CN115597324B - Water squeezing and drying device for polyester fabric - Google Patents

Abstract

The utility model relates to a dacron rolls water drying device, it includes the frame, the frame rotates to be connected with the roll, frame one side is equipped with heating chamber and air feed chamber, the heating chamber is located the roll with between the air feed chamber, the fabric passes through in proper order the roll the heating chamber with the air feed chamber, be equipped with the conveying assembly who is used for carrying the fabric in the heating chamber, conveying assembly top and below all are equipped with the electric plate, be equipped with a plurality of air feed spare in the air feed chamber, each air feed spare is located respectively air feed chamber top and bottom. The application has the following effects: the weight of the fabric after pad dyeing can be reduced, and the fabric is convenient for workers to transport.

Description

Water squeezing and drying device for polyester fabric

Technical Field

The application relates to the field of fabric pad dyeing equipment, in particular to a polyester fabric pad water drying device.

Background

Polyester fabric is a very large number of chemical fiber clothing fabric used in daily life. The biggest advantage is that the crease resistance and the shape retention are good, so that the anti-wrinkle fabric is suitable for being used as outdoor articles such as outerwear, various cases and tents.

Pad dyeing is a dyeing method in which after the fabric is immersed in a solution, the solution is pressed by a roller so that the solution penetrates into the fabric and the residual solution is removed. The pad dyeing method is to dip the fabric in the dye liquor for a short time, then roll the fabric with a roller, squeeze the dye liquor into the interstitial spaces of the fabric, and remove the redundant dye liquor to make the dye evenly distributed on the fabric.

After the fabric is pad dyed by a pad dyeing machine, excess water in the fabric is pressed out by a roller, but the fabric is still in a wet state, the wet fabric has heavy weight, and the fabric is inconvenient for workers to transport.

Disclosure of Invention

In order to reduce the weight of the fabric after pad dyeing, the fabric is convenient for workers to transport, and the application provides a dacron water padding drying device.

The application provides a dacron rolls water drying device adopts following technical scheme:

the utility model provides a dacron rolls water drying device, includes the frame, the frame rotates to be connected with the roll, frame one side is equipped with heating chamber and air supply chamber, the heating chamber is located the roll with between the air supply chamber, the fabric passes through in proper order the roll the heating chamber with the air supply chamber, be equipped with the conveying subassembly that is used for carrying the fabric in the heating chamber, conveying subassembly top and below all are equipped with the electric plate, be equipped with a plurality of air supply spare in the air supply chamber, each air supply spare is located air supply chamber top and bottom respectively.

Through adopting above-mentioned technical scheme, the fabric is output from the roll after padding through the padding machine, and the fabric gets into in the heating chamber, and the electric plate heats the fabric, can evaporate partial moisture in the fabric, and the fabric is carried in the air supply chamber from the heating chamber, and the air supply piece is bloied to the fabric, can get rid of partial moisture in the fabric, can cool down the fabric simultaneously, and the fabric has alleviateed the weight of fabric after the padding after export from the air supply chamber, makes things convenient for the staff to transport the fabric.

Preferably, the conveying assembly comprises a first conveying roller, a second conveying roller and a receiving plate, the length direction of the receiving plate is consistent with the length direction of the heating chamber, the first conveying roller and the second conveying roller are respectively positioned at two ends of the receiving plate along the length direction, and the length direction of the first conveying roller, the length direction of the second conveying roller and the width direction of the receiving plate are distributed along the width direction of the cloth.

Through adopting above-mentioned technical scheme, the fabric is entering the heating chamber, carries on the board through first conveying roller and second conveying roller, and the board is held to the board that holds can hold the fabric bottom, can avoid the fabric to take place deformation because of the bottom sagging when drying as far as possible.

Preferably, the bearing plate is provided with a plurality of first holes and a plurality of second holes, the first holes and the second holes are uniformly and alternately distributed on the bearing plate at intervals, a first stirring assembly is arranged in the first holes, a second stirring assembly is arranged in the second holes, and the first stirring assembly and the second stirring assembly are both used for stirring the bottom of the fabric so as to realize that the bottom of the fabric is far away from the top of the bearing plate.

Through adopting above-mentioned technical scheme, when the fabric is carried on the board that holds, the heat of the electric plate of board top can be to fabric top heating, the heat accessible each first hole of electric plate below that holds and second hole conduction to fabric bottom, fabric top and bottom when being heated, first subassembly and the second subassembly of stirring can stir the fabric bottom, the fabric bottom can keep away from and hold the board top to this can shake the fabric, can accelerate the air flow around the fabric, and then can accelerate the heat exchange of air and fabric, can improve the drying efficiency to the fabric.

Preferably, the first stirring assembly comprises a first rotating roller and first stirring sheets, the length direction of the first hole, the length direction of the first rotating roller and the length direction of the first stirring sheets are consistent with the width direction of the bearing plate, the first stirring sheets are distributed on the peripheral wall of the first rotating roller at equal angle intervals, the first rotating roller is rotatably arranged in the first hole, and when the first rotating roller rotates, each first stirring sheet sequentially penetrates through the opening of the first hole to beat the bottom of the fabric.

Through adopting above-mentioned technical scheme, first rotating roller drives each first plectrum and rotates when rotating, and first plectrum is when rotating, and the one end that first rotating roller was kept away from to first plectrum is rotated out the first hole and is beaten the fabric bottom, and a plurality of first rotating rollers rotate, and each first plectrum can be beaten the fabric bottom simultaneously to this can realize the effect of shake fabric.

Preferably, the second stirring assembly comprises a second rotating roller and second stirring sheets, the length direction of the second hole, the length direction of the second rotating roller and the length direction of the second stirring sheets are consistent with the width direction of the bearing plate, the second stirring sheets are distributed on the peripheral wall of the second rotating roller at equal angular intervals, the number of the second stirring sheets is different from that of the first stirring sheets, the second rotating roller is rotatably arranged in the second hole, and when the second rotating roller rotates, each second stirring sheet sequentially penetrates through the opening of the second hole to beat the bottom of the fabric.

Through adopting above-mentioned technical scheme, the second live-rollers drives each second plectrum and rotates when rotating, and the second plectrum is when rotating, and the one end that the second live-rollers was kept away from to the second plectrum beats the fabric bottom after revolving out the second hole, and a plurality of second live-rollers rotate, and each second plectrum can beat the fabric bottom simultaneously to this effect that can realize the shake fabric, simultaneously, because second plectrum quantity is different with first plectrum quantity, first live-rollers and second live-rollers are when rotating, and first plectrum and second plectrum can beat the fabric bottom in turn, can improve the shake effect to the fabric, and then can improve the drying efficiency to the fabric.

Preferably, the bearing plate is provided with a plurality of driving rods in a penetrating manner, the length direction of the driving rods is consistent with the width direction of the bearing plate, the driving rods penetrate through the first rotating roller and the second rotating roller and then are connected with a synchronizing assembly, and the synchronizing assembly is used for rotating the driving rods together.

Through adopting above-mentioned technical scheme, the synchronization subassembly can together drive each actuating lever and rotate, and each actuating lever can drive first rotor and second rotor and rotate simultaneously, and first plectrum and second plectrum can beat the fabric bottom with this in turn.

Preferably, the synchronous assembly comprises a motor, a synchronous belt and a plurality of gears, each gear is connected with each driving rod respectively, the synchronous belt is in transmission connection with each gear, and an output shaft of the motor is connected with each gear.

Through adopting above-mentioned technical scheme, a gear rotation is driven to the motor, and other gears together rotate through the hold-in range can be driven to the gear to this can make each actuating lever synchronous rotation.

Preferably, a plurality of brush rollers are rotatably arranged below the bearing plate, the brush rollers are uniformly distributed at intervals along the length direction of the bearing plate, the length direction of the brush rollers is consistent with the width direction of the bearing plate, the rotation direction of the brush rollers is consistent with the rotation direction of the second rotating rollers, and when the first rotating rollers and the second rotating rollers rotate, the first poking pieces and the second poking pieces are sequentially contacted with the brush rollers.

Through adopting above-mentioned technical scheme, when first plectrum and second plectrum are beating fabric bottom, the fabric bottom can drop fine hair, and fine hair can be stained with and attach on first plectrum and second plectrum, and first plectrum and second plectrum all contact with the brush roller when rotating to accepting the board below, and the brush roller can brush down the fine hair of being stained with and attaching on first plectrum and second plectrum when rotating, can avoid first plectrum and second plectrum to beat the fine hair that drops again when the fabric bottom again and be stained with on the fabric as far as possible.

Preferably, a first abdication groove is formed in the peripheral wall of the first rotating roller, the length direction of the first abdication groove is consistent with that of the first rotating roller, the opening width of the first abdication groove is larger than the bottom width of the groove, and one end of the first plectrum along the width direction is positioned in the first abdication groove and hinged with the end wall of the first abdication groove;

the second rotating roller peripheral wall is provided with a second abdication groove, the length direction of the second abdication groove is consistent with that of the second rotating roller, the opening width of the second abdication groove is larger than the width of the groove bottom of the second abdication groove, and one end of the second poking piece in the width direction is positioned in the second abdication groove and hinged with the end wall of the second abdication groove.

By adopting the technical scheme, when the first poking piece and the second poking piece rotate to the lower part of the bearing plate and contact with the brush roller, the first poking piece is propped against the side wall of the brush roller when continuously rotating, and the first poking piece rotates in the opposite direction in the first abdication groove until the first poking piece is propped against the side wall of one end of the opening of the first abdication groove, and the first poking piece rotates in the state to be separated from the side wall of the brush roller and then resets; the second plectrum is supported against the side wall of the brush roller when continuing to rotate, and the second plectrum rotates in the second abdicating groove along the opposite direction until the second plectrum is supported against the side wall of the opening end of the second abdicating groove, and the second plectrum rotates in the state to be reset after being separated from the side wall of the brush roller, so that the contact time of the first plectrum, the second plectrum and the brush roller can be prolonged, and the brushing effect of the brush roller on the fluff attached to the first plectrum and the second plectrum can be improved.

Preferably, one end of the first pulling sheet, which is far away from the first rotating roller, is connected with a first rubber sheet, the length direction of the first rubber sheet is consistent with the length direction of the first pulling sheet, and when the first rotating roller rotates, the first rubber sheet contacts with the wall of the first hole;

one end of the second shifting piece, which is far away from the second rotating roller, is connected with a second rubber piece, the length direction of the second rubber piece is consistent with the length direction of the second shifting piece, and when the second rotating roller rotates, the second rubber piece is in contact with the hole wall of the second hole.

By adopting the technical scheme, the fluff fallen from the fabric is adhered to the hole walls of the first hole and the second hole, and when the first rotary roller drives the first shifting sheet to rotate, the first rubber sheet is contacted with the hole wall of the first hole and deforms, so that the contact time with the hole wall of the first hole can be prolonged, and the fluff cleaning effect on the hole wall of the first hole can be improved; when the second rotating roller drives the second shifting sheet to rotate, the second rubber sheet contacts with the hole wall of the second hole and deforms, so that the contact time with the hole wall of the second hole can be prolonged, and the effect of cleaning fluff on the hole wall of the second hole can be improved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the fabric is padded by a padding machine and then is output from a roller, the fabric enters a heating chamber, an electric heating plate heats the fabric, part of moisture in the fabric can be evaporated, the fabric is conveyed from the heating chamber to a wind supply chamber, the wind supply piece blows the fabric, part of moisture in the fabric can be removed, meanwhile, the fabric can be cooled, and after the fabric is output from the wind supply chamber, the weight of the padded fabric is reduced, so that the fabric is convenient for workers to transport;

2. when the fabric is conveyed on the bearing plate, the heat of the electric heating plate above the bearing plate can heat the top of the fabric, the heat of the electric heating plate below the bearing plate can be conducted to the bottom of the fabric through each first hole and each second hole, when the top and the bottom of the fabric are heated, the first stirring component and the second stirring component can stir the bottom of the fabric, and the bottom of the fabric can be far away from the top of the bearing plate, so that the fabric can be vibrated, the air flow around the fabric can be accelerated, the heat exchange between the air and the fabric can be accelerated, and the drying efficiency of the fabric can be improved;

3. the second plectrum quantity is different with first plectrum quantity, and first rotor and second rotor are when rotating, and first plectrum and second plectrum can be patted the fabric bottom in turn, can improve the shake effect to the fabric, and then can improve the drying efficiency to the fabric.

Drawings

Fig. 1 is a schematic diagram of an overall structure of a water squeezing and drying device for polyester fabrics according to an embodiment of the application.

Fig. 2 is a partial structural sectional view of a water squeezing and drying device for polyester fabrics, which is used for showing a heating chamber.

Fig. 3 is a partial structural cross-sectional view of a water squeezing and drying device for polyester fabrics, which is used for showing an air supply chamber.

Fig. 4 is a schematic diagram of a part of a water squeezing and drying device for dacron according to an embodiment of the present application, which is used for showing a first stirring assembly and a second stirring assembly.

Fig. 5 is a schematic view of a part of a water squeezing and drying device for polyester fabrics, which is used for showing an air suction pipe and a vacuum pump.

Reference numerals illustrate:

100. a frame; 101. a roller;

200. a heating chamber; 201. an electric heating plate; 202. an air suction pipe; 203. opening holes; 204. a vacuum pump;

300. an air supply chamber; 301. an air supply member;

400. a transport assembly; 401. a first conveying roller; 402. a second conveying roller; 403. a receiving plate; 404. a first hole; 405. a second hole; 406. a driving rod; 407. a brush roller;

500. a first toggle assembly; 501. a first rotating roller; 502. a first plectrum; 503. a first relief groove; 504. a first rubber sheet;

600. a second toggle assembly; 601. a second rotating roller; 602. a second pulling piece; 603. a second relief groove; 604. a second rubber sheet;

700. a synchronization component; 701. a motor; 702. a synchronous belt; 703. a gear.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses a dacron water squeezing and drying device. Referring to fig. 1 and 2, the dacron water rolling and drying device comprises a frame 100, a heating chamber 200 and an air supply chamber 300, wherein two rollers 101 are rotatably connected to the frame 100, the heating chamber 200 is positioned between the rollers 101 and the air supply chamber 300, the heating chamber 200 is communicated with the air supply chamber 300, the heating chamber 200 is used for heating fabrics, the air supply chamber 300 is used for blowing air to the fabrics, the fabrics are sequentially pressed by the rollers 101, heated and dried by the heating chamber 200 and blown and dried by the air supply chamber 300 and then are output from the air supply chamber 300, the weight of the fabrics after padding can be reduced, and convenience is brought to workers to transport the fabrics.

Both rolls 101 are distributed in the fabric width direction in the length direction and are spaced apart to form a conveying gap. Both the longitudinal direction of the heating chamber 200 and the longitudinal direction of the air supply chamber 300 are distributed along the fabric conveying direction.

A plurality of electric heating plates 201 are arranged in the heating chamber 200, in this embodiment, two electric heating plates 201 are respectively distributed at the top and the bottom of the heating chamber 200, the length direction of the electric heating plates 201 is consistent with the length direction of the heating chamber 200, and the electric heating plates 201 are used for heating air in the heating chamber 200.

Referring to fig. 3, a plurality of air supply pieces 301 are disposed in an air supply chamber 300, the air supply pieces 301 are divided into two groups by fans, the two groups of air supply pieces 301 are respectively located at the top and the bottom of the air supply chamber 300, and the air supply pieces 301 are uniformly distributed at intervals along the length direction of the air supply chamber 300.

Referring to fig. 2 and 4, a transport assembly 400 for transporting a fabric is provided in the heating chamber 200, and the transport assembly 400 includes a first transport roller 401, a second transport roller 402, and a receiving plate 403, wherein the first transport roller 401 and the second transport roller 402 are both two, and the length direction of the first transport roller 401 and the length direction of the second transport roller 402 are both identical to the length direction of the roller 101. Two first conveying rollers 401 are located on the cloth feeding side of the heating chamber 200, and two second conveying rollers 402 are located on the cloth discharging side of the heating chamber 200. The receiving plate 403 is a long plate, and its longitudinal direction is identical to the longitudinal direction of the heating chamber 200. The first conveying roller 401 and the second conveying roller 402 are respectively positioned at both ends of the receiving plate 403 in the longitudinal direction. The two electric heating plates 201 are respectively located above and below the receiving plate 403. The fabric enters the heating chamber 200, passes through two first conveying rollers 401, is conveyed on a receiving plate 403, and passes through two second conveying rollers 402, and is conveyed to the air supply chamber 300.

The receiving plate 403 is provided with a plurality of first holes 404 and a plurality of second holes 405, the first holes 404 and the second holes 405 are uniformly and alternately distributed on the receiving plate 403 at intervals, and the length direction of the first holes 404 and the length direction of the second holes 405 are consistent with the width direction of the receiving plate 403. The receiving plate 403 has a first hole 404 and a second hole 405 distributed along the width direction.

The first hole 404 is provided with a first stirring assembly 500, the first stirring assembly 500 comprises a first rotating roller 501 and a first stirring sheet 502, the first rotating roller 501 is rotatably arranged in the first hole 404, the first stirring sheet 502 is rectangular sheet-shaped, and the length direction of the first stirring sheet 502 and the length direction of the first rotating roller 501 are identical to the length direction of the first hole 404. In this embodiment, there are two first paddles 502, and the two first paddles 502 are equiangularly spaced on the peripheral wall of the first rotating roller 501. One end of the first pulling sheet 502 far away from the peripheral wall of the first rotating roller 501 is connected with a first rubber sheet 504, and the length direction of the first rubber sheet 504 is consistent with the length direction of the first pulling sheet 502. When the first rotating roller 501 rotates, one end of the two first shifting sheets 502 far away from the first rotating roller 501 sequentially rotates out of the top opening and the bottom opening of the first hole 404, so as to flap the bottom of the fabric. When the first pulling piece 502 rotates into the first hole 404, the first rubber piece 504 contacts with the wall of the first hole 404.

Two first abdication grooves 503 are formed in the peripheral wall of the first rotating roller 501, the length direction of the first abdication grooves 503 is consistent with that of the first rotating roller 501, the opening width of the first abdication grooves 503 is larger than the bottom width of the grooves, one ends of the two first shifting sheets 502 along the width direction are respectively positioned in the first abdication grooves 503, and the two end walls of the first abdication grooves 503 are hinged through torsion springs.

The second hole 405 is provided with a second stirring assembly 600, the second stirring assembly 600 comprises a second rotating roller 601 and a second stirring piece 602, the second rotating roller 601 is rotatably arranged in the second hole 405, the second stirring piece 602 is rectangular, and the length direction of the second stirring piece 602 and the length direction of the second rotating roller 601 are identical to the length direction of the second hole 405. In this embodiment, there are three second paddles 602, and the three second paddles 602 are equiangularly spaced on the peripheral wall of the second rotating roller 601. One end of the second pulling piece 602 far away from the peripheral wall of the second rotating roller 601 is connected with a second rubber piece 604, and the length direction of the second rubber piece 604 is consistent with the length direction of the second pulling piece 602. When the second rotating roller 601 rotates, one ends of the three second shifting sheets 602, which are far away from the second rotating roller 601, sequentially rotate out of the top opening and the bottom opening of the second hole 405, so as to flap the bottom of the fabric. When the second pulling piece 602 rotates into the second hole 405, the second rubber piece 604 contacts the wall of the second hole 405.

Three second abdication grooves 603 are formed in the peripheral wall of the second rotating roller 601, the length direction of the second abdication grooves 603 is two to the length direction of the second rotating roller 601, the opening width of the second abdication grooves 603 is larger than the bottom width of the grooves, one ends of the three second poking sheets 602 in the width direction are respectively located in the second abdication grooves 603, and the two end walls of the second abdication grooves 603 are hinged through torsion springs.

The receiving plate 403 is penetrated with a plurality of driving rods 406, the driving rods 406 are round rods, and the length direction is consistent with the width direction of the receiving plate 403. Each driving rod 406 is uniformly distributed at intervals along the length direction of the receiving plate 403, one end of each driving rod 406 penetrates into one end of the receiving plate 403 along the width direction and then penetrates through the first rotating roller 501 and the second rotating roller 601, and the driving rods 406 are rotationally connected with the receiving plate 403. Each drive rod 406 rotates together by a synchronizing assembly 700, and the synchronizing assembly 700 includes a motor 701, a timing belt 702, and a plurality of gears 703. Each gear 703 is respectively connected with one end of each driving rod 406 protruding out of the bearing plate 403, each gear 703 is in transmission connection through a synchronous belt 702, the output shaft of the motor 701 is connected with one gear 703, the motor 701 drives the gears 703 to rotate, and the gears 703 drive other gears 703 to rotate through the synchronous belt 702, so that the first conveying roller 401 and the second conveying roller 402 can be simultaneously rotated through each driving rod 406.

Referring to fig. 2 and 5, a plurality of brush rollers 407 are rotatably provided below the receiving plate 403, and bristles are distributed on the peripheral walls of the brush rollers 407. The length direction of each brush roller 407 is consistent with the width direction of the receiving plate 403, and each brush roller 407 is uniformly distributed at intervals along the length direction of the receiving plate 403, and each brush roller 407 is respectively distributed below each driving rod 406 and near one side of the first conveying roller 401.

Referring to fig. 2 and 4, the first paddle 502 and the second paddle 602 sequentially contact the brush roller 407 when rotating, and the brush roller 407 is used for brushing down the fluff adhered on the first paddle 502 and the second paddle 602.

Referring to fig. 2 and 5, the suction pipes 202 are disposed below the receiving plate 403, and two suction pipes 202 are disposed along the length direction of the receiving plate 403. The air suction pipe 202 is located between the brush roller 407 and the electric heating plate 201. A plurality of openings 203 are formed in the top of the air suction pipe 202, and the openings 203 are uniformly distributed at intervals along the length direction of the air suction pipe 202. The two air suction pipes 202 are arranged in the width direction of the receiving plate 403. The ends of the two air suction pipes 202 near the cloth inlet side of the heating chamber 200 are communicated with each other and then penetrate through the side wall of the heating chamber 200 to be communicated with a vacuum pump 204.

The implementation principle of the dacron water squeezing and drying device provided by the embodiment of the application is as follows: after the fabric is pressed out by the roller 101, the fabric enters the heating chamber 200, and the electric heating plate 201 heats the fabric, so that part of water in the fabric can be evaporated. The fabric is conveyed to the receiving plate 403 through the first conveying roller 401, the first rotating roller 501 and the second rotating roller 601 rotate to drive the first poking piece 502 and the second poking piece 602 to rotate, and the first poking piece 502 and the second poking piece 602 sequentially penetrate out of the top opening of the first hole 404 and the top opening of the second hole 405 when rotating, so that the bottom of the fabric can be alternately beaten. The first pulling piece 502 and the second pulling piece 602 sequentially penetrate through the bottom opening of the first hole 404 and the bottom opening of the second hole 405 when rotating, the first pulling piece 502 and the second pulling piece 602 are in contact with the brush roller 407, the brush roller 407 can brush down the fluff on the first pulling piece 502 and the second pulling piece 602 when rotating, and the vacuum pump 204 can suck the fluff in the air through the air suction pipe 202 and discharge the fluff out of the heating chamber 200. The fabric is conveyed from the heating chamber 200 to the air supply chamber 300 through the second conveying roller 402, and the air supply member 301 blows air to the fabric, so that part of moisture in the fabric can be evaporated, and meanwhile, the fabric can be cooled, and after the fabric is output from the air supply chamber 300, the weight of the fabric after padding is reduced, and the fabric can be conveniently transported by workers.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (3)

1. The utility model provides a dacron rolls water drying device which characterized in that: the device comprises a frame (100), wherein the frame (100) is rotationally connected with a roller (101), one side of the frame (100) is provided with a heating chamber (200) and an air supply chamber (300), the heating chamber (200) is positioned between the roller (101) and the air supply chamber (300), fabrics sequentially pass through the roller (101), the heating chamber (200) and the air supply chamber (300), a conveying assembly (400) for conveying the fabrics is arranged in the heating chamber (200), electric heating plates (201) are arranged above and below the conveying assembly (400), a plurality of air supply pieces (301) are arranged in the air supply chamber (300), and the air supply pieces (301) are respectively positioned at the top and the bottom of the air supply chamber (300);

the conveying assembly (400) comprises a first conveying roller (401), a second conveying roller (402) and a receiving plate (403), the length direction of the receiving plate (403) is consistent with the length direction of the heating chamber (200), the first conveying roller (401) and the second conveying roller (402) are respectively positioned at two ends of the receiving plate (403) along the length direction, and the length direction of the first conveying roller (401), the length direction of the second conveying roller (402) and the width direction of the receiving plate (403) are distributed along the width direction of cloth;

the bearing plate (403) is provided with a plurality of first holes (404) and a plurality of second holes (405), the first holes (404) and the second holes (405) are uniformly and alternately distributed on the bearing plate (403), a first stirring component (500) is arranged in the first holes (404), a second stirring component (600) is arranged in the second holes (405), and the first stirring component (500) and the second stirring component (600) are both used for stirring the bottom of the fabric so as to realize that the bottom of the fabric is far away from the top of the bearing plate (403);

the first stirring assembly (500) comprises a first rotating roller (501) and first stirring sheets (502), the length direction of the first hole (404), the length direction of the first rotating roller (501) and the length direction of the first stirring sheets (502) are consistent with the width direction of the bearing plate (403), the first stirring sheets (502) are distributed on the peripheral wall of the first rotating roller (501) at equal angular intervals, the first rotating roller (501) is rotatably arranged in the first hole (404), and when the first rotating roller (501) rotates, each first stirring sheet (502) sequentially penetrates through the opening of the first hole (404) to beat the bottom of a fabric;

the second stirring assembly (600) comprises a second rotating roller (601) and second stirring sheets (602), the length direction of the second hole (405), the length direction of the second rotating roller (601) and the length direction of the second stirring sheets (602) are consistent with the width direction of the bearing plate (403), the second stirring sheets (602) are distributed on the peripheral wall of the second rotating roller (601) at equal angular intervals, the number of the second stirring sheets (602) is different from that of the first stirring sheets (502), the second rotating roller (601) is rotatably arranged in the second hole (405), and when the second rotating roller (601) rotates, each second stirring sheet (602) sequentially penetrates through the opening of the second hole (405) to beat the bottom of a fabric;

the bearing plate (403) is provided with a plurality of driving rods (406) in a penetrating manner, the length direction of the driving rods (406) is consistent with the width direction of the bearing plate (403), the driving rods (406) penetrate through the first rotating roller (501) and the second rotating roller (601) and then are connected with a synchronizing assembly (700), and the synchronizing assembly (700) is used for rotating all the driving rods (406) together;

the synchronous assembly (700) comprises a motor (701), a synchronous belt (702) and a plurality of gears (703), each gear (703) is respectively connected with each driving rod (406), the synchronous belt (702) is in transmission connection with each gear (703), and an output shaft of the motor (701) is connected with the gears (703);

the peripheral wall of the first rotating roller (501) is provided with a first abdication groove (503), the length direction of the first abdication groove (503) is consistent with that of the first rotating roller (501), the opening width of the first abdication groove (503) is larger than the groove bottom width of the first abdication groove, and one end of the first shifting piece (502) along the width direction is positioned in the first abdication groove (503) and hinged with the end wall of the first abdication groove (503);

the second rotating roller (601) perisporium has seted up second groove (603) of stepping down, second groove (603) length direction of stepping down with second rotating roller (601) length direction is unanimous, second groove (603) open width of stepping down is greater than its tank bottom width, one end along width direction of second plectrum (602) is located in second groove (603) of stepping down and with second groove (603) end wall articulates.

2. The dacron water squeezing and drying device according to claim 1, wherein: the brush roller (407) is evenly distributed at intervals along the length direction of the bearing plate (403), the length direction of the brush roller (407) is consistent with the width direction of the bearing plate (403), the rotation direction of the brush roller (407) is consistent with the rotation direction of the second rotating roller (601), and when the first rotating roller (501) and the second rotating roller (601) rotate, the first poking pieces (502) and the second poking pieces (602) are sequentially contacted with the brush roller (407).

3. The dacron water squeezing and drying device according to claim 1, wherein: one end of the first shifting sheet (502) far away from the first rotating roller (501) is connected with a first rubber sheet (504), the length direction of the first rubber sheet (504) is consistent with the length direction of the first shifting sheet (502), and when the first rotating roller (501) rotates, the first rubber sheet (504) is contacted with the wall of the first hole (404);

one end of the second shifting sheet (602) far away from the second rotating roller (601) is connected with a second rubber sheet (604), the length direction of the second rubber sheet (604) is consistent with the length direction of the second shifting sheet (602), and when the second rotating roller (601) rotates, the second rubber sheet (604) is contacted with the hole wall of the second hole (405).