A lint blowing cleaning device and method for garment production
By using a U-shaped frame partition and a shaking mechanism in the fabric cleaning equipment, combined with water adsorption, the problem of incomplete lint cleaning is solved, achieving a more efficient fabric cleaning effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SHANDONG LIANGHUA CLOTHING CO LTD
- Filing Date
- 2025-01-08
- Publication Date
- 2026-06-26
AI Technical Summary
In existing technologies, when cleaning lint from fabric surfaces, the lint that has been scraped off is easily re-falling back onto the fabric due to static electricity or gravity, resulting in poor cleaning performance.
A lint blowing and cleaning device for garment production was designed. It uses a U-shaped frame to divide the fabric into multiple isolation zones. Combined with a shaking mechanism and a filter, it cleans the fabric step by step through shaking and water adsorption, reducing the possibility of impurities re-adhering.
It achieves more thorough fabric cleaning, reduces the re-adhesion of impurities caused by static friction, improves cleaning effect, and avoids repeated contamination.
Smart Images

Figure CN119615596B_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of cleaning technology, and in particular to a lint blowing and cleaning device and method for garment production. Background Technology
[0002] Fabric is used in the garment production process. During the production process, due to friction and textile residue, there may be lint, fuzz, and other debris left on the surface of the fabric. If it is not cleaned in time, the residual lint may enter the finished garment during the garment making process, affecting the surface quality of the garment. At the same time, the residual lint may be inhaled by workers during the garment making process, affecting their health.
[0003] Therefore, before fabric is made into clothing, it is necessary to clean the lint on its surface. For example, patent application CN114405888A discloses a winding structure for a fabric cleaning device, belonging to the field of fabric cleaning and winding. It includes a base, with rotating seats fixedly connected to both sides of the upper surface of the base. A winding roller is rotatably connected to each of the two rotating seats. Two frame plates are fixedly connected to the upper surface of the base between the two rotating seats. Each frame plate has a circular groove on one side, and a rotating roller is rotatably connected within the two circular grooves. One end of the rotating roller passes through the circular groove, and a scraper is provided on the outer circumference of the rotating roller. This prior art uses the scraper to remove lint adhering to one side of the fabric. After the fabric slides over the scraper, it is flipped so that it slides over the scraper again to remove lint adhering to the other side. By quickly removing lint from both sides of the fabric, the surface of the fabric remains clean, which is beneficial for subsequent processing and finishing.
[0004] Although the above-mentioned patent application can clean and finish the surface of the fabric, it still has the following problems: when scraping the surface of the fabric, the scraped cotton wool (i.e., lint) may fall back onto the fabric due to static electricity, gravity and other effects, resulting in incomplete removal of lint from the fabric and poor cleaning effect.
[0005] Based on this, and given the above viewpoints, there is still room for improvement in the existing technology for handling fabric surfaces. Summary of the Invention
[0006] To solve the above-mentioned technical problems, this application provides a lint blowing and cleaning device and method for garment production, adopting the following technical solution:
[0007] In a first aspect, a lint blowing and cleaning device for garment production includes a U-shaped frame, wherein multiple partition plates are evenly arranged inside the U-shaped frame along its length direction, and the partition plates divide the U-shaped frame into multiple isolation zones along the length direction of the U-shaped frame, and each isolation zone is equipped with a shaking mechanism.
[0008] The shaking mechanism includes: multiple reciprocating blocks, each corresponding to an isolation zone, and each reciprocating block is located at the top center of the two partition plates.
[0009] The swaying rod is symmetrically arranged along the length of the reciprocating block and is mounted on the bottom of the reciprocating block via bearings.
[0010] Preferably, adjacent partition plates are jointly equipped with C-shaped plates with openings facing the isolation zone. A rotating shaft extending along the depth direction of the isolation zone is installed through a bearing on the horizontal section of the C-shaped plate. A cam blade is installed on the rotating shaft. An extension frame is installed on the horizontal section of the C-shaped plate. A reciprocating plate is slidably arranged through the extension frame, and a reciprocating block is installed at the bottom of the corresponding reciprocating plate. The extension frame is provided with a support protrusion corresponding to the reciprocating plate. A return spring rod is installed on the support protrusion. The end of the return spring rod away from the corresponding support protrusion is installed on the corresponding reciprocating plate. A linkage rod is installed on the end of the reciprocating plate away from the return spring rod, and the linkage rod abuts against the cam blade.
[0011] Preferably, an elastic telescopic rod is installed on one side wall inside the C-shaped frame. A linkage roller is installed on the telescopic end of the elastic telescopic rod through a connecting frame. A through groove is opened on each of the partition plates. A rotating roller extending along the depth direction of the isolation area is installed in each through groove through a bearing. Adjacent rotating rollers are staggered. A support frame is installed on the top of the end of the C-shaped frame away from the elastic telescopic rod. A winding roller is installed on the support frame and the bottom of the C-shaped frame through a bearing.
[0012] Preferably, a closing rod that slides back and forth along the depth direction of the isolation zone is installed on the side of the isolation zone near the vertical section of the frame. A filter screen is installed inside the closing rod, and multiple vertical protrusions that cooperate with the filter screen are evenly installed on the bottom of the isolation zone.
[0013] Preferably, the closing rod has a connecting protrusion inside, and a bidirectional screw corresponding to the closing rod is installed at the bottom of the isolation zone through a bearing. The bidirectional screw is connected to the connecting protrusion through a threaded connection, and a sprocket is installed at the end of the bidirectional screw away from the bottom of the isolation zone.
[0014] Preferably, a pulley one is installed on the lower side of the circumferential surface of the rotating shaft, and a pulley two that cooperates with the pulley is installed on the bidirectional screw inside the same isolation zone and close to the rotating shaft, and the pulley one and the adjacent pulley two are connected by belt drive.
[0015] Preferably, the diameter of the self-elastic telescopic rod of the pulley decreases sequentially towards the winding roller.
[0016] Preferably, the length of the linkage rod decreases sequentially from the elastic telescopic rod towards the winding roller.
[0017] Preferably, the isolation zone is symmetrically provided with vibrating rods with openings facing the bottom of the C-shaped frame and in the shape of a C-shape. Each closed rod inside the isolation zone is provided with a linkage protrusion. Multiple vibration protrusions that cooperate with the linkage protrusion are evenly provided along the length of the vertical section of the vibrating rod near the linkage protrusion. The bottom of the isolation zone is provided with a telescopic spring rod for resetting the vibrating rod, and the telescopic end of the telescopic spring rod is connected to the vibrating rod.
[0018] Secondly, a method for cleaning lint in garment production includes the following steps: S1: Fabric threading, in which the fabric is passed around the linkage roller and then around the rotating roller in sequence before being wound onto the winding roller.
[0019] S2: Shaking treatment, the fabric is shaken by the cooperation of the reciprocating block and the shaking rod.
[0020] S3: Dust collection. Loose threads, lint, and other impurities that fall off during shaking are collected through the filter.
[0021] S4: Winding process, which involves winding the cleaned fabric using a winding roller.
[0022] In summary, this application includes at least one of the following beneficial technical effects:
[0023] 1. In the shaking mechanism designed in this invention, the reciprocating block and the shaking rod cooperate to reciprocate the shaking of the fabric. During the shaking process, the fabric can use its own inertia to remove impurities such as threads and lint adhering to its surface or interior, thereby achieving a cleaning effect. Compared with traditional cleaning methods such as contacting the fabric and scraping, this invention can reduce the possibility of impurities re-adhering to the fabric due to static electricity generated by contact friction.
[0024] 2. The U-shaped frame designed in this invention has multiple isolation zones inside, so that the fabric inside the U-shaped frame can be cleaned step by step during the fabric cleaning process, avoiding the possibility of repeated contamination due to excessive impurities on the fabric.
[0025] 3. The closed rod and filter screen designed in this invention work together to absorb and collect impurities that are scattered and shaken in the isolation area through water, so as to avoid the possibility of impurities scattered in the isolation area repeatedly adhering to the fabric. Attached Figure Description
[0026] Figure 1 This is a three-dimensional structural schematic diagram of the present invention.
[0027] Figure 2 This is a schematic diagram of the three-dimensional installation structure between the elastic telescopic rod, the linkage roller, and the rotating roller of the present invention.
[0028] Figure 3This is a schematic diagram of the three-dimensional installation structure between the shaped plate, rotating shaft, and cam blade of the present invention.
[0029] Figure 4 This is the present invention. Figure 2 Enlarged view of a portion of point A in the middle.
[0030] Figure 5 This is a three-dimensional installation structure diagram of the C-shaped plate, rotating shaft, and pulley of the present invention.
[0031] Figure 6 This is a top view of the installation structure between the pulley and the linkage rod of the present invention.
[0032] Figure 7 This is a schematic diagram of the three-dimensional installation structure between the closing rod and the vibration rod of the present invention.
[0033] Figure 8 This is the present invention. Figure 7 Enlarged view of section B in the middle.
[0034] Figure 9 This is a schematic diagram of the three-dimensional installation structure between the reciprocating block and the rocking rod of the present invention.
[0035] Figure 10 This is a flowchart of the lint blowing and cleaning method for garment production according to the present invention.
[0036] Explanation of reference numerals in the attached drawings: 1. C-shaped frame; 11. Elastic telescopic rod; 12. Linkage roller; 13. Rotating roller; 14. Support frame; 15. Winding roller; 2. Separator plate; 21. C-shaped plate; 22. Rotating shaft; 221. Pulley one; 222. Pulley two; 23. Cam blade; 24. Extension frame; 25. Reciprocating plate; 26. Return spring rod; 27. Linkage rod; 3. Isolation zone; 31. Closing rod; 32. Filter screen; 33. Vertical protrusion; 34. Connecting protrusion; 35. Bidirectional screw; 36. Sprocket; 4. Shaking mechanism; 41. Reciprocating block; 42. Shaking rod; 421. Air outlet; 5. Vibration rod; 51. Linkage protrusion; 52. Vibration protrusion; 53. Telescopic spring rod. Detailed Implementation
[0037] The following is in conjunction with the appendix Figures 1 to 10 This application will be described in further detail.
[0038] This application discloses a lint blowing and cleaning device and method for garment production, which uses a combination of graded cleaning and fabric shaking to clean the fabric, resulting in better cleaning effect.
[0039] Example 1:
[0040] Reference Figure 1 as well as Figure 2A lint blowing and cleaning device for garment production includes a U-shaped frame 1. Multiple partition plates 2 are evenly arranged inside the U-shaped frame 1 along its length direction, and the partition plates 2 divide the U-shaped frame 1 into multiple isolation zones 3 along the length direction of the U-shaped frame 1. A shaking mechanism 4 is installed inside each isolation zone 3.
[0041] An elastic telescopic rod 11 is installed on one side wall inside the C-shaped frame 1. A linkage roller 12 is installed on the telescopic end of the elastic telescopic rod 11 through a connecting frame. A through groove is opened on each of the partition plates 2. A rotating roller 13 extending along the depth direction of the isolation zone 3 is installed in each through groove through a bearing. Adjacent rotating rollers 13 are staggered. A support frame 14 is installed on the top of the end of the C-shaped frame 1 away from the elastic telescopic rod 11. A winding roller 15 is installed on the support frame 14 and the bottom of the C-shaped frame 1 through a bearing.
[0042] In practice, the rolled fabric is placed on the side of the frame 1 close to the linkage roller 12. The fabric is then manually wrapped around the linkage roller 12 and then alternately wrapped around the rotating roller 13 before being wound onto the winding roller 15. The winding roller 15 is then rotated by an existing drive motor (not shown in the figure).
[0043] The rotating roller 13 extends along the depth of the isolation zone 3, so the fabric is in a vertical position during movement. Compared with the traditional horizontal placement of fabric, this ensures that impurities on both sides of the fabric can fall to the bottom of the isolation zone 3 during the shedding process and will not fall back onto the fabric.
[0044] Reference Figure 2 as well as Figure 3 The shaking mechanism 4 includes: multiple reciprocating blocks 41, each corresponding to one of the isolation zones 3, and each reciprocating block 41 is located at the top middle position of the two partition plates 2.
[0045] The swaying rod 42 is symmetrically arranged along the length of the reciprocating block 41 and is mounted on the bottom of the reciprocating block 41 via a bearing.
[0046] During the rotation of the winding roller 15, the fabric moves within the isolation zone 3. During the movement of the fabric, the reciprocating block 41 and the shaking rod 42 work together to reciprocate and shake the fabric. During the shaking, the fabric can use its own inertia to remove impurities such as threads and lint adhering to its surface or interior, thus achieving a cleaning effect. Compared with traditional cleaning methods such as contacting the fabric and scraping, this invention can reduce the possibility of impurities re-adhering to the fabric due to static electricity generated by contact friction.
[0047] The elastic telescopic rod 11 and the linkage roller 12 work together to give way to the fabric during the shaking process. The deformation of the elastic telescopic rod 11 can compensate for the displacement of the fabric during the shaking process and avoid the possibility of the fabric being rigidly broken.
[0048] Reference Figure 3 Adjacent partition plates 2 are jointly equipped with a U-shaped plate 21 with an opening facing the isolation zone 3. A rotating shaft 22 extending along the depth direction of the isolation zone 3 is installed through a bearing on the horizontal section of the U-shaped plate 21. A cam blade 23 is installed on the rotating shaft 22. An extension frame 24 is installed on the horizontal section of the U-shaped plate 21. A reciprocating plate 25 is slidably arranged through the extension frame 24, and a reciprocating block 41 is installed at the bottom of the corresponding reciprocating plate 25. A support protrusion corresponding to the reciprocating plate 25 is provided on the extension frame 24. A return spring rod 26 is installed on the support protrusion. The end of the return spring rod 26 away from the corresponding support protrusion is installed on the corresponding reciprocating plate 25. A linkage rod 27 is installed on the end of the reciprocating plate 25 away from the return spring rod 26, and the linkage rod 27 abuts against the cam blade 23.
[0049] The cam blade 23 consists of four protrusions evenly distributed around the circumference of the rotating shaft 22. During operation, the fabric passes between the two swaying rods 42 corresponding to the isolation zone 3. As the rotating shaft 22 rotates, it drives the cam blade 23 to rotate. During the rotation of the cam blade 23, the protrusions on its surface drive the linkage rod 27 to move from the bottom of the protrusion to the top of the protrusion. At this time, the linkage rod 27 moves towards the side supporting the protrusion, and the return spring rod 26 is compressed. When the top of the protrusion on the surface of the cam blade 23 contacts the linkage rod 27, the compression of the return spring rod 26 reaches its maximum. That is, when the cam blade 23 continues to rotate, the linkage rod 27 will return to its original position along the protrusion on its surface. At this time, the return spring rod 26 returns to its original position simultaneously.
[0050] When the linkage rod 27 moves to the bottom of the protrusion of the next cam blade 23, the surface protrusion of the cam blade 23 during its rotation drives the linkage rod 27 to move towards the supporting protrusion side. Repeating the above action, the cam blade 23 and the return spring rod 26 cooperate with each other and can drive the reciprocating plate 25 to slide back and forth in the length direction of the extension frame 24 through the linkage rod 27. During the reciprocating sliding of the reciprocating plate 25, the reciprocating block 41 can drive the shaking rod 42 to shake the fabric.
[0051] Since the cleaning of fabric surfaces in the prior art is carried out in the same area, if impurities are not collected in time during the cleaning process, the impurities that fall off the fabric can easily re-adhere to the fabric. Therefore, in this invention, the inside of the shaped frame 1 is provided with multiple isolation zones 3. Thus, during the fabric cleaning process, the shaking mechanism 4 and the isolation zones 3 cooperate with each other to perform step-by-step cleaning of the fabric inside the shaped frame 1. This makes the impurities in each isolation zone 3 gradually decrease as the fabric moves from the self-linking roller 12 to the winding roller 15, thus avoiding the possibility of repeated contamination of the fabric after cleaning.
[0052] Reference Figure 4To further reduce the possibility of impurities re-attaching to the fabric surface after falling off, the closed rod 31 designed in this invention works in conjunction with the filter screen 32. Water can be used to adsorb and collect impurities that are scattered in the isolation zone 3, so as to avoid the possibility of impurities scattered in the isolation zone 3 re-attaching to the fabric. Specifically, a closed rod 31 that slides back and forth along the depth direction of the isolation zone 3 is installed on the side of the isolation zone 3 near the vertical section of the frame 1. A filter screen 32 is installed inside the closed rod 31. Multiple vertical protrusions 33 that cooperate with the filter screen 32 are evenly installed on the bottom of the isolation zone 3.
[0053] The closing rod 31 has a connecting protrusion 34 inside. The bottom of the isolation zone 3 is equipped with a bidirectional screw 35 corresponding to the closing rod 31 through a bearing. The bidirectional screw 35 is connected to the connecting protrusion 34 through a threaded connection. A sprocket 36 is installed at the end of the bidirectional screw 35 away from the bottom of the isolation zone 3.
[0054] Initially, the sprockets 36 are connected by chain drive, and water is then filled into each isolation zone 3, ensuring that the water depth does not exceed the bottom of the through groove and that the height of the vertical protrusion 33 is greater than the water depth. The existing drive motor drives any one of the bidirectional screws 35 to rotate. During the rotation of the bidirectional screw 35, the remaining bidirectional screws 35 are driven to rotate through the sprockets 36 and chain drive. During the rotation of the bidirectional screws 35, the closing rod 31 is driven to move downward along the depth direction of the isolation zone 3 through the connecting protrusion 34. When the closing rod 31 moves into the water, the closing rod 31 reaches its lowest point, and the filter screen 32 is wetted and the vertical protrusion 33 is inserted into the mesh of the filter screen 32.
[0055] The bidirectional screw 35 continues to rotate, driving the closing rod 31 upward through the connecting protrusion 34. During the upward movement of the closing rod 31, the water-soaked filter screen 32 is simultaneously moved upward. After the filter screen 32 leaves the water surface, it moves upward along the depth direction of the isolation zone 3. Thus, the bidirectional screw 35, through the cooperation of the connecting protrusion 34 and the closing rod 31, drives the water-soaked filter screen 32 to move up and down reciprocally inside the isolation zone 3. During the movement of the filter screen 32, the water can adhere and collect the loose threads and lint inside the isolation zone 3, preventing the impurities from re-adhering to the fabric.
[0056] Each time the filter screen 32 gets wet, it can also clean the impurities that were previously adhered and collected, preventing impurities from accumulating on the filter screen 32 and affecting the subsequent adhesion effect of the filter screen 32 to impurities.
[0057] The vertical protrusions 33 can puncture the water film formed by the mesh of the filter screen 32, preventing the formation of a water film on the surface of the filter screen 32 when it is wet. This avoids the water film preventing air from escaping through the mesh of the filter screen 32 during its up-and-down movement. Consequently, the water film compresses the air towards the fabric side during the up-and-down movement of the filter screen 32, thus preventing impurities from re-adhering to the fabric.
[0058] Reference Figure 4 as well as Figure 5 A pulley 221 is installed on the lower side of the circumferential surface of the rotating shaft 22. A pulley 222 that cooperates with the pulley is installed on the bidirectional screw 35 inside the same isolation zone 3 and close to the rotating shaft 22. The pulley 221 and the adjacent pulley 222 are connected by belt drive.
[0059] In actual operation, pulley 221 and pulley 222 inside the same isolation zone 3 are connected by an existing belt (not shown in the figure). The cooperation between pulley 221 and pulley 222 allows the bidirectional screw 35 to rotate synchronously with the rotating shaft 22, thereby reducing the use of the existing drive.
[0060] Reference Figure 6 The diameter of the pulley 222 self-elastic telescopic rod 11 decreases sequentially towards the winding roller 15.
[0061] In actual operation, the diameter of pulley 222 gradually decreases, indicating that the rotation speed of the rotating shaft 22 corresponding to pulley 222 decreases sequentially. Since there are many impurities on the surface of the fabric when it first enters the isolation zone 3 and the impurities are distributed on the inside and outside of the fabric, the rotation speed of the rotating shaft 22 corresponding to the isolation zone 3 near the linkage roller 12 is the largest. During the process, the rotating shaft 22 with the largest rotation speed drives the reciprocating plate 25 to move back and forth quickly through the cooperation of the cam blade 23 and the linkage rod 27. Then, the reciprocating plate 25 can drive the shaking rod 42 to shake the fabric at a faster frequency through the reciprocating block 41, so as to perform coarse cleaning treatment on the impurities on the inside and outside of the fabric.
[0062] Since shaking the fabric at a high frequency increases the possibility of fabric damage, after the fabric is coarsely cleaned in the isolation zone 3 of the linkage roller 12, the fabric enters the subsequent isolation zone 3 for step-by-step cleaning. That is, the rotation speed of the rotating shaft 22 gradually decreases and the shaking frequency of the shaking rod 42 gradually slows down. Thus, while the fabric is being cleaned step-by-step in the subsequent isolation zone 3, the possibility of the fabric being easily damaged by shaking the fabric at a high frequency by the shaking rod 42 is reduced.
[0063] Continue to refer to Figure 6 The length of the linkage 27 decreases sequentially from the elastic telescopic rod 11 toward the winding roller 15.
[0064] In actual operation, the length of the linkage rod 27 decreases sequentially, indicating that the connection length between the linkage rod 27 and the cam blade 23 decreases sequentially. Since there are many impurities on the surface of the fabric when it first enters the isolation zone 3 and the impurities are distributed on the inside and outside of the fabric, the linkage rod 27 corresponding to the isolation zone 3 near the linkage roller 12 has the largest displacement. The linkage rod 27 with the largest displacement can drive the shaking rod 42 to shake the fabric with a large amplitude through the cooperation of the reciprocating plate 25 and the reciprocating block 41. During the shaking of the fabric, the impurities on the inside and outside of the fabric can be roughly cleaned.
[0065] Since the fabric is more likely to come into contact with airborne impurities during a large-amplitude shaking process, after the fabric is coarsely cleaned inside the isolation zone 3 of the linkage roller 12, the fabric enters the subsequent isolation zone 3 for step-by-step cleaning. That is, the displacement of the linkage rod 27 gradually decreases, and the shaking amplitude also gradually decreases. Thus, while the fabric is being cleaned step-by-step in the subsequent isolation zone 3, the shaking amplitude of the shaking rod 42 is reduced to avoid the possibility of the fabric re-adhering to impurities.
[0066] Therefore, by changing the shaking frequency and shaking amplitude of the shaking rod 42, the fabric can be graded and cleaned, thereby improving the cleaning effect of the fabric.
[0067] Example 2: Refer to Figure 7 as well as Figure 8 Based on Embodiment 1, since the shaking rod 42 can only shake the fabric in the middle of the isolation zone 3, the shaking effect of the fabric from the shaking rod 42 to both sides of the isolation zone 3 gradually weakens. Therefore, the shaking effect of the fabric on both sides of the isolation zone 3 is poor. The vibration rod 5 provided by the present invention can also shake the fabric on both sides. Specifically, the isolation zone 3 is symmetrically provided with vibration rods 5 with openings facing the bottom of the C-shaped frame 1 and in the C-shaped structure. The vibration rod 5 is slidably disposed on the bottom of the C-shaped frame 1. A linkage protrusion 51 is provided on any closed rod 31 inside the isolation zone 3. Multiple vibration protrusions 52 that cooperate with the linkage protrusion 51 are evenly provided along the length of the vertical section of the vibration rod 5 near the linkage protrusion 51. The bottom of the isolation zone 3 is provided with a telescopic spring rod 53 for resetting the vibration rod 5, and the telescopic end of the telescopic spring rod 53 is connected to the vibration rod 5.
[0068] In actual operation, the closing rod 31 moves up and down reciprocally inside the isolation zone 3, driving the linkage protrusion 51 to move up and down reciprocally. During the up and down reciprocating movement of the linkage protrusion 51, it cooperates with the vibration protrusion 52 to drive the vibration rod 5 to move back and forth reciprocally. During the reciprocating movement of the vibration rod 5, the parts on both sides of the fabric isolation zone 3 can be shaken. In this way, the vibration rod 5 and the shaking rod 42 cooperate to fully shake the fabric inside the isolation zone 3, improving the removal effect of impurities on the fabric surface. The telescopic spring rod 53 plays a resetting role for the vibration rod 5.
[0069] Example 3, based on Example 1, refers to... Figure 9 The shaking rod 42 has a hollow structure inside, and multiple air outlets 421 are evenly opened on the circumference of the shaking rod 42. In actual operation, during the shaking of the fabric, air is pumped into the shaking rod 42 by an existing air pump. The air is discharged outward through the air outlets 421, thereby increasing the air flow rate on the fabric surface and blowing off impurities on the fabric surface, thus achieving the cleaning treatment of the fabric surface.
[0070] Finally, refer to Figure 10 The present invention also provides a method for cleaning lint in garment production by blowing it away. The method includes the following steps: S1: Place the rolled fabric on the side of the frame 1 close to the linkage roller 12. At this time, the fabric is manually wrapped around the linkage roller 12 and then wrapped around the rotating roller 13 in sequence before being wound onto the winding roller 15. At this time, the winding roller 15 is driven to rotate by an existing drive motor (not shown in the figure).
[0071] S2: Shaking treatment. During the rotation of the rotating shaft 22, the cam blade 23 is driven to rotate. During the rotation of the cam blade 23, the protrusion on its surface drives the linkage rod 27 to move from the bottom of the protrusion to the top of the protrusion. At this time, the linkage rod 27 moves towards the side supporting the protrusion, and the return spring rod 26 is compressed. When the top of the protrusion on the surface of the cam blade 23 contacts the linkage rod 27, the compression of the return spring rod 26 reaches its maximum. That is, when the cam blade 23 continues to rotate, the linkage rod 27 will return to its original position along the protrusion on its surface. At this time, the return spring rod 26 returns to its original position synchronously.
[0072] When the linkage rod 27 moves to the bottom of the protrusion of the next cam blade 23, the surface protrusion of the cam blade 23 during its rotation drives the linkage rod 27 to move towards the supporting protrusion side. Repeating the above action, the cam blade 23 and the return spring rod 26 cooperate with each other and can drive the reciprocating plate 25 to slide back and forth in the length direction of the extension frame 24 through the linkage rod 27. During the reciprocating sliding of the reciprocating plate 25, the reciprocating block 41 can drive the shaking rod 42 to shake the fabric.
[0073] S3: Dust collection. The sprockets 36 are connected by a chain drive. Water is then added to each isolation zone 3, ensuring the water depth does not exceed the bottom of the through groove. During the rotation of the bidirectional screw 35, the connecting protrusion 34 drives the closing rod 31 to move downwards along the depth direction of the isolation zone 3. When the closing rod 31 moves into the water, it reaches its lowest point. At this time, the filter screen 32 is wetted and the vertical protrusion 33 is inserted into the mesh of the filter screen 32. The bidirectional screw 35 continues to rotate, driving the closing rod 31 upwards through the connecting protrusion 34. During the upward movement of the closing rod 31, the wetted filter screen 32 is simultaneously moved upwards. After the filter screen 32 leaves the water surface, it moves upwards along the depth direction of the isolation zone 3. Thus, the bidirectional screw 35, through the cooperation of the connecting protrusion 34 and the closing rod 31, drives the wetted filter screen 32 to move up and down repeatedly inside the isolation zone 3. During the movement of the filter screen 32, the water can adhere and collect impurities such as loose threads and lint inside the isolation zone 3.
[0074] S4: Winding process, the cleaned fabric is wound up by the winding roller 15.
[0075] It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered in all respects as exemplary and non-limiting, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.
[0076] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. A lint blowing and cleaning device for garment production, comprising a frame (1), characterized in that: The shaped frame (1) has multiple partition plates (2) evenly arranged along its length, and the partition plates (2) divide the shaped frame (1) into multiple isolation zones (3) along its length. Each isolation zone (3) is equipped with a swaying mechanism (4). The aforementioned swaying mechanism (4) includes: There are multiple reciprocating blocks (41) that correspond one-to-one with the isolation zone (3), and each reciprocating block (41) is located at the top middle position of the two partition plates (2); The swaying rod (42) is symmetrically arranged along the length of the reciprocating block (41) and is mounted on the bottom of the reciprocating block (41) via a bearing; The isolation zone (3) is equipped with a closed rod (31) that slides back and forth along the depth direction of the isolation zone (3) on one side near the vertical section of the frame (1). A filter screen (32) is installed inside the closed rod (31). Multiple vertical protrusions (33) that cooperate with the filter screen (32) are evenly installed on the bottom of the isolation zone (3). The isolation zone (3) is symmetrically provided with vibrating rods (5) with openings facing the bottom of the C-shaped frame (1) and in the shape of a C-shaped structure. A linkage protrusion (51) is provided on any closed rod (31) inside the isolation zone (3). Multiple vibration protrusions (52) that cooperate with the linkage protrusion (51) are evenly provided along the length of the vertical section of the vibrating rod (5) near the linkage protrusion (51). A telescopic spring rod (53) for resetting the vibrating rod (5) is provided at the bottom of the isolation zone (3), and the telescopic end of the telescopic spring rod (53) is connected to the vibrating rod (5).
2. The lint blowing and cleaning equipment for garment production according to claim 1, characterized in that: The adjacent partition plates (2) are jointly equipped with a U-shaped plate (21) with an opening facing the isolation area (3). A rotating shaft (22) extending along the depth direction of the isolation area (3) is installed through the horizontal section of the U-shaped plate (21) via a bearing. A cam blade (23) is installed on the rotating shaft (22). An extension frame (24) is installed on the horizontal section of the U-shaped plate (21). A reciprocating plate (25) is slidably arranged through the extension frame (24), and a reciprocating block (41) is installed at the bottom of the corresponding reciprocating plate (25). A support protrusion corresponding to the reciprocating plate (25) is provided on the extension frame (24). A return spring rod (26) is installed on the support protrusion. The end of the return spring rod (26) away from the corresponding support protrusion is installed on the corresponding reciprocating plate (25). A linkage rod (27) is installed on the end of the reciprocating plate (25) away from the return spring rod (26), and the linkage rod (27) abuts against the cam blade (23).
3. The lint blowing and cleaning equipment for garment production according to claim 2, characterized in that: The inner side wall of the C-shaped frame (1) is equipped with an elastic telescopic rod (11). The telescopic end of the elastic telescopic rod (11) is equipped with a linkage roller (12) through a connecting frame. The partition plate (2) is provided with a through groove. The through groove is equipped with a rotating roller (13) extending along the depth direction of the isolation area (3) through a bearing. The adjacent rotating rollers (13) are staggered. The top of the inner end of the C-shaped frame (1) away from the elastic telescopic rod (11) is equipped with a support frame (14). The support frame (14) and the bottom of the C-shaped frame (1) are equipped with a winding roller (15) through a bearing.
4. The lint blowing and cleaning equipment for garment production according to claim 1, characterized in that: The closing rod (31) is provided with a connecting protrusion (34) inside. The bottom of the isolation zone (3) is equipped with a bidirectional screw (35) corresponding to the closing rod (31) through a bearing. The bidirectional screw (35) is connected to the connecting protrusion (34) through a threaded connection. A sprocket (36) is installed at the end of the bidirectional screw (35) away from the bottom of the isolation zone (3).
5. The lint blowing and cleaning equipment for garment production according to claim 3, characterized in that: A pulley (221) is installed on the lower side of the circumferential surface of the rotating shaft (22). A pulley (222) that cooperates with the pulley (221) is installed on the bidirectional screw (35) inside the same isolation area (3) and close to the rotating shaft (22). The pulley (221) and the adjacent pulley (222) are connected by belt drive.
6. The lint blowing and cleaning equipment for garment production according to claim 5, characterized in that: The diameter of the pulley two (222) decreases sequentially from the elastic telescopic rod (11) toward the winding roller (15).
7. The lint blowing and cleaning equipment for garment production according to claim 3, characterized in that: The length of the linkage rod (27) decreases sequentially from the elastic telescopic rod (11) toward the winding roller (15).
8. A method for cleaning lint in garment production by blowing away lint, comprising a lint-blowing and cleaning device for garment production as described in any one of claims 1-7, characterized in that, Its usage includes the following steps: S1: Fabric threading process, the fabric is wrapped around the linkage roller (12) and then around the rotating roller (13) in sequence before being wound onto the winding roller (15); S2: Shaking treatment, the fabric is shaken by the cooperation of the reciprocating block (41) and the shaking rod (42); S3: Dust collection, the loose threads, lint and other impurities that fall off when shaken are collected through the filter screen (32); S4: Winding process, the cleaned fabric is wound up by the winding roller (15).