CN114751249A

CN114751249A - Textile machinery matched filament winding device and use method thereof

Info

Publication number: CN114751249A
Application number: CN202210304003.9A
Authority: CN
Inventors: 王逸群; 薛莉英
Original assignee: Individual
Current assignee: Zhongshan Chen Yuan Textile Technology Co ltd
Priority date: 2022-03-25
Filing date: 2022-03-25
Publication date: 2022-07-15
Anticipated expiration: 2042-03-25
Also published as: CN114751249B

Abstract

The invention discloses a textile machinery matched filament winding device and a using method thereof, and belongs to the field of textile equipment. A textile machine cooperative filament winding device comprising: the filament collecting module comprises a filament collecting cylinder, a filament collecting module and a filament collecting module, wherein the filament collecting cylinder is used for enabling spinning to be wound on the surface of the filament collecting cylinder, and the lower end of the filament collecting cylinder is connected with a containing cavity with deformation capacity in the vertical direction so as to drive the filament collecting cylinder to move in the vertical direction; the winding rail is annularly arranged on the periphery of the take-up drum; the bunching module is arranged on the winding rail and is in sliding connection with the winding rail so as to move along the winding rail, and the bunching module comprises a bunching rod for clamping spinning to move along a fixed axis; the lifting module comprises an inflation cavity communicated with the elastic containing cavity, and the closed cavity is fixedly arranged on the outer side of the wire collecting module; when the wire harness module moves through the lifting module, the inflation cavity is compressed or expanded to inflate or inhale air to the elastic containing cavity; the friction of the spinning can be reduced during filament winding, and the surface quality of the spinning is ensured.

Description

Textile machinery matched winding device and using method thereof

Technical Field

The invention belongs to the field of textile equipment, and particularly relates to a textile machinery matched filament winding device and a using method thereof.

Background

The existing spinning and filament winding mode is that the filament is continuously wound on the outer surface of a take-up cylinder, and when the filament is wound in a spinning mode, the filament revolves around the axis of the take-up cylinder and is translated along the axis direction of the take-up cylinder, namely, the filament is wound on the surface of the take-up cylinder from one end of the take-up cylinder until the filament is wound to the other end of the take-up cylinder and then moves reversely, so that the spinning on the surface of the take-up cylinder is uniformly distributed.

The present filament winding is for making clearance be zero between every circle of spinning, guarantees to receive a line section of thick bamboo surface average covering and has the spinning, and every circle of spinning between every layer of spinning can not produce the friction when the filament winding, leads to the problem of spinning surface quality reduction to take place, can adopt: the distance of horizontal movement of the threadline per revolution needs to be controlled in a manner exactly equal to the diameter size of the threadline.

However, in real life, it is desirable to control the distance of horizontal movement of the spun yarn every turn to be exactly equal to the diameter of the spun yarn, and the diameter of the spun yarn is not uniform in practice, so that the method of winding is desirable, and it is difficult to achieve the purpose of forming the spun yarn without friction.

Disclosure of Invention

The invention aims to solve the technical problem of providing a spinning machine matched winding device and a using method thereof, which can reduce friction during spinning and ensure the surface quality of spinning.

The invention relates to a textile machinery matched winding device and a using method thereof, comprising

The filament collecting module comprises a filament collecting cylinder, wherein spinning can be wound on the surface of the filament collecting cylinder, and the lower end of the filament collecting cylinder is connected with a containing cavity with the deformation capability in the vertical direction so as to drive the filament collecting cylinder to move in the vertical direction;

the winding rail is annularly arranged on the periphery of the take-up drum;

the bunching module is arranged on the winding rail and is in sliding connection with the winding rail so as to move along the winding rail, and the bunching module comprises a bunching rod for clamping spinning to move along a fixed axis; and

the lifting module comprises an inflation cavity communicated with the elastic containing cavity, and the closed cavity is fixedly arranged on the outer side of the wire collecting module; when the wire harness module moves through the lifting module, the inflation cavity is compressed or expanded so as to inflate or inhale air to the elastic containing cavity.

As a further improvement of the invention, the occupation range of the lifting module and the movement range of the wire harness module have at least partial coincidence.

As a further improvement of the invention, the lifting module comprises an air box, a piston rod and an air pipe; the air box is positioned at the lower side of the winding rail; the piston rod is embedded in the air box and is in sealed sliding connection with the inner wall of the air box, and the sliding connection has self-return property; the upper end of the piston rod penetrates through the upper wall of the air box and is positioned on the upper side of the air box; in an initial state, the upper end part of the piston rod is positioned in the moving range of the wire binding module; the upper end part of the piston rod is round-head-shaped, so that the piston rod moves in the air box after being abutted by the lower side part of the wire bundling module positioned on the winding track; the air box containing cavity at the lower side of the piston rod is an inflation cavity, an air outlet of the inflation cavity is a one-way port and is communicated with an air pipe, and an air inlet of the inflation cavity is a one-way port.

As a further improvement of the invention, the lifting module comprises a magnetic driving piece, and the wire harness module is provided with a magnetic driven piece with the same or opposite magnetism to the magnetic driving piece; the magnetic driven part is one of the component walls of the inflation cavity, and when the magnetic driving part and the magnetic driven part have at least partially overlapped horizontal projections, the magnetic driven part is close to or far away from the magnetic driving part under the magnetic force so as to expand or compress the volume of the inflation cavity.

As a further improvement of the invention, the lifting module comprises an air box, a permanent magnet sealing plate and an air pipe; the air box is positioned on the lower side of the winding rail; the permanent magnet sealing plate is embedded in the air box and is in sealed sliding connection with the inner wall of the air box, and the sliding connection has self-return property; the permanent magnet sealing plate is positioned in the moving range of the magnetic driving piece of the wire harness module; the air box cavity at the lower side of the magnetic driven element is an inflation cavity, an air outlet of the inflation cavity is a one-way port and is communicated with an air pipe, and an air inlet of the inflation cavity is a one-way port.

As a further improvement of the invention, the wire collecting module also comprises a flexible air bag; the flexible air bag is fixedly connected to the lower end of the take-up drum, and the wall of the flexible air bag is made of flexible materials with deformation capacity only in the vertical direction; the inner cavity of the flexible air bag is communicated with the inflation cavity through a pipeline; the lower end of the flexible air bag is a fixed end.

As a further improvement of the invention, the height dimension of the single ascending or descending of the flexible air bag is larger than the diameter dimension of the spinning.

As a further improvement of the invention, the flexible air bag is also communicated with an external air pump through a pipeline; the start of the air pump is controlled by the controller, and the air pump pumps air or inflates the flexible air bag; the working state of the air pump is opposite to that of the inflation cavity.

As a further improvement of the invention, the magnetic driving piece is positioned on the electromagnet, and the positions of the positive and negative magnetic poles of the electromagnet can be periodically replaced, wherein the replacement period is the time for spinning to fully wind the take-up drum.

The invention also provides a use method of the textile machinery matched with the filament winding device, which comprises the following steps:

s1, fixedly clamping a spinning to be wound by using a bunch module, wherein one end of the spinning is fixed with the uppermost end of the outer surface of a take-up cylinder; the bunching module is placed on the winding track and is ready to revolve around the take-up drum; the starting point of the revolution of the bunching module is positioned at the lifting module, and the lifting module is not started at the moment;

s2, clamping the spinning by the bunching module to revolve around the take-up cylinder for one circle, and spinning on the take-up cylinder for one circle; during the period, the lifting module is started by the bunching module, the containing cavity at the lower end of the take-up cylinder expands upwards, the take-up cylinder rises, and no contact is generated between the spinning threads wound by one circle;

And S3, winding and collecting the spun yarn on the take-up drum according to the step S2 until the spun yarn is wound to the lower end of the take-up drum.

Compared with the prior art, the invention has the beneficial effects that:

when the spinning is revolved and wound by taking the take-up drum as an axis, the take-up drum can ascend or descend for a certain distance every time the spinning is wound for one circle, so that the sliding friction among the spinning is avoided, the quality of the spinning surface is improved, and burrs are avoided.

The lifting module is arranged on the lower side of the winding rail, when the lower end of the bunching module moves to the position of the lifting module, the lower end of the bunching module can abut against the round head on the upper end of the piston rod to force the piston rod to press downwards, the inflation cavity is pressed to inflate the flexible air bag, the take-up drum is lifted upwards, and friction interference between a variable section on one turn of spinning and a front line section is avoided.

The lifting module is arranged on the lower side of the winding track, when the electromagnet at the lower end of the bunching module moves to the position of the lifting module, the electromagnet and the permanent magnet sealing plate attract or repel each other, the polarity of the electromagnet is adjusted, the inflating cavity can be controlled to inflate or inhale the flexible air bag, so that the flexible air bag drives the take-up cylinder to ascend or descend, and the moving direction of the take-up cylinder can be switched to match the direction of the spun yarn when the spun yarn is wound on the take-up cylinder for one layer.

The invention is provided with the air pump which is started intermittently, so that the flexible air bag intermittently drives the take-up drum to ascend or descend, and the problem that the interval between every two circles of spinning is too large and one layer of spinning cannot cover the outer surface of the take-up drum completely is solved; the wound spinning is tightly attached and then continues to wind, the gap between every two circles of winding wires is continuously reduced, and the winding wires are compressed and abutted, so that relative friction is avoided, and the loss to the outer surface is small.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention;

fig. 2 is a perspective view of a yarn winding module according to a first embodiment of the present invention;

FIG. 3 is a schematic diagram of a spinning device according to a first embodiment of the present invention;

FIG. 4 is a schematic diagram of a beam line module according to a first embodiment of the present invention;

fig. 5 is a schematic plan sectional view of a lifting module according to a first embodiment of the present invention;

fig. 6 is a schematic perspective view of an air pump according to a second embodiment of the present invention;

fig. 7 is a schematic structural diagram of a lifting module and a wire harness module according to a third embodiment of the present invention.

The reference numbers in the figures illustrate:

the winding device comprises a yarn collecting module 1, a winding drum 11, a flexible air bag 12, a winding track 2, a yarn bunching module 3, a yarn bunching rod 31, a supporting plate 32, a limiting block 33, an electromagnet 34, a lifting module 4, an air box 41, a piston rod 42, an air pipe 43, an air outlet 44, an air inlet 45, a permanent magnet sealing plate 46, a spinning yarn 5, a front line section 51, a changing section 52, a rear line section 53 and an air pump 6.

Detailed Description

The first embodiment is as follows: referring to fig. 1-5, a filament winding device for a textile machine includes a filament winding module 1, a winding rail 2, a bunching module 3 and a lifting module 4.

The wire collecting module 1 comprises a wire collecting cylinder 11 and a flexible air bag 12; the spinning 5 can be wound on the surface of the take-up drum 11, the flexible airbag 12 is fixedly connected to the lower end of the take-up drum 11, the wall of the flexible airbag 12 is made of a flexible material which has deformation capacity only in the vertical direction, and the containing cavity of the flexible airbag 12 can be expanded or compressed in the vertical direction to drive the take-up drum 11 to move in the vertical direction; the lower end of the flexible air bag 12 is fixed on the ground.

The inner cavity of the flexible air bag 12 is communicated with the inflation cavity through a pipeline.

The winding track 2 is annular and is fixedly arranged on the periphery of the take-up drum 11.

The wire harness module 3 comprises a wire harness rod 31, a supporting plate 32, a limiting block 33 and a driving rod which are sequentially connected from top to bottom; the limiting block 33 is embedded in the winding rail 2, and the driving rod penetrates through the winding rail 2 and is positioned on the lower side of the winding rail 2; the yarn bundling rod 31 can clamp the spun yarn 5, so that the spun yarn 5 is sent to the take-up cylinder 11 at a fixed height, and the friction between the spun yarn 5 and other spun yarns 5 when the spun yarn 5 is wound on the take-up cylinder 11 is avoided; the wire rod 31 is connected with a driver for driving the wire rod 31 to move, and the driver can be a motor, and the technology is a conventional means used by those skilled in the art and is not described in detail in the present application.

The lifting module 4 comprises an inflation cavity communicated with the elastic containing cavity, and the closed cavity is fixedly arranged on the outer side of the yarn collecting module 1; when the wire harness module 3 moves through the lifting module 4, the inflation cavity is compressed or expanded to inflate or inhale air to the elastic containing cavity.

The lifting module 4 comprises an air box 41, a piston rod 42 and an air pipe 43; the air box 41 is positioned at the lower side of the winding rail 2; the piston rod 42 is embedded in the air box 41 and is in sealed sliding connection with the inner wall of the air box 41, the lower end of the piston rod 42 is a sealing section, and the sealing section is in sliding sealing connection with the inner wall of the air box 41; the upper end of the piston rod 42 is a round head section, and the round head section penetrates through the upper wall of the air box 41 and is positioned on the upper side of the air box 41; a spring is sleeved on the outer side of the round head section and positioned in the air box 41, and the spring is fixedly connected with the sealing section and the inner top wall of the air box 41; in an initial state, the round head section is positioned in the moving range of the driving rod, and the top end of the round head section is higher than the lower end of the driving rod; in a driving state, the driving rod is abutted against the round head section, the piston rod 42 is driven to move downwards by the movement of the driving rod, and the inflation cavity is compressed; the inflatable cavity is provided with an air outlet 44, the air outlet 44 is a one-way port, the air outlet 44 is arranged at the lower side of the periphery of the inflatable cavity, an air pipe 43 is connected outside the air outlet 44, and the inflatable cavity is communicated with the flexible air bag 12 through the air pipe 43; the air charging cavity is provided with an air inlet 45, the air inlet 45 is a one-way port and is arranged at the lower side of the periphery of the air charging cavity, and the air inlet 45 is arranged on the lower side of the periphery of the air charging cavity; after the inflation cavity is compressed, the gas is discharged from the gas outlet 44 and enters the flexible airbag 12 through the gas pipe 43, so that the flexible airbag 12 drives the take-up drum 11 to ascend; after the driving rod is far away from the round head section, the piston rod 42 returns, the inflation cavity returns, air is fed from the air inlet 45, and the next operation is guaranteed.

It should be noted that the single rise of the flexible bladder 12 is greater in height than the diameter of the threadline 5.

After the spun yarn 5 is wound on the take-up drum 11, the spun yarn 5 can be divided into a front line segment 51, a change segment 52 and a rear line segment 53; the front line segment 51 is a line segment firstly wound on the outer side of the take-up drum 11, and the height of each point of the front line segment 51 is kept unchanged; the variation section 52 is a line segment having a variation in height; the rear line section 53 is the line section wound on the outer side of the take-up drum 11 finally, the height of each point of the rear line section 53 is kept unchanged, and the rear line section 53 can also be regarded as the front line section 51 of the next spinning 5; three line segments are wound into a circle in an end-to-end way; in the conventional existing filament winding mode, the height of the head end and the tail end of the variable section 52 is not changed enough, and the rear filament section 53 is wound on the take-up drum 11, so that the front filament section 51 and the rear filament section 53 generate sliding friction, and burrs are generated on the outer surface of the spinning 5, thus the appearance and the appearance quality are influenced.

In the present embodiment, the take-up drum 11 moves upward a distance for each downward winding of the spun yarn 5, so that the height of the variable section 52 is sufficiently varied to avoid friction between the spun yarn 5 itself.

A use method of a textile machine matched with a filament winding device comprises the following steps:

S1, fixing and clamping a spinning yarn 5 to be wound by using a bunching module 3, wherein one end of the spinning yarn 5 is fixed with the uppermost end of the outer surface of a take-up cylinder 11; the bunching module 3 is placed on the winding rail 2 and is ready to revolve around the take-up drum 11; the starting point of the revolution of the bunching module 3 is positioned at the lifting module 4, and the lifting module 4 is not started at the moment;

s2, clamping the spinning 5 by the bunching module 3 to revolve around the take-up cylinder 11 for one circle, and spinning 5 on the take-up cylinder 11 for one circle; during the period, the lifting module 4 is started by the bunching module 3, the containing cavity at the lower end of the take-up cylinder 11 expands upwards, the take-up cylinder 11 rises, and no contact is generated between the spinning threads 5 which are wound for one circle;

and S3, winding and collecting the spun yarn 5 on the take-up drum 11 according to the step S2 until the spun yarn 5 is wound to the lower end of the take-up drum 11.

The second embodiment is as follows: on the basis of the first embodiment, please refer to the filament winding device of fig. 6, in which the flexible airbag 12 is further connected to an external air pump 6 through a pipeline; the start of the air pump 6 is controlled by the controller, and the air pump 6 can pump air to the flexible air bag 12.

Because the height dimension that flexible gasbag 12 single risees all is greater than the diameter size of spinning 5, so when spinning 5 was wound to the lower extreme from the upper end of receiving a line section of thick bamboo 11, the clearance between every circle spinning 5 was too big, and the number of turns of every layer spinning 5 is too little, is difficult for forming inseparable line layer, can lead to in next layer spinning 5 can imbed the gap, is difficult for carrying out the layering collection to spinning 5. The operation method comprises the following steps:

A1. When the spinning 5 winds to the lower end of the take-up drum 11 every time, the bunching module 3 stops moving, the air pump 6 is started, the flexible air bag 12 is pumped, the take-up drum 11 moves downwards, each circle of spinning 5 is close to the butt joint, and the abrasion caused by the butt joint is far smaller than that caused by sliding, so the scheme can effectively protect the appearance quality of the spinning 5;

A2. then the air pump 6 is closed, the wire bunching module 3 is started, and the wire winding is continued;

A3. A1-A2 were repeated until one layer of filaments 5 had no gaps between them, forming a dense layer of filaments.

In order to realize the method, the upper end of the cylinder body of the take-up cylinder 11 is fixedly provided with an upper cylinder plate, and the lower end of the cylinder body is fixedly provided with a lower cylinder plate; the lower end of the lower tube plate is connected with a flexible air bag 12; the lower end of the upper cylinder plate is provided with a pressure sensor, and the upper end of the lower cylinder plate is provided with a contact sensor; when the contact sensor is in contact with the spinning 5, the pressure sensor collects the pressure of the spinning 5 to the spinning, the controller of the air pump 6 calculates whether the air pump 6 should be started, the pressure sensor senses the pressure of the spinning 5 to the spinning after the air pump 6 is started in real time, and whether the spinning 5 is tightly matched or not is judged; until the filaments 5 form a complete, closely fitting thread layer.

The third concrete embodiment: in contrast to the first or second embodiment, referring to fig. 7, in a textile machine with a filament winding device, the piston rod 42 of the lifting module 4 is replaced by a permanent magnet sealing plate 46;

The permanent magnet sealing plate 46 is embedded in the air box 41 and is in sealing sliding connection with the inner wall of the air box 41, and a spring is fixedly arranged between the permanent magnet sealing plate 46 and the inner top wall of the air box 41; the cavity of the air box 41 at the lower side of the permanent magnet sealing plate 46 is an inflation cavity;

the driving rod of the wire harness module 3 is replaced with an electromagnet 34; the permanent magnet seal plate 46 is located within the range of movement of the electromagnet 34; when the magnetism of the close ends of the electromagnet 34 and the permanent magnet sealing plate 46 is the same, the electromagnet 34 repels the permanent magnet sealing plate 46 to move downwards, so that the inflation cavity is compressed, and the inflation of the flexible airbag 12 is realized;

the positions of the positive and negative magnetic poles of the electromagnet 34 can be periodically replaced, and the replacement period is the time that the spinning 5 is wound around the take-up drum 11;

after the spinning 5 winds one wire layer, the spinning can wind the second wire layer upwards continuously, and the height of the wire bundling rod 31 is unchanged, so that the wire winding drum 11 needs to move downwards at the moment, the polarities of the two ends of the electromagnet 34 are switched, and when the electromagnet 34 and the permanent magnet sealing plate 46 are opposite in magnetism close to each other, the electromagnet 34 can attract the permanent magnet sealing plate 46 to move upwards, so that the inflation cavity is expanded, and air suction of the flexible air bag 12 is realized.

It should be noted that the height dimension of the flexible bladder 12 for a single rise or fall is greater than the diameter dimension of the filament 5.

In order to implement the above scheme, in this embodiment, the air box 41 is placed on a turntable, the turntable rotates 180 degrees when being started and rotated each time, the start and stop of the turntable are controlled by the controller, and when the spinning 5 needs to wind the next layer of yarn, the turntable is started to drive the air box 41 to rotate; in the present embodiment, the air outlet 44 and the air inlet 45 are provided on the wall of the air box 41 in opposite directions; the air pipe 43 is detachably and hermetically abutted against the wall of the air box 41; when the electromagnet 34 switches the magnetic property, the turntable rotates, so that the air port corresponding to the air pipe 43 is changed, thereby achieving the technical purpose of the embodiment.

Claims

1. The utility model provides a spinning machine cooperation winding device which characterized in that: the spinning machine comprises a yarn collecting module (1) and a yarn collecting module, wherein the yarn collecting module comprises a yarn collecting cylinder (11) so that spinning (5) can be wound on the surface of the yarn collecting cylinder (11), and the lower end of the yarn collecting cylinder (11) is connected with a containing cavity with deformability in the vertical direction so as to drive the yarn collecting cylinder (11) to move in the vertical direction; the winding rail (2) is annularly arranged on the periphery of the take-up drum (11); the bunching module (3) is arranged on the winding track (2) and is connected with the winding track (2) in a sliding mode so as to move along the winding track (2), and the bunching module (3) comprises a bunching rod (31) for clamping the spinning (5) to move along a fixed axis; the lifting module (4) comprises an inflation cavity communicated with the elastic containing cavity, and the closed cavity is fixedly arranged on the outer side of the wire collecting module (1); when the wire harness module (3) moves through the lifting module (4), the inflation cavity is compressed or expanded to inflate or inhale air to the elastic containing cavity.

2. A textile machine cooperative yarn winding device according to claim 1, wherein: the occupation range of the lifting module (4) and the movement range of the wire harness module (3) are at least partially overlapped.

3. A textile machine cooperative yarn winding apparatus as in claim 2, wherein: the lifting module (4) comprises an air box (41), a piston rod (42) and an air pipe (43); the air box (41) is positioned at the lower side of the winding rail (2); the piston rod (42) is embedded in the air box (41) and is in sealed sliding connection with the inner wall of the air box (41), and the sliding connection has self-returning performance; the upper end of the piston rod (42) penetrates through the upper wall of the air box (41) and is positioned on the upper side of the air box (41); in an initial state, the upper end part of the piston rod (42) is positioned in the moving range of the wire binding module (3); the upper end part of the piston rod (42) is in a round head shape, so that the piston rod (42) is abutted by the lower side part of the wire harness module (3) positioned on the winding track (2) and then moves into the air box (41); the cavity of the air box (41) at the lower side of the piston rod (42) is an inflation cavity, the air outlet (44) of the inflation cavity is a one-way port and is communicated with the air pipe (43), and the air inlet (45) of the inflation cavity is a one-way port.

4. A textile machine cooperative yarn winding device according to claim 1, wherein: the lifting module (4) comprises a magnetic driving piece, and the wire harness module (3) is provided with a magnetic driven piece with the same or opposite magnetism to the magnetic driving piece; the magnetic driven part is one of the walls of the gas-filled cavity, and when the magnetic driving part and the magnetic driven part have at least partially overlapped horizontal projections, the magnetic driven part is close to or far away from the magnetic driving part under the magnetic force so as to expand or compress the volume of the gas-filled cavity.

5. A textile machine cooperative winding arrangement according to claim 4, characterised in that: the lifting module (4) comprises an air box (41), a permanent magnet sealing plate (46) and an air pipe (43); the air box (41) is positioned at the lower side of the winding rail (2); the permanent magnet sealing plate (46) is embedded in the air box (41) and is in sealing sliding connection with the inner wall of the air box (41), and the sliding connection has self-resetting property; the permanent magnet sealing plate (46) is positioned in the moving range of the magnetic driving piece of the wire harness module (3); the cavity of the air box (41) at the lower side of the magnetic driven part is an inflation cavity, the air outlet (44) of the inflation cavity is a one-way port and is communicated with an air pipe (43), and the air inlet (45) of the inflation cavity is a one-way port.

6. A textile machine cooperative filament winding device according to claim 1, wherein: the silk reeling module (1) also comprises a flexible air bag (12); the flexible air bag (12) is fixedly connected to the lower end of the take-up drum (11), and the wall of the flexible air bag (12) is made of flexible materials which only have deformation capacity in the vertical direction; the inner cavity of the flexible air bag (12) is communicated with the inflation cavity through a pipeline; the lower end of the flexible air bag (12) is a fixed end.

7. A textile machine cooperative filament winding device according to claim 6, wherein: the height dimension of the flexible air bag (12) rising or falling once is larger than the diameter dimension of the spinning (5).

8. A textile machine cooperative filament winding device according to claim 6, wherein: the flexible air bag (12) is also communicated with an external air pump (6) through a pipeline; the start of the air pump (6) is controlled by the controller, and the air pump (6) pumps or inflates the flexible air bag (12); the working state of the air pump (6) is opposite to that of the inflation cavity.

9. A textile machine cooperative filament winding device according to claim 4, wherein: the magnetic driving piece is positioned on the electromagnet (34), and the positions of the positive and negative magnetic poles of the electromagnet (34) can be periodically replaced, wherein the replacement period is the time when the spinning (5) is wound on the take-up drum (11).

10. A use method of a textile machine matched with a filament winding device is characterized in that: the method comprises the following steps: s1, fixedly clamping a spinning (5) to be wound by using a bunching module (3), wherein one end of the spinning (5) is fixed with the uppermost end of the outer surface of a take-up cylinder (11); the bunching module (3) is placed on the winding track (2) and is ready to revolve around the take-up drum (11); the starting point of the revolution of the bunching module (3) is positioned at the lifting module (4), and the lifting module (4) is not started at the moment; s2, the bunching module (3) clamps the spinning (5) to revolve around the take-up cylinder (11) for one circle, and the spinning (5) winds around the take-up cylinder (11) for one circle; during the period, the lifting module (4) is started by the bunching module (3), the containing cavity at the lower end of the take-up cylinder (11) expands upwards, the take-up cylinder (11) rises, and no contact is generated between the spinning threads (5) wound by one circle; and S3, winding and collecting the spun yarn (5) on the take-up cylinder (11) according to the step S2 until the spun yarn (5) is wound to the lower end of the take-up cylinder (11).