CN113371492A

CN113371492A - Textile fabric winding device and method

Info

Publication number: CN113371492A
Application number: CN202110729658.6A
Authority: CN
Inventors: 吴海彬; 彭芳; 孔维华; 张财波; 刘勇; 王辉; 贺祥
Original assignee: Guangdong Esquel Textiles Co Ltd
Current assignee: Guangdong Esquel Textiles Co Ltd
Priority date: 2021-06-29
Filing date: 2021-06-29
Publication date: 2021-09-10

Abstract

The invention relates to textile fabric winding equipment and a winding method. In the textile fabric winding device, a first position sensor detects a distance signal between the outer surface of fabric on a winding shaft and a flat roller. The first position sensor and the open width roller driving piece are respectively electrically connected with the first controller, the first controller is used for receiving a distance signal detected by the first position sensor and controlling the open width roller driving piece to drive the open width roller to act so as to enable the open width roller and the outer surface of the fabric on the reel to keep a preset distance. When the textile fabric winding device is used, the preset distance can be kept between the open width roller and the outer surface of the fabric on the reel, so that the fabric can be fully buffered under the action of the open width roller, and the flatness of the fabric on the reel is improved. And as the thickness of the fabric on the reel is larger and larger, the relative position between the flat roller and the reel is effectively adjusted, and the fabric can still be smoothly wound on the reel at the moment.

Description

Textile fabric winding device and method

Technical Field

The invention relates to the technical field of spinning, in particular to textile fabric winding equipment and a winding method.

Background

In the textile process, the fabric is wound on a reel through a series of operations in the fabric winding process, so that the textile fabric is orderly stored. Because the fabric is usually subjected to a series of physical and chemical treatments before being rolled, the components attached to the fabric are complex, and the strength, the expansion performance and the like of the fabric are difficult to control effectively. Meanwhile, in the processing process, joints such as sewing and the like are difficult to avoid on the fabric, the thickness of the joints is usually higher than that of other positions on the surface of the fabric, and along with the winding of the fabric, the thickness of the fabric on a winding shaft is larger and larger, which means that the diameter of the winding shaft and the whole fabric is larger and larger, so that the defects of surface folding, surface indentation and the like are easy to occur when the traditional direct winding method is adopted to roll the fabric, the flatness of the surface of the fabric is reduced, and the quality of the fabric is further reduced.

Disclosure of Invention

Therefore, a need exists for a winding device and a winding method capable of effectively improving the surface smoothness of the textile fabric.

In order to solve the problems, the technical scheme of the invention is as follows:

a textile fabric winding device comprises a rack, a flat width roller driving piece, a scroll driving piece, a first position sensor and a first controller;

the open width roller and the scroll are arranged on the rack, the open width roller driving part is connected with the open width roller to adjust the relative position between the open width roller and the scroll, the scroll driving part is connected with the scroll to drive the scroll to rotate, and the open width roller is used for opening the fabric and guiding the fabric after opening to the scroll for winding;

the first position sensor and the open width roller driving piece are respectively and electrically connected with the first controller, and the first position sensor is used for detecting a distance signal between the outer surface of the fabric on the reel and the open width roller; the first controller is used for receiving the distance signal detected by the first position sensor and controlling the open width roller driving part to drive the open width roller to act according to the distance signal so as to enable the open width roller to keep a preset distance from the outer surface of the fabric on the reel.

In one embodiment, the flat web roll is positioned above the reel spool with respect to the frame.

In one embodiment, the textile fabric winding device further comprises a tension roller, the tension roller is arranged on the machine frame, and the tension roller is farther away from the winding shaft than the open width roller in the fabric conveying direction.

In one embodiment, the textile fabric winding device further comprises a tension sensor and a second controller, the tension sensor and the winding shaft driving member are respectively electrically connected with the second controller, the tension sensor is connected with the tension roller and used for detecting a tension signal of fabric on the tension roller, and the second controller is used for receiving the tension signal detected by the tension sensor and controlling the winding shaft driving member to adjust the rotating speed of the winding shaft.

In one embodiment, the textile fabric winding device further comprises a second position sensor and an arithmetic unit, the second position sensor is close to the winding shaft and used for detecting a winding thickness signal of the fabric on the winding shaft, and the arithmetic unit is electrically connected with the second position sensor and used for receiving the winding thickness signal detected by the second position sensor and calculating the rotating speed of the winding shaft according to the winding thickness signal and the transmission speed of the fabric.

In one embodiment, the textile fabric winding device further includes a third controller, the arithmetic unit and the spool driving member are electrically connected to the third controller respectively, and the third controller is configured to receive the rotation speed calculated by the arithmetic unit and control the spool driving member to drive the spool to rotate at the rotation speed.

In one embodiment, the textile fabric winding device further comprises a pressure providing member connected with the open width roller for providing the pressure applied by the open width roller to the fabric on the winding shaft.

A textile fabric winding method using the textile fabric winding apparatus according to any one of the above embodiments, the textile fabric winding method comprising the steps of:

introducing the fabric into the textile fabric winding device, and winding the fabric on the reel after the fabric passes through the open width roller;

controlling the first position to detect a distance signal between the outer surface of the fabric on the reel and the open width roller;

the first controller receives the distance signal detected by the first position sensor, and controls the open width roller driving part to drive the open width roller to act according to the distance signal so as to enable the open width roller to keep a preset distance from the outer surface of the fabric on the reel.

In one embodiment, the preset distance is 0-10 cm.

In one embodiment, the step of winding the fabric on the reel after passing through the open width roller further comprises the steps of:

and applying 0-0.15 MPa pressure to the fabric on the reel through the open width roller.

Open width roller and spool all locate in the frame among the above-mentioned textile fabric package equipment, and open width roller driving piece is connected with the open width roller driving piece and adjusts the relative position between open width roller and the spool, and the spool driving piece is connected with the spool and drives the spool and rotate, and first position sensor detects the surface of the surface fabric on the spool and the distance signal between the open width roller. The first position sensor and the open width roller driving piece are respectively electrically connected with the first controller, the first controller is used for receiving a distance signal detected by the first position sensor and controlling the open width roller driving piece to drive the open width roller to act so as to enable the open width roller and the outer surface of the fabric on the reel to keep a preset distance. When the textile fabric winding device is used, the preset distance between the open width roller and the outer surface of the fabric on the winding shaft can be kept through the first position sensor, the first controller and the open width roller driving piece, so that the fabric can be fully buffered under the action of the open width roller, and the flatness of the fabric on the winding shaft is improved. In addition, in the following winding process, along with the fact that the thickness of the fabric on the reel is larger and larger, the relative position between the flat width roller and the reel is effectively adjusted, the fabric can still be smoothly wound on the reel at the moment, and the surface flatness of the textile fabric can be effectively improved.

Drawings

Fig. 1 is a schematic structural diagram of a textile fabric winding device according to an embodiment of the invention.

The notation in the figure is:

100. textile fabric winding equipment; 101. a frame; 102. an open width roller; 103. a reel; 104. a first position sensor; 105. a tension roller; 106. a feed roll; 200. fabric.

Detailed Description

The present invention will be described in detail with reference to the following embodiments in order to make the aforementioned objects, features and advantages of the invention more comprehensible. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, an embodiment of the present invention provides a textile fabric winding apparatus 100. The textile winding apparatus 100 includes a frame 101, a spreader bar 102, a spreader bar driving member (not shown), a reel 103, a reel driving member (not shown), a first position sensor 104, and a first controller (not shown). The open width roller 102 and the scroll 103 are both arranged on the frame 101, the open width roller driving part is connected with the open width roller 102 and used for adjusting the relative position between the open width roller 102 and the scroll 103, the scroll driving part is connected with the scroll 103 and used for driving the scroll 103 to rotate, and the open width roller 102 is used for opening the fabric 200 and guiding the fabric 200 after opening to the scroll 103 for winding. The first position sensor 104 and the flat roller driving member are respectively electrically connected with the first controller, and the first position sensor 104 is used for detecting a distance signal between the outer surface of the fabric 200 on the reel 103 and the flat roller 102; the first controller is configured to receive the distance signal detected by the first position sensor 104, and control the open-width roller driving member to drive the open-width roller 102 to move according to the distance signal, so that the open-width roller 102 maintains a preset distance from the outer surface of the fabric 200 on the reel 103.

In the textile material winding apparatus 100 of the present embodiment, the open width roller 102 and the reel 103 are provided on the frame 101, the open width roller driving member is connected to the open width roller 102 to adjust the relative position between the open width roller 102 and the reel 103, the reel driving member is connected to the reel 103 to drive the reel 103 to rotate, and the first position sensor 104 detects a distance signal between the outer surface of the material 200 on the reel 103 and the open width roller 102. The first position sensor 104 and the flat roller driving member are electrically connected to a first controller, respectively, and the first controller is configured to receive a distance signal detected by the first position sensor 104, and control the flat roller driving member to drive the flat roller 102 to move so as to keep a predetermined distance between the flat roller 102 and the outer surface of the fabric 200 on the reel 103. When the textile fabric winding device 100 is used, the first position sensor 104, the first controller and the open width roller driving part can keep the preset distance between the open width roller 102 and the outer surface of the fabric 200 on the winding shaft 103, so that the fabric 200 can be fully buffered under the action of the open width roller 102, and the flatness of the fabric 200 on the winding shaft 103 can be improved. In addition, in the following winding process, as the thickness of the fabric 200 on the reel 103 is larger and larger, the relative position between the flat roller 102 and the reel 103 is effectively adjusted, and at the moment, the fabric 200 can still be smoothly wound on the reel 103, so that the surface flatness of the textile fabric 200 can be effectively improved.

It should be noted that the textile fabric winding apparatus 100 of the present embodiment may also be used for winding other flexible materials, and is particularly suitable for winding a flexible material which is prone to surface folding and surface indentation. When the flexible material needs to be rolled, the flatness of the flexible material roll can be effectively improved by the textile fabric rolling device 100 in this embodiment, so that the flexible material can be rolled on the reel 103 smoothly.

Further, the textile fabric winding device 100 of the embodiment is more suitable for winding the textile fabric with higher moisture content. When the moisture content of the textile fabric is higher, the fabric is more sensitive to tension, temperature, pressure and the like, and the defects of surface folding and surface indentation are more likely to occur in the fabric winding process. By adopting the textile fabric winding device 100 in the embodiment, the problems of surface folding, surface indentation and the like easily occurring in the winding process of the fabric with high moisture content can be well solved, so that the fabric with high moisture content can be flatly wound on the reel 103. At this time, as a specific example, the textile winding apparatus 100 is a moisture-containing textile winding apparatus.

Further, the textile fabric winding apparatus 100 of the present embodiment is more suitable for winding of moisture-crosslinking fabric. The moisture crosslinking is an important step for improving the performance of the textile fabric, and the fabric needs to be subjected to package cold-batch treatment under the condition of high moisture content, and the problem of folding and indentation of the surface of the fabric is more likely to occur at the moment. At this time, as a specific example, the textile winding apparatus 100 is a moisture crosslinking textile winding apparatus.

It is understood that, when the textile material winding apparatus 100 of the present embodiment is used, for the rotation of the open width roller 102, the friction of the material 200 may drive the open width roller 102 to rotate, and the drive mechanism may drive the open width roller 102 to rotate.

It is also understood that the first position sensor 104 may be, but is not limited to, a laser range finder, an infrared range finder, an electro-optical switch, a proximity switch, and the like.

In one particular example, the first position sensor 104 is disposed on the gantry 101. Further, a first position sensor 104 is close to the reel 103 for detecting a distance signal between the outer surface of the fabric 200 on the reel 103 and the flat roll 102.

In another specific example, the first position sensor 104 is provided on the flat roll 102, and the distance signal between the outer surface of the fabric 200 on the reel shaft 103 and the flat roll 102 can be directly measured by the first position sensor 104.

In a preferable scheme, the preset distance is 0-10 cm.

Further, the textile material winding apparatus 100 further includes a pressure providing member (not shown) connected to the open width roller 102 for providing a pressure of the open width roller 102 to the material 200 on the winding shaft 103.

As a preferred solution, the flat roller 102 is located above the reel 103 with respect to the frame 101. This allows the fabric 200 to be smoothly transferred to the winding shaft 103 through the flat roll 102 and then wound. More importantly, the arrangement that the flat roller 102 is positioned above the scroll 103 can well balance the gravity of the fabric 200, avoid the problem of uneven stress caused by the winding due to the influence of the gravity of the fabric 200 in the winding process, and further reduce the risks of surface folding and surface indentation of the fabric 200. More preferably, the center of the flat roller 102 and the center of the reel 103 are located on the same vertical line. The flat roll 102 is now positioned directly above the reel 103.

In a specific example, the textile material winding apparatus 100 further includes a tension roller 105, the tension roller 105 is provided on the frame 101, and the tension roller 105 is further away from the winding shaft 103 than the open width roller 102 in the transporting direction of the material 200. The arrangement of the tension roller 105 can adjust the conveying direction of the fabric 200 on one hand and adjust the tension of the fabric 200 on the other hand, so that the fabric 200 can be more stably transported to the flat roller 102 after passing through the tension roller 105.

Further, the textile material winding apparatus 100 further comprises a tension sensor (not shown in the figure) connected to the tension roller 105 for detecting a tension signal of the material 200 on the tension roller 105. After the tension sensor detects the tension signal of the fabric 200 on the tension roller 105, the tension of the fabric 200 can be monitored in real time according to the tension signal, and the transmission speed of the fabric 200 and the rotation speed of the reel 103 can be adjusted according to the tension signal, so that the rotation speed of the reel 103 is matched with the transmission speed of the fabric 200.

Further, the textile fabric winding device 100 further includes a second controller (not shown), and the reel driving member and the tension sensor are electrically connected to the second controller respectively, and the second controller is configured to receive the tension signal detected by the tension sensor and control the reel driving member to adjust the rotation speed of the reel 103. With the winding of the fabric 200 on the reel 103, the thickness of the fabric 200 on the reel 103 is increased, and when the transmission speed of the fabric 200 is constant, the rotation speed of the reel 103 needs to be adjusted to adapt to the transmission speed of the fabric 200, specifically, the rotation speed of the reel 103 needs to be reduced to adapt to the transmission speed of the fabric 200, otherwise, the problem that the fabric 200 is pulled due to the excessively high rotation speed of the reel 103 is likely to occur, so that the fabric 200 is deformed, and the quality of the fabric 200 is reduced. At this time, the second controller receives the tension signal detected by the tension sensor and controls the reel driving element to adjust the rotating speed of the reel 103, so that the rotating speed of the reel 103 is matched with the conveying speed of the fabric 200, and the winding flatness of the fabric 200 is further improved.

In another specific example, the textile fabric winding device 100 further comprises a second position sensor (not shown in the figure), the second position sensor is close to the winding shaft 103 and is used for detecting a winding thickness signal of the fabric 200 on the winding shaft 103, so that the winding thickness of the fabric 200 on the winding shaft 103 can be obtained by acquiring the winding thickness signal of the fabric 200, and the rotation speed of the winding shaft 103 can be adjusted according to the winding thickness, so that the rotation speed of the winding shaft 103 is matched with the transmission speed of the fabric 200. It is understood that the second position sensor may be, but is not limited to, a laser range finder, an infrared range finder, an electro-optical switch, a proximity switch, and the like.

Further, the textile fabric winding device 100 further comprises an arithmetic unit (not shown in the figure), which is electrically connected to the second position sensor for receiving the winding thickness signal detected by the second position sensor and calculating the rotation speed of the winding shaft 103 according to the winding thickness signal and the transmission speed of the fabric 200. It can be understood that the transmission speed of the fabric 200 can be directly set and obtained according to the transmission device of the fabric 200, the winding thickness signal of the fabric 200 can be obtained in real time through the second position sensor, and the rotating speed of the winding shaft 103 can be calculated in real time through the arithmetic unit. As a calculation method of the rotation speed of the reel 103, the circumferential length L of the circumference formed by the fabric 200 at the current thickness can be calculated from the winding thickness signal detected by the second position sensor, where L is 2 pi r and r is the sum of the current thickness and the radius of the reel 103. Then, the rotation speed ω of the reel 103 is calculated from the circumferential length L and the transport speed v of the fabric 200, where ω is v/L, whereby the rotation speed of the reel 103 can be calculated.

Furthermore, the textile fabric winding device 100 further includes a third controller (not shown), and the arithmetic unit and the reel driving member are electrically connected to the third controller respectively, and the third controller is configured to receive the rotation speed calculated by the arithmetic unit and control the reel driving member to drive the reel 103 to rotate at the rotation speed. The third controller receives the rotating speed calculated by the arithmetic unit in real time, and adjusts the rotating speed of the reel 103 in real time through the reel driving piece, so that the reel 103 rotates in the optimal rotating speed state, and the fabric 200 is further stably and flatly wound on the reel 103.

It is understood that the first controller, the second controller and the third controller may be separate controllers or may be integrated controllers.

It will be appreciated that the textile material winding apparatus 100 further comprises a feed roller 106, and the feed roller 106 is further away from the winding shaft 103 than the flat web roller 102 in the transport direction of the material 200, and the material 200 is wound on the winding shaft 103 after passing through the feed roller 106 and the flat web roller 102 in sequence. Further, the feed roller 106 is further away from the winding shaft 103 than the tension roller 105 in the conveyance direction of the fabric 200, and the fabric 200 is wound on the winding shaft 103 after passing through the feed roller 106, the tension roller 105, and the open width roller 102 in this order. The feed rollers 106 are used to guide the fabric 200 into the textile fabric winding apparatus 100.

In yet another embodiment of the present invention, a method of winding a textile fabric is provided. The textile fabric winding method adopts the textile fabric winding device 100, and comprises the following steps:

the fabric 200 is introduced into the fabric winding apparatus 100, and the fabric 200 is wound on the winding shaft 103 after passing through the flat roll 102.

The distance signal between the outer surface of the fabric 200 on the first position-detecting spool 103 and the open width roll 102 is controlled.

The first controller receives the distance signal detected by the first position sensor 104, and controls the open-width roller driving member to drive the open-width roller 102 to move according to the distance signal, so that the open-width roller 102 keeps a preset distance from the outer surface of the fabric 200 on the reel 103.

By adopting the method for winding the textile fabric 200 in the embodiment, the fabric 200 can be smoothly wound on the reel 103, and the flatness of the fabric 200 on the reel 103 is improved. In addition, in the following winding process, as the thickness of the fabric 200 on the reel 103 is larger and larger, the relative position between the flat roller 102 and the reel 103 is effectively adjusted, and at the moment, the fabric 200 can still be smoothly wound on the reel 103, so that the surface flatness of the textile fabric 200 can be effectively improved.

In a preferable scheme, the preset distance is 0-10 cm. At this time, the first controller is configured to receive the distance signal detected by the first position sensor 104, and control the open-width roller driving member to drive the open-width roller 102 to move so as to keep the distance between the open-width roller 102 and the outer surface of the fabric 200 on the reel 103 at 0-10 cm, that is, in the process of winding the fabric 200, as the thickness of the fabric 200 on the reel 103 increases continuously, the first controller controls the action of the open-width roller driving member to keep the distance between the open-width roller 102 and the outer surface of the fabric 200 on the reel 103 at 0-10 cm, so that the open-width roller 102 approaches the outer surface of the fabric 200 on the reel 103, and thus the fabric 200 can be wound on the reel 103 in a short stroke after passing through the open-width roller 102, and the open-width effect of the open-width roller 102 is effectively maintained, so that the fabric 200 is wound on the reel 103 more smoothly. Alternatively, the distance between the flat roll 102 and the outer surface of the fabric 200 on the reel 103 may be maintained at 0cm, 0.2cm, 0.5cm, 0.8cm, 1cm, 1.5cm, 2cm, 2.5cm, 3cm, 3.5cm, 4cm, 4.5cm, 5cm, 5.5cm, 6cm, 6.5cm, 7cm, 7.5cm, 8cm, 8.5cm, 9cm, 9.5cm, or 10 cm. Preferably, the distance between the flat roll 102 and the outer surface of the fabric 200 on the reel 103 is kept to be less than or equal to 5 cm.

Further preferably, the first controller receives the distance signal detected by the first position sensor 104, and controls the flat-width roller driving member to drive the flat-width roller 102 to act so as to keep the flat-width roller 102 at a fixed distance from the outer surface of the fabric 200 on the reel 103. This makes it possible to keep the distance between the flat roll 102 and the outer surface of the fabric 200 on the reel 103 constant during the winding process, thereby further improving the uniformity of the winding of the fabric 200 and the quality of the fabric 200.

In one specific example, the step of winding the fabric 200 on the reel 103 after passing through the flat roll 102 further comprises: and applying a pressure of 0-0.15 MPa to the fabric 200 on the reel 103 through the flat roller 102.

Further, the textile fabric winding apparatus 100 further includes a pressure providing member connected to the flat web roll 102 for providing a pressure of the flat web roll 102 to the fabric 200 on the reel 103. When the distance between the flat roll 102 and the outer surface of the fabric 200 on the reel 103 is 0, the flat roll 102 comes into contact with the outer surface of the fabric 200 on the reel 103, which makes it possible to wind the fabric 200 more stably. Preferably, the pressure provided by the pressure providing part is 0-0.15 MPa, which is applied by the open width roller 102 to the fabric 200 on the reel 103, and further preferably, the pressure provided by the pressure providing part is 0, which is applied by the open width roller 102 to the fabric 200 on the reel 103. It can be understood that the pressure providing member is not suitable for providing the open width roller 102 with excessive pressure applied to the fabric 200 on the winding shaft 103, when the pressure is excessive, the open width roller 102 may have a risk of leaving an impression on the surface of the fabric 200, and when the pressure is 0-0.15 MPa, the fabric 200 can be stably wound on the winding shaft 103, and surface indentation defects due to the pressure of the open width roller 102 are not generated. Alternatively, the pressure applied by the flat roll 102 to the fabric 200 on the spool 103 may be, but is not limited to, 0, 0.01MPa, 0.02MPa, 0.03MPa, 0.04MPa, 0.05MPa, 0.06MPa, 0.07MPa, 0.08MPa, 0.09MPa, 0.1MPa, 0.11MPa, 0.12MPa, 0.13MPa, 0.14MPa, or 0.15 MPa.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the patent of the present invention should be subject to the appended claims, and the description and the drawings can be used for explaining the contents of the claims.

Claims

1. A textile fabric winding device is characterized by comprising a rack, a flat width roller driving piece, a scroll driving piece, a first position sensor and a first controller;

2. A textile fabric winding apparatus according to claim 1, wherein the flat web roll is positioned above the winding shaft with respect to the frame.

3. A textile fabric winding apparatus according to any one of claims 1 to 2, further comprising a tension roller provided on the frame, the tension roller being further away from the winding shaft than the flat roller in a fabric conveying direction.

4. The textile fabric winding device according to claim 3, further comprising a tension sensor and a second controller, wherein the tension sensor and the winding shaft driving member are respectively electrically connected to the second controller, the tension sensor is connected to the tension roller for detecting a fabric tension signal on the tension roller, and the second controller is configured to receive the tension signal detected by the tension sensor and control the winding shaft driving member to adjust the rotation speed of the winding shaft.

5. The apparatus for winding a textile fabric according to claim 4, further comprising a second position sensor disposed close to the winding shaft for detecting a winding thickness signal of the fabric on the winding shaft, and an arithmetic unit electrically connected to the second position sensor for receiving the winding thickness signal detected by the second position sensor and calculating a rotation speed of the winding shaft based on the winding thickness signal and a fabric transport speed.

6. The textile fabric winding device according to claim 5, further comprising a third controller, wherein the arithmetic unit and the winding shaft driving member are electrically connected to the third controller respectively, and the third controller is configured to receive the rotation speed calculated by the arithmetic unit and control the winding shaft driving member to drive the winding shaft to rotate at the rotation speed.

7. A textile fabric winding apparatus according to any one of claims 1 to 2, further comprising a pressure providing member connected to the open width roller for providing pressure applied by the open width roller to the fabric on the winding shaft.

8. A textile fabric winding method, characterized in that the textile fabric winding apparatus according to any one of claims 1 to 7 is used, and the textile fabric winding method comprises the steps of:

9. The textile fabric winding method according to claim 8, wherein the predetermined distance is 0 to 10 cm.

10. A method of winding a textile fabric according to claim 8, wherein the step of winding the fabric on the bobbin after passing the fabric through the open width roller further comprises the steps of: