CN116752304A

CN116752304A - High-precision printing and dyeing device for textiles

Info

Publication number: CN116752304A
Application number: CN202310586819.XA
Authority: CN
Inventors: 黄文广
Original assignee: Anhui Topology Digital New Material Co ltd
Current assignee: Anhui Topology Digital New Material Co ltd
Priority date: 2023-05-19
Filing date: 2023-05-19
Publication date: 2023-09-15

Abstract

The invention relates to the technical field of textile processing equipment and discloses a high-precision printing and dyeing device for textiles, which comprises a shell, wherein a first guide roller, a first winding roller, a second winding roller and a second guide roller are sequentially arranged in the shell from left to right, a dust removing assembly is arranged between the first guide roller and the first winding roller, a deviation preventing structure is arranged on the right side of the second guide roller, a support is fixedly connected on the right side of the shell, a belt conveyor is arranged on the upper portion of the support, a connecting frame is fixedly connected on the upper surface of the support, connecting rods are fixedly connected on the lower surface of the top of the connecting frame at equal intervals, and printing and dyeing cylinders are rotatably connected at the lower ends of the connecting rods. Through setting up and preventing off tracking structure, when the fabrics take place off tracking, can control fabrics reverse movement and reset, be convenient for follow-up accurate printing and dyeing, avoid printing and dyeing dislocation and make whole fabrics damage, and off tracking problem equipment can solve by oneself, need not shut down artificial reset.

Description

High-precision printing and dyeing device for textiles

Technical Field

The invention relates to the technical field of textile processing equipment, in particular to a high-precision printing and dyeing device for textiles.

Background

Textile is a product of textile fibers woven through processing, and in order to make the textile more beautiful, printing or embroidery is usually required to be performed on the surface of the textile after the textile is manufactured, so that the attractiveness of the textile is improved. In the prior art, when printing and dyeing is carried out, textile cloth is usually pulled to the lower part of printing and dyeing equipment, and is printed and dyed through the printing and dyeing equipment, however, when the cloth with high-precision printing and dyeing is required to be obtained, a deviation prevention component is usually required to be additionally arranged on the printing and dyeing equipment, and the deviation of the cloth is controlled through the deviation prevention component.

The Chinese patent discloses a piece goods roll conveying prevent off tracking device, grant bulletin number is CN214326672U, this patent technology can be through setting up the swager, adjustment mechanism and fine setting mechanism, adjust the distance between swager and the conveying roller, make swager and conveying roller hug closely, prevent that upward deviation from taking place in the conveying process piece goods, and can adjust the distance between swager and the conveying roller in real time according to the thickness of piece goods roll on the conveying roller, can carry out effectual spacing to piece goods, prevent piece goods off tracking effectively, but this patent technology is through swager and conveying roller extrusion, solve the drawback of upward deviation in the cloth transportation, and only carry out spacingly through the spacing disc that is located the conveying roller both sides to the left and right sides of piece goods, when the left and right sides of piece goods take place to shift, the piece goods can lean on the spacing disc of one side, rethread swager and conveying roller's extrusion, only can make the piece goods appear the fold, on the piece goods cause the influence instead.

There is also chinese patent that discloses a printing and dyeing equipment of preventing off tracking, authorized bulletin number is CN105463732a, and this technique detects whether the fabrics takes place off tracking through setting up deviation correcting device, and when the textile fabric off tracking, the signal of telecommunication that photoelectric sensor output changes, when the change exceeds the threshold value of predetermineeing, triggers the alarm and carries out the warning suggestion, has guaranteed the printing and dyeing effect, prevents to damage printing and dyeing equipment card and dies, but this technique can only play the dead problem of avoiding printing and dyeing equipment card to can not directly adjust and reset the fabrics of off tracking, the effect limitation is great.

Accordingly, a high-precision printing and dyeing apparatus for textiles is provided by those skilled in the art to solve the problems set forth in the background art.

Disclosure of Invention

The invention aims to provide a high-precision printing and dyeing device for textiles, which aims to solve the problems in the background technology.

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

the utility model provides a high accuracy printing and dyeing device for fabrics, includes the shell, the left and right sides wall of shell runs through respectively has fabrics inlet and fabrics outlet, the inside of shell has set gradually first guide roll, first around roller, second around roller and second guide roll from a left side to the right side, first guide roll is located the right side in fabrics inlet, first guide roll with be provided with dust removal subassembly between the first around roller, the right side of second guide roll is provided with the anti-deviation structure, the anti-deviation structure is located the left side in fabrics outlet, the right side rigid coupling of shell has the support, the upper portion of support is provided with the belt feeder, the upper surface rigid coupling of support has the link, the top lower surface equidistance rigid coupling of link has the connecting rod, the lower extreme rotation of connecting rod is connected with printing and dyeing section of thick bamboo.

As still further aspects of the invention: the utility model provides a rack, including preventing off tracking structure, prevent off tracking box's left and right sides link up the setting, prevent that off tracking box's inside rotates and is connected with the compression roller, the quantity of compression roller is provided with four, four the compression roller is two sets up into a set of, and two of every group the compression roller vertical setting, two of every group clearance between the compression roller is the same with the thickness of fabrics, two sets of in the compression roller lie in the axle center of downside the compression roller and lie in same level, prevent that off tracking box's lower surface fixed mounting has the second motor, the drive end of second motor extends to prevent the inside of off tracking box, the drive end rigid coupling of second motor has first bevel gear, the inside bottom surface rigid coupling of off tracking box has the regulation section of thick bamboo support, the top equidistance of regulation section of thick bamboo support rotates and is equipped with the regulation section of thick bamboo pivot, the lateral part of thick bamboo pivot is provided with the regulation section of thick bamboo main part, the tip of thick bamboo pivot is provided with the second round gear, the inside articulated connecting axle that lies in the compression roller is located the downside the same level, the second bevel gear and the rack is provided with the second bevel gear mesh, a rack and a rack tooth mesh, the second bevel gear meshes with the second bevel gear, the rack is provided with down the side of tooth mesh.

As still further aspects of the invention: the axial direction of the rotating shaft of the adjusting cylinder is perpendicular to the axial direction of the pressing roller.

As still further aspects of the invention: the highest position of the regulating cylinder main body and the highest position of the compression roller positioned at the lower side are positioned on the same horizontal plane.

As still further aspects of the invention: the inside top surface of preventing the off tracking box is provided with laser photoelectric switch transmitter, laser photoelectric switch transmitter is provided with two, two laser photoelectric switch transmitter is located the front and back side of the inside top surface of preventing the off tracking box, the vertical orientation of irradiation direction of laser photoelectric switch transmitter is down, two the distance between the laser photoelectric switch transmitter irradiation beam equals the width of fabrics, the inside bottom surface of preventing the off tracking box is provided with two laser photoelectric switch and shines the board, two laser photoelectric switch shines the board and be located two respectively under the laser photoelectric switch transmitter.

As still further aspects of the invention: the dust collection assembly comprises a dust collection hopper, the dust collection hopper is in a funnel shape, a dust collection nozzle is arranged at the funnel opening of the dust collection hopper, a dust collection connection port is arranged at the converging end of the dust collection hopper, the dust collection connection port is connected with a dust collection pipe, the dust collection pipe is connected with a dust collector, an air outlet of the dust collector is connected with a dust collection fan, the dust collection hopper is provided with two dust collection fans, the two dust collection hoppers are respectively arranged between a first guide roller and a first winding roller and between a second winding roller and a second guide roller, and the two dust collection nozzles of the dust collection hopper are oppositely arranged.

As still further aspects of the invention: the inside of the dust collecting nozzle is provided with a fixed block, the inside of the fixed block is provided with a spring, the tail end of the spring is fixedly connected with a wedge block, the end part of the wedge block penetrates through the fixed block and extends to the outside of the dust collecting hopper, the inside of the shell is vertically fixedly connected with two retaining plates, the two retaining plates are respectively positioned on the side edge of the dust collecting nozzle, and the initial distance between the retaining plates and the end part of the wedge block is smaller than the width of a textile.

As still further aspects of the invention: the rear side of the connecting frame is fixedly provided with a first motor, the driving end of the first motor is fixedly connected to the rotating shaft end part of the printing and dyeing cylinder, the rotating shaft end part of the printing and dyeing cylinder and the rotating shaft end part of the adjacent printing and dyeing cylinder are jointly wound with a first belt, and the rotating shaft end part of the printing and dyeing cylinder and the end part of the driving cylinder shaft body of the belt conveyor are jointly wound with a second belt.

As still further aspects of the invention: the diameter of the shaft body of the belt conveyor transmission drum wound by the second belt is the same as the diameter of the rotating shaft of the printing and dyeing cylinder, and the radius of the printing and dyeing cylinder is equal to the sum of the radius of the belt conveyor transmission drum and the thickness of the belt conveyor surface conveyer belt.

Compared with the prior art, the invention has the beneficial effects that:

1. through setting up the anti-deviation structure, the fabrics piece is when being pulled between the compression roller and remove, can effectively avoid the piece to take place the skew of upper and lower direction through the compression roller, and make the piece to be in the state of stretching, when the piece takes place the off tracking when pulling, can lead to the laser of one side laser photoelectric switch transmitter to launch the laser photoelectric switch and shine the board surface, make between laser photoelectric switch transmitter and the laser photoelectric switch shine the board and be in the off-state, the circuit is put through, the second motor is operated, through first bevel gear and second bevel gear meshing, make the connecting axle rotate, again through first circular gear and rack meshing, make the rack take place the displacement, have rack and second circular gear meshing again, adjust a section of thick bamboo main part and will rotate, make the piece remove towards the opposite direction of skew direction, when the piece moves to the normal position, the laser that is sheltered from by the piece will shine the below laser photoelectric switch radiation board's surface again by the laser photoelectric switch transmitter laser of this moment, the second motor in the circuit is again by the short circuit and stop running, follow-up dyeing and printing and dyeing, the printing and dyeing is convenient for, and dyeing, and the equipment that can reset can take place the offset fast, can avoid the offset to take place offset each other, the problem can be reset, the fabric piece offset equipment to be reset fast-stop, can be reset, and the offset equipment can be reset, and the problem can be solved simultaneously.

2. Through setting up the dust subassembly to set up two dust buckets, can all handle the dust on fabrics two sides, and because the initial distance between butt plate and the wedge tip is less than the width of fabrics, when making the cloth pass through from wedge and butt plate, can extrude the wedge, the tip of wedge can scratch the cloth surface, thereby further get rid of the dust impurity of adhesion, the dust impurity of scraping will inhale the dust catcher inside collection from the mouth of gathering dust, effectively avoid follow-up when carrying out printing and dyeing, the condition that impurity such as dust blockked printing and dyeing material printing and dyeing to the cloth surface takes place.

3. The first motor is shared by the belt conveyor and the printing and dyeing barrel, the diameter of the shaft body of the belt conveyor transmission drum wound by the second belt is the same as the diameter of the rotating shaft of the printing and dyeing barrel, the radius of the printing and dyeing barrel is equal to the sum of the radius of the belt conveyor transmission drum and the thickness of the belt conveyor surface conveying belt, so that the first motor can ensure that the angular speed of the printing and dyeing barrel is the same as the angular speed of the belt conveyor transmission drum when in operation, and meanwhile, the linear speed of the printing and dyeing barrel is the same as the running speed of the belt conveyor conveying belt, thereby ensuring that textile cloth is synchronous with the printing and dyeing barrel when moving on the surface of the belt conveyor conveying belt, and avoiding printing and dyeing dislocation.

Drawings

FIG. 1 is a schematic diagram of a high-precision printing and dyeing apparatus for textiles;

FIG. 2 is a rear view of a high-precision printing apparatus for textiles;

FIG. 3 is an enlarged view of a portion of FIG. 1 at A;

FIG. 4 is a schematic structural view of a deviation preventing structure in a high-precision printing and dyeing device for textiles;

FIG. 5 is a schematic view showing an internal structure of an anti-deviation mechanism in a high-precision printing and dyeing apparatus for textile;

FIG. 6 is a schematic view of the structure in the direction B-B in FIG. 5;

fig. 7 is a circuit diagram of a servo motor control in a high-precision printing and dyeing apparatus for textile.

In the figure: 1. a housing; 2. a first guide roller; 3. a first winding roller; 4. a second winding roller; 5. a second guide roller; 6. an anti-deviation structure; 7. a dust removal assembly; 8. a bracket; 9. a belt conveyor; 10. a connecting frame; 11. a connecting rod; 12. a printing cylinder; 13. a first motor; 14. a first belt; 15. a second belt; 16. a dust collection fan; 17. a dust collector; 18. a dust collection connection port; 19. a dust collection pipe; 20. a dust collection hopper; 21. a retaining plate; 22. a dust collection nozzle; 23. a fixed block; 24. a spring; 25. wedge blocks; 26. anti-deviation box; 27. a second motor; 28. a press roller; 29. a laser photoelectric switch emitter; 30. a first bevel gear; 31. a second bevel gear; 32. a connecting shaft; 33. a first circular gear; 34. an adjusting cylinder bracket; 35. a rack; 36. adjusting a cylinder rotating shaft; 37. a second circular gear; 38. an adjustment cylinder body; 39. the laser photoelectric switch irradiates the plate.

Detailed Description

Referring to fig. 1 to 7, in the embodiment of the invention, a high-precision printing and dyeing device for textiles comprises a housing 1, wherein a textile inlet hole and a textile outlet hole are respectively penetrated through the left side wall and the right side wall of the housing 1, a first guide roller 2, a first winding roller 3, a second winding roller 4 and a second guide roller 5 are sequentially arranged in the housing 1 from left to right, the first guide roller 2 is positioned on the right side of the textile inlet hole, a dust removing component 7 is arranged between the first guide roller 2 and the first winding roller 3, a deviation preventing structure 6 is arranged on the right side of the second guide roller 5, the deviation preventing structure 6 is positioned on the left side of the textile outlet hole, a bracket 8 is fixedly connected on the right side of the housing 1, a belt conveyor 9 is arranged on the upper portion of the bracket 8, a connecting frame 10 is fixedly connected on the upper surface of the bracket 8, a connecting rod 11 is fixedly connected on the top and the lower surface of the connecting frame 10 at equal intervals, and the lower end of the connecting rod 11 is rotatably connected with a printing and dyeing cylinder 12.

Preferably, the anti-deviation structure 6 comprises an anti-deviation box 26, the left side and the right side of the anti-deviation box 26 are communicated, compression rollers 28 are rotatably connected in the anti-deviation box 26, the number of the compression rollers 28 is four, the four compression rollers 28 are arranged in a group in pairs, two compression rollers 28 of each group are vertically arranged, the gap between the two compression rollers 28 of each group is the same as the thickness of textiles, the axes of the two compression rollers 28 positioned at the lower side of the two groups of compression rollers 28 are positioned at the same level, a second motor 27 is fixedly arranged on the lower surface of the anti-deviation box 26, the driving end of the second motor 27 extends into the anti-deviation box 26, a first bevel gear 30 is fixedly connected at the driving end of the second motor 27, an adjusting cylinder bracket 34 is fixedly connected at the inner bottom surface of the anti-deviation box 26, an adjusting cylinder rotating shaft 36 is equidistantly and rotatably arranged at the top of the adjusting cylinder bracket 34, an adjusting cylinder main body 38 is arranged at the side of the adjusting cylinder rotating shaft 36, the end of the adjusting cylinder rotating shaft 36 is provided with a second round gear 37, the inside of the adjusting cylinder bracket 34 is hinged with a connecting shaft 32, two ends of the connecting shaft 32 are fixedly connected with a second bevel gear 31 and a first round gear 33 respectively, the second bevel gear 31 is meshed with the first bevel gear 30, the side wall of the adjusting cylinder bracket 34 is slidably provided with a rack 35, the upper surface and the lower surface of the rack 35 are respectively provided with meshing teeth, the first round gear 33 is meshed with the meshing teeth on the lower side of the rack 35, the second round gear 37 is meshed with the meshing teeth on the upper side of the rack 35, the forward and reverse rotation of the adjusting cylinder 38 can be controlled through the forward and reverse rotation of the second motor 27, the connecting shaft 32 rotates through the meshing of the first bevel gear 30 and the second bevel gear 31 when the second motor 27 operates, the rack 35 is meshed with the first round gear 33, the rack 35 is displaced, and the rack 35 is meshed with the second round gear 37, the adjusting cylinder main body 38 rotates, and finally, the cloth is transversely moved through contact friction between the adjusting cylinder main body 38 and the lower surface of the cloth, so that the problem that the cloth cannot be reset after being offset is solved.

Preferably, the axial direction of the adjusting cylinder rotating shaft 36 and the axial direction of the press roller 28 are mutually perpendicular, the highest position of the adjusting cylinder main body 38 and the highest position of the press roller 28 positioned at the lower side are positioned on the same horizontal plane, the adjusting cylinder main body 38 is in contact with the lower surface of the cloth, the adjusting cylinder main body 38 and the press roller 28 are mutually perpendicular, and the offset cloth can be laterally displaced by rotating the adjusting cylinder main body 38, so that the cloth is restored to the initial position.

Preferably, the inner top surface of the anti-deviation box 26 is provided with two laser photoelectric switch emitters 29, the two laser photoelectric switch emitters 29 are arranged on the front side and the rear side of the inner top surface of the anti-deviation box 26, the irradiation directions of the laser photoelectric switch emitters 29 are vertically oriented downwards, the distance between the irradiation beams of the two laser photoelectric switch emitters 29 is equal to the width of the textile, the inner bottom surface of the anti-deviation box 26 is provided with two laser photoelectric switch irradiation plates 39, the two laser photoelectric switch irradiation plates 39 are respectively arranged under the two laser photoelectric switch emitters 29, when the cloth is not deviated, the laser emitted by the laser photoelectric switch emitters 29 irradiates on the surface of the laser photoelectric switch irradiation plates 39 at the moment, the second motor is short-circuited, and when the cloth is deviated, the laser emitted by the laser photoelectric switch emitter 29 in the offset direction is blocked, at this time, the laser photoelectric switch irradiation plate 39 below the laser photoelectric switch emitter 29 is not irradiated by the laser, so that the laser photoelectric switch emitter 29 and the laser photoelectric switch irradiation plate 39 are in an off state, the circuit is completed, the second motor 27 is operated, the connecting shaft 32 is rotated by meshing the first bevel gear 30 with the second bevel gear 31, and the first round gear 33 is meshed with the rack 35, so that the rack 35 is displaced, and the rack 35 is meshed with the second round gear 37, the regulating cylinder body 38 is rotated, and the highest position of the regulating cylinder body 38 and the highest position of the pressing roller 28 positioned at the lower side are positioned at the same horizontal plane, the regulating cylinder body 38 is in contact with the lower surface of the cloth, the regulating cylinder body 38 is rotated so that the cloth is moved in the opposite direction of the offset direction, when the cloth is moved to the original position, the laser emitted by the laser photoelectric switch emitter 29 blocked by the cloth at this time will be re-irradiated to the surface of the lower laser photoelectric switch irradiation plate 39, and at this time the second motor 27 in the circuit is re-shorted and stopped.

Preferably, the dust collection assembly 7 comprises a dust collection hopper 20, the dust collection hopper 20 is in a funnel shape, a dust collection nozzle 22 is arranged at the funnel opening of the dust collection hopper 20, a dust collection connection port 18 is arranged at the converging end of the dust collection hopper 20, the dust collection connection port 18 is connected with a dust collection pipe 19, the dust collection pipe 19 is connected with a dust collector 17, an air outlet of the dust collector 17 is connected with a dust collection fan 16, the dust collection hopper 20 is provided with two dust collection hoppers 20, the two dust collection hoppers 20 are respectively positioned between the first guide roller 2 and the first winding roller 3 and between the second winding roller 4 and the second guide roller 5, and the dust collection nozzles 22 of the two dust collection hoppers 20 are oppositely arranged and can collect dust on two sides of cloth.

Preferably, the inside of the dust collecting nozzle 22 is provided with the fixed block 23, the spring 24 is arranged in the fixed block 23, the wedge block 25 is fixedly connected to the tail end of the spring 24, the end part of the wedge block 25 penetrates through the fixed block 23 and extends to the outside of the dust collecting bucket 20, the inside of the shell 1 is vertically fixedly connected with two retaining plates 21, the two retaining plates 21 are respectively positioned on the side edges of the dust collecting nozzle 22, the initial distance between the retaining plates 21 and the end parts of the wedge block 25 is smaller than the width of a textile, when cloth passes through the wedge block 25 and the retaining plates 21, the wedge block 25 is extruded, the spring 24 is contracted, and the surface of the cloth can be scratched through the end parts of the wedge block 25, so that attached dust impurities are removed, the scratched dust impurities are sucked into the dust collector 17 from the dust collecting nozzle 22 to be collected, and the condition that the impurities such as dust block the printing and dyeing substances to the surface of the cloth during the subsequent printing and dyeing is effectively avoided.

Preferably, the rear side of the connecting frame 10 is fixedly provided with a first motor 13, the driving end of the first motor 13 is fixedly connected to the rotating shaft end of one printing drum 12, the rotating shaft end of the printing drum 12 and the rotating shaft end of the adjacent printing drum 12 are jointly wound with a first belt 14, the rotating shaft end of the printing drum 12 and the rotating shaft end of the driving drum shaft of the belt conveyor 9 are jointly wound with a second belt 15, the diameter of the driving drum shaft of the belt conveyor 9 wound with the second belt 15 is the same as the rotating shaft diameter of the printing drum 12, the radius of the printing drum 12 is equal to the sum of the radius of the driving drum of the belt conveyor 9 and the thickness of the surface conveyor belt of the belt conveyor 9, and the diameter of the driving drum shaft of the belt conveyor 9 wound with the second belt 15 is the same as the rotating shaft diameter of the printing drum 12, so that when the first motor 13 runs, the angular speed of the printing drum 12 and the angular speed of the driving drum 9 are the same, and the linear speed of the belt conveyor 9 is ensured to be the same, and the linear speed of the belt conveyor 9 and the surface conveyor 9 of the textile conveyor belt are prevented from moving at the same, and the same speed of the surface conveyor belt 9 is ensured, and the offset speed of the textile conveyor belt is prevented from moving.

The working principle of the invention is as follows: when the textile cloth is printed with high precision, the textile is required to be kept at the central position at all times and is not deviated, so that the textile is ensured to move to the lower side of the printing cylinder 12 to be printed, after the textile is respectively wound around the first guide roller 2, the first winding roller 3, the second winding roller 4 and the second guide roller 5, the textile cloth passes through the space between the first group of compression rollers 28 and the second group of compression rollers 28 and is pulled to the surface of the conveying belt of the belt conveyor 9, the printing is carried out through the printing cylinder 12, because the belt conveyor 9 and the printing cylinder 12 are connected through the second belt 15, the belt conveyor 9 and the printing cylinder 12 share the same motor, the diameter of the shaft body of the driving cylinder of the belt conveyor 9 wound by the second belt 15 is the same as the diameter of the rotating shaft of the printing cylinder 12, and the radius of the printing cylinder 12 is equal to the sum of the radius of the driving cylinder of the belt conveyor 9 and the thickness of the conveying belt on the surface of the belt conveyor 9, when the first motor 13 is operated, the angular speed of the printing cylinder 12 and the angular speed of the transmission roller of the belt conveyor 9 can be ensured to be the same, meanwhile, the linear speed of the printing cylinder 12 and the operation speed of the conveying belt of the belt conveyor 9 are ensured to be the same, the textile cloth is ensured to be synchronous with the printing cylinder 12 when moving on the surface of the conveying belt of the belt conveyor 9, the printing dislocation is avoided, the damage of the whole textile is further caused, when the textile cloth passes through the inside of the anti-deviation box 26, the vertical deviation of the cloth is effectively avoided under the action of the press roller 28, the cloth can be in a straight state, the distance between the two laser photoelectric switch emitters 29 irradiating light beams is equal to the width of the textile because the laser photoelectric switch emitters 29 are arranged, when the cloth passes through the two laser photoelectric switch emitters 29, at this time, the laser emitted from the laser photoelectric switch emitter 29 irradiates the surface of the laser photoelectric switch irradiation plate 39, referring to fig. 7, at this time, the second motor 27 is short-circuited, and when the piece goods are offset, the laser emitted from the laser photoelectric switch emitter 29 in the offset direction is blocked, at this time, the laser photoelectric switch irradiation plate 39 under the laser photoelectric switch emitter 29 is not irradiated by the laser, so that the laser photoelectric switch emitter 29 and the laser photoelectric switch irradiation plate 39 are in an off state, the circuit is on, the second motor 27 is operated, the connecting shaft 32 is rotated by the engagement of the first bevel gear 30 and the second bevel gear 31, and the first circular gear 33 and the rack 35 are engaged, so that the rack 35 is displaced, and the rack 35 is engaged with the second circular gear 37, the regulating cylinder main body 38 is rotated, while the highest position of the adjusting cylinder main body 38 and the highest position of the pressing roller 28 positioned at the lower side are positioned at the same horizontal plane, the adjusting cylinder main body 38 is contacted with the lower surface of the cloth, the adjusting cylinder main body 38 rotates to enable the cloth to move in the direction opposite to the offset direction, when the cloth moves to the original position, the laser emitted by the laser photoelectric switch emitter 29 shielded by the cloth at the moment is re-irradiated to the surface of the lower laser photoelectric switch irradiating plate 39, the second motor 27 in the circuit is shorted again to stop operation, otherwise, when the cloth is offset in the opposite direction, the laser emitted by the laser photoelectric switch emitter 29 at the other side is shielded by the cloth to enable the circuit to be reversely connected, the second motor 27 is reversely operated, so that the cloth is controlled to move in the direction opposite to the offset direction by the adjusting cylinder main body 38 until the cloth is positioned at the middle part, the laser emitted by the two laser photoelectric switch emitters 29 can irradiate the surface of the laser photoelectric switch irradiation plate 39, in this way, the offset cloth can be quickly reset, the dislocation can not occur in the subsequent printing and dyeing process, the dust collection assembly 7 is arranged between the first guide roller 2 and the first winding roller 3 and between the second winding roller 4 and the second guide roller 5, dust and impurities on two sides of the cloth can be absorbed after the dust collection fan 16 is started, the dust and impurities enter the dust collection hopper 20 through the dust collection nozzle 22 and enter the dust collector 17 from the dust collection connection port 18 through the dust collection pipe 19 for collection, when dust and impurities attached to the surface of the cloth cannot be directly sucked away, the dust and impurities are required to be removed through extrusion between the wedge block 25 and the retaining plate 21, and since the initial distance between the retaining plate 21 and the end part of the wedge block 25 is smaller than the width of the textile, when the cloth passes through the wedge block 25 and the retaining plate 21, the wedge block 25 can be extruded, the spring 24 is contracted, the end part of the wedge block 25 can scratch the surface of the cloth, so that the attached dust and impurities are removed, the scraped dust and impurities are sucked into the dust collector 17 from the dust collecting nozzle 22, and the condition that the impurities such as dust block the printing and dyeing substances to the surface of the cloth during subsequent printing and dyeing is effectively avoided.

The foregoing description is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical solution of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. The utility model provides a fabrics is with high accuracy printing and dyeing device, includes shell (1), its characterized in that: the utility model discloses a textile fabric dyeing machine, including shell (1), textile fabric inlet and textile fabric outlet, the inside of shell (1) has set gradually first guide roll (2), first around roller (3), second around roller (4) and second guide roll (5) from a left side to the right side of shell (1), first guide roll (2) are located the right side of textile fabric inlet, first guide roll (2) with be provided with dust removal subassembly (7) between first around roller (3), the right side of second guide roll (5) is provided with anti-deviation structure (6), anti-deviation structure (6) are located the left side of textile fabric outlet, the right side rigid coupling of shell (1) has support (8), the upper portion of support (8) is provided with belt feeder (9), the upper surface rigid coupling of support (8) has link (10), the top lower surface equidistance rigid coupling of link (11), the lower extreme rotation of link (11) is connected with printing and dyeing section of thick bamboo (12).

2. The high-precision textile printing apparatus according to claim 1, wherein: the anti-deviation structure (6) comprises an anti-deviation box (26), the left side and the right side of the anti-deviation box (26) are communicated, the inside of the anti-deviation box (26) is rotationally connected with press rolls (28), the number of the press rolls (28) is four, the press rolls (28) are arranged into a group in pairs, the two press rolls (28) of each group are vertically arranged, the gap between the two press rolls (28) of each group is the same as the thickness of a textile, the axes of the two press rolls (28) positioned at the lower side of the two press rolls (28) are positioned at the same level, the lower surface of the anti-deviation box (26) is fixedly provided with a second motor (27), the driving end of the second motor (27) extends to the inside of the anti-deviation box (26), the driving end of the second motor (27) is fixedly connected with a first bevel gear (30), the inside of the anti-deviation box (26) is fixedly connected with an adjusting cylinder bracket (34), the gap between the two press rolls (28) is the thickness of the textile, the adjusting cylinder bracket (34) is provided with an adjusting cylinder (36), the rotating shaft (36) is connected with the rotating shaft (32) of the adjusting cylinder bracket (36), the adjusting cylinder (36) is provided with the rotating shaft (36), the utility model discloses a motor drive mechanism for a motor drive mechanism, including connecting axle (32), first bevel gear (35) and second bevel gear (31) and first circular gear (33) are fixed respectively at both ends of connecting axle (32), second bevel gear (31) with first bevel gear (30) meshing, the lateral wall of adjusting section of thick bamboo support (34) slides and is provided with rack (35), the upper and lower surface of rack (35) all is provided with the meshing tooth, first circular gear (33) with the meshing tooth meshing of rack (35) downside, second circular gear (37) with the meshing tooth meshing of rack (35) upside.

3. The high-precision printing and dyeing apparatus for textile according to claim 2, wherein: the axial direction of the adjusting cylinder rotating shaft (36) and the axial direction of the pressing roller (28) are perpendicular to each other.

4. The high-precision printing and dyeing apparatus for textile according to claim 2, wherein: the highest position of the regulating cylinder main body (38) and the highest position of the compression roller (28) positioned at the lower side are positioned at the same horizontal plane.

5. The high-precision printing and dyeing apparatus for textile according to claim 2, wherein: the inside top surface of anti-deviation box (26) is provided with laser photoelectric switch transmitter (29), laser photoelectric switch transmitter (29) are provided with two, two laser photoelectric switch transmitter (29) are located the front and back side of anti-deviation box (26) inside top surface, the irradiation direction of laser photoelectric switch transmitter (29) is vertical down, two the distance between laser photoelectric switch transmitter (29) irradiation beam equals the width of fabrics, the inside bottom surface of anti-deviation box (26) is provided with two laser photoelectric switch irradiation board (39), two laser photoelectric switch irradiation board (39) are located two respectively under laser photoelectric switch transmitter (29).

6. The high-precision textile printing apparatus according to claim 1, wherein: the dust collection assembly (7) comprises a dust collection hopper (20), the dust collection hopper (20) is in a funnel shape, a dust collection nozzle (22) is arranged at the funnel opening of the dust collection hopper (20), a dust collection connection opening (18) is arranged at the converging end of the dust collection hopper (20), the dust collection connection opening (18) is connected with a dust collection pipe (19), the dust collection pipe (19) is connected with a dust collector (17), an air outlet of the dust collector (17) is connected with a dust collection fan (16), the dust collection hopper (20) is provided with two dust collection hoppers (20) which are respectively arranged between a first guide roller (2) and a first winding roller (3), between a second winding roller (4) and a second guide roller (5), and the dust collection nozzles (22) of the dust collection hopper (20) are oppositely arranged.

7. The high-precision textile printing apparatus according to claim 6, wherein: the inside of dust collection mouth (22) is provided with fixed block (23), the internally mounted of fixed block (23) has spring (24), the end rigid coupling of spring (24) has wedge (25), the tip of wedge (25) runs through fixed block (23) and extends to the outside of dust collection fill (20), the inside vertical rigid coupling of shell (1) has two butt plates (21), two butt plates (21) are located respectively the side of dust collection mouth (22), just butt plate (21) with initial distance between wedge (25) tip is less than the width of fabrics.

8. The high-precision textile printing apparatus according to claim 1, wherein: the rear side of link (10) fixed mounting has first motor (13), the drive end rigid coupling of first motor (13) in one the pivot tip of printing and dyeing section of thick bamboo (12), this pivot tip of printing and dyeing section of thick bamboo (12) and adjacent the pivot tip of printing and dyeing section of thick bamboo (12) twine together first belt (14), this pivot tip of printing and dyeing section of thick bamboo (12) with the transmission drum shaft body tip of belt feeder (9) twines together second belt (15).

9. The high-precision textile printing apparatus as defined in claim 8, wherein: the diameter of the shaft body of the transmission roller of the belt conveyor (9) wound by the second belt (15) is the same as the diameter of the rotating shaft of the printing and dyeing cylinder (12), and the radius of the printing and dyeing cylinder (12) is equal to the sum of the radius of the transmission roller of the belt conveyor (9) and the thickness of the conveying belt on the surface of the belt conveyor (9).