CN112064240A

CN112064240A - Can flatten weaving cloth processing production of weaving cloth fast and use pressurization laminating mechanism

Info

Publication number: CN112064240A
Application number: CN202010926232.5A
Authority: CN
Inventors: 朱姝颖
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-07
Filing date: 2020-09-07
Publication date: 2020-12-11

Abstract

The invention discloses a pressurizing and attaching mechanism for processing and producing woven cloth capable of quickly flattening the woven cloth, which comprises a device shell, an atomizing spray head, a cleaning brush, an electric heating roller, a cooling fan and a limiting plate, wherein a driving motor is fixedly welded on the device shell, the output end of the driving motor is rotatably connected with a reciprocating screw rod, a second bidirectional threaded rod is rotatably connected in the device shell, the second bidirectional threaded rod is movably connected with the limiting plate, the limiting plate is slidably connected with a sliding rod, and the sliding rod is fixedly welded in the device shell. This weaving cloth processing production of weaving cloth that can flatten fast is provided with the limiting plate with pressurization laminating mechanism, can drive the limiting plate of both sides simultaneously to middle motion that carries out stably on the slide bar through rotating second bidirectional threaded rod, can convenient and fast carry out spacing work to the surface fabric body of different width, can prevent effectively that the surface fabric body from taking place the offset and leading to the rolling block when flattening the during operation.

Description

Can flatten weaving cloth processing production of weaving cloth fast and use pressurization laminating mechanism

Technical Field

The invention relates to the technical field of textile fabric processing, in particular to a pressurizing and attaching mechanism capable of quickly flattening textile fabric for textile fabric processing and production.

Background

China is a large country for textile production and export, the China textile industry develops for years, has obvious competitive advantages, has the most complete industrial chain in the world, has the highest processing matching level, and continuously enhances the self-regulation capability of a plurality of developed industries for dealing with market risks, provides a solid guarantee for keeping the steady development pace of the industry, and along with the continuous development and perfection of a textile knowledge system and a subject system, the textile technology is gradually perfected, not only the traditional hand-made spinning and weaving but also the textile machine is used for textile work, wrinkles are easily generated in the production and processing process of textile cloth, and the wrinkles need to be flattened by a pressurizing and laminating mechanism.

Most of the existing pressurizing and attaching mechanisms for textile fabric processing and production have the following problems:

firstly, most of the conventional pressurizing and attaching mechanisms for textile fabric processing and production adopt an ironing type flattening method, but textile fabrics with excessive folds cannot be stably pulled and flattened, so that the stability of subsequent ironing work cannot be ensured, and the fabrics are easily damaged;

secondly, when the conventional pressurizing and laminating mechanism for textile fabric processing and production is used for flattening textile fabric, uniform and stable pre-wetting treatment cannot be carried out on the textile fabric, so that stable ironing and flattening work of the processing mechanism on the fabric cannot be guaranteed;

thirdly, conventional weaving cloth processing production is with pressurization laminating mechanism flattening the during operation to weaving cloth, can not carry out stable spacing work to weaving cloth, weaving cloth takes place offset easily when flattening the during operation, and then can make the wind-up roll take place to twine the card shell, leads to the device to damage.

Therefore, a pressing and attaching mechanism for textile processing and production capable of quickly flattening textile cloth is provided so as to solve the problems.

Disclosure of Invention

The invention aims to provide a pressurizing and attaching mechanism for processing and producing textile cloth, which can quickly flatten the textile cloth, and solves the problems that the pressurizing and attaching mechanism for processing and producing the textile cloth in the current market, which is provided by the background technology, can not stably pull and flatten the textile cloth, can not uniformly and stably pre-wet the textile cloth, and can not stably limit the textile cloth.

In order to achieve the purpose, the invention provides the following technical scheme: a pressurizing and laminating mechanism capable of quickly flattening textile cloth for processing and producing the textile cloth comprises a device shell, an atomizing nozzle, a cleaning brush, an electric heating roller, a cooling fan and a limiting plate, wherein a driving motor is fixedly welded on the device shell, the output end of the driving motor is rotatably connected with a reciprocating lead screw, a first transmission belt is meshed on the reciprocating lead screw and is connected on a central shaft of a half gear, the half gear shaft is connected on the device shell, a first circular gear is meshed on the half gear and is fixedly welded on a winding roller, the winding roller is rotatably connected in the device shell, a fabric body is wound on the winding roller, a conveying pipe is arranged on the reciprocating lead screw, a universal pipe is mounted on the conveying pipe through bolts, the atomizing nozzle is mounted on the conveying pipe through bolts, the top end of the universal pipe is connected on a storage box through bolts, and the storage box is connected with the device shell through screws, the conveying pipe is connected with a gear tooth plate through screws, the gear tooth plate is connected with a second circular gear in a meshed mode, the second circular gear is welded and fixed on a fixed shaft, the fixed shaft is rotatably connected in the device shell, a rotary disc is welded and fixed at the bottom end of the fixed shaft, a cleaning brush is connected below the rotary disc through screws, a second transmission belt is connected on the fixed shaft in a meshed mode, the second transmission belt is connected on a first bidirectional threaded rod in a meshed mode, a connecting plate is movably connected on the first bidirectional threaded rod and is connected in the device shell in a sliding mode, a support rod is movably connected below the connecting plate, an electric heating roller is fixed at the bottom end of the support rod through bolts, a rubber rod is connected on the support rod, a third transmission belt is connected on the first bidirectional threaded rod in a meshed mode, the connecting axle rotates to be connected in the device shell, and the bottom welded fastening of connecting axle has cooling blower, the device shell internal rotation is connected with the second bidirectional threaded rod, and swing joint has the limiting plate on the second bidirectional threaded rod, sliding connection has the slide bar on the limiting plate, and slide bar welded fastening is in the device shell, the welded fastening has flexible loop bar in the device shell, and the top welded fastening of flexible loop bar is on the conveyer pipe.

Preferably, reciprocal lead screw is fixed in the middle part of conveyer pipe, and is threaded connection between reciprocal lead screw and the conveyer pipe to the equidistance distributes on the conveyer pipe has universal pipe, and the length of past multifilament pole is greater than the width of surface fabric body moreover.

Preferably, the fixed shaft is fixed at the central part of the rotating disc, the cleaning brushes are distributed on the rotating disc at equal angles, and the bottom end surfaces of the cleaning brushes are attached to the top end surface of the fabric body.

Preferably, the first bidirectional threaded rod is in threaded connection with the connecting plates, the connecting plates are symmetrically distributed on the upper side and the lower side of the first bidirectional threaded rod, and the distances from the connecting plates on the upper side and the lower side to the fabric body are equal.

Preferably, the left side and the right side of the connecting plate are symmetrically provided with support rods, the connecting plate is hinged with the support rods, and the support rods are fixed in the middle of the connecting plate.

Preferably, the supporting rods correspond to the electric heating rollers one by one, the supporting rods are fixed in the middle of the electric heating rollers, and the length of the electric heating rollers is larger than that of the fabric body.

Preferably, the second bidirectional threaded rod is in threaded connection with the limiting plates, the limiting plates are symmetrically distributed on the left side and the right side of the second bidirectional threaded rod, and the cross sections of the limiting plates are F-shaped.

Preferably, the sliding rods are symmetrically distributed on the left side and the right side of the limiting plate, and the height of the sliding rods is equal to that of the second bidirectional threaded rod.

Preferably, the total length of the telescopic loop bar is greater than the length of the inner space of the shell of the device, the central axis of the shell of the device and the central axis of the fabric body are positioned on the same vertical central line, and the width of the fabric body is equal to the diameter of the rotary disc.

Compared with the prior art, the invention has the beneficial effects that: the pressurizing and laminating mechanism for processing and producing the textile fabric capable of quickly flattening the textile fabric;

(1) the mechanism is provided with an atomizing nozzle, a driving motor can drive a conveying pipe to perform stable reciprocating motion in a shell of the device through a reciprocating lead screw, at the moment, the atomizing nozzle can uniformly spray water in a storage tank to a fabric body in a reciprocating mode through a universal pipe, so that the subsequent fabric body can be stably ironed and flattened, the fabric body can be effectively prevented from being damaged due to overhigh temperature during ironing, and the use stability of a pressurizing and laminating mechanism is improved;

(2) the mechanism is provided with an electric heating roller, when a conveying pipe reciprocates, a gear tooth plate can drive a fixed shaft to reciprocate left and right through a second circular gear, at the moment, a second transmission belt can drive a connecting plate to reciprocate up and down through a first bidirectional threaded rod, a supporting rod can drive the electric heating rollers on two sides to push ironing work to two sides of a fabric body at the same time, the fabric body can be pulled to be flat while the fabric body is ironed and flattened, and the use diversity of the pressurizing and laminating mechanism is increased;

(3) this mechanism is provided with the limiting plate, can drive the limiting plate of both sides simultaneously to middle stable motion on the slide bar through rotating the bidirectional threaded rod of second, under the effect of limiting plate, can convenient and fast carry out spacing work to the surface fabric body of different width, can prevent effectively that the surface fabric body from taking place offset when flattening the during operation and leading to the rolling block, has increased the safety in utilization of pressurization laminating mechanism.

Drawings

FIG. 1 is a schematic overall front view of the present invention;

FIG. 2 is a schematic top view of the present invention;

FIG. 3 is a side view of the telescopic rod of the present invention;

FIG. 4 is a schematic view of the structure of the delivery tube of the present invention;

FIG. 5 is a schematic top view of the turntable according to the present invention;

FIG. 6 is a schematic view of a half-gear configuration of the present invention;

FIG. 7 is a schematic diagram of a side view of an electrical heating roller according to the present invention;

fig. 8 is a schematic side view of the limiting plate according to the present invention.

In the figure: 1. a device housing; 2. a drive motor; 3. a reciprocating screw rod; 4. a first drive belt; 5. a half gear; 6. a first circular gear; 7. a wind-up roll; 8. a fabric body; 9. a delivery pipe; 10. a universal tube; 11. a storage box; 12. an atomizing spray head; 13. a toothed plate; 14. a second circular gear; 15. a fixed shaft; 16. a turntable; 17. cleaning with a brush; 18. a second belt; 19. a first bidirectional threaded rod; 20. a connector tile; 21. a support bar; 22. an electrically heated roller; 23. a rubber rod; 24. a third belt; 25. a connecting shaft; 26. a cooling fan; 27. a second bidirectional threaded rod; 28. a limiting plate; 29. a slide bar; 30. a telescopic loop bar.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a pressurizing and laminating mechanism capable of quickly flattening textile cloth for processing and producing the textile cloth comprises a device shell 1, a driving motor 2, a reciprocating screw rod 3, a first transmission belt 4, a half gear 5, a first circular gear 6, a winding roller 7, a fabric body 8, a conveying pipe 9, a universal pipe 10, a storage box 11, an atomizing nozzle 12, a gear tooth plate 13, a second circular gear 14, a fixed shaft 15, a turntable 16, a cleaning brush 17, a second transmission belt 18, a first bidirectional threaded rod 19, a connecting plate 20, a supporting rod 21, an electric heating roller 22, a rubber rod 23, a third transmission belt 24, a connecting shaft 25, a cooling fan 26, a second bidirectional threaded rod 27, a limiting plate 28, a sliding rod 29 and a telescopic sleeve rod 30, wherein the driving motor 2 is fixedly welded on the device shell 1, the output end of the driving motor 2 is rotatably connected with the reciprocating screw rod 3, the first transmission belt 4 is connected on the reciprocating screw rod 3 in a meshing manner, the first transmission belt 4 is connected on a central shaft of the half gear 5 in a meshing manner, the half gear 5 is connected on the device shell 1 in a shaft manner, the half gear 5 is connected with a first circular gear 6 in a meshing manner, the first circular gear 6 is fixedly welded on a winding roller 7, the winding roller 7 is rotatably connected in the device shell 1, a fabric body 8 is wound on the winding roller 7, a conveying pipe 9 is arranged on the reciprocating screw rod 3, a universal pipe 10 is arranged on the conveying pipe 9 in a bolt manner, an atomizing nozzle 12 is arranged on the conveying pipe 9 in a bolt manner, the top end of the universal pipe 10 is connected on a storage box 11 in a bolt manner, the storage box 11 is connected on the device shell 1 in a bolt manner, a gear tooth plate 13 is connected on the conveying pipe 9 in a bolt manner, a second circular gear 14 is connected on the gear tooth plate 13 in a meshing manner, the second circular gear 14 is, a rotary table 16 is fixedly welded at the bottom end of a fixed shaft 15, a cleaning brush 17 is connected with the lower screw of the rotary table 16, a second transmission belt 18 is connected with the fixed shaft 15 in a meshed manner, the second transmission belt 18 is connected with a first bidirectional threaded rod 19 in a meshed manner, a connecting plate 20 is movably connected with the first bidirectional threaded rod 19, the connecting plate 20 is connected in the device shell 1 in a sliding manner, a support rod 21 is movably connected with the lower end of the connecting plate 20, an electric heating roller 22 is fixed at the bottom end of the support rod 21 through a bolt, a rubber rod 23 is connected with the support rod 21 through a screw, a third transmission belt 24 is connected with the first bidirectional threaded rod 19 in a meshed manner, the third transmission belt 24 is connected with a connecting shaft 25 in a meshed manner, the connecting shaft 25 is rotatably connected in the device shell 1, a cooling fan 26 is fixedly welded at the bottom end of the connecting shaft 25, a second, the limiting plate 28 is connected with a sliding rod 29 in a sliding manner, the sliding rod 29 is fixed in the device shell 1 in a welding manner, a telescopic loop bar 30 is fixed in the device shell 1 in a welding manner, and the top end of the telescopic loop bar 30 is fixed on the conveying pipe 9 in a welding manner.

Reciprocating screw 3 fixes in the middle part of conveyer pipe 9, and is threaded connection between reciprocating screw 3 and the conveyer pipe 9 to equidistant universal pipe 10 that distributes on the conveyer pipe 9, reciprocating screw 3's length is greater than the width of surface fabric body 8 moreover, can guarantee that reciprocating screw 3 can drive conveyer pipe 9 and carry out stable processing of prewetting to surface fabric body 8.

The fixed shaft 15 is fixed at the central part of the rotating disc 16, the sweeping brushes 17 are distributed on the rotating disc 16 at equal angles, the bottom end surfaces of the sweeping brushes 17 are attached to the top end surface of the fabric body 8, and the rotating disc 16 can be ensured to rotate stably on the fixed shaft 15.

For threaded connection between first two-way threaded rod 19 and the linkage plate 20, and linkage plate 20 symmetric distribution is in the upper and lower both sides of first two-way threaded rod 19 to the distance between upper and lower both sides linkage plate 20 to surface fabric body 8 equals, can conveniently control linkage plate 20 and can carry out stable motion on first two-way threaded rod 19, has increased the stability in use of the laminating mechanism that flattens.

Support rods 21 are symmetrically distributed on the left side and the right side of the connecting plate 20, the connecting plate 20 is hinged to the support rods 21, the support rods 21 are fixed in the middle of the connecting plate 20, the stability of the connection state between the connecting plate 20 and the support rods 21 can be guaranteed, and the use stability of the support rods 21 is improved.

The supporting rods 21 correspond to the electric heating rollers 22 one by one, the supporting rods 21 are fixed in the middle of the electric heating rollers 22, the length of the electric heating rollers 22 is larger than that of the fabric body 8, the electric heating rollers 22 can be guaranteed to stably flatten the fabric body 8, and the use efficiency of the mechanism is improved.

For threaded connection between second bidirectional threaded rod 27 and the limiting plate 28, and limiting plate 28 symmetric distribution is in the left and right sides of second bidirectional threaded rod 27 to the transversal "F" of limiting plate 28 shape of personally submitting can guarantee that limiting plate 28 can carry out stable spacing work to surface fabric body 8, has increased the stability in use of the laminating mechanism that flattens.

The sliding rods 29 are symmetrically distributed on the left side and the right side of the limiting plate 28, and the height of the sliding rods 29 is equal to that of the second bidirectional threaded rod 27, so that the adverse effect of the sliding rods 29 on the second bidirectional threaded rod 27 can be effectively avoided, and the use stability of the second bidirectional threaded rod 27 is improved.

The total length of flexible loop bar 30 is greater than the inner space length of device shell 1, and the central axis of device shell 1 and the central axis of surface fabric body 8 are located same vertical central line to the width of surface fabric body 8 equals with the diameter of carousel 16, can guarantee the stability of flexible loop bar 30 working effect in device shell 1, has increased the stability in use of mechanism that flattens.

The working principle is as follows: before the pressurizing and attaching mechanism capable of quickly flattening the textile cloth for processing and producing the textile cloth is used, the overall condition of the device needs to be checked firstly to determine that the device can normally work;

when the pressurizing and laminating mechanism starts to work, with reference to fig. 1-5 and under the limiting action of the telescopic loop bar 30, the driving motor 2 drives the reciprocating screw rod 3 to rotate, and simultaneously can drive the conveying pipe 9 to stably reciprocate in the device shell 1, at the moment, the universal pipe 10 can convey purified water in the storage box 11 to the conveying pipe 9, then the atomizing nozzle 12 can uniformly spray the purified water to the fabric body 8 in a reciprocating manner, and further stable ironing and flattening work of the subsequent fabric body 8 can be ensured;

and at the same time of the reciprocating motion of the conveying pipe 9, with reference to fig. 1-7, the toothed plate 13 can be driven to reciprocate, and further the fixed shaft 15 on the second circular gear 14 can be driven to reciprocate left and right, at this time, the fixed shaft 15 can drive the cleaning brush 17 under the turntable 16 to reciprocate, and can stably clean the fabric body 8, so as to ensure the stability of the subsequent processing state of the fabric body 8, and at the same time of the rotation of the fixed shaft 15, the second driving belt 18 can drive the connecting plates 20 at the upper and lower sides to reciprocate up and down through the first bidirectional threaded rod 19, when the connecting plates 20 at the upper and lower sides move toward the middle at the same time, the upper and lower two sets of electric heating rollers 22 can respectively extrude the fabric body 8 up and down, at this time, under the extrusion action, the support rod 21 can drive the upper and lower two sets of electric heating rollers 22 to push the fabric body 8 to, when the fabric body 8 is ironed and flattened, the fabric body 8 can be pulled to be flattened, so that the stability of subsequent ironing work can be ensured, and when the connecting plates 20 on the upper side and the lower side move outwards at the same time, the electric heating roller 22 can be driven to return to the original position through the supporting rod 21 under the action of the rubber rod 23, and meanwhile, the electric heating roller 22 can perform reciprocating ironing work on the fabric body 8;

and when the first bidirectional threaded rod 19 rotates, with reference to fig. 1, 2 and 8, the third transmission belt 24 can drive the cooling fan 26 below the connecting shaft 25 to perform stable rotation work, so as to perform stable cooling and forming work on the ironed fabric body 8, thereby facilitating subsequent winding work, and when the reciprocating screw rod 3 rotates, the first transmission belt 4 can drive the first circular gear 6 to perform intermittent rotation through the half gear 5, so as to drive the winding roller 7 to perform intermittent rotation and winding work on the fabric body 8, thereby ensuring the stability during subsequent ironing work, and by rotating the second bidirectional threaded rod 27, the limiting plates 28 on both sides can be driven to perform stable movement on the sliding rod 29 towards the middle at the same time, and under the action of the limiting plates 28, the fabric bodies 8 with different widths can be conveniently and quickly limited, the rolling clamping caused by the position deviation of the fabric body 8 during the flattening operation can be effectively prevented, which is the working process of the whole device, and the details which are not described in detail in the specification, such as the driving motor 2, the fabric body 8, the universal pipe 10, the atomizer 12, the electric heating roller 22, the rubber rod 23 and the cooling fan 26, all belong to the prior art known to those skilled in the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a textile fabric processing production of weaving cloth that can flatten fast is with pressurization laminating mechanism, includes device shell (1), atomizer (12), brush cleaner (17), electrical heating roller (22), cooling blower (26) and limiting plate (28), its characterized in that: the device is characterized in that a driving motor (2) is fixedly welded on a shell (1), the output end of the driving motor (2) is rotatably connected with a reciprocating screw rod (3), a first driving belt (4) is connected to the reciprocating screw rod (3) in a meshed mode, the first driving belt (4) is connected to the central shaft of a half gear (5) in a meshed mode, the half gear (5) is connected to the device shell (1) in a shaft mode, a first circular gear (6) is connected to the half gear (5) in a meshed mode, the first circular gear (6) is fixedly welded on a winding roller (7), the winding roller (7) is rotatably connected into the device shell (1), a fabric body (8) is wound on the winding roller (7), a conveying pipe (9) is arranged on the reciprocating screw rod (3), a universal pipe (10) is installed on the conveying pipe (9) in a bolt mode, and an atomization nozzle (12) is installed on the conveying pipe (9) in, the top end bolted connection of universal pipe (10) is on storage box (11), and storage box (11) screwed connection is on device shell (1), screwed connection has teeth of a cogwheel board (13) on conveyer pipe (9), and meshing connection has second circular gear (14) on teeth of a cogwheel board (13), second circular gear (14) welded fastening is on fixed axle (15), and fixed axle (15) rotate to connect in device shell (1), the bottom welded fastening of fixed axle (15) has carousel (16), and carousel (16) lower screwed connection has cleaning brush (17), meshing connection has second drive belt (18) on fixed axle (15), and second drive belt (18) meshing connection is on first bidirectional threaded rod (19), swing joint has linkage board (20) on first bidirectional threaded rod (19), and linkage board (20) sliding connection is in device shell (1), movably connected with bracing piece (21) under linkage plate (20), and the bottom bolted fixation of bracing piece (21) has electrical heating roller (22) to screwed connection has rubber pole (23) on bracing piece (21), the meshing is connected with third drive belt (24) on first bidirectional threaded rod (19), and third drive belt (24) meshing connects on connecting axle (25), connecting axle (25) rotate to be connected in device shell (1), and the bottom welded fastening of connecting axle (25) has cooling blower (26), device shell (1) internal rotation is connected with second bidirectional threaded rod (27), and swing joint has limiting plate (28) on second bidirectional threaded rod (27), sliding connection has slide bar (29) on limiting plate (28), and slide bar (29) welded fastening is in device shell (1), device shell (1) internal welding is fixed with flexible loop bar (30), and the top end of the telescopic loop bar (30) is welded and fixed on the conveying pipe (9).

2. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the reciprocating screw rod (3) is fixed in the middle of the conveying pipe (9), the reciprocating screw rod (3) is in threaded connection with the conveying pipe (9), universal pipes (10) are distributed on the conveying pipe (9) at equal intervals, and the length of the reciprocating screw rod (3) is larger than the width of the fabric body (8).

3. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the fixed shaft (15) is fixed at the central part of the turntable (16), the cleaning brushes (17) are distributed on the turntable (16) at equal angles, and the bottom end surfaces of the cleaning brushes (17) are attached to the top end surface of the fabric body (8).

4. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the first bidirectional threaded rod (19) is in threaded connection with the connecting plates (20), the connecting plates (20) are symmetrically distributed on the upper side and the lower side of the first bidirectional threaded rod (19), and the distances from the connecting plates (20) on the upper side and the lower side to the fabric body (8) are equal.

5. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: support rods (21) are symmetrically distributed on the left side and the right side of the connecting plate (20), the connecting plate (20) is hinged to the support rods (21), and the support rods (21) are fixed in the middle of the connecting plate (20).

6. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the supporting rods (21) correspond to the electric heating rollers (22) one by one, the supporting rods (21) are fixed in the middle of the electric heating rollers (22), and the length of the electric heating rollers (22) is larger than that of the fabric body (8).

7. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the second bidirectional threaded rod (27) is in threaded connection with the limiting plates (28), the limiting plates (28) are symmetrically distributed on the left side and the right side of the second bidirectional threaded rod (27), and the cross sections of the limiting plates (28) are F-shaped.

8. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the sliding rods (29) are symmetrically distributed on the left side and the right side of the limiting plate (28), and the height of the sliding rods (29) is equal to that of the second bidirectional threaded rod (27).

9. The pressing and attaching mechanism for textile fabric processing and production capable of rapidly flattening textile fabric according to claim 1, characterized in that: the total length of the telescopic loop bar (30) is greater than the length of the inner space of the shell (1), the central axis of the shell (1) and the central axis of the fabric body (8) are located on the same vertical central line, and the width of the fabric body (8) is equal to the diameter of the rotary disc (16).