Figure 1 - Figure 6In this embodiment, the fixed box 24 has a groove at a relative position to the sliding frame 28. The sliding frame 28 is slidably connected to the groove. The groove restricts the sliding of the sliding frame 28, preventing it from tilting during sliding and affecting the filtration of dust by the filter plate. A first motor 212 is fixedly connected to the fixed box 24, and a cam 213 is fixedly connected to the output end of the first motor 212. A first connecting plate 214 is fixedly connected to the sliding frame 28, and a second fixing plate 215 is fixedly connected to the fixed box 24. The second fixing plate 215 is connected to the first connecting plate 214. A second spring 216 is fixedly connected between the connecting plates 214. A fixing rod 217 is fixedly connected to the first connecting plate 214. A cam 213 cooperates with the fixing rod 217 to drive the first connecting plate 214 to reciprocate. A dust collection box 218 for collecting dust is slidably connected to the fixed box 24. A second motor 219 is fixedly connected to the fixed box 24. A bidirectional threaded rod 220 is fixedly connected to the output end of the second motor 219. A second sliding plate 221 is threadedly connected to the bidirectional threaded rod 220. The second sliding plate 221 is slidably connected to the fixed box. On the second sliding plate 221, one end is fixedly connected to an opening and closing plate 222. A first threaded rod 223 is rotatably connected to the main body 1 to drive the first sliding plate 21 to slide. One end of the first threaded rod 223 is fixedly connected to a first knob 224. Through the cooperation of a cam 213 and a fixed rod 217, the first connecting plate 214 is pushed to make the sliding frame 28 slide. A second spring 216 provides thrust, thereby causing the sliding frame 28 and the filter plate to reciprocate and shake off the dust adhering to the surface. The fixed box 24 is located on the second sliding plate 221. A guide groove is provided for the position, and the second sliding plate 221 is slidably connected to the groove. The groove restricts the sliding of the second sliding plate 221 and prevents the second sliding plate 221 from tilting when sliding, which would affect the closing of the opening and closing plate 222. The main body 1 of the device has a limiting groove at the relative position of the first threaded rod 223. The first threaded rod 223 is rotatably connected to the groove. The groove restricts the rotation of the first threaded rod 223 and prevents the first threaded rod 223 from disengaging from the main body 1 when rotating, which would affect its ability to drive the sliding of the first sliding plate 21.
[0029] Please see Figure 1 , Figure 2 , Figure 8 - Figure 9In this embodiment, the feeding mechanism includes a fixed bracket 31, which is fixedly connected to the main body 1 of the device. A guide rod 32 for guiding the material is fixedly connected to the fixed bracket 31. A material roll roller 33 for placing the material roll is provided on the fixed bracket 31. A first pressure roller 34 for pressing the material is provided on the main body 1. A second pressure roller 35 for pressing the material is provided on the main body 1. An embossing roller body 36 for embossing is provided on the main body 1. A third motor 37 is fixedly connected to the main body 1. A conveying roller 38 for conveying the material forward is fixedly connected to the output end of the third motor 37. The conveying roller 38 is rotatably connected to... On the main body 1 of the device, a sprocket 39 is fixedly connected to the conveying roller 38, and a chain 310 is meshed on the sprocket 39. A second threaded rod 311 is rotatably connected to the main body 1 of the device. A second knob 312 is fixedly connected to one end of the second threaded rod 311. A first sliding seat 313 is threadedly connected to the second threaded rod 311. The first sliding seat 313 is slidably connected to the main body 1 of the device. A limiting roller 314 for pressing the material forward is rotatably connected to the first sliding seat 313. Through the cooperation of the sprocket 39 and the chain 310, the conveying roller 38 is driven to rotate by the third motor 37, and the other side of the conveying roller 38 rotates synchronously to drive the material forward steadily.
[0030] Preferably, the main body 1 of the device has a rotating groove at the relative position of the second threaded rod 311. The second threaded rod 311 is rotatably connected to the rotating groove. The rotating groove restricts the rotation of the second threaded rod 311, preventing the second threaded rod 311 from disengaging from the main body 1 when rotating, thus affecting its ability to adjust the height position of the first sliding seat 313 and the limiting roller 314.
[0031] During operation, the material roll is placed at the material roll roller 33, and then one end of the material roll is passed through each roller one by one. Depending on the thickness of the material, the second knob 312 and the first knob 224 are rotated. Rotating the second knob 312 drives the second threaded rod 311 to rotate, causing the first sliding seat 313 to slide on the device body 1 to adjust the height of the limiting roller 314. Rotating the first knob 224 drives the first threaded rod 223 to rotate, causing the first sliding plate 21 to slide on the device body 1 to adjust the height of the air intake 22. The third motor 37 operates, with the sprocket 39 and chain 310 working together to drive the rollers on both sides of the device body 1. The conveyor rollers 38 rotate synchronously, thereby driving the material forward. When the material passes through the air inlet 22, the centrifugal fan body 27 provides suction, causing the dust on the surface of the material to be sucked into the fixed box 24 through the air inlet 22, the first connecting pipe 23, the second connecting pipe 25 and the connecting hose 26. When passing through the sliding frame 28 inside the fixed box 24, the impurities in the gas are filtered by the pre-filter plate body 29, the dust is filtered by the dust filter plate body 210, and the smaller particles are filtered by the activated carbon filter plate body 211. Thus, the intake air is fully filtered before being discharged. The material after passing through the air inlet 22 continues to move forward and is embossed at the embossing roller body 36.
[0032] When it is necessary to clean the dust on the filter plate, the second motor 219 operates, driving the bidirectional threaded rod 220 to rotate. When the bidirectional threaded rod 220 rotates, it drives the second sliding plate 221 to slide on the fixed box 24, thereby opening the opening and closing plate 222. Then, the first motor 212 operates, driving the cam 213 to rotate. When the cam 213 rotates, it cooperates with the fixed rod 217 to drive the first connecting plate 214 and the sliding frame 28 to move. Then, the second spring 216 provides a pushing force to the first connecting plate 214, thereby pushing the first connecting plate 214 to reset, causing the sliding frame 28 to reciprocate and shake, thereby shaking off the dust on the filter. The dust falls into the dust collection box 218 for centralized storage. When vacuuming is performed again, the opening and closing plate 222 is closed to prevent the suction force of the centrifugal fan body 27 from sucking out the dust and other impurities inside the dust collection box 218.
[0033] Through the above steps, the centrifugal fan body 27 provides suction during use, drawing dust and air into the fixed box 24 to avoid dust affecting the subsequent embossing work. This solves the problem that if the material surface is contaminated with dust, directly performing embossing will affect the quality of the finished product and even affect the subsequent use of the material.
Claims
1. A dotted wave pattern lace embossing device, comprising a main body (1), characterized in that: It also includes a first sliding plate (21) and a feeding mechanism. A support leg (4) for support is fixedly connected to the main body (1). A feeding mechanism is provided on the main body (1). A first sliding plate (21) is slidably connected to the main body (1). An air intake port (22) for air intake is fixedly connected to the first sliding plate (21). A first connecting pipe (23) is fixedly connected to the air intake port (22). A fixed box (24) is fixedly connected to the main body (1). A second connecting pipe (25) is fixedly connected to the fixed box (24). A connecting hose (26) is fixedly connected between the pipe (25) and the first connecting pipe (23). A centrifugal fan body (27) for providing suction is fixedly connected to the fixed box (24). A sliding frame (28) is slidably connected to the fixed box (24). A pre-filter plate body (29) for filtering impurities is provided on the sliding frame (28). A dust filter plate body (210) for filtering dust is provided on the sliding frame (28). An activated carbon filter plate body (211) for filtering fine particles is provided on the sliding frame (28).
2. The embossing device for a dotted wave pattern lace machine according to claim 1, characterized in that: The fixed box (24) has a groove at the relative position of the sliding frame (28), and the sliding frame (28) is slidably connected to the groove.
3. The embossing device for a dotted wave pattern lace machine according to claim 1, characterized in that: A first motor (212) is fixedly connected to the fixed box (24). A cam (213) is fixedly connected to the output end of the first motor (212). A first connecting plate (214) is fixedly connected to the sliding frame (28). A second fixed plate (215) is fixedly connected to the fixed box (24). A second spring (216) is fixedly connected between the second fixed plate (215) and the first connecting plate (214). A fixed rod (217) is fixedly connected to the first connecting plate (214). The cam (213) and the fixed rod (217) work together to drive the first connecting plate (214) to move back and forth. A collection device is slidably connected to the fixed box (24). A dust collection box (218) for dust collection is fixedly connected to a second motor (219) on a fixed box (24). A bidirectional threaded rod (220) is fixedly connected to the output end of the second motor (219). A second sliding plate (221) is threadedly connected to the bidirectional threaded rod (220). The second sliding plate (221) is slidably connected to the fixed box (24). An opening and closing plate (222) is fixedly connected to one end of the second sliding plate (221). A first threaded rod (223) for driving the first sliding plate (21) to slide is rotatably connected to the main body (1). A first knob (224) is fixedly connected to one end of the first threaded rod (223).
4. The embossing device for a dotted wave pattern lace machine according to claim 3, characterized in that: The fixed box (24) has a guide groove at the relative position of the second sliding plate (221), and the second sliding plate (221) is slidably connected to the groove.
5. The embossing device for a dotted wave pattern lace machine according to claim 3, characterized in that: The main body of the device (1) has a limiting groove at the relative position of the first threaded rod (223), and the first threaded rod (223) is rotatably connected to the groove.
6. The embossing device for a dotted wave pattern lace machine according to claim 1, characterized in that: The feeding mechanism includes a fixed bracket (31), which is fixedly connected to the main body (1) of the device. A guide rod (32) for guiding the material is fixedly connected to the fixed bracket (31). A material roll roller (33) for placing the material roll is provided on the fixed bracket (31). A first pressure roller (34) for pressing the material is provided on the main body (1). A second pressure roller (35) for pressing the material is provided on the main body (1). An embossing roller body (36) for embossing is provided on the main body (1). A third motor (37) is fixedly connected to the main body (1). The output end of the third motor (37) is fixedly connected to... There is a conveying roller (38) for conveying materials forward. The conveying roller (38) is rotatably connected to the main body of the device (1). A sprocket (39) is fixedly connected to the conveying roller (38). A chain (310) is meshed on the sprocket (39). A second threaded rod (311) is rotatably connected to the main body of the device (1). A second knob (312) is fixedly connected to one end of the second threaded rod (311). A first sliding seat (313) is threadedly connected to the second threaded rod (311). The first sliding seat (313) is slidably connected to the main body of the device (1). A limiting roller (314) for pressing materials forward is rotatably connected to the first sliding seat (313).
7. The embossing device for a dotted wave pattern lace machine according to claim 6, characterized in that: The main body of the device (1) has a rotating groove at the relative position of the second threaded rod (311), and the second threaded rod (311) is rotatably connected to the rotating groove.