CN114872434B - Negative pressure infiltration process and equipment for plane printing - Google Patents

Abstract

The invention discloses a negative pressure infiltration process for plane printing and equipment thereof, and belongs to the technical field of plane printing, wherein the processing box is placed on a horizontal plane, the heat transfer equipment is arranged at the top of the processing box, the infiltration equipment is arranged in the processing box and below the heat transfer equipment, and the conveying equipment is fixedly arranged on the side wall of the processing box; according to the invention, the thermal transfer printing equipment is used for carrying out thermal transfer printing on the stained paper and the cloth, and the infiltration equipment is used for carrying out negative pressure on the bottom of the cloth, so that the infiltration degree of the dye on the cloth is improved, and the dye on the cloth is more uniform.

Description

Negative pressure infiltration process and equipment for plane printing

Technical Field

The invention relates to the technical field of plane printing, in particular to a negative pressure infiltration process for plane printing and equipment thereof.

Background

The heat transfer printing machine is a general name of machines used in the heat transfer printing technology, the heat transfer printing machine comprises a plane pyrograph machine, a high-pressure pyrograph machine, a shaking pyrograph machine, a cup baking machine, a baking tray machine, a cap baking machine and other heat transfer printing machines, the printing range is wide, the heat transfer printing machine comprises the plane pyrograph and the curved surface pyrograph such as a cup, a plate and a cap, the heat transfer printing is a new technology, the user just steps into the right rail, and the heat transfer printing machine is widely applied to the printing of the surface of clothing along with the continuous development of the scientific technology.

However, the existing thermal printing has the following problems: when the existing thermal printing is used for hot-pressing the patterns onto the cloth, the phenomena of incomplete printing patterns on the cloth and the like can be caused due to low permeability of dye, so that the attractiveness of the cloth patterns is directly affected.

Disclosure of Invention

The embodiment of the invention provides a negative pressure infiltration process for planar printing and equipment thereof, which are used for solving the technical problems.

The embodiment of the invention adopts the following technical scheme: a negative pressure infiltration process for flat printing, comprising the following infiltration process steps:

the first step: an operator places cloth on a plurality of conveying rollers, then a driving disc is driven by a conveying motor to rotate, and a driving belt is driven by the rotation of the driving disc to rotate two rotating discs and the plurality of conveying rollers, so that the cloth can be moved to a placing plate through the plurality of conveying rollers, and the cloth feeding operation is completed;

and a second step of: when the cloth is moved to the placing plate, the transfer belt moves the stained paper to the upper part of the cloth, then the pattern on the stained paper is printed on the cloth through the thermal transfer printing equipment, and when the thermal transfer printing equipment works, the permeation equipment carries out negative pressure on the dye on the cloth through a plurality of through holes below the placing plate, so that the permeation degree of the dye on the cloth is improved, and after the transfer printing is finished, the cloth can be moved out through the conveying belts on the two sides of the placing plate, so that the work is finished;

and a third step of: when the pattern on the stained paper is required to be transferred onto the cloth, the heating plate is driven to move and press downwards by the driving cylinder, and the dye on the stained paper is thermally pressed onto the cloth to complete the thermal transfer work;

fourth step: when the pattern on the stained paper is hot-pressed to the cloth by the heat transfer printing equipment, the driving motor drives the screw rod to rotate, the screw rod rotates to drive the movable plate to move, the movable plate moves to drive the clamping rods on the two groups of movable pieces to move, the clamping rods move to enable the adjusting block to move on the sliding groove, the groove on the adjusting block is abutted against the clamping block on the side wall of the processing box in the moving process, so that the adjusting block can turn over in the moving process, the clamping rods can be driven to rotate by the turning over of the adjusting block, the air suction pipe can be driven to rotate by the rotation of the clamping rods, a plurality of suction nozzles facing downwards are upwards arranged and are contacted with the bottom of the placing plate, so that dye in the hot transfer printing equipment can be attached to the cloth when the thermal transfer printing is carried out on the stained paper and the cloth, the penetration degree of the dye on the suction nozzle is improved, and after the cloth transfer printing is finished, the suction nozzle of the suction pipe is contacted with the bottom plate downwards, dust can be effectively prevented from entering the bottom plate, and normal processing operation is affected.

Further, including processing case, heat transfer device, infiltration equipment and conveying equipment, processing case is placed on the horizontal plane, heat transfer device sets up at the top of processing case, infiltration equipment sets up in processing incasement and is located heat transfer device's below, conveying equipment is fixed to be set up on the lateral wall of processing case.

Further, the heat transfer printing equipment comprises a mounting shell, a driving electric cylinder and a heating plate, wherein the mounting shell is fixedly arranged at the top of the processing box, the driving electric cylinder is arranged at the inner top of the mounting shell, and the heating plate is arranged at the telescopic end of the driving electric cylinder and is in sliding fit with the mounting shell.

Further, infiltration equipment includes driving motor, lead screw, movable plate, bottom plate, breathing pipe and two sets of moving parts, driving motor sets up on the inside wall of processing case, the lead screw sets up on driving motor's main shaft and with driving motor's main shaft transmission cooperation, the movable plate sets up on the inside wall of processing case and with the inside wall sliding fit of processing case, movable plate and lead screw thread fit, the bottom plate is fixed to be set up in the interior bottom of processing case, two sets of moving part symmetry sets up on the inside wall of processing case and with the inside wall sliding fit of processing case, the breathing pipe is connected with two sets of moving parts, still be equipped with a plurality of suction nozzles on the breathing pipe.

Further, two sets of moving parts all include clamping rod and regulating block, the clamping rod rotates and sets up on the movable plate, regulating block and clamping rod fixed connection, the inside wall of processing case is equipped with the sliding tray with regulating block sliding fit, the regulating block setting just with the sliding tray sliding fit of processing case inside wall on the inside wall of processing case, be equipped with three recess on the regulating block, be equipped with the fixture block that contradicts with three recess on the inside wall of processing case, the both ends of breathing pipe are connected with the clamping rod on two sets of moving parts.

Further, the top of processing case still is equipped with places the board, place and be equipped with a plurality of through-holes on the board, place the board and be located between thermal transfer equipment and the infiltration equipment, the both sides of placing the board still are equipped with two sets of conveyer belts, two sets of conveyer belt symmetry sets up on the processing case, still be equipped with the conveyer belt on the lateral wall of processing case.

Further, conveying equipment includes installation curb plate, conveying motor, driving disk, driving belt, two rolling discs, a plurality of driving discs and a plurality of conveying rollers, the fixed setting of installation curb plate is on the lateral wall of processing case, conveying motor sets up on the lateral wall of installation curb plate, the driving disc sets up on conveying motor's main shaft and with conveying motor's main shaft transmission cooperation, two the rolling disc rotates and sets up on the installation curb plate, and a plurality of driving discs equidistant rotation sets up on the installation lateral wall, and a plurality of conveying rollers are connected and rotate the cooperation with the installation curb plate respectively with a plurality of driving discs, driving belt cover is established on driving disk, two rolling discs and a plurality of driving discs.

The above at least one technical scheme adopted by the embodiment of the invention can achieve the following beneficial effects:

firstly, the invention carries out heat transfer printing on stained paper and cloth through the heat transfer printing equipment and simultaneously carries out negative pressure on the bottom of the cloth through the infiltration equipment, thereby improving the infiltration degree of dye on the cloth and leading the dye on the cloth to be more uniform.

Secondly, when the pattern on the stained paper is required to be transferred to the cloth, the heating plate is driven to move and press downwards by the driving electric cylinder, and the dye on the stained paper is thermally pressed to the cloth to finish the thermal transfer work.

Thirdly, when the thermal transfer printing equipment carries out pattern hot pressing on stained paper to cloth, driving motor drives the lead screw to rotate, the lead screw rotates to drive the movable plate to move, the movable plate moves to drive clamping rods on two groups of movable pieces to move, the clamping rods move to enable the regulating block to move on the sliding groove, the groove on the regulating block can be abutted against the clamping block on the side wall of the processing box in the moving process, so that the regulating block can overturn in the moving process, the regulating block overturns to drive the clamping rods to rotate, the clamping rods rotate to drive the air suction pipe to rotate, the air suction pipe rotates to enable a plurality of suction nozzles facing downwards to be upwards arranged and contact with the bottom of the placing plate, so that dye in the hot transfer printing equipment is attached to the cloth in the hot transfer printing process, the penetration degree of the dye on the suction nozzle is improved, after the cloth transfer printing is completed, the air suction pipe can be effectively prevented from contacting the bottom plate downwards, and normal processing operation of dust can be effectively prevented.

Fourth, when the cloth moves to place on the board, the conveyer belt moves the stained paper to the top of cloth, later through thermal transfer equipment with the pattern seal on the stained paper on the cloth, when thermal transfer equipment works, infiltration equipment then carries out the negative pressure to the dyestuff on the cloth through a plurality of through-holes of placing the board below to improved the degree that the dyestuff permeated on the cloth, accessible place the conveyer belt of board both sides after accomplishing the rendition and shift out the cloth, accomplish work.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention. In the drawings:

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

FIG. 2 is a partial perspective view of the present invention;

FIG. 3 is a partial perspective sectional view of a thermal transfer device of the present invention;

FIG. 4 is a partial perspective view of the present invention;

FIG. 5 is a schematic perspective view of a permeation device according to the present invention;

fig. 6 is a schematic perspective view of the conveying apparatus of the present invention.

Reference numerals

The processing box 1, the slide groove 11, the cartridge 12, the thermal transfer device 2, the mounting case 21, the driving cylinder 22, the heating plate 23, the penetrating device 3, the driving motor 31, the screw rod 32, the moving plate 33, the bottom plate 34, the suction pipe 35, the suction nozzle 351, the moving member 36, the cartridge 361, the adjusting block 362, the recess 363, the placing plate 4, the through hole 41, the conveyor belt 42, the conveyor belt 5, the conveying device 6, the mounting side plate 61, the conveying motor 62, the driving plate 63, the driving belt 64, the rotating plate 65, the driving plate 66, and the conveying roller 67.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to specific embodiments of the present invention and corresponding drawings. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The following describes in detail the technical solutions provided by the embodiments of the present invention with reference to the accompanying drawings.

Referring to fig. 1-6, an embodiment of the present invention provides a negative pressure infiltration process for flat printing, comprising the following infiltration process steps:

the first step: an operator places cloth on a plurality of conveying rollers 67, then a conveying motor 62 drives a driving disc 63 to rotate, the driving disc 63 rotates to drive a driving belt 64 to enable two rotating discs 65 and the plurality of conveying rollers 67 to rotate, and the cloth can be moved onto a placing plate 4 through the plurality of conveying rollers 67, so that cloth feeding operation is completed;

and a second step of: when the cloth is moved onto the placement plate 4, the transfer belt 5 moves the stained paper to the upper part of the cloth, then the pattern on the stained paper is printed on the cloth through the thermal transfer printing equipment 2, and when the thermal transfer printing equipment 2 works, the permeation equipment 3 carries out negative pressure on the dye on the cloth through the plurality of through holes 41 below the placement plate 4, so that the permeation degree of the dye on the cloth is improved, and when the transfer printing is finished, the cloth can be moved out through the transfer belts 42 on the two sides of the placement plate 4, so that the work is finished;

and a third step of: when the pattern on the stained paper is required to be transferred onto the cloth, the heating plate 23 is driven to move and press downwards by the driving cylinder 22, and the dye on the stained paper is thermally pressed onto the cloth to complete the thermal transfer work;

fourth step: when the thermal transfer printing device 2 thermally presses the pattern on the stained paper onto the cloth, the driving motor 31 drives the screw rod 32 to rotate, the screw rod 32 rotates to drive the movable plate 33 to move, the movable plate 33 moves to drive the clamping rods 361 on the two groups of movable pieces 36 to move, the clamping rods 361 move to enable the adjusting block 362 to move on the sliding groove 11, the grooves 363 on the adjusting block 362 are in contact with the clamping blocks 12 on the side wall of the processing box 1 in the moving process, so that the adjusting block 362 overturns in the moving process, the adjusting block 362 overturns to drive the clamping rods 361 to rotate, the clamping rods 361 rotates to drive the air suction pipe 35 to rotate, the air suction pipe 35 rotates to enable the plurality of suction nozzles 351 facing downwards to be upwards arranged to be in contact with the bottom of the placing plate 4, so that when the thermal transfer printing device 2 thermally transfers the stained paper and the cloth, the dye in the thermal transfer printing device is attached to the cloth at the bottom of the cloth, the dye in the thermal transfer printing device is enabled to be absorbed on the cloth, and the penetration degree of the dye on the cloth is improved, after the cloth is transferred, the suction nozzles 351 of the air suction pipe 35 can be downwards contacted with the bottom plate 34, and the suction nozzles 351 can be effectively prevented from entering into the suction nozzles 351 to the normal processing operation.

Preferably, the device comprises a processing box 1, a thermal transfer device 2, a penetrating device 3 and a conveying device 6, wherein the processing box 1 is placed on a horizontal plane, the thermal transfer device 2 is arranged at the top of the processing box 1, the penetrating device 3 is arranged in the processing box 1 and below the thermal transfer device 2, and the conveying device 6 is fixedly arranged on the side wall of the processing box 1; according to the invention, the thermal transfer printing equipment 2 is used for carrying out thermal transfer printing on the stained paper and the cloth, and the infiltration equipment 3 is used for carrying out negative pressure on the bottom of the cloth, so that the infiltration degree of the dye on the cloth is improved, and the dye on the cloth is more uniform.

Preferably, the thermal transfer device 2 comprises a mounting housing 21, a driving electric cylinder 22 and a heating plate 23, wherein the mounting housing 21 is fixedly arranged at the top of the processing box 1, the driving electric cylinder 22 is arranged at the inner top of the mounting housing 21, and the heating plate 23 is arranged on the telescopic end of the driving electric cylinder 22 and is in sliding fit with the mounting housing 21; when the pattern on the stained paper is required to be transferred to the cloth, the heating plate 23 is driven to move and press downwards by the driving cylinder 22, and the dye on the stained paper is hot-pressed to the cloth to complete the heat transfer work.

Preferably, the infiltration device 3 comprises a driving motor 31, a screw rod 32, a moving plate 33, a bottom plate 34, an air suction pipe 35 and two groups of moving pieces 36, wherein the driving motor 31 is arranged on the inner side wall of the processing box 1, the screw rod 32 is arranged on a main shaft of the driving motor 31 and is in transmission fit with the main shaft of the driving motor 31, the moving plate 33 is arranged on the inner side wall of the processing box 1 and is in sliding fit with the inner side wall of the processing box 1, the moving plate 33 is in threaded fit with the screw rod 32, the bottom plate 34 is fixedly arranged at the inner bottom of the processing box 1, the two groups of moving pieces 36 are symmetrically arranged on the inner side wall of the processing box 1 and are in sliding fit with the inner side wall of the processing box 1, the air suction pipe 35 is connected with the two groups of moving pieces 36, and a plurality of suction nozzles 351 are further arranged on the air suction pipe 35; when the thermal transfer printing device 2 thermally presses the pattern on the stained paper onto the cloth, the driving motor 31 drives the screw rod 32 to rotate, the screw rod 32 rotates to drive the movable plate 33 to move, the movable plate 33 moves to drive the clamping rods 361 on the two groups of movable pieces 36 to move, the clamping rods 361 move to enable the adjusting block 362 to move on the sliding groove 11, the grooves 363 on the adjusting block 362 are in contact with the clamping blocks 12 on the side wall of the processing box 1 in the moving process, so that the adjusting block 362 overturns in the moving process, the adjusting block 362 overturns to drive the clamping rods 361 to rotate, the clamping rods 361 rotates to drive the air suction pipe 35 to rotate, the air suction pipe 35 rotates to enable the plurality of suction nozzles 351 facing downwards to be upwards arranged to be in contact with the bottom of the placing plate 4, so that when the thermal transfer printing device 2 thermally transfers the stained paper and the cloth, the dye in the thermal transfer printing device is attached to the cloth at the bottom of the cloth, the dye in the thermal transfer printing device is enabled to be absorbed on the cloth, and the penetration degree of the dye on the cloth is improved, after the cloth is transferred, the suction nozzles 351 of the air suction pipe 35 can be downwards contacted with the bottom plate 34, and the suction nozzles 351 can be effectively prevented from entering into the suction nozzles 351 to the normal processing operation.

Preferably, the two groups of moving members 36 each comprise a clamping rod 361 and an adjusting block 362, the clamping rods 361 are rotatably arranged on the moving plate 33, the adjusting blocks 362 are fixedly connected with the clamping rods 361, the inner side wall of the processing box 1 is provided with a sliding groove 11 in sliding fit with the adjusting blocks 362, the adjusting blocks 362 are arranged on the inner side wall of the processing box 1 and are in sliding fit with the sliding groove 11 on the inner side wall of the processing box 1, three grooves 363 are arranged on the adjusting blocks 362, clamping blocks 12 which are in contact with the three grooves 363 are arranged on the inner side wall of the processing box 1, two ends of the air suction pipe 35 are connected with the clamping rods 361 on the two groups of moving members 36, the top of the processing box 1 is also provided with a placing plate 4, the placing plate 4 is provided with a plurality of through holes 41, the placing plate 4 is positioned between the heat transfer printing equipment 2 and the penetrating equipment 3, two groups of conveying belts 42 are also arranged on two sides of the placing plate 4, the two groups of conveying belts 42 are symmetrically arranged on the processing box 1, and the conveying belt 5 is also arranged on the outer side wall of the processing box 1; when the cloth moves to place on the board 4, the conveyer belt 5 moves stained paper to the top of cloth, later prints the pattern on the stained paper on the cloth through thermal transfer equipment 2, and when thermal transfer equipment 2 works, infiltration equipment 3 then carries out the negative pressure to the dyestuff on the cloth through a plurality of through-holes 41 of placing the board 4 below to improve the degree that the dyestuff permeated on the cloth, accessible place the conveyer belt 42 of board 4 both sides after accomplishing the rendition and shift out the cloth, accomplish work.

Preferably, the conveying device 6 comprises a mounting side plate 61, a conveying motor 62, a driving plate 63, a driving belt 64, two rotating plates 65, a plurality of transmission plates 66 and a plurality of conveying rollers 67, wherein the mounting side plate 61 is fixedly arranged on the outer side wall of the processing box 1, the conveying motor 62 is arranged on the side wall of the mounting side plate 61, the driving plate 63 is arranged on a main shaft of the conveying motor 62 and is in transmission fit with the main shaft of the conveying motor 62, the two rotating plates 65 are rotatably arranged on the mounting side plate 61, the plurality of transmission plates 66 are rotatably arranged on the mounting side wall at equal intervals, the plurality of conveying rollers 67 are respectively connected with the plurality of transmission plates 66 and are in rotation fit with the mounting side plate 61, and the driving belt 64 is sleeved on the driving plate 63, the two rotating plates 65 and the plurality of transmission plates 66; the operator places the cloth on a plurality of conveying rollers 67, and then the conveying motor 62 drives the driving disc 63 to rotate, and the driving disc 63 rotates to drive the driving belt 64 to enable the two rotating discs 65 and the plurality of conveying rollers 67 to rotate, and the cloth can be moved onto the placing plate 4 through the plurality of conveying rollers 67, so that the cloth feeding operation is completed.

The foregoing is merely exemplary of the present invention and is not intended to limit the present invention. Various modifications and variations of the present invention will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the invention are to be included in the scope of the claims of the present invention.

Claims (7)

1. A negative pressure infiltration process for flat printing, characterized by comprising the following infiltration process steps:

the first step: an operator places cloth on a plurality of conveying rollers (67), then a conveying motor (62) drives a driving disc (63) to rotate, the driving disc (63) rotates to drive a driving belt (64) to enable two rotating discs (65) and the plurality of conveying rollers (67) to rotate, and the cloth can be moved onto a placing plate (4) through the plurality of conveying rollers (67), so that cloth feeding operation is completed;

and a second step of: when the cloth is moved onto the placing plate (4), the transfer belt (5) moves the stained paper to the upper part of the cloth, then the pattern on the stained paper is printed on the cloth through the thermal transfer printing equipment (2), and when the thermal transfer printing equipment (2) works, the permeation equipment (3) carries out negative pressure on the dye on the cloth through a plurality of through holes (41) below the placing plate (4), so that the permeation degree of the dye on the cloth is improved, and after the transfer printing is finished, the cloth can be moved out through the conveying belts (42) on two sides of the placing plate (4), so that the work is finished;

and a third step of: when the pattern on the stained paper is required to be transferred onto the cloth, the heating plate (23) is driven to move and press downwards by the driving cylinder (22), and the dye on the stained paper is thermally pressed onto the cloth to complete the thermal transfer work;

fourth step: when the thermal transfer printing equipment (2) thermally presses patterns on stained paper onto cloth, the driving motor (31) drives the screw rod (32) to rotate, the screw rod (32) rotates to drive the movable plate (33) to move, the movable plate (33) moves to drive the clamping rods (361) on the two groups of movable pieces (36) to move, the clamping rods (361) move to enable the regulating block (362) to move on the sliding groove (11), the upper groove (363) of the regulating block (362) is abutted against the clamping blocks (12) on the side wall of the processing box (1) in the moving process, so that the regulating block (362) is overturned in the moving process, the regulating block (362) can drive the clamping rods (361) to rotate, the clamping rods (361) can drive the air suction pipe (35) to rotate, the air suction pipe (35) rotates to enable the plurality of suction nozzles (351) facing downwards to be upwards arranged to be contacted with the bottom of the placing plate (4), the bottom of the cloth is subjected to negative pressure in the thermal transfer printing equipment (2) when the stained paper and the cloth are thermally transferred, the dye in the thermal transfer printing process is attached to the bottom of the cloth, so that the dye in the thermal transfer printing equipment can be effectively prevented from penetrating into the cloth (351) to the bottom plate (35) after the dye is contacted with the suction pipe (351) in the moving process, affecting the normal machining operation of the suction nozzle (351).

2. An apparatus for a negative pressure infiltration process for flat printing as claimed in claim 1, characterized by comprising a processing tank (1), a thermal transfer apparatus (2), an infiltration apparatus (3) and a conveying apparatus (6), wherein the processing tank (1) is placed on a horizontal plane, the thermal transfer apparatus (2) is arranged at the top of the processing tank (1), the infiltration apparatus (3) is arranged in the processing tank (1) and below the thermal transfer apparatus (2), and the conveying apparatus (6) is fixedly arranged on the side wall of the processing tank (1).

3. The apparatus according to claim 2, characterized in that the thermal transfer apparatus (2) comprises a mounting housing (21), a driving cylinder (22) and a heating plate (23), the mounting housing (21) is fixedly arranged at the top of the processing box (1), the driving cylinder (22) is arranged at the inner top of the mounting housing (21), and the heating plate (23) is arranged on the telescopic end of the driving cylinder (22) and is in sliding fit with the mounting housing (21).

4. The device according to claim 2, characterized in that the infiltration device (3) comprises a driving motor (31), a screw rod (32), a moving plate (33), a bottom plate (34), an air suction pipe (35) and two groups of moving pieces (36), wherein the driving motor (31) is arranged on the inner side wall of the processing box (1), the screw rod (32) is arranged on a main shaft of the driving motor (31) and is in transmission fit with the main shaft of the driving motor (31), the moving plate (33) is arranged on the inner side wall of the processing box (1) and is in sliding fit with the inner side wall of the processing box (1), the moving plate (33) is in threaded fit with the screw rod (32), the bottom plate (34) is fixedly arranged at the inner bottom of the processing box (1), the two groups of moving pieces (36) are symmetrically arranged on the inner side wall of the processing box (1) and are in sliding fit with the inner side wall of the processing box (1), the air suction pipe (35) is connected with the two groups of moving pieces (36), and a plurality of suction nozzles (351) are also arranged on the air suction pipe (35).

5. The device according to claim 4, wherein the two groups of moving members (36) each comprise a clamping rod (361) and an adjusting block (362), the clamping rods (361) are rotatably arranged on the moving plates (33), the adjusting blocks (362) are fixedly connected with the clamping rods (361), sliding grooves (11) which are in sliding fit with the adjusting blocks (362) are formed in the inner side walls of the processing box (1), the adjusting blocks (362) are arranged on the inner side walls of the processing box (1) and are in sliding fit with the sliding grooves (11) in the inner side walls of the processing box (1), three grooves (363) are formed in the adjusting blocks (362), clamping blocks (12) which are in interference with the three grooves (363) are formed in the inner side walls of the processing box (1), and two ends of the air suction pipe (35) are connected with the clamping rods (361) on the two groups of moving members (36).

6. The device according to claim 2, characterized in that the top of the processing box (1) is further provided with a placement plate (4), the placement plate (4) is provided with a plurality of through holes (41), the placement plate (4) is located between the thermal transfer printing device (2) and the infiltration device (3), two groups of conveying belts (42) are further arranged on two sides of the placement plate (4), the two groups of conveying belts (42) are symmetrically arranged on the processing box (1), and the outer side wall of the processing box (1) is further provided with a conveying belt (5).

7. The apparatus according to claim 2, wherein the conveying apparatus (6) comprises a mounting side plate (61), a conveying motor (62), a driving plate (63), a driving belt (64), two rotating plates (65), a plurality of transmission plates (66) and a plurality of conveying rollers (67), the mounting side plate (61) is fixedly arranged on the outer side wall of the processing box (1), the conveying motor (62) is arranged on the side wall of the mounting side plate (61), the driving plate (63) is arranged on a main shaft of the conveying motor (62) and is in transmission fit with the main shaft of the conveying motor (62), two rotating plates (65) are rotatably arranged on the mounting side plate (61), a plurality of transmission plates (66) are rotatably arranged on the mounting side wall at equal intervals, a plurality of conveying rollers (67) are respectively connected with the plurality of transmission plates (66) and are rotatably fit with the mounting side plate (61), and the driving belt (64) is sleeved on the driving plate (63), the two rotating plates (65) and the plurality of transmission plates (66).