CN118912827B

CN118912827B - Textile dewatering device

Info

Publication number: CN118912827B
Application number: CN202411419461.2A
Authority: CN
Inventors: 杨曦杰
Original assignee: Nantong Longxiang Textile Co ltd
Current assignee: Nantong Longxiang Textile Co ltd
Priority date: 2024-10-12
Filing date: 2024-10-12
Publication date: 2024-12-24
Anticipated expiration: 2044-10-12
Also published as: CN118912827A

Abstract

The invention discloses a textile dewatering device, which relates to the technical field of textile processing, wherein a cover plate is arranged above a shell, a water outlet pipe is arranged below the shell, a dewatering cavity and an operating cavity are formed in the inner part of the shell, a transmission cavity is arranged below the dewatering cavity and the operating cavity, a transmission mechanism is arranged in the operating cavity and penetrates through the dewatering cavity and the operating cavity, the lower part of a cylinder body is connected with an expansion component, dewatering holes are formed in the periphery of the cylinder body, a rubber inner cylinder is coaxially arranged in the cylinder body, the expansion component is coaxially arranged in the rubber inner cylinder, the cylinder body drives the expansion component to move synchronously through the transmission mechanism, the expansion component is driven to be unfolded by the rotation of the cylinder body, so that the expansion component drives the rubber inner cylinder to be attached to the cylinder body.

Description

Textile dewatering device

Technical Field

The invention relates to the technical field of textile processing, in particular to a textile dewatering device.

Background

Textiles are materials made from fibers or yarns by braiding, knitting, stitching or other processing methods, which are widely used in various fields of clothing, furniture articles, industrial applications and the like, and the basic constituent units of the textiles are fibers, which can be natural cotton, wool or synthetic polyester fibers, nylon, so as to prevent the post-processing of the textiles from being influenced by excessive moisture contained in the textiles, and therefore, the textiles need to be dehydrated in the process of textile production.

In most of the existing textiles and industrial applications, the textile is usually subjected to centrifugal dehydration to remove redundant moisture in the textile, the textile is mainly placed in a dehydration drum, a centrifugal machine rotating at a high speed is used for enabling the dehydration drum to generate strong centrifugal force to throw out redundant moisture in the textile, the inside of the textile is ensured not to contain redundant moisture, but due to the shape of the dehydration drum, the textile is placed in the dehydration drum, the textile can be deposited at the bottom of the dehydration drum, when the dehydration drum rotates for dehydration, the textile below the dehydration drum is more, the textile above and at the top of the dehydration drum is less, redundant moisture in the textile above is caused to throw out in the dehydration process, and a small amount of moisture is also contained in the textile below the dehydration drum, so that the subsequent processing of the textile is influenced.

In view of the above, the present invention provides a textile dewatering device, which solves the above technical problems.

Disclosure of Invention

In view of the shortcomings of the prior art, the invention aims to provide a textile dewatering device which solves the problems of the prior art

When the textile is dehydrated, centrifugal dehydration causes uneven textile on the upper and lower sides inside the dehydration cylinder, so that the problem that the textile on the lower side of the dehydration cylinder prevents the separation of moisture among the textiles more and the dehydration effect is poor is solved.

In order to achieve the above purpose, the present invention provides the following technical solutions:

A textile dewatering device is used for removing redundant moisture in textiles and comprises a shell, a cover plate is arranged above the shell and used for avoiding redundant moisture in the textiles from splashing, a water outlet pipe is arranged below the shell, the inner portion of the shell is provided with a dewatering cavity and an operating cavity, a transmission cavity is arranged below the dewatering cavity and the operating cavity, a transmission mechanism is arranged in the operating cavity and penetrates through the dewatering cavity and the operating cavity, a cylinder body is arranged in the dewatering cavity and connected with an expansion component below the cylinder body, dewatering holes are formed in the periphery of the cylinder body, a rubber inner cylinder is coaxially arranged inside the cylinder body, the expansion component is arranged inside the rubber inner cylinder and coaxially arranged with the rubber inner cylinder, the cylinder body drives the cylinder body to synchronously move through the transmission mechanism, and the cylinder body rotates to drive the expansion component to be unfolded, so that the expansion component drives the rubber inner cylinder body to be attached to the inner wall of the cylinder body.

Preferably, the transmission mechanism comprises a driving motor, a driving wheel, a driven wheel and a belt, wherein the driving motor is arranged in the operation cavity, the output end of the driving motor is arranged in a vertical horizontal plane, the output end of the driving motor is connected with the driving wheel, the driven wheel is arranged on one side of the driving wheel, and the driving wheel is connected with the driven wheel through the belt.

Preferably, the expansion assembly comprises a rotating shaft, a moving groove, a sliding sleeve, a connecting rod, a transmission rod and a supporting column, wherein the rotating shaft and the cylinder are coaxially arranged, the supporting column is arranged on the periphery of the annular array, the moving groove is formed in the middle of the rotating shaft, the sliding sleeve is arranged on the circumferential surface of the moving groove, a fixed vertical plate is arranged on the sliding sleeve, a sliding sleeve is arranged on the supporting column, the same fixed vertical plate is arranged on the sliding sleeve, the connecting rod is arranged on the fixed vertical plate of the sliding sleeve, one end of the connecting rod, far away from the fixed vertical plate, is connected with the transmission rod, and one end of the transmission rod, far away from the connecting rod, is connected with the fixed vertical plate on the sliding sleeve.

Preferably, the upper end and the lower end of the rotating shaft are symmetrically provided with fixed vertical plates, the support columns around the rotating shaft are provided with fixed vertical plates, the rotating shaft is provided with connecting rods through the fixed vertical plates, one ends of the connecting rods, far away from the rotating shaft, of the fixed vertical plates are connected with transmission rods, and the transmission rods are connected with the fixed vertical plates on the support columns.

Preferably, the support column is provided with a fixed shaft, one side of the support column is connected with an arc plate, the inner side of the arc plate is connected with the fixed shaft, and the outer side of the arc plate is attached to the rubber inner cylinder.

Preferably, the rotary shaft is arranged at the top end of the cylinder, fixing mechanisms are symmetrically arranged in the rotary groove, and the cylinder is rotated to drive the fixing mechanisms to rotate in the rotary groove.

Preferably, the fixing mechanism comprises a supporting plate, a control rod, a swinging rod and a clamping rod, wherein the supporting plate is arranged in the rotating groove, a rotating hole is formed in the supporting plate, the control rod is coaxially arranged in the rotating hole, the lower part of the control rod is of a rectangular structure, the swinging rod is connected with the lower part of the control rod, one end of the swinging rod is connected with the rectangular structure below the control rod, the other end of the swinging rod is connected with the middle part of the clamping rod, one end of the clamping rod is connected with the supporting plate, and the other end of the clamping rod is connected with a clamping block.

Preferably, the swing rod and the clamping rod are symmetrically arranged on two sides of the control rod, the clamping block connected with one end of the clamping rod is a triangular block, and the bottom surfaces of the clamping blocks are parallel to each other.

Preferably, the rotary hole is internally provided with a limit groove, the control rod is provided with a limit block matched with the limit groove, and the control rod is rotationally connected with the lower-end rectangular structure.

Preferably, a plurality of dehydration holes are formed in the annular array around the dehydration holes, and the dehydration holes are of conical structures with large inner ends and small outer ends.

The invention has the beneficial effects that:

1. According to the textile dewatering device provided by the invention, the cylinder is driven to rotate through the transmission mechanism, so that the cylinder rotates, the expansion assembly is driven to expand when the cylinder rotates, so that the expansion assembly expands to be attached to the rubber inner cylinder, the expansion assembly pushes the rubber inner cylinder to expand towards the inner wall of the cylinder, textiles are uniformly distributed between the rubber inner cylinder and the cylinder, and accordingly, when the cylinder rotates, excessive moisture in the textiles can be uniformly thrown out, uneven vertical distribution of the textiles in the cylinder is avoided, more textiles in the cylinder prevent separation of moisture, and accordingly, textile dewatering effect is improved.

2. According to the textile dewatering device, the fixing mechanism rotates along with the rotation of the cylinder in the rotating groove of the cylinder in the rotating process of the cylinder, one end of the textile is fixed through the fixing mechanism, so that the textile is uniformly distributed up and down, and the textile can rotate along with the rotation of the cylinder and is attached to the inner wall of the cylinder in the rotating process of the cylinder, so that the dewatering effect of the textile is guaranteed.

3. According to the textile dewatering device provided by the invention, the dewatering holes are formed in the circumferential surface of the cylinder in the annular array, so that redundant moisture in the textile is discharged out of the cylinder through the dewatering holes, the special shape of the dewatering holes is limited, the situation that the dewatering holes discharged out of the cylinder reenter the cylinder can be avoided, the textile is prevented from being dewatered for the second time, and the fact that a large amount of moisture in the textile cannot remain to influence subsequent processing of the textile is ensured.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of the overall structure of the present invention;

FIG. 3 is a schematic view of the overall structure of the barrel fitting expansion assembly of the present invention;

FIG. 4 is an enlarged view of a portion of the invention at A in FIG. 3;

FIG. 5 is a schematic illustration of the overall construction of the expansion assembly of the present invention;

FIG. 6 is a cross-sectional view of an expansion assembly of the present invention;

FIG. 7 is a schematic view of the whole structure of the fixing mechanism of the present invention;

fig. 8 is a cross-sectional view of the overall structure of the securing mechanism of the present invention.

Reference numerals:

1. The device comprises a shell, 11, a water outlet pipe, 12, a cover plate, 2, a transmission mechanism, 21, a driving motor, 22, a driving wheel, 23, a driven wheel, 24, a belt, 3, a cylinder, 31, a dehydration hole, 32, a rotating groove, 4, a rubber inner cylinder, 5, an expansion assembly, 51, a rotating shaft, 52, a moving groove, 53, a fixed vertical plate, 54, a sliding sleeve, 55, a connecting rod, 56, a transmission rod, 57, a supporting column, 571, a sliding sleeve, 572, a fixed shaft, 573, an arc plate, 6, a fixing mechanism, 61, a supporting plate, 611, a rotating hole, 612, a limiting groove, 62, a control rod, 621, a limiting block, 63, a swinging rod, 64, a clamping rod, 641 and a clamping block.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention, and it is apparent that the described embodiments are some, but not all, embodiments of the present invention, and all other embodiments obtained by persons of ordinary skill in the art without inventive labor based on the described embodiments of the present invention are included in the scope of protection of the present invention.

Referring to fig. 1,2 and 3, a textile dewatering device is used for removing redundant moisture in textiles and comprises a shell 1, a cover plate 12 is arranged above the shell 1, the cover plate 12 is used for avoiding redundant moisture in the textiles from splashing, a water outlet pipe 11 is arranged below the shell 1, the interior of the shell 1 is divided into a dewatering cavity and an operation cavity, a transmission cavity is arranged below the dewatering cavity and the operation cavity, a transmission mechanism 2 is arranged in the operation cavity, the transmission mechanism 2 penetrates through the dewatering cavity and the operation cavity, a cylinder body 3 is arranged in the dewatering cavity, the lower side of the cylinder body 3 is connected with an expansion component 5, dewatering holes 31 are formed in the periphery of the cylinder body 3, a rubber inner cylinder 4 is coaxially arranged inside the cylinder body 3, the expansion component 5 is coaxially arranged with the rubber inner cylinder 4, the cylinder body 3 drives the synchronous motion of the cylinder body through the transmission mechanism 2, and the cylinder body 3 rotates to drive the expansion component 5 to be unfolded, so that the expansion component 5 drives the rubber inner cylinder 4 to be attached to the inner wall of the cylinder body 3.

In the working process, an operator firstly opens the cover plate 12 arranged above the shell 1, places the textile to be dehydrated into the cylinder 3, uniformly weaves the textile into the cylinder 3, closes the cover plate 12 after uniformly distributing the textile, thereby ensuring that the cover plate 12 can prevent water from splashing when the textile is dehydrated when the cylinder 3 is dehydrated, starts the transmission mechanism 2 after closing the cover plate 12, drives the cylinder 3 to rotate through the transmission mechanism 2, discharges redundant water in the textile into the textile by utilizing the centrifugal force generated by high-speed rotation when the cylinder 3 rotates, ensures that the redundant water in the textile flows out of the cylinder 3 from the inside of the dehydration hole 31, and the water flowing out of the cylinder 3 flows out of the water outlet pipe 11 arranged on the surface of the shell 1, so that the redundant water in the textile is discharged out of the inside of the shell 1, in order to ensure that textiles are uniformly distributed up and down in the cylinder 3, when the cylinder 3 rotates, an expansion assembly 5 coaxially installed in the cylinder 3 expands along with the rotation of the cylinder 3, when the expansion assembly 5 expands, the expansion assembly 5 expands to drive a rubber inner cylinder 4 coaxially arranged with the cylinder 3 to expand, so that the rubber inner cylinder 4 pushes the textiles to be attached to the inner wall of the cylinder 3, and simultaneously, when the rubber inner cylinder 4 expands, the textiles are thrown out in a cavity formed between the rubber inner cylinder 4 and the cylinder 3, and simultaneously, when the rubber inner cylinder 4 pushes the textiles to be attached to the inner wall of the cylinder 3, the textiles can be uniformly distributed up and down in the cavity formed between the rubber inner cylinder 4 and the inner wall of the cylinder 3, and when the cylinder 3 rotates, the textiles can be ensured to be uniformly separated from redundant moisture in the textiles, so that the dehydration effect of the textiles is ensured, the method has the advantages that the influence of excessive moisture in the textile on subsequent processing of the textile is avoided, after dehydration is finished, the cover plate 12 on the shell 1 is opened, and the textile is taken out for subsequent processing.

The transmission mechanism 2 comprises a driving motor 21, a driving wheel 22, a driven wheel 23 and a belt 24, wherein the driving motor 21 is arranged in an operation cavity, the output end of the driving motor 21 is arranged in a vertical horizontal plane, the output end of the driving motor 21 is connected with the driving wheel 22, one side of the driving wheel 22 is provided with the driven wheel 23, the driving wheel 22 is connected with the driven wheel 23 through the belt 24, the driving motor 21 is started, the driving wheel 22 arranged at the output end of the driving motor 21 is driven to rotate through the rotation of the driving motor 21, the driving wheel 22 drives the driven wheel 23 to rotate through the belt 24, the driven wheel 23 rotates to drive the cylinder 3 to rotate, the driving wheel 22 and the driven wheel 23 are driven to rotate through the belt 24, vibration and impact can be effectively absorbed, noise and vibration generated during transmission are reduced, and meanwhile the running stability of the whole device can be improved.

As shown in fig. 4 and 5, the expansion assembly 5 includes a rotating shaft 51, a moving groove 52, a sliding sleeve 54, a connecting rod 55, a transmission rod 56 and a supporting column 57, the rotating shaft 51 and the cylinder 3 are coaxially arranged, the circumference of the rotating shaft 51 is provided with the supporting column 57 in a ring array, the middle position of the rotating shaft 51 is provided with the moving groove 52, the circumference surface of the moving groove 52 is provided with the sliding sleeve 54, the sliding sleeve 54 is provided with a fixed vertical plate 53, the supporting column 57 is provided with a sliding sleeve 571, the sliding sleeve 571 is provided with the same fixed vertical plate 53, the fixed vertical plate 53 of the sliding sleeve 54 is provided with the connecting rod 55, one end of the connecting rod 55 far away from the fixed vertical plate 53 is connected with the transmission rod 56, and one end of the transmission rod 56 far away from the connecting rod 55 is connected with the fixed vertical plate 53 on the sliding sleeve 571.

In the working process, when the barrel 3 rotates, because the rotating shaft 51 is coaxially arranged with the barrel 3, and the rotating shaft 51 is fixedly connected with the barrel 3, the barrel 3 rotates to drive the rotating shaft 51 to rotate, in an initial state, the sliding sleeve 54 is arranged at the bottommost end of the moving groove 52, the sliding sleeve 571 on the supporting column 57 is parallel to the sliding sleeve 54, when the rotating shaft 51 rotates, the sliding sleeve 54 moves downwards in the moving groove 52, the fixed vertical plate 53 arranged on the sliding sleeve 54 is rotationally connected with the connecting rod 55, thereby the sliding sleeve 54 moves upwards to drive the connecting rod 55 to swing, when the connecting rod 55 swings, the sliding sleeve 571 on the supporting column 57 is driven to move upwards through the transmission rod 56 which is rotationally connected, at the moment, the supporting column 57 can be driven to expand around the rotating shaft 51, the supporting column 57 is driven to extrude textiles through the supporting column 57, so that extrusion force is applied to the textiles through the supporting column 57, the separation of redundant moisture in the textiles is accelerated, and the dehydration efficiency of the textiles is accelerated, when the barrel 3 stops rotating, at the moment, the rotating shaft 51 moves downwards in the moving groove 52, the sliding sleeve 54 moves downwards, the sliding sleeve 55, so that the sliding sleeve 571 moves downwards, and the transmission rod 56 is driven by the connecting rod 55 to move downwards, and then the supporting column 57 is moved downwards, and the textile 57 is not extruded by the textile 3.

As shown in fig. 5 and 6, the upper and lower ends of the rotating shaft 51 are symmetrically provided with fixed vertical plates 53, the support columns 57 around the rotating shaft 51 are provided with fixed vertical plates 53, the rotating shaft 51 is provided with connecting rods 55, one ends of the connecting rods 55, which are far away from the fixed vertical plates 53 on the rotating shaft 51, are connected with transmission rods 56, and the transmission rods 56 are connected with the fixed vertical plates 53 on the support columns 57, through such arrangement, when the support columns 57 are unfolded around, the fixed vertical plates 53 arranged on the support columns 57 drive the transmission rods 56 to swing, and when the transmission rods 56 swing, the transmission rods 56 drive the connecting rods 55 to enable the transmission rods 56 and the connecting rods 55 to fix the support columns 57, so that the stability of the whole device can be ensured when the cylinder 3 rotates.

Be provided with fixed axle 572 on the support column 57, and support column 57 one side is connected with arc 573, arc 573 inboard is connected with fixed axle 572, arc 573 outside and rubber inner tube 4 laminating, laminating through arc 573 and rubber inner tube 4 for form the cavity of placing the fabrics between rubber inner tube 4 and the barrel 3 inner wall, because the pivot 51 sets up a plurality of support columns 57 all around, therefore fabrics can be in the cavity even dehydration, thereby arc 573 can laminate rubber inner tube 4 even and applys the extrusion force to the fabrics, make fabrics even dehydration, thereby ensure the inside unnecessary moisture separation's of fabrics effect.

The axis of rotation has been seted up on barrel 3 top, and the symmetry is provided with fixed establishment 6 in the rotary tank 32, barrel 3 is rotatory to drive fixed establishment 6 at the rotary tank 32 internal rotation, through such setting, and fixed establishment 6 carries out the centre gripping to the fabrics, guarantees that fabrics evenly dewaters at the dehydration in-process, avoids the fabrics to appear overlapping winding phenomenon to influence the dehydration effect of fabrics, can avoid the fabrics that twine together to appear damaging the phenomenon at the dehydration in-process simultaneously.

As shown in fig. 7 and 8, the fixing mechanism 6 includes a support plate 61, a control rod 62, a swinging rod 63 and a clamping rod 64, the support plate 61 is disposed in the rotating groove 32, a rotating hole 611 is formed in the support plate 61, the control rod 62 is coaxially disposed in the rotating hole 611, the lower part of the control rod 62 is in a rectangular structure, the swinging rod 63 is connected below the control rod 62, one end of the swinging rod 63 is connected with the rectangular structure below the control rod 62, the other end of the swinging rod 63 is connected with the middle of the clamping rod 64, one end of the clamping rod 64 is connected with the support plate 61, and the other end of the clamping rod 64 is connected with a clamping block 641.

During operation, when an operator places textiles in the cavity between the cylinder body 3 and the rubber inner cylinder 4, the operator evenly distributes the textiles in the cavity, then the control rod 62 is pulled upwards, when the control rod 62 moves upwards, the control rod 62 drives the swinging rod 63 to swing, the swinging rod 63 is connected with the middle of the clamping rod 64, one side of the clamping rod 64 is rotationally arranged on the supporting plate 61, the swinging rod 63 drives the clamping rod 64 to swing towards the control rod 62 during swinging, at this time, the swinging rod 63 and the clamping rod 64 are symmetrically arranged on two sides of the control rod 62, the clamping blocks 641 connected with one end of the clamping rod 64 are triangular blocks, the bottom surfaces of the clamping blocks 641 are parallel to each other, the clamping rods 64 arranged on two sides drive the clamping blocks 641 to move towards the middle, the textiles can be fixed, the phenomenon that the textiles are separated from and stacked at the bottom of the cylinder body 3 is avoided when the textiles move, and meanwhile, the supporting rod can evenly apply pressure to the textiles, and the moisture inside the textiles is evenly separated.

The inside spacing groove 612 that is provided with of rotatory hole 611, be provided with stopper 621 on the control lever 62 and cooperate with spacing groove 612, and be rotationally connected between control lever 62 and the lower extreme rectangle structure, when control lever 62 drive swinging arms 63 transfer clamping lever 64 motion, make the stopper 621 on the control lever 62 slide in spacing groove 612 when pressing from both sides tight fabrics to clamp block 641, after pressing from both sides tightly, rotatory control lever 62 makes stopper 621 on the control and spacing groove 612 skew, thereby can guarantee that the fabrics can not appear rocking the phenomenon in rotatory in-process, the fixed establishment 6 of symmetry setting can the centre gripping multiunit fabrics simultaneously, thereby the dehydration efficiency of whole device to the fabrics has been accelerated.

The annular array around the dehydration hole 31 has offered a plurality of dehydration holes 31, and the toper structure that dehydration hole 31 is big for the inner outer end is little through such setting, avoids by barrel 3 inside exhaust moisture secondary entering barrel 3 to make the inside fabrics of barrel 3 need carry out the secondary dehydration, ensured the dehydration effect of whole device to the fabrics.

The above embodiments are only exemplary embodiments of the present invention and are not intended to limit the present invention, the scope of the present invention is defined by the claims, and various modifications or equivalent substitutions can be made by those skilled in the art within the spirit and scope of the present invention, and such modifications or equivalent substitutions should be considered to fall within the scope of the present invention.

Claims

1. The textile dewatering device is used for removing redundant moisture in textiles and comprises a shell (1), a cover plate (12) is arranged above the shell (1), the cover plate (12) is used for avoiding redundant moisture in the textiles from splashing, a water outlet pipe (11) is arranged below the shell (1), and the textile dewatering device is characterized in that the inner part of the shell (1) is provided with a dewatering cavity and an operating cavity, a transmission cavity is arranged below the dewatering cavity and the operating cavity, a transmission mechanism (2) is arranged in the operating cavity, and the transmission mechanism (2) penetrates through the dewatering cavity and the operating cavity;

The dewatering device is characterized in that a cylinder body (3) is arranged in the dewatering cavity, the lower part of the cylinder body (3) is connected with an expansion assembly (5), dewatering holes (31) are formed in the periphery of the cylinder body (3), a rubber inner cylinder (4) is coaxially arranged in the cylinder body (3), the expansion assembly (5) is arranged in the rubber inner cylinder (4), and the expansion assembly (5) and the rubber inner cylinder (4) are coaxially arranged;

The cylinder body (3) drives the cylinder body (3) to synchronously move through the transmission mechanism (2), and the cylinder body (3) rotates to drive the expansion assembly (5) to be unfolded, so that the expansion assembly (5) drives the rubber inner cylinder (4) to be attached to the inner wall of the cylinder body (3);

The expansion assembly (5) comprises a rotating shaft (51), a moving groove (52), a sliding sleeve (54), a connecting rod (55), a transmission rod (56) and a supporting column (57), wherein the rotating shaft (51) and the cylinder body (3) are coaxially arranged, the supporting column (57) is arranged on the periphery of the rotating shaft (51) in an annular array, the moving groove (52) is formed in the middle of the rotating shaft (51), the sliding sleeve (54) is arranged on the circumferential surface of the moving groove (52), a fixed vertical plate (53) is arranged on the sliding sleeve (54), a sliding sleeve (571) is arranged on the supporting column (57), the same fixed vertical plate (53) is arranged on the sliding sleeve (571), the connecting rod (55) is arranged on the fixed vertical plate (53) of the sliding sleeve (54), one end, far away from the fixed vertical plate (53), of the connecting rod (55) is connected with the transmission rod (56), and one end, far away from the connecting rod (55), of the transmission rod (56) is connected with the fixed vertical plate (53) on the sliding sleeve (571).

When barrel (3) rotate, inside coaxial arrangement's of barrel (3) expansion subassembly (5) expand along with the rotation of barrel (3), and when expansion subassembly (5) expanded, expansion subassembly (5) expanded drive with the coaxial rubber inner tube (4) expansion that set up of barrel (3) for rubber inner tube (4) promote fabrics laminating barrel (3) inner wall.

2. The textile dewatering device according to claim 1, wherein the transmission mechanism (2) comprises a driving motor (21), a driving wheel (22), a driven wheel (23) and a belt (24), the driving motor (21) is arranged in the operation cavity, the output end of the driving motor (21) is arranged in a vertical horizontal plane, the output end of the driving motor (21) is connected with the driving wheel (22), the driven wheel (23) is arranged on one side of the driving wheel (22), and the driving wheel (22) is connected with the driven wheel (23) through the belt (24).

3. The textile dewatering device according to claim 1, wherein the upper end and the lower end of the rotating shaft (51) are symmetrically provided with fixed vertical plates (53), support columns (57) around the rotating shaft (51) are provided with the fixed vertical plates (53), connecting rods (55) are arranged on the fixed vertical plates (53) on the rotating shaft (51), one ends, far away from the fixed vertical plates (53) on the rotating shaft (51), of the connecting rods (55) are connected with transmission rods (56), and the transmission rods (56) are connected with the fixed vertical plates (53) on the support columns (57).

4. A textile dewatering device according to claim 3, wherein the support column (57) is provided with a fixed shaft (572), one side of the support column (57) is connected with an arc plate (573), the inner side of the arc plate (573) is connected with the fixed shaft (572), and the outer side of the arc plate (573) is attached to the rubber inner cylinder (4).

5. The textile dewatering device according to claim 1, wherein the top end of the cylinder (3) is provided with a rotary groove (32), fixing mechanisms (6) are symmetrically arranged in the rotary groove (32), and the cylinder (3) rotates to drive the fixing mechanisms (6) to rotate in the rotary groove (32).

6. The textile dewatering device according to claim 5, further comprising a fixing mechanism (6), wherein the fixing mechanism (6) comprises a supporting plate (61), a control rod (62), a swinging rod (63) and a clamping rod (64), the supporting plate (61) is arranged in the rotating groove (32), a rotating hole (611) is formed in the supporting plate (61), a control rod (62) is coaxially arranged in the rotating hole (611), a rectangular structure is arranged below the control rod (62), the swinging rod (63) is connected below the control rod (62), one end of the swinging rod (63) is connected with the rectangular structure at the lower end of the control rod (62), the other end of the swinging rod is connected with the middle of the clamping rod (64), one end of the clamping rod (64) is connected with the supporting plate (61), and the other end of the clamping rod is connected with the clamping block (641).

7. The textile dewatering device as claimed in claim 6, wherein the swing rod (63) and the clamping rod (64) are symmetrically arranged at both sides of the control rod (62), and the clamping block (641) connected to one end of the clamping rod (64) is a triangle block, and the bottom surfaces of the clamping blocks (641) are parallel to each other.

8. The textile dewatering device according to claim 6, wherein a limiting groove (612) is formed in the rotary hole (611), a limiting block (621) is arranged on the control rod (62) and is matched with the limiting groove (612), and the control rod (62) is in rotary connection with the lower-end rectangular structure.

9. The textile dewatering device according to claim 1, wherein a plurality of dewatering holes (31) are formed in an annular array around the dewatering holes (31), and the dewatering holes (31) are of a conical structure with a large inner end and a small outer end.