A drape powder suction device and method

By designing a support component, a dust-absorbing component, and a cleaning component to work in synergy, the cleaning problem caused by static electricity and sticky substances on the lining surface is solved, achieving efficient removal of fiber debris and dust, and improving cleaning efficiency and safety.

CN122169333APending Publication Date: 2026-06-09NANTONG JIANGHUAI LINING CLOTH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
NANTONG JIANGHUAI LINING CLOTH CO LTD
Filing Date
2026-03-05
Publication Date
2026-06-09

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Abstract

This invention belongs to the field of lining production technology and discloses a lining dust suction device, including a support assembly. A dust suction assembly is located at the upper end of the support assembly, and a cleaning assembly is fixedly installed on one side of the support assembly. A conveying component is located in the middle of the inner cavity of the support assembly. The cleaning assembly includes a storage unit, and a drive unit is fixedly installed in the middle of the inner cavity of the support assembly. A connecting unit is located in the inner cavity of the storage unit. By using the drive unit and connecting unit in conjunction, this invention allows the cleaning plate to scrape off fiber debris, dust, or other contaminants from the lining surface during cleaning, preventing the dust suction device from failing to remove debris. Furthermore, after the second connecting component contacts and releases the cleaning plate, the cleaning plate shakes, causing the scraped fiber debris, dust, or other contaminants to fall off, thus facilitating better cleaning of the lining in subsequent applications.
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Description

Technical Field

[0001] This invention belongs to the field of lining production technology, specifically a lining powder absorption device and method. Background Technology

[0002] Lining is a material used to enhance the shape, structure, or thickness of fabrics or clothing. During the production of lining, processes such as gluing, drying, and cutting are required, which can easily generate fiber debris, dust, or other pollutants. It is necessary to clean up the fiber debris, dust, or other pollutants generated during the production of lining in a timely manner to reduce the negative impact on the environment and human health.

[0003] When cleaning fiber debris, dust, or other contaminants generated during the production of lining fabric, a dust collection device is activated to clean the surface of the lining fabric. However, when there is static electricity or other sticky substances on the surface of the lining fabric, the fibers of the lining fabric will firmly adhere to the debris, making it impossible for the dust collection device to effectively absorb and clean these debris. This reduces the dust removal effect on the lining fabric, requiring manual cleaning of the surface of the lining fabric again, which reduces the efficiency of dust removal. Therefore, improvements are needed. Summary of the Invention

[0004] To address the problem mentioned in the background art that when the surface of the lining has static electricity and other sticky substances, the fibers of the lining will firmly adsorb debris, resulting in a poor dust absorption effect and reduced work efficiency in dust removal, the present invention provides a lining dust absorption device and method.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a lining powder absorption device, comprising a support assembly, a powder absorption assembly disposed at the upper end of the support assembly, a cleaning assembly fixedly installed on one side of the support assembly, a conveying component disposed in the middle of the inner cavity of the support assembly, the cleaning assembly comprising a storage unit, a driving unit fixedly installed in the middle of the inner cavity of the support assembly, a connecting unit disposed in the inner cavity of the storage unit, the driving unit comprising a first connecting rod, a second connecting rod disposed at one end of the first connecting rod, and a movable [device] fixedly connected to the end of the second connecting rod away from the first connecting rod. The movable block has a mounting rod movably connected to its bottom, a fixing rod fixedly installed on one side of the movable block, a connecting rope fixedly installed on the side of the movable block, and a cleaning plate fixedly installed at the end of the connecting rope. The connecting unit includes a first connecting member, a first spring elastically connecting the first connecting member and the fixing box, a second connecting member provided at the upper end of the fixing box, a second spring elastically connecting the second connecting member and the fixing box, one end of the first connecting member being set as an inclined surface, and a groove being opened on the second connecting member near the fixing box, with the first connecting member and the second connecting member abutting against each other.

[0006] Preferably, a drive motor is fixedly connected to the end of the first connecting rod away from the second connecting rod, the support assembly includes a support base, a dust cover is fixedly installed on the top of the support base, the dust cover is fixedly connected to the powder suction assembly, and a mounting block is provided at the bottom of the drive motor, and the mounting block is fixedly connected to the support base.

[0007] Preferably, the storage unit includes a fixed box, the inner cavity of which is movably connected to the storage box, and the fixed box is fixedly connected to the support base.

[0008] Preferably, the powder suction assembly includes a mounting box, a powder cleaning component is movably connected to the inner cavity of the mounting box, a powder suction pipe is fixedly connected to one side of the mounting box, a movable plate is fixedly installed at the lower end of the powder suction pipe, and a pneumatic cylinder is fixedly installed on the top surface of the movable plate.

[0009] Preferably, a handle is fixedly installed on one side of the powder cleaning component, the top surface of the pneumatic cylinder is fixedly connected to the dust cover, the middle part of the powder suction pipe is set as a threaded pipe, and the moving plate is movably connected to the dust cover.

[0010] Preferably, the mounting rod is fixedly connected to the top surface of the support base, the top surface of the mounting rod is provided with a sliding groove and is movably connected to the moving block, the inner wall of the sliding groove is smooth, and the lower end of the cleaning plate is set as an inverted triangle.

[0011] Preferably, the fixing rod is in contact with the first connecting member, the first connecting member is movably connected to the fixing box, a viewing window is provided on one side of the dust cover, and a control panel is provided on one side of the support base.

[0012] The present invention also includes a method for a powder-absorbing device for a lining fabric, the specific steps of which are as follows: Step 1: First, open the door at the top of the support base, place the lining on the surface of the conveyor, start the pneumatic cylinder, the pneumatic cylinder drives the powder suction pipe and the moving plate to move downwards, and when the powder suction pipe moves downwards, the powder suction point of the powder suction pipe is close to the lining. Step 2: When the suction pipe sucks up the fiber debris, dust or other contaminants on the surface of the lining, start the drive motor. The drive motor rotates and drives the first connecting rod to rotate. The first connecting rod drives the second connecting rod and the moving block to move. The second connecting rod drives the moving block to slide on the surface of the mounting rod. At the same time, the moving block drives the cleaning plate, the fixing rod and the connecting rope to move. The cleaning plate moves to scrape off the fiber debris, dust or other contaminants that have not been sucked up from the surface of the lining. Step 3: When the first connecting rod and the second connecting rod are on the same horizontal line, the fixed rod abuts against the first connecting piece. The first connecting piece moves and abuts against the second connecting piece closer to the support base. The second connecting piece moves and abuts against the cleaning plate. The drive motor rotates continuously, driving the second connecting rod and the first connecting rod to move, thereby driving the connecting rope and the cleaning plate to reciprocate. When the second connecting piece is no longer abutting against the cleaning plate, the cleaning plate shakes. The connecting rope drives the cleaning plate to shake, causing the fiber debris, dust or other contaminants scraped off the surface of the cleaning plate to fall into the inner cavity of the storage box. Step 4: When the second connector is no longer in contact with the cleaning plate, the second spring and the first spring drive the second connector and the first connector to reset, so that they can contact the cleaning plate again next time. After a certain period of time, move the storage box and the cleaning component to clean the fiber debris, dust or other contaminants in the storage box and the cleaning component.

[0013] Compared with the prior art, the beneficial effects of the present invention are as follows: This invention, through the cooperation of structures such as a drive unit and a connecting unit, can scrape off fiber debris, dust, or other contaminants from the surface of the lining when cleaning it. When there is static electricity or other sticky substances on the surface of the lining, the cleaning plate scrapes off the fiber debris, dust, or other contaminants, avoiding the situation where the vacuum cleaner cannot clean up the debris. Furthermore, after the second connecting member contacts and releases the contact with the cleaning plate, the cleaning plate shakes, which can cause the scraped fiber debris, dust, or other contaminants to fall off, thus facilitating better cleaning of the lining in the next cycle.

[0014] This invention, through the combination of a suction pipe and a pneumatic cylinder, allows the suction pipe to move up and down under the drive of the pneumatic cylinder when there are floating fiber debris, dust, or other contaminants inside the suction device and on the surface of the lining. When the suction pipe moves up and down, it can quickly clean the fiber debris, dust, or other contaminants inside the device, avoiding the situation where the suction device can only be at a fixed height and cannot clean the fiber debris, dust, or other contaminants. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram showing the structural relationship between the support component and the powder absorption component of the present invention; Figure 3 This is a schematic diagram of the disassembled structure of the powder-absorbing component of the present invention; Figure 4 This is a schematic diagram showing the structural relationship between the support base and the cleaning component of the present invention; Figure 5This is a schematic diagram showing the structural cooperation relationship between the driving unit and the connecting unit of the present invention; Figure 6 This is a schematic diagram of the split structure at the drive unit of the present invention; Figure 7 This is a schematic diagram showing the split structure of the driving unit and the connecting unit of the present invention.

[0016] In the diagram: 1. Support assembly; 11. Support base; 12. Dust cover; 2. Powder suction assembly; 21. Mounting box; 22. Powder cleaning component; 23. Powder suction pipe; 24. Moving plate; 25. Pneumatic cylinder; 3. Cleaning assembly; 31. Storage unit; 311. Fixing box; 312. Storage box; 32. Drive unit; 321. Drive motor; 322. First connecting rod; 323. Second connecting rod; 324. Moving block; 325. Mounting rod; 326. Fixing rod; 327. Connecting rope; 328. Cleaning plate; 33. Connecting unit; 331. First connecting piece; 332. First spring; 333. Second connecting piece; 334. Second spring; 4. Conveying component. Detailed Implementation

[0017] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0018] like Figures 1 to 7 As shown, the present invention provides a lining powder absorption device, including a support assembly 1, a powder absorption assembly 2 disposed at the upper end of the support assembly 1, a cleaning assembly 3 fixedly installed on one side of the support assembly 1, a conveying component 4 disposed in the middle of the inner cavity of the support assembly 1, the cleaning assembly 3 including a storage unit 31, a driving unit 32 fixedly installed in the middle of the inner cavity of the support assembly 1, a connecting unit 33 disposed in the inner cavity of the storage unit 31, the driving unit 32 including a first connecting rod 322, a second connecting rod 323 disposed at one end of the first connecting rod 322, a moving block 324 fixedly connected to the end of the second connecting rod 323 away from the first connecting rod 322, an installation rod 325 movably connected to the bottom of the moving block 324, a fixing rod 326 fixedly installed on one side of the moving block 324, a connecting rope 327 fixedly installed on the side of the moving block 324, and a cleaning plate 328 fixedly installed at the end of the connecting rope 327.

[0019] Using the above scheme: Through the cooperation of the drive unit 32 and the connecting unit 33, the lining cloth is placed on the surface of the conveyor 4. The conveyor 4 consists of a conveyor belt, a connecting shaft, and a servo motor, thereby driving the conveyor 4 to rotate and conveying the lining cloth. The pneumatic cylinder 25 is activated, which drives the moving plate 24 and the powder suction pipe 23. The suction tube 23 moves downwards, bringing its suction point close to the lining fabric to prepare for efficient suction. The suction assembly 2 is then activated, moving downwards to absorb and clean fiber debris, dust, or other contaminants from the lining fabric surface. Simultaneously, the drive motor 321 is activated, rotating the first connecting rod 322. The first connecting rod 322 then moves the second connecting rod 323 and the moving block 324. The second connecting rod 323 causes the moving block 324 to slide on the surface of the mounting rod 325. Simultaneously, the moving block 324 moves the cleaning plate 328, the fixing rod 326, and the connecting rope 327. The cleaning plate 328 scrapes away any remaining fiber debris, dust, or other contaminants from the lining fabric surface. When the first connecting rod 322 and the second connecting rod 323 rotate to the same horizontal line, the fixing rod 326 contacts the first connecting member 331, pushing the first connecting member 331 to move and compressing the first spring 332. The first connecting member 331 then contacts the second connecting member 333. The device moves towards the support base 11, compressing the second spring 334 and creating resistance against the cleaning plate 328. The drive motor 321 rotates continuously, causing the second connecting rod 323 and the first connecting rod 323 to reset, thereby causing the connecting rope 327 and the cleaning plate 328 to reciprocate. When the fixed rod 326 separates from the first connecting member 331, the second connecting member 333 releases its resistance against the cleaning plate 328. Under the action of the elastic connecting rope 327, the cleaning plate 328 shakes violently, causing the contaminants adhering to its surface to fall into the inner cavity of the storage box 312. The support assembly 1 has a discharge port on the side away from the cleaning assembly 3, allowing the cleaned lining to be removed from the discharge port. This achieves the effect of effectively adsorbing and cleaning these debris when there is static electricity and other sticky substances on the surface of the lining, improving the efficiency of cleaning fiber debris, dust, or other contaminants on the surface of the lining.

[0020] like Figure 2 , Figure 5 and Figure 7As shown, a drive motor 321 is fixedly connected to the end of the first connecting rod 322 away from the second connecting rod 323. The support assembly 1 includes a support base 11, and a dust cover 12 is fixedly installed on the top of the support base 11. The dust cover 12 is fixedly connected to the powder suction assembly 2. An installation block is provided at the bottom of the drive motor 321, and the installation block is fixedly connected to the support base 11. The storage unit 31 includes a fixed box 311, and a storage box 312 is movably connected to the inner cavity of the fixed box 311. The fixed box 311 is fixedly connected to the support base 11. The connecting unit 33 includes a first connecting member 331, and a first spring 332 is elastically connected between the first connecting member 331 and the fixed box 311. A second connecting member 333 is provided at the upper end of the fixed box 311, and a second spring 334 is elastically connected between the second connecting member 333 and the fixed box 311.

[0021] The above solution involves the cooperation of the support base 11 and the dust cover 12. The dust cover 12 encloses the device, preventing fiber fragments, dust, or other pollutants from the lining fabric from floating in the air, thus reducing air pollution and protecting the health of workers. The first connecting rod 322 is fixedly connected to the drive motor 321, causing the drive motor 321 to rotate and drive the first connecting rod 322 to rotate. This, in turn, causes the first connecting rod 322 to move the second connecting rod 323 and the moving block 324. The top surface of the support base 11 has a through groove, allowing the first connecting rod 322 and the second connecting rod 323 to rotate as they rotate, thereby driving the moving block 324 and the cleaning plate 328 to reciprocate, thus cleaning the surface of the lining fabric. The design of the mounting block at the bottom of the drive motor 321 supports the drive motor 321, making it more stable during operation. Through the design of the fixed box 311 and the storage box 312, after a certain period of time, the storage box 312 can be moved to clean up any fallen fiber debris, dust, or other contaminants, preventing long-term accumulation and corrosion of the storage box 312. The fixed box 311 is fixedly connected to the support base 11, thereby fixing the storage unit 31 and the drive unit 32. Through the cooperation of the first connecting member 331 and the first spring 332, the fixing rod 326 abuts against the first connecting member 331, and the movement of the first connecting member 331 moves the first spring 322. The second connecting member 333 abuts against the support base 11. The second connecting member 333 moves to abut against the cleaning plate 328. As the second connecting rod 323 drives the moving block 324 and the fixed rod 326 to move closer to the first connecting member 331, the fixed rod 326 gradually abuts against the first connecting member 331. As the fixed rod 326 gradually abuts against the first connecting member 331, the first connecting member 331 moves closer to the second connecting member 333, causing the first connecting member 331 to gradually abut against both second connecting members 333. When the first connecting member 331 abuts against the second connecting members 333, the second connecting members 333 move closer to the support base 11, causing the second connecting member 333 to abut against the cleaning plate 328. The drive motor... The continuous rotation of 321 drives the second connecting rod 323 and the first connecting rod 322 to move, thereby driving the connecting rope 327 and the cleaning plate 328 to reciprocate. The sensor at the groove of the support assembly 1 controls the speed of the drive motor 321, making the speed of the drive motor 321 relatively slow. The drive motor 321 drives the moving block 324 and the fixed rod 326 to move. When the fixed rod 326 does not contact the first connecting member 331, the second connecting member 333 does not contact the cleaning plate 328. The second spring 334 and the first spring 332 drive the second connecting member 333 and the first connecting member 331 to reset. When the second connecting member 333 does not contact the cleaning plate 328, the connecting rope 327 causes the cleaning plate 328 to sway due to the elasticity of the rope.The cleaning plate 328 vibrates. Due to the elasticity of the connecting rope 327, it undergoes elastic deformation under the force of the second connecting piece 333 when it contacts the cleaning plate 328. After the second connecting piece 333 releases its contact with the cleaning plate 328, the elastic force of the first spring 332 and the second spring 334 causes the first connecting piece 331 and the second connecting piece 333 to quickly return to their original positions. The elastic rope then releases its energy through its own elasticity, causing the cleaning plate 328 to vibrate. After several movements or adjustments, the elastic rope returns to its unstretched state, facilitating its next contact with the cleaning plate 328. After the device has been working continuously for a certain period of time, the storage box 312 and the powder cleaning component 22 are pulled out to collect and clean the fiber debris, dust, and other contaminants. After cleaning, the storage box 312 and the powder cleaning component 22 are reset, and the lining cleaning operation can continue.

[0022] like Figure 2 , Figure 3 As shown, the powder suction assembly 2 includes a mounting box 21. A powder cleaning component 22 is movably connected to the inner cavity of the mounting box 21. A powder suction pipe 23 is fixedly connected to one side of the mounting box 21. A movable plate 24 is fixedly installed at the lower end of the powder suction pipe 23. A pneumatic cylinder 25 is fixedly installed on the top surface of the movable plate 24. A handle is fixedly installed on one side of the powder cleaning component 22. The top surface of the pneumatic cylinder 25 is fixedly connected to the dust cover 12. The middle part of the powder suction pipe 23 is configured as a threaded pipe. The movable plate 24 is movably connected to the dust cover 12.

[0023] The above solution involves using the suction pipe 23 and the pneumatic cylinder 25 to place the lining fabric on the surface of the conveyor 4. Activating the pneumatic cylinder 25 causes the suction pipe 23 and the moving plate 24 to move downwards. As the suction pipe 23 moves downwards, its suction point approaches the lining fabric, allowing for better cleaning of fiber debris, dust, or other contaminants from the fabric surface. This prevents the suction device from remaining at the same height and unable to move, which would hinder effective cleaning of the lining fabric. The pneumatic cylinder 25 is fixedly installed between the dust cover 12 and the moving plate 24, ensuring that activation of the pneumatic cylinder 25 causes the moving plate 24 to move downwards. The suction pipe 23 expands, and the threaded design in the middle of the suction pipe 23 allows it to move up and down to retract, thereby adjusting the distance between the suction device and the lining cloth, and thus better suctioning and cleaning the lining cloth. The outer wall of the suction pipe 23 is equipped with an air pressure pump. The moving plate 24 is movably connected to the dust cover 12, which limits the movement of the moving plate 24, making the moving plate 24 more stable. The handle design of the cleaning component 22 makes it easier to move. The suction pipe 23 is connected to the mounting box 21 and the cleaning component 22, so that the cleaned fiber debris, dust or other contaminants can enter the cleaning component 22 for temporary buffering.

[0024] like Figure 1 , Figure 6 and Figure 7 As shown, the mounting rod 325 is fixedly connected to the top surface of the support base 11. The top surface of the mounting rod 325 is provided with a sliding groove and is movably connected to the moving block 324. The inner wall of the sliding groove is smooth. The lower end of the cleaning plate 328 is set as an inverted triangle. One end of the first connecting piece 331 is set as a bevel. The second connecting piece 333 is provided with a groove near the fixed box 311. The first connecting piece 331 and the second connecting piece 333 are in contact with each other. The fixed rod 326 is in contact with the first connecting piece 331. The first connecting piece 331 is movably connected to the fixed box 311. A viewing window is provided on one side of the dust cover 12. A control panel is provided on one side of the support base 11.

[0025] The above solution employs the following: The mounting rod 325 and support base 11 are fixedly connected, making the sliding block 324 more stable when sliding within the mounting rod 325. The sliding block 324 is movably connected to the mounting rod 325. The design of the groove in the middle of the mounting rod 325 limits the movement of the sliding block 324 within the mounting rod 325, making the mounting rod 325 more stable during movement. The smooth inner wall of the groove reduces friction with the sliding block 324 during movement, resulting in less resistance for the sliding block 324. The inverted triangular design at the lower end of the cleaning plate 328 allows for better cleaning of the lining cloth. Fiber debris, dust, or other contaminants on the surface are scraped off to prevent them from adhering to the lining surface and becoming impossible to clean. The inclined design of the first connector 331 allows the fixing rod 326 to better engage with the first connector 331 when it moves closer to it, causing the two first connectors 331 to move towards each other. The movement of the first connector 331 engages with the second connector 333, causing the second connector 333 to move closer to the support base 11 and engage with the cleaning plate 328. The groove in the second connector 333 allows the first connector... When the first connecting member 331 abuts against the second connecting member 333, the moving blocks 324 and fixing rods 326 on both sides move closer to the first connecting member 331. As the two fixing rods 326 gradually abut against the two first connecting members 331, the two first connecting members 331 move towards each other, moving closer to the two second connecting members 333. This causes the two first connecting members 331 to gradually abut against the two second connecting members 333. When the two first connecting members 331 abut against the two second connecting members 333, the second connecting members 333 move closer to the support... The support 11 moves, causing the second connector 333 to abut against the cleaning plate 328. The groove of the second connector 333 facilitates the movement of the second connector 333 towards the support 11 when the first connector 331 abuts against it, thereby causing the second connector 333 to abut against the cleaning plate 328. The first connector 331 is movably connected to the fixed box 311, which limits the movement of the fixed box 311. The design of the viewing window of the dust cover 12 allows for observation of the cleaning of the lining cloth at any time. The design of the control panel on one side of the support 11 allows for better control of the device.

[0026] The present invention also includes a method for a powder-absorbing device for a lining fabric, the specific steps of which are as follows: Step 1: First, open the door at the top of the support base 11, place the lining cloth on the surface of the conveyor 4, start the pneumatic cylinder 25, the pneumatic cylinder 25 drives the powder suction pipe 23 and the moving plate 24 to move downwards, and when the powder suction pipe 23 moves downwards, the powder suction point of the powder suction pipe 23 is close to the lining cloth. Step 2: When the suction pipe 23 sucks up the fiber debris, dust or other contaminants on the surface of the lining, the drive motor 321 is started. The drive motor 321 rotates and drives the first connecting rod 322 to rotate. The first connecting rod 322 drives the second connecting rod 323 and the moving block 324 to move. The second connecting rod 323 drives the moving block 324 to slide on the surface of the mounting rod 325. At the same time, the moving block 324 drives the cleaning plate 328, the fixing rod 326 and the connecting rope 327 to move. The cleaning plate 328 moves to scrape off the fiber debris, dust or other contaminants that have not been sucked up from the surface of the lining. Step 3: When the first connecting rod 322 and the second connecting rod 323 are on the same horizontal line, the fixed rod 326 abuts against the first connecting member 331. The first connecting member 331 moves to abut against the second connecting member 333 closer to the support seat 11. The second connecting member 333 moves to abut against the cleaning plate 328. The drive motor 321 rotates continuously to drive the second connecting rod 323 and the first connecting rod 322 to move, thereby driving the connecting rope 327 and the cleaning plate 328 to reciprocate. When the second connecting member 333 is not abutting against the cleaning plate 328, the cleaning plate 328 shakes. The connecting rope 327 drives the cleaning plate 328 to shake, causing the fiber debris, dust or other contaminants scraped off the surface of the cleaning plate 328 to fall into the inner cavity of the storage box 312. Step 4: When the second connector 333 is not in contact with the cleaning plate 328, the second spring 334 and the first spring 332 drive the second connector 333 and the first connector 331 to reset, so that they can contact the cleaning plate 328 next time. After a certain period of time, move the storage box 312 and the powder cleaning component 22 to clean the fiber debris, dust or other contaminants in the storage box 312 and the powder cleaning component 22.

[0027] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus.

[0028] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A powder-absorbing device and method for a lining fabric, comprising a support assembly (1), characterized in that: The upper end of the support component (1) is provided with a powder suction component (2), a cleaning component (3) is fixedly installed on one side of the support component (1), and a conveying component (4) is provided in the middle of the inner cavity of the support component (1). The cleaning component (3) includes a storage unit (31), a drive unit (32) is fixedly installed in the middle of the inner cavity of the support component (1), and a connection unit (33) is provided in the inner cavity of the storage unit (31). The drive unit (32) includes a first connecting rod (322), a second connecting rod (323) is provided at one end of the first connecting rod (322), a moving block (324) is fixedly connected to the end of the second connecting rod (323) away from the first connecting rod (322), an installation rod (325) is movably connected to the bottom of the moving block (324), a fixing rod (326) is fixedly installed on one side of the moving block (324), a connecting rope (327) is fixedly installed on the side of the moving block (324), and a cleaning plate (328) is fixedly installed at the end of the connecting rope (327). The connecting unit (33) includes a first connector (331), a first spring (332) is elastically connected between the first connector (331) and the fixed box (311), a second connector (333) is provided at the upper end of the fixed box (311), a second spring (334) is elastically connected between the second connector (333) and the fixed box (311), one end of the first connector (331) is set as an inclined surface, the second connector (333) has a groove near the fixed box (311), and the first connector (331) and the second connector (333) are in contact connection.

2. The lining powder absorption device according to claim 1, characterized in that: A drive motor (321) is fixedly connected to the end of the first connecting rod (322) away from the second connecting rod (323); The support component (1) includes a support base (11), a dust cover (12) is fixedly installed on the top of the support base (11), the dust cover (12) is fixedly connected to the powder suction component (2), and an installation block is provided at the bottom of the drive motor (321), and the installation block is fixedly connected to the support base (11).

3. The lining powder absorption device according to claim 1, characterized in that: The storage unit (31) includes a fixed box (311), and a storage box (312) is movably connected to the inner cavity of the fixed box (311). The fixed box (311) is fixedly connected to the support base (11).

4. The lining powder absorption device according to claim 1, characterized in that: The powder suction assembly (2) includes a mounting box (21), a powder cleaning component (22) is movably connected to the inner cavity of the mounting box (21), a powder suction pipe (23) is fixedly connected to one side of the mounting box (21), a moving plate (24) is fixedly installed at the lower end of the powder suction pipe (23), and a pneumatic cylinder (25) is fixedly installed on the top surface of the moving plate (24).

5. The lining powder absorption device according to claim 4, characterized in that: A handle is fixedly installed on one side of the powder cleaning component (22), the top surface of the pneumatic cylinder (25) is fixedly connected to the dust cover (12), the middle part of the powder suction pipe (23) is set as a threaded pipe, and the moving plate (24) is movably connected to the dust cover (12).

6. The lining powder absorption device according to claim 1, characterized in that: The mounting rod (325) is fixedly connected to the top surface of the support base (11). The top surface of the mounting rod (325) is provided with a sliding groove and is movably connected to the moving block (324). The inner wall of the sliding groove is smooth, and the lower end of the cleaning plate (328) is set as an inverted triangle.

7. The lining powder absorption device according to claim 2, characterized in that: The fixing rod (326) is in contact with the first connector (331), the first connector (331) is movably connected to the fixing box (311), a viewing window is provided on one side of the dust cover (12), and a control panel is provided on one side of the support base (11).

8. A method for a lining powder absorption device, applied to the lining powder absorption device according to any one of claims 1-7, characterized in that, The specific steps are as follows: Step 1: First, open the door at the top of the support base (11), place the lining on the surface of the conveyor (4), start the pneumatic cylinder (25), the pneumatic cylinder (25) drives the powder suction pipe (23) and the moving plate (24) to move downwards, and when the powder suction pipe (23) moves downwards, the powder suction point of the powder suction pipe (23) is close to the lining. Step 2: When the suction pipe (23) sucks up the fiber debris, dust or other contaminants on the surface of the lining, start the drive motor (321). The drive motor (321) rotates and drives the first connecting rod (322) to rotate. The first connecting rod (322) drives the second connecting rod (323) and the moving block (324) to move. The second connecting rod (323) drives the moving block (324) to slide on the surface of the mounting rod (325). At the same time, the moving block (324) drives the cleaning plate (328), the fixing rod (326) and the connecting rope (327) to move. The cleaning plate (328) moves to scrape off the fiber debris, dust or other contaminants that have not been sucked up from the surface of the lining. Step 3: When the first connecting rod (322) and the second connecting rod (323) are on the same horizontal line, the fixed rod (326) abuts against the first connecting piece (331), the first connecting piece (331) moves to abut against the second connecting piece (333) closer to the support base (11), the second connecting piece (333) moves to abut against the cleaning plate (328), and the drive motor (321) continues to rotate, driving the second connecting rod (323) and the first connecting rod. (322) moves, thereby driving the connecting rope (327) and the cleaning plate (328) to reciprocate. When the second connecting piece (333) does not contact the cleaning plate (328), the cleaning plate (328) shakes. The connecting rope (327) drives the cleaning plate (328) to shake, causing the fiber debris, dust or other contaminants scraped off the surface of the cleaning plate (328) to fall into the inner cavity of the storage box (312). Step 4: When the second connector (333) does not contact the cleaning plate (328), the second spring (334) and the first spring (332) drive the second connector (333) and the first connector (331) to reset, so that the cleaning plate (328) can be contacted again next time. After a certain period of time, move the storage box (312) and the cleaning component (22) to clean the fiber debris, dust or other contaminants in the storage box (312) and the cleaning component (22).