CN214218946U - Back way subassembly of chenille machine - Google Patents

Abstract

The utility model discloses a back way subassembly of chenille machine, set up the frame in chenille machine support body both sides respectively including two, top one side of frame all is provided with the guide rail, and the top opposite side of frame all is provided with the rack, and the top of frame all is provided with the detection mechanism that removes dust with guide rail and rack matched with, and one side of detection mechanism that removes dust all is provided with the automatic mechanism that doffs with guide rail and rack matched with. The device not only can effectively reduce the concentration of suspended particles in the air, improve the working environment of a spinning workshop, but also can reduce the risk of fire hazards in the workshop, ensure the life and property safety of enterprises and staff, effectively reduce the labor intensity of the staff and improve the automation degree and the production efficiency of equipment.

Description

Back way subassembly of chenille machine

Technical Field

The utility model relates to a spinning auxiliary assembly technical field particularly, relates to a back way subassembly of chenille machine.

Background

The chenille yarn is also named as corduroy, is a novel pattern yarn, and is spun by taking two plied yarns as core yarns and clamping down yarns in the middle through twisting. At present, the known chenille machine spinning chenille wool has the main yarn forming principle that: the knitting wool raw materials (yarns, threads, long threads and the like) pass through a hollow rotary head upright post and a rotary disc connected with the rotary head upright post and then are wound on a distance cutting sheet, and the rotary disc is driven by a rotary motor to rotate at a high speed through a belt pulley; the rotary left and right delivery rollers are pressed by a swing arm tension spring mechanism and then abut against the distance cutting piece, the wool tightly wound on the distance cutting piece is stripped downwards by the left and right delivery rollers, and then the wool is divided into two parts by a blade below the distance cutting piece. The core yarn wound on the left and right delivery rollers and the two core yarns which penetrate through the left and right cutting distance pieces respectively clamp the wool which is cut into two parts by the blade, and then the two strands of chenille wool are manufactured by twisting.

At present, the chenille machine is easy to form flying flowers and hairiness in the production of chenille knitting wool, and in order to ensure the production quality of the chenille knitting wool, the flying flowers and the hairiness which are generated need to be removed, and the defects of yarns need to be detected in the spinning process. An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

To the problem among the correlation technique, the utility model provides a back end subassembly of chenille machine for solving the defect detection of the fly, the filoplume and the yarn that produce.

Therefore, the utility model discloses a specific technical scheme as follows:

the utility model provides a back way subassembly of chenille machine, include that two set up the frame in chenille frame body both sides respectively, top one side of frame all is provided with the guide rail, the top opposite side of frame all is provided with the rack, the top of frame all is provided with the detection mechanism that removes dust with guide rail and rack matched with, and chenille frame body's inside be provided with the detection mechanism matched with that removes dust down dust absorption wind channel, and the one end in dust absorption wind channel is connected with the fan case that is located chenille frame body one end down, one side of detection mechanism that removes dust all is provided with the automatic mechanism that doffs with guide rail and rack matched with.

As a preferable scheme, in order to effectively remove and recover the flying flowers and hairiness formed during the spinning of the chenille machine and detect the defects of the yarn in the spinning process, the dust removal detection mechanism comprises first guide wheel assemblies respectively installed on a guide rail and a rack, a bottom plate is arranged between the tops of the first guide wheel assemblies, a movable box body is arranged at the top of the bottom plate, a servo transmission unit is arranged on one side of the inner bottom of the movable box body, the bottom end of an output shaft on the servo transmission unit penetrates through the bottom plate and is connected with a gear located inside the first guide wheel assemblies, one side of the gear is meshed with the rack, a dust removal assembly is arranged on one side of the inside of the movable box body, and a visual detection assembly is arranged on one side of the inner top of the movable box body.

As a preferred scheme, in order to effectively realize the removal and recovery of the flying flowers and the hairiness formed during the chenille machine spinning, the dust removal component comprises a fan cabinet arranged on one side inside the movable box body, a centrifugal fan is arranged on the fan cabinet, an upper air outlet pipe is arranged at the top of the fan cabinet, a lower air outlet pipe is arranged at the bottom of the fan cabinet, and one ends of the lower air outlet pipe and the upper air outlet pipe, which are far away from the movable box body, extend to the outer side of the movable box body.

As a preferable scheme, in order to effectively realize the defect detection of the yarn in the spinning process, the visual detection assembly comprises a fixing frame arranged on one side inside the movable box body, an industrial camera is arranged at the bottom of the fixing frame, a lens is arranged on one side of the industrial camera, and an annular light source is arranged on one side of the lens, which is far away from the industrial camera.

As an optimal scheme, in order to play automatic doffing effect, alleviate staff's intensity of labour, improve equipment's degree of automation and production efficiency, automatic doffing mechanism is including installing the second leading wheel subassembly on guide rail and rack respectively, be provided with braced frame between the top of second leading wheel subassembly, braced frame's top is provided with doffing dolly frame, install the doffing baffle in the doffing dolly frame, and one side of frame be provided with doffing baffle matched with full yarn dolly, the top of doffing dolly frame is provided with sharp module, the top of sharp module is provided with lift cylinder assembly, the bottom of lift cylinder assembly is provided with grabs a tub subassembly.

As a preferred scheme, in order to facilitate the realization of the placement of yarns, both sides of the chenille machine frame body are provided with yarn clamps, the yarn clamps are sleeved with full bobbins, the rear sides of the full bobbins are provided with yarn guide plates, and the chenille machine frame body is provided with a yarn guide plate overturning device matched with the yarn guide plates.

As an optimal scheme, in order to play direction and location effect to bottom plate and braced frame's removal, first leading wheel subassembly and second leading wheel subassembly all include the mounting bracket, and the vertical symmetry in one side of mounting bracket is provided with two sets of bearings, and the middle part of bearing all alternates and is provided with matched with pivot with it, and the nut is passed through to the one end of pivot and is connected with the mounting bracket.

As a preferred scheme, in order to achieve the effect of collecting the generated flying cotton and the generated hairiness, a roller cotton cleaning device is arranged on one side of the inner bottom of a fan box, one side of the roller cotton cleaning device is connected with a negative pressure cabin, a vortex air pump is arranged on one side of the inner top of the fan box, a first hose is arranged at an air outlet of the vortex air pump, the other end of the first hose is connected with the negative pressure cabin, a second hose is arranged at an air inlet of the vortex air pump, the other end of the second hose is connected with a cotton collection box connector, the cotton collection box connector is further connected with the negative pressure cabin through a third hose, and a negative pressure fan connected with the negative pressure cabin is arranged on one side of the vortex air pump.

The utility model has the advantages that:

1) the use through dust removal detection mechanism, fly flower and the filoplume that form when can clear away the recovery chenille machine spinning effectively also carry out the defect detection to the yarn of spinning in-process simultaneously to not only can effectively reduce the concentration of suspended particles in the air, improve the operational environment in spinning workshop, but also can reduce the risk of workshop conflagration, ensure enterprise and staff's the security of the lives and property.

2) By using the automatic doffing mechanism, the automatic doffing effect can be realized, the labor intensity of workers is effectively reduced, and the automation degree and the production efficiency of equipment are improved; simultaneously, use through the cooperation of dust removal detection mechanism and automatic doffing mechanism, make the utility model discloses have the function of tour dust removal, yarn detection and automatic doffing.

Drawings

Fig. 1 is a schematic structural view of a rear assembly of a chenille machine according to an embodiment of the present invention;

FIG. 2 is an enlarged view of a portion of the structure at A in FIG. 1;

fig. 3 is a schematic structural diagram of a dust removal detection mechanism in a subsequent assembly of the chenille machine according to an embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of the structure shown at B in FIG. 3;

fig. 5 is a schematic structural diagram of a visual inspection assembly in a subsequent assembly of the chenille machine according to an embodiment of the present invention;

fig. 6 is a schematic structural view of an automatic doffing mechanism in a rear assembly of the chenille machine according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a linear module in a subsequent assembly of the chenille machine according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a first guide wheel assembly in a subsequent assembly of the chenille machine according to an embodiment of the present invention;

fig. 9 is a schematic diagram of an internal structure of a fan case in a subsequent module of the chenille machine according to an embodiment of the present invention.

In the figure:

1. a chenille airframe body; 2. a frame; 3. a guide rail; 4. a rack; 5. a dust removal detection mechanism; 6. an automatic doffing mechanism; 7. a fan box; 8. a first guide wheel assembly; 9. a base plate; 10. moving the box body; 11. A servo transmission unit; 12. a gear; 13. a fan cabinet; 14. a centrifugal fan; 15. an air outlet pipe is arranged; 16. A lower air outlet pipe; 17. a fixed mount; 18. an industrial camera; 19. a lens; 20. an annular light source; 21. a second guide wheel assembly; 22. a support frame; 23. a doffing cart frame; 24. a pipe falling guide plate; 25. a full yarn trolley; 26. a linear module; 27. a lift cylinder assembly; 28. a pipe grasping assembly; 29. a yarn gripper; 30. Filling the bobbin; 31. a yarn guide plate turnover device; 32. a mounting frame; 33. a bearing; 34. a rotating shaft; 35. a nut; 36. a roller blowing device; 37. a negative pressure cabin; 38. a vortex air pump; 39. a first hose; 40. a second hose; 41. a cotton collecting box connector; 42. a third hose; 43. a negative pressure fan; 44. a lower dust collection air duct.

Detailed Description

The invention will now be further described with reference to the accompanying drawings and specific embodiments, as shown in figures 1-9, the back component of the chenille machine according to the embodiment of the utility model comprises a frame 2 arranged at two sides of a chenille machine frame body 1, a guide rail 3 is arranged at one side of the top of the frame 2, a rack 4 is arranged at the other side of the top of the frame 2, a dust removal detection mechanism 5 matched with the guide rail 3 and the rack 4 is arranged at the top of the frame 2, and the chenille machine frame body 1 is internally provided with a lower dust suction duct 44 matched with the dust removal detection mechanism 5, and one end of the lower dust suction duct 44 is connected with the fan box 7 positioned at one end of the chenille machine frame body 1, one side of the dust removal detection mechanism 5 is provided with an automatic doffing mechanism 6 matched with the guide rail 3 and the rack 4, and the automatic doffing mechanism 6 and the dust removal detection mechanism 5 move synchronously.

Dust removal detection mechanism 5 is including installing first leading wheel subassembly 8 on guide rail 3 and rack 4 respectively, be provided with bottom plate 9 between the top of first leading wheel subassembly 8, the top of bottom plate 9 is provided with removes box 10, interior bottom one side of removing box 10 is provided with servo drive unit 11 (servo motor), and the bottom of output shaft runs through bottom plate 9 and is connected with the gear 12 that is located first leading wheel subassembly 8 inside on servo drive unit 11, and one side and the rack 4 mesh of gear 12, inside one side of removing box 10 is provided with the subassembly that removes dust, it is provided with the visual detection subassembly to remove interior top one side of box 10. Through the use of dust removal detection mechanism 5, can clear away the fly flower and the filoplume that form when retrieving chenille machine spinning effectively, also carry out the defect detection to the yarn of spinning in-process simultaneously, can effectively reduce the concentration of suspended particles in the air on the one hand, improve the operational environment in spinning workshop, reduce the risk of workshop conflagration, ensure enterprise and staff's the security of the lives and property.

The dust removal component comprises a fan cabinet 13 arranged on one side inside the movable box body 10, a centrifugal fan 14 is arranged on the fan cabinet 13, an upper air outlet pipe 15 is arranged at the top of the fan cabinet 13, a lower air outlet pipe 16 is arranged at the bottom of the fan cabinet 13, and the lower air outlet pipe 16 and one end, far away from the movable box body 10, of the upper air outlet pipe 15 all extend to the outer side of the movable box body 10. Through the use of the dust removal component, the flying cotton and the hairiness formed during the spinning of the chenille machine can be effectively removed and recovered.

The visual inspection assembly comprises a fixed frame 17 arranged on one side inside the movable box body 10, an industrial camera 18 is arranged at the bottom of the fixed frame 17, a lens 19 is arranged on one side of the industrial camera 18, and an annular light source 20 is arranged on one side, far away from the industrial camera 18, of the lens 19. Through the use of the visual inspection assembly, the defect detection of the yarn in the spinning process can be effectively realized.

The automatic doffing mechanism 6 comprises a second guide wheel component 21 respectively arranged on the guide rail 3 and the rack 4, a supporting frame 22 is arranged between the tops of the second guide wheel components 21 to form a movable bearing platform, the second guide wheel component 21 and the first guide wheel component 8 share the same servo transmission unit and gear to drive the supporting frame 22 to move, a doffing trolley frame 23 is arranged at the top of the supporting frame 22, a doffing guide plate 24 is arranged in the doffing trolley frame 23, a full-yarn trolley 25 matched with the doffing guide plate 24 is arranged at one side of the frame 2, the full-yarn trolley 25 is connected with the automatic doffing mechanism 6 to move together, a linear module 26 (which can be formed by a lead screw component) is arranged at the top of the doffing trolley frame 23 and is used for advancing and retreating in the X-axis direction, and a lifting cylinder component 27 is arranged at the top of the linear module 26, for ascending and descending in the Y-axis direction, the bottom end of the lifting cylinder assembly 27 is provided with a pipe grabbing assembly 28. Through the use of the automatic doffing mechanism 6, the automatic doffing effect can be realized, the labor intensity of workers is effectively reduced, and the automation degree and the production efficiency of equipment are improved.

Both sides of the chenille machine frame body 1 are provided with yarn grippers 29, the yarn grippers 29 are sleeved with full bobbins 30, the rear sides of the full bobbins 30 are provided with yarn guide plates, and the chenille machine frame body 1 is provided with a yarn guide plate overturning device 31 matched with the yarn guide plates. Through the use of the yarn clamping device 29, the yarn can be conveniently placed, and through the use of the yarn guide plate overturning device 31, a certain overturning effect can be achieved on the yarn guide plate.

First guide wheel subassembly 8 and second guide wheel subassembly 21 all include mounting bracket 32, and the vertical symmetry in one side of mounting bracket is provided with two sets of bearings 33, and the middle part of bearing 33 all alternates and is provided with matched with pivot 34 with it, and the external screw thread has been seted up to the one end of pivot 34 to be connected with mounting bracket 32 through nut 35. Through the use of the first guide wheel assembly 8 and the second guide wheel assembly 21, a guiding and positioning effect can be provided for the movement of the base plate 9 and the support frame 22.

The cotton collecting box comprises a fan box 7, a roller blowing device 36 is arranged on one side of the inner bottom of the fan box 7, one side of the roller blowing device 36 is connected with a negative pressure cabin 37, a vortex air pump 38 is arranged on one side of the inner top of the fan box 7, a first hose 39 is arranged at an air outlet of the vortex air pump 38, the other end of the first hose 39 is connected with the negative pressure cabin 37, a second hose 40 is arranged at an air inlet of the vortex air pump 38, the other end of the second hose 40 is connected with a cotton collecting box connector 41, the cotton collecting box connector 41 is further connected with the negative pressure cabin 37 through a third hose 42, and a negative pressure fan 43 connected with the negative pressure cabin 37 is arranged on one side of the vortex air pump 38. By using the fan box 7, the generated flying flowers and hairiness can be collected.

When the yarn is used, the chenille machine is used for spinning, and in order not to influence the production efficiency, the three modes are all independently operated and do not interfere with each other. The operation of the three modes is explained in detail below.

Firstly, a dust removal mode:

the servo transmission unit 11 is started to drive the gear 12 to rotate, and the gear 12 and the rack 4 are used for transmission, so that the rack 4 is fixed on the rack 2, and the gear 12 drives the first guide wheel assembly 8, the bottom plate 9, the movable box body 10, the centrifugal fan 14, the fan cabinet 13, the upper air outlet pipe 15 and the lower air outlet pipe 16 to do circular linear motion. Meanwhile, the centrifugal fan 14 sucks air from the outside, after the air is filtered by the filter screen, the air flows from the fan cabinet 13 to the upper air outlet pipe 15 and the lower air outlet pipe 16, and at the moment, the air speed in the pipe is increased due to the change of the sectional area of the air pipe. The high air speed at the air outlet of the upper air outlet pipe 15 can blow the flying flowers and hairiness in the upper spindle spinning area of the machine to the lower dust collection air duct 44 in the machine, and the high air speed at the air outlet of the lower air outlet pipe 16 can blow the flying flowers and hairiness in the ring spindle area of the lower spindle of the machine to the lower dust collection air duct 44 in the machine. The negative pressure fan 43 inside the fan box 7 causes a strong negative pressure inside the lower dust suction duct 44 connecting the fan box, so that the flying flowers and hairs suspended inside the machine are sucked into the duct and flow towards the rear fan box 7. The flying flowers and the hairiness finally reach a closed negative pressure cabin in the fan box, a roller blowing device 36 is arranged in the cabin, the flying flowers and the hairiness are adsorbed on a filter screen of the device, and a scraper motor arranged in the device drives a scraper to rotate to scrape the flying flowers and the hairiness from the filter screen. The vortex pump 38 has an air inlet and an air outlet, the two air inlets are respectively connected with one ends of a first hose 39 and a second hose 40, the other end of the first hose 39 is connected with the negative pressure chamber 37, the other end of the second hose 40 is connected with the cotton collection box connector 41, one end of a third hose 42 is connected with the cotton collection box connector 41, and the other end is connected with the negative pressure chamber 37. The vortex air pump 38, the first hose 39, the second hose 40, the third hose 42 and the cotton collecting box combining member 41 form a circulation cycle. The vortex air pump 38 forms a negative pressure higher than a negative pressure fan 43, the first hose 39 is connected with an air inlet and can be connected with a cotton collecting box combining piece 41, the third hose 42 sucks flying flowers and hairiness in a negative pressure cabin into the cotton collecting box combining piece 41, a filter screen is arranged in the cotton collecting box combining piece, the flying flowers and the hairiness can be adsorbed on the filter screen, meanwhile, the air outlet at the other end of the vortex air pump 38 can discharge sucked air into the negative pressure cabin 37 through the first hose 39, the flying flowers and the hairiness collected in the cotton collecting box combining piece 41 can be completely collected through a small door outside a cotton collecting box of a worker, and finally the purpose of dust removal of the machine is achieved.

II, a yarn detection mode:

the servo transmission unit 11 drives the gear 12 to rotate, and drives the first guide wheel assembly 8, the bottom plate 9 and the visual detection system (visual detection assembly) to do linear motion through transmission of the gear 12 and the rack 4. When the device moves to a designated position (the designated position can be detected by a contact switch and a corresponding controller, and the servo transmission unit is also controlled by an internal or external controller), the servo transmission unit 11 stops running, and the visual detection system photographs the yarn to obtain a related picture. The vision system uses its internal algorithm to distinguish whether the yarn meets the requirement, if it meets the algorithm requirement, the servo transmission unit 11 continues to run, and reaches the next detection position, if it does not meet the algorithm requirement, it gives NG signal to stop spinning at this position.

Thirdly, automatic doffing mode:

when the chenille machine obtains a doffing signal, doffing according to the following steps: s1, the servo transmission unit on the second guide wheel component 21 drives the gear wheel to rotate, the gear wheel and the rack 4 are used for transmission, and the dust removal detection mechanism (the itinerant dust removal and yarn detection device) drives the automatic doffing mechanism 6 to reach a first group of doffing positions, generally at the head or the tail of the machine. S2, after the chenille machine stops, the tail yarn is wound on the yarn gripper 29, and the yarn guide plate overturning device 31 overturns the yarn guide plate for a certain angle. And S3, the linear module 26 drives the lifting cylinder assembly 27 and the pipe grabbing assembly 28 to move from the original position to the direction of the full bobbin 30, and the operation is stopped after the bobbin grabbing position is reached. And S4, the pipe grabbing component 28 consists of an air cylinder and 5 groups of mechanical clamping jaws, and after the air cylinder is ventilated, the mechanical clamping jaws grab the full bobbin 30. And S5, the lifting cylinder assembly 27 moves upwards under the driving of the cylinder to pull the full bobbin 30 away from the spindle, and the lifting cylinder assembly 27 stops after rising to the highest position. And S6, the linear module 26 drives the lifting cylinder assembly 27 and the pipe grabbing assembly 28 to move to the original position and stop after returning to the original position. And S7, the air cylinder in the pipe grabbing assembly 28 is deflated, the mechanical clamping jaws loosen the full bobbin 30, and the full bobbin 30 rolls from the bobbin dropping guide plate 24 into the full yarn trolley 25. S8, when the linear module 26 moves to the original position, the servo transmission unit rotates to move the whole device to the second group of doffing positions, and after the device reaches the designated position, the steps S3-S8 are repeated.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a back way subassembly of chenille machine, includes chenille frame body, its characterized in that, the both sides of chenille frame body all are provided with the frame, and top one side of this frame all is provided with the guide rail, and the top opposite side of this frame all is provided with the rack, and the top of this frame all is provided with the detection mechanism that removes dust with guide rail and rack matched with, just the inside of chenille frame body is provided with down the dust absorption wind channel with the detection mechanism matched with that removes dust, and the one end of this time dust absorption wind channel is connected with the fan box that is located chenille frame body one end, and one side of this detection mechanism that removes dust all is provided with the automatic mechanism that doffs with guide rail and rack matched with.

2. The chenille machine rear assembly according to claim 1, wherein the dust removal detection mechanism comprises a first guide wheel assembly respectively mounted on the guide rail and the rack, a bottom plate is disposed between the tops of the first guide wheel assembly, a movable box is disposed on the top of the bottom plate, a servo transmission unit is disposed on one side of the inner bottom of the movable box, the bottom end of an output shaft on the servo transmission unit penetrates through the bottom plate and is connected with a gear inside the first guide wheel assembly, one side of the gear is meshed with the rack, a dust removal assembly is disposed on one side of the inner portion of the movable box, and a visual detection assembly is disposed on one side of the inner top of the movable box.

3. The chenille machine back channel assembly as claimed in claim 2, wherein the dust removing assembly comprises a fan cabinet mounted on one side inside the movable box body, the fan cabinet is provided with a centrifugal fan, the top of the fan cabinet is provided with an upper air outlet pipe, the bottom of the fan cabinet is provided with a lower air outlet pipe, and the ends of the lower air outlet pipe and the upper air outlet pipe, which are far away from the movable box body, extend to the outside of the movable box body.

4. The chenille machine rear assembly as claimed in claim 2, wherein the visual inspection assembly comprises a fixing frame arranged on one side inside the movable box body, an industrial camera is arranged on the bottom of the fixing frame, a lens is arranged on one side of the industrial camera, and an annular light source is arranged on one side of the lens far away from the industrial camera.

5. The chenille machine rear assembly of claim 2, wherein the automatic doffing mechanism comprises a second guide wheel assembly respectively mounted on the guide rail and the rack, a support frame is arranged between the tops of the second guide wheel assembly, a doffing trolley frame is arranged on the top of the support frame, a doffing guide plate is mounted in the doffing trolley frame, a full-yarn trolley matched with the doffing guide plate is arranged on one side of the frame, a linear module is arranged on the top of the doffing trolley frame, a lifting cylinder assembly is arranged on the top of the linear module, and a pipe grabbing assembly is arranged at the bottom end of the lifting cylinder assembly.

6. The back end assembly of the chenille machine according to claim 5, characterized in that the two sides of the chenille machine frame body are respectively provided with a yarn gripper, the yarn gripper is sleeved with a full bobbin, the rear side of the full bobbin is provided with a yarn guide plate, and the chenille machine frame body is provided with a yarn guide plate turnover device matched with the yarn guide plate.

7. The chenille machine rear assembly as claimed in claim 5, wherein the first guide wheel assembly and the second guide wheel assembly each comprise a mounting frame, two sets of bearings are vertically and symmetrically arranged on one side of the mounting frame, a rotating shaft matched with the bearings is inserted into the middle of each bearing, and one end of each rotating shaft is connected with the mounting frame through a nut.

8. The chenille machine back-end assembly according to claim 1, characterized in that a roller blowing device is arranged on one side of the inner bottom of the fan box, one side of the roller blowing device is connected with the negative pressure cabin, a vortex air pump is arranged on one side of the inner top of the fan box, an air outlet of the vortex air pump is provided with a first hose, the other end of the first hose is connected with the negative pressure cabin, an air inlet of the vortex air pump is provided with a second hose, the other end of the second hose is connected with a cotton collecting box combining member, the cotton collecting box combining member is further connected with the negative pressure cabin through a third hose, and a negative pressure fan connected with the negative pressure cabin is arranged on one side of the vortex air pump.

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