阅读说明：本技术 一种多孔布料的加工方法 (Processing method of porous cloth ) 是由 戴美秀 于 2021-09-13 设计创作，主要内容包括：本发明涉及布料加工领域,具体是一种多孔布料的加工方法,该多孔布料的加工方法采用一种多孔布料的加工设备配合完成,该多孔布料的加工设备包括加工箱,加工箱一侧设有进料口,进料口后侧设有传输部件,传输部件远离进料口方向下方设有染色部件,传输部件上方设有脱水部件,脱水部件上方设有展平部件,染色部件远离传输部件方向设有烘干定型部件。本发明通过脱水部件对多孔布料进挤压、出气、下端未染色的布料吸收,有利于快速把布料脱水,未染色的布料吸收有利于节约资源；通过展平部件对多孔布料进行吸块往两边吸引进行展平,避免了多孔布料的破坏；通过烘干定型部件对布料进行均匀加热,使布料受热均匀,有利于布料的定型。(The invention relates to the field of cloth processing, in particular to a processing method of porous cloth, which is completed by matching processing equipment of the porous cloth, wherein the processing equipment of the porous cloth comprises a processing box, a feed inlet is arranged on one side of the processing box, a transmission part is arranged on the rear side of the feed inlet, a dyeing part is arranged below the transmission part in the direction far away from the feed inlet, a dehydration part is arranged above the transmission part, a flattening part is arranged above the dehydration part, and a drying and shaping part is arranged above the dyeing part in the direction far away from the transmission part. According to the invention, the porous cloth is extruded and discharged through the dehydration part, and the undyed cloth at the lower end is absorbed, so that the cloth can be dehydrated quickly, and the undyed cloth is absorbed, so that resources can be saved; the porous cloth is sucked by the sucking blocks towards two sides for flattening through the flattening component, so that the damage of the porous cloth is avoided; the cloth is uniformly heated through the drying and shaping component, so that the cloth is uniformly heated, and the shaping of the cloth is facilitated.)

1. The processing method of the porous cloth is characterized by comprising the following steps:

s1, feeding cloth into the processing box through the feed inlet on the roller;

s2, cloth is conveyed into the coloring drum through the conveying mechanism;

s3: coloring the cloth, wherein the cloth is colored on two sides in the coloring cylinder;

s4: dehydrating the cloth, extruding and blowing out excess water in the cloth and absorbing the excess water by the un-colored cloth;

s5: flattening the cloth, namely flattening the two sides of the cloth through a flattening component;

s6: drying and shaping the cloth, and drying and shaping the cloth;

s7, taking out the cloth, and taking out the shaped cloth through a discharge hole for use;

the steps S1-S7 adopt the cooperation of a processing device of porous cloth to accomplish, and the processing device of this porous cloth includes processing case (1), processing case (1) one side is equipped with feed inlet (101), feed inlet (101) rear side is equipped with transmission part (2), transmission part (2) are kept away from feed inlet (101) direction below and are equipped with dyeing part (3), transmission part (2) top is equipped with dehydration part (4), dehydration part (4) top is equipped with flat part (5), dyeing part (3) are kept away from transmission part (2) direction and are equipped with stoving design part (6).

2. The method for processing a porous cloth according to claim 1, wherein: feed inlet (101) are kept away from transmission part (2) direction and are equipped with two backup pads (104), it is equipped with rotary column (103) to rotate between two backup pads (104), the outer periphery of rotary column (103) has set firmly sleeve (102), the cloth that will process is being overlapped to the outer periphery of sleeve (102).

3. The method for processing a porous cloth according to claim 1, wherein: transmission part (2) include first motor (201), first motor (201) are fixed outside a lateral wall of processing case, first motor (201) are equipped with first pivot (202) to processing case (1) inside direction, first pivot (202) rotate to be connected on processing case (1), first pivot (202) have set firmly first commentaries on classics cover (203) on the outer periphery in processing case (1), first pivot (202) are equipped with second pivot (204) to feed inlet (101) direction, second pivot (204) are equipped with third pivot (205) to feed inlet (101) direction, third pivot (205) are equipped with fourth pivot (206) to feed inlet (101) direction, second pivot (204), third pivot (205), fourth pivot (206) rotate to be connected on processing case (1), second pivot (204), Be connected between third pivot (205), fourth pivot (206) and first pivot (202) and be equipped with first conveyer belt (207), second commentaries on classics cover (208) have set firmly on second pivot (204) outer periphery, third pivot (205) outer periphery has set firmly third commentaries on classics cover (209), fourth pivot (206) outer periphery has set firmly fourth commentaries on classics cover (210).

4. The method for processing a porous cloth according to claim 1, wherein: the dyeing part (3) comprises a dyeing box (301), the dyeing box (301) is positioned at the middle bottom of the processing box (1), a conveying mechanism (302) is rotatably connected above the dyeing box (301), a dyeing cup group (303) is arranged on the conveying mechanism (302), the coloring cup group (303) comprises a cylinder (304), a push plate (305) is arranged in the middle of the inside of the cylinder (304) in a sliding manner, the cylinder (304) is connected with the push plate (305) and is provided with a first spring (306), a rotating column (307) is arranged above the conveying mechanism (302), the rotating column (307) is rotationally connected to the dyeing box (301), a rotating sleeve (308) is arranged on the periphery of the rotating column (307), a pigment cavity (309) is arranged on the periphery of the rotating sleeve (308), a discharge channel (310) is arranged between the pigment cavity (309) and the cloth, and a recovery plate (311) is fixedly arranged on the dyeing box (301) towards the direction of the feed inlet (101).

5. The method for processing a porous cloth according to claim 1, wherein: dehydration part (4) are including three dehydration group (401), three dehydration group (401) are located transmission part (2) top, dehydration group (401) contain and are equipped with axis of rotation (402), axis of rotation (402) rotate and connect on processing case (1), axis of rotation (402) outer periphery has set firmly and has rotated cover (404), axis of rotation (402) inside is equipped with first air cavity (403), it evenly is equipped with six extrusion piece (405) to rotate cover (404) last circumference array, six extrusion piece (405) are equipped with six slide (407) to rotating cover (404) inside direction, it is equipped with six connecting rod (406) to be connected between six slide (407) and six extrusion piece (405), six connecting rod (406) periphery is equipped with six second spring (408), six connecting rod (406), six extrusion piece (405), Six air outlet channels (409) are arranged between the six sliding plates (407) and the first air cavity (403), six first air valves (410) are outwards arranged on the six air outlet channels (409), and a second conveying belt (411) is connected between the three dehydration groups (401).

6. The method for processing a porous cloth according to claim 1, wherein: the flattening component (5) comprises three flattening column groups (501), the three flattening column groups (501) are located above the dewatering component (4), the flattening column groups (501) comprise rotating rods (502), the rotating rods (502) are rotatably connected to the processing box (1), rotating rod sleeves (503) are fixedly arranged on the periphery of the rotating rods (502), second air chambers (504) are arranged inside the rotating rods (502), first air pumps (505) are arranged in the middles of the second air chambers (504), two air suction pipes (506) are arranged on two sides of each first air pump (505), a sliding chute (508) is arranged at the lower end of each first air pump (505), a first air outlet pipe (507) is arranged between each sliding chute (508) and each first air pump (505), two flattening groups (509) are arranged in each sliding chute (508), each flattening group (509) comprises a sliding block (510), and a suction block (211) is arranged at the lower end of each sliding block (510), the lower end of the suction block (211) is provided with a suction valve (512), and an air outlet cavity (513) is connected between the suction valve (512) and the second air cavity (504).

7. The method for processing a porous cloth according to claim 1, wherein: the drying and shaping component (6) comprises a second motor (601), the second motor (601) is positioned on one side wall in the processing box (1), a drying column group (602) is arranged in the second motor (601) towards the inner direction of the processing box (1), the drying column group (602) comprises a linkage column (604), a heat conduction sleeve (603) is fixedly arranged on the periphery of the linkage column (604), a hot air cavity is arranged between the linkage column (604) and the second air pump (605), a heating plate (608) is arranged outside the linkage column (604) far away from the second motor (601), a second air pump (605) is arranged on the heating plate (608) towards the direction of the feed inlet (101), a second air outlet pipe (607) is arranged on the second air pump (605) towards the heating plate (608), an air inlet pipe (606) is arranged on the second air pump (605) in the direction away from the heating plate (608), and an outlet (609) is formed in one end, far away from the feeding hole (101), of the processing box (1).

Technical Field

The invention relates to the field of cloth processing, in particular to a processing method of porous cloth.

Background

In the processing process, the cloth needs to be subjected to printing and dyeing and drying steps and then is wound through a winding frame. Adopt dewatering device to wring out the cloth among the prior art, but the wringing roller among the dewatering device is for fixing in the frame, can't realize the activity from top to bottom, consequently at the dehydration in-process, when dewatering mechanism pulling cloth for the cloth is in the straight dress state of stretching all the time in the pulling in-process, can't take place the buffering to the cloth by the pulling in-process, consequently can influence the toughness of the cloth of producing, and then the cloth damages easily, and porous cloth can not use too big power to destroy the cloth wantonly when going on the exhibition flat.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a method for processing porous cloth.

In order to achieve the purpose, the invention adopts the following technical scheme: a processing method of porous cloth comprises the following steps:

s1, feeding cloth into the processing box through the feed inlet on the roller;

s2, cloth is conveyed into the coloring drum through the conveying mechanism;

s3: coloring the cloth, wherein the cloth is colored on two sides in the coloring cylinder;

s4: dehydrating the cloth, extruding and blowing out excess water in the cloth and absorbing the excess water by the un-colored cloth;

s5: flattening the cloth, namely flattening the two sides of the cloth through a flattening component;

s6: drying and shaping the cloth, and drying and shaping the cloth;

s7, taking out the cloth, and taking out the shaped cloth through a discharge hole for use;

the steps S1-S7 are completed by matching processing equipment of porous cloth, the processing equipment of the porous cloth comprises a processing box, a feeding hole is formed in one side of the processing box, a transmission part is arranged on the rear side of the feeding hole, a dyeing part is arranged below the transmission part in the direction away from the feeding hole, a dewatering part is arranged above the transmission part, a flattening part is arranged above the dewatering part, and a drying and shaping part is arranged on the dyeing part in the direction away from the transmission part.

Preferably, the feed inlet is provided with two supporting plates in the direction away from the conveying part, a rotating column is rotatably arranged between the two supporting plates, a sleeve is fixedly arranged on the outer circumferential surface of the rotating column, and the cloth to be processed is sleeved on the outer circumferential surface of the sleeve.

Preferably, the transmission component includes a first motor, the first motor is fixed outside a side wall of the processing box, the first motor is provided with a first rotating shaft towards the inside of the processing box, the first rotating shaft is rotatably connected to the processing box, a first rotating sleeve is fixedly arranged on the outer circumferential surface in the processing box of the first rotating shaft, a second rotating shaft is arranged towards the direction of the feed inlet of the first rotating shaft, a third rotating shaft is arranged towards the direction of the feed inlet of the second rotating shaft, a fourth rotating shaft is arranged towards the direction of the feed inlet of the third rotating shaft, the second rotating shaft, the third rotating shaft and the fourth rotating shaft are rotatably connected to the processing box, a first transmission belt is connected between the second rotating shaft, the third rotating shaft and the fourth rotating shaft and the first rotating shaft, a second rotating sleeve is fixedly arranged on the outer circumferential surface of the second rotating shaft, a third rotating sleeve is fixedly arranged on the outer circumferential surface of the third rotating shaft, and a fourth rotating sleeve is fixedly arranged on the outer circumferential surface of the fourth rotating shaft.

Preferably, the dyeing part includes the dyeing case, the dyeing case is located the middle bottom of processing case, dyeing case top is rotated and is connected and be equipped with transport mechanism, the last cup group of coloring that is equipped with of transport mechanism, the cup group of coloring contains and is equipped with the drum, the inside middle slip of drum is equipped with the push pedal, the drum is connected with the push pedal and is equipped with first spring, the transport mechanism top is equipped with rotates the post, it rotates to connect on the dyeing case to rotate the post, it is equipped with the rotating sleeve to rotate the post periphery, it is equipped with the pigment chamber to rotate the sleeve periphery, be equipped with discharging channel between pigment chamber and the cloth, the dyeing case has set firmly the recovery board to the feed inlet direction.

Preferably, the dewatering component comprises three dewatering groups, the three dewatering groups are located above the transmission component, each dewatering group comprises a rotating shaft, the rotating shaft is rotatably connected to the processing box, a rotating sleeve is fixedly arranged on the outer circumferential surface of the rotating shaft, a first air cavity is formed in the rotating shaft, six extrusion blocks are uniformly arranged on the rotating sleeve in a circumferential array mode, six sliding plates are arranged in the six extrusion blocks towards the inner direction of the rotating sleeve, six connecting rods are connected between the six sliding plates and the six extrusion blocks, six second springs are arranged on the peripheries of the six connecting rods, the six extrusion blocks, six air outlet channels are arranged between the six sliding plates and the first air cavity, six first air valves are outwards arranged on the six air outlet channels, and a second conveying belt is connected between the three dewatering groups.

Preferably, the flat part of exhibition includes three flat post group, three flat post group is located the dehydration part top, flat post group contains and is equipped with the dwang, the dwang rotates to be connected on the processing case, the dwang periphery has set firmly the dwang cover, the inside second air cavity that is equipped with of dwang, be equipped with first air pump in the middle of the second air cavity, first air pump both sides are equipped with two breathing pipes, first air pump lower end is equipped with the spout, be equipped with first outlet duct between spout and the first air pump, be equipped with two flat groups of exhibition in the spout, flat group of exhibition contains and is equipped with the slider, the slider lower extreme is equipped with the suction block, the suction block lower extreme is equipped with the suction valve, it is equipped with out the air cavity to be connected between suction valve and the second air cavity.

Preferably, stoving design part includes the second motor, the second motor is located a processing incasement lateral wall, the second motor is equipped with the stoving post group to the processing incasement orientation, the stoving post group contains and is equipped with the linkage post, linkage post periphery has set firmly the heat conduction cover, with the steam chamber between linkage post and the second air pump, the linkage post is kept away from second motor orientation and is equipped with the hot plate outward, the hot plate is equipped with the second air pump to the feed inlet orientation, the second air pump is equipped with the second outlet duct to the hot plate orientation, the hot plate orientation is kept away from to the second air pump and is equipped with the intake pipe, the processing case is kept away from feed inlet one end and is equipped with the export.

Has the advantages that:

1. the porous cloth is extruded and discharged through the dewatering component, and the undyed cloth at the lower end is absorbed, so that the cloth can be dewatered quickly, and the undyed cloth is absorbed, so that resources are saved.

2. The porous cloth is sucked by the sucking blocks towards two sides through the flattening component to be flattened, so that the damage of the porous cloth is avoided.

3. The cloth is uniformly heated through the drying and shaping component, so that the cloth is uniformly heated, and the shaping of the cloth is facilitated.

Drawings

The invention is further explained below with reference to the figures and examples:

FIG. 1 is a flow chart of the method of the present invention.

Fig. 2 is a schematic isometric view of the present invention.

Fig. 3 is a schematic top view of the present invention.

Fig. 4 is a schematic sectional view at a-a in fig. 3.

Fig. 5 is a schematic cross-sectional view at B-B in fig. 3.

Fig. 6 is a schematic view of a portion a in fig. 4.

Fig. 7 is a schematic view of a portion B in fig. 4.

Fig. 8 is a schematic view of a portion C in fig. 5.

Fig. 9 is a schematic internal isometric view of the present invention.

In the figure, a processing box 1, a conveying part 2, a dyeing part 3, a dewatering part 4, a flattening part 5, a drying and shaping part 6, a feed inlet 101, a sleeve 102, a rotary column 103, a support plate 104, a first motor 201, a first rotary shaft 202, a first rotary sleeve 203, a second rotary shaft 204, a third rotary shaft 205, a fourth rotary shaft 206, a first conveyor belt 207, a second rotary sleeve 208, a third rotary sleeve 209, a fourth rotary sleeve 210, a dyeing box 301, a conveying mechanism 302, a coloring cup 303, a cylinder 304, a push plate 305, a first spring 306, a rotary column 307, a rotary sleeve 308, a pigment cavity 309, a discharge channel 310, a recovery plate 311, a dewatering group 401, a rotary shaft 402, a first air cavity 403, a rotary sleeve 404, a squeezing block 405, a connecting rod air cavity 406, a sliding plate 407, a second spring 408, an air outlet channel 409, a first air valve 410, a second conveyor belt 411, a column flattening group 501, a rotary rod 502, a rotary rod sleeve 503, a second air cavity 504, a sleeve 404, a rotary rod air cavity 504, a rotary rod air cavity, The device comprises a first air pump 505, an air suction pipe 506, a first air outlet pipe 507, a sliding groove 508, a flattening group 509, a sliding block 510, an air suction block 211, an air suction valve 512, an air outlet cavity 513, a second motor 601, a drying column group 602, a heat conducting sleeve 603, a linkage column 604, a second air pump 605, an air inlet pipe 606, a second air outlet pipe 607, a heating plate 608 and an outlet 609.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

With reference to fig. 1, 2 and 4, a method for processing porous cloth includes the following steps:

s1, feeding cloth into the processing box through the feed inlet on the roller;

s2, cloth is conveyed into the coloring drum through the conveying mechanism;

s3: coloring the cloth, wherein the cloth is colored on two sides in the coloring cylinder;

s4: dehydrating the cloth, extruding and blowing out excess water in the cloth and absorbing the excess water by the un-colored cloth;

s5: flattening the cloth, namely flattening the two sides of the cloth through a flattening component;

s6: drying and shaping the cloth, and drying and shaping the cloth;

s7, taking out the cloth, and taking out the shaped cloth through a discharge hole for use;

the steps S1-S7 are completed by matching processing equipment of porous cloth, the processing equipment of the porous cloth comprises a processing box 1, a feeding hole 101 is formed in one side of the processing box 1, a transmission part 2 is arranged on the rear side of the feeding hole 101, a dyeing part 3 is arranged below the transmission part 2 in the direction away from the feeding hole 101, a dewatering part 4 is arranged above the transmission part 2, a flattening part 5 is arranged above the dewatering part 4, and a drying and shaping part 6 is arranged on the dyeing part 3 in the direction away from the transmission part 2.

Further, referring to fig. 4, the feeding port 101 is provided with two supporting plates 104 in a direction away from the conveying member 2, a rotating column 103 is rotatably provided between the two supporting plates 104, a sleeve 102 is fixedly provided on an outer circumferential surface of the rotating column 103, and a cloth to be processed is sleeved on an outer circumferential surface of the sleeve 102.

Further, referring to fig. 4 and 9, the transmission component 2 includes a first motor 201, the first motor 201 is fixed outside a sidewall of the processing box, the first motor 201 is provided with a first rotating shaft 202 towards the interior of the processing box 1, the first rotating shaft 202 is rotatably connected to the processing box 1, the first rotating shaft 202 is fixedly provided with a first rotating sleeve 203 on the outer circumferential surface of the processing box 1, the first rotating shaft 202 is provided with a second rotating shaft 204 towards the feeding port 101, the second rotating shaft 204 is provided with a third rotating shaft 205 towards the feeding port 101, the third rotating shaft 205 is provided with a fourth rotating shaft 206 towards the feeding port 101, the second rotating shaft 204, the third rotating shaft 205 and the fourth rotating shaft 206 are rotatably connected to the processing box 1, a first conveying belt 207 is connected between the second rotating shaft 204, the third rotating shaft 205, the fourth rotating shaft 206 and the first rotating shaft 202, a second rotating sleeve 208 is fixedly provided on the outer circumferential surface of the second rotating shaft 204, a third rotating sleeve 209 is fixedly provided on the outer circumferential surface of the third rotating shaft 205, a fourth rotating sleeve 210 is fixedly arranged on the outer circumferential surface of the fourth rotating shaft 206.

Further, with reference to fig. 4 and 6, the dyeing part 3 includes a dyeing box 301, the dyeing box 301 is located at the middle bottom of the processing box 1, a conveying mechanism 302 is rotatably connected to the upper side of the dyeing box 301, a coloring cup set 303 is arranged on the conveying mechanism 302, the coloring cup set 303 includes a cylinder 304, a push plate 305 is slidably arranged in the middle of the inner portion of the cylinder 304, the cylinder 304 is connected with the push plate 305 and provided with a first spring 306, a rotating column 307 is arranged above the conveying mechanism 302, the rotating column 307 is rotatably connected to the dyeing box 301, a rotating sleeve 308 is arranged on the periphery of the rotating column 307, a pigment cavity 309 is arranged on the periphery of the rotating sleeve 308, a discharge channel 310 is arranged between the pigment cavity 309 and the cloth, and a recovery plate 311 is fixedly arranged on the dyeing box 301 in the direction of the feed inlet 101.

Further, referring to fig. 4, 7 and 9, the dewatering component 4 includes three dewatering groups 401, the three dewatering groups 401 are located above the transmission component 2, the dewatering groups 401 include a rotating shaft 402, the rotating shaft 402 is rotatably connected to the processing box 1, a rotating sleeve 404 is fixedly disposed on the outer circumferential surface of the rotating shaft 402, a first air cavity 403 is disposed inside the rotating shaft 402, six squeezing blocks 405 are uniformly disposed on the rotating sleeve 404 in a circumferential array, six sliding plates 407 are disposed on the six squeezing blocks 405 in the direction toward the inside of the rotating sleeve 404, six connecting rods 406 are connected between the six sliding plates 407 and the six squeezing blocks 405, six second springs 408 and six connecting rods 406 are disposed on the peripheries of the six connecting rods 406, six air outlet channels 409 are arranged among the six extrusion blocks 405, the six sliding plates 407 and the first air cavity 403, six first air valves 410 are outwards arranged on the six air outlet channels 409, and a second conveyor belt 411 is connected among the three dewatering groups 401.

Further, combine fig. 4, 5, 8, flat part 5 includes three flat column group 501 that appears, three flat column group 501 is located dehydration part 4 top, flat column group 501 contains and is equipped with dwang 502, dwang 502 rotates to be connected on processing case 1, dwang 502 periphery has set firmly dwang cover 503, dwang 502 is inside to be equipped with second air cavity 504, be equipped with first air pump 505 in the middle of second air cavity 504, first air pump 505 both sides are equipped with two breathing pipes 506, first air pump 505 lower extreme is equipped with spout 508, be equipped with first outlet duct 507 between spout 508 and the first air pump 505, be equipped with two flat group in the spout 508, flat group 509 contains and is equipped with slider 510, slider 510 lower extreme is equipped with suction block 211, suction block 211 lower extreme 512 is equipped with suction valve 512, it is equipped with air outlet chamber 513 to connect between suction valve 509 and the second air cavity 504.

Further, with reference to fig. 4 and 9, the drying and shaping component 6 includes a second motor 601, the second motor 601 is located on a side wall of the processing box 1, the second motor 601 is provided with a drying column group 602 toward the interior of the processing box 1, the drying column group 602 includes a linkage column 604, a heat conduction sleeve 603 is fixedly provided on the periphery of the linkage column 604, a hot air cavity is provided between the linkage column 604 and the second air pump 605, a heating plate 608 is provided outside the linkage column 604 away from the second motor 601, the heating plate 608 is provided with a second air pump 605 toward the feed inlet 101, the second air pump 605 is provided with a second air outlet 607 toward the heating plate 608, the second air pump 605 is provided with an air inlet pipe 606 away from the heating plate 608, and an outlet 609 is provided at an end of the processing box 1 away from the feed inlet 101.

Principle of operation

S1, the cloth is put in, and the staff puts the colorless porous cloth on the sleeve 102 into the processing box 1 through the feed inlet 101.

S2, the cloth is conveyed, the colorless porous cloth is placed on a fourth rotating sleeve 210, a first motor 201 is started to drive a first rotating shaft 202, a second rotating shaft 204, a third rotating shaft 205 and a fourth rotating shaft 206 to rotate through a first conveying belt 207, the first rotating shaft 202, the second rotating shaft 204, the third rotating shaft 205 and the fourth rotating shaft 206 respectively drive a first rotating sleeve 203, a second rotating sleeve 208, a third rotating sleeve 209 and the fourth rotating sleeve 210 to rotate, and the colorless porous cloth is conveyed towards the dyeing part 3.

S3: the cloth is colored, the colourless porous cloth enters into dyeing case 301 in, colourless porous cloth rotates round rotating sleeve 308, the outside dyestuff of colourless porous cloth in dyeing case 301 is colored rethread transport mechanism 302 and is colored the cup 303 cooperation and carry out the secondary to colourless porous cloth outside and color, transport mechanism 302 drives and goes up color cup 303 and remove, color cup 303 packs into the dyestuff when the lower extreme into and removes to the top horizontality on first spring 306 promotion push pedal 305 in the color cup 303 spills the dyestuff to colourless porous cloth, pigment chamber 309 in the rotating sleeve 308, color through discharging channel 310 to colourless porous cloth inside, carry out two sides and evenly color in the colourless porous cloth.

S4: cloth dehydration, porous cloth reaches the 4 lower extremes of dehydration unit, porous cloth upper end is that the lower extreme of dehydration group 401 is colourless porous cloth, porous cloth is popped out by second spring 408 by extrusion piece 405 and extrudees porous cloth and extrude rethread air outlet channel 409 and first air valve 410 cooperation and air-dry porous cloth, it absorbs unnecessary dyestuff on the porous cloth to combine colourless porous cloth at last, extrude the dyestuff that drops and enter into dyeing box 301 through retrieving board 311 in, porous cloth dehydration is accomplished and is driven axis of rotation 402 through second conveyer belt 411 and rotate and enter into in the exhibition flat part 5.

S5: the cloth is flattened, the first air pump 505 starts to suck air from two sides and discharge air from the lower end to match with the flattening group 509, the porous cloth is firstly slightly sucked by the suction valves 512 on the two suction blocks 211 in the middle, the downward air blows off the two sliders 510 in the sliding grooves 508 towards two sides, the two sliders 510 drive the two suction blocks 211 to slide on two sides to flatten the porous cloth, and the porous cloth cannot be flattened by using the slight suction force due to too large force.

S6: drying and shaping the cloth, wherein the porous cloth enters the drying and shaping component 6, the second air pump 605 sucks air through the air inlet pipe 606 and then exhausts the air in the direction of the heating plate 608 through the second air outlet pipe 607, the heating plate 608 heats the air, hot air enters the air cavity in the heat conducting sleeve 603 to heat the heat conducting sleeve 603, the porous cloth on the heat conducting sleeve 603 is dried, and the second motor 601 is started to rotate and dry the porous cloth;

s7, taking out the cloth, and taking out the porous cloth through an outlet 609 for use.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.