CN114232259B - Continuous tie-dyeing machine for intelligent cloth - Google Patents

Abstract

The invention provides an intelligent cloth continuous tie-dyeing machine which comprises a dip-dyeing box, wherein a plurality of dyeing discs are sequentially arranged in the dip-dyeing box, a tie-cloth lifting mechanism is arranged outside the dip-dyeing box, and a dye extrusion mechanism is arranged at the top end of the dip-dyeing box; the dye extrusion mechanism comprises a supporting table arranged on the outer surface of the top end of the dip dyeing box, a rotary extrusion assembly arranged on a shell of the supporting table in sequence, and a diversion air-drying assembly arranged on the top end of the supporting table. According to the invention, after tie-dyeing, the redundant dye in the tie-cloth can be effectively extruded, so that the redundant dye is prevented from dripping outside and affecting the external environment.

Description

Continuous tie-dyeing machine for intelligent cloth

Technical Field

The invention mainly relates to the technical field of cloth tie-dyeing, in particular to an intelligent cloth continuous tie-dyeing machine.

Background

Tie-dyeing is a traditional and unique dyeing process in China, and is divided into a tying process and a dyeing process by partially tying the fabric during dyeing to make the fabric incapable of being dyed.

According to the tie-dyeing machine provided by the patent document with the application number of CN201710716243.9, the tie-dyeing machine comprises a base, support rods respectively arranged on two sides of the base, a footstock is arranged between the tops of the two support rods, an electric lifting rod is arranged on the inner side of each support rod, a dye vat is arranged on the base, a solid wood plate with holes is arranged in the dye vat, two sides of the solid wood plate with holes are connected with the corresponding electric lifting rods through connecting pieces, an unreeling device is arranged above the inner side of one of the two support rods, a reeling device is arranged above the inner side of the other one of the two support rods, and a plurality of slide rails are longitudinally arranged below the footstock.

The tie-dyeing machine has the advantages of simple structure, convenient operation, portability and small manual labor intensity, but after the completion of dip dyeing, the traditional tie-dyeing machine is difficult to extrude redundant dye, so that the dye is easy to drop on equipment and sprinkled outside, and the working environment is easy to influence.

Disclosure of Invention

The invention mainly provides an intelligent cloth continuous tie-dyeing machine which is used for solving the technical problems in the background technology.

The technical scheme adopted for solving the technical problems is as follows:

the intelligent cloth continuous tie-dyeing machine comprises a dip-dyeing box, wherein a plurality of dyeing discs are sequentially arranged in the dip-dyeing box, a tie-cloth lifting mechanism is arranged outside the dip-dyeing box, and a dye extrusion mechanism is arranged at the top end of the dip-dyeing box;

the dye extrusion mechanism comprises a supporting table arranged on the outer surface of the top end of the dip dyeing box, a rotary extrusion assembly arranged on a shell of the supporting table in sequence, and a diversion air-drying assembly arranged on the top end of the supporting table;

the rotary extrusion assembly comprises through holes which are sequentially formed in the supporting table shell and through which the binding cloth passes, a wringing component which is embedded in the supporting table shell and corresponds to the through holes, and a power component which is connected with the driving end of the wringing component;

the air-drying assembly comprises a guide frame arranged on the upper surface of the supporting table and an air inducing mechanism arranged on one side of the guide frame.

Further, the wringing component comprises a supporting chamber which is sequentially arranged on the supporting table shell from top to bottom, a supporting ring which is rotationally connected with the bottom end inside the supporting chamber, and extrusion flaps which are rotationally connected with the supporting ring through a rotating shaft, wherein two adjacent extrusion flaps are connected end to close to form a ring shape, and the extrusion flaps rotate by taking the rotating shaft of the extrusion flaps on the supporting ring as a rotating center, so that the opening of the supporting ring can be controlled by the extrusion flaps, and the binding cloth can be clamped through the extrusion flaps.

Further, the wringing component further comprises a toothed ring which is in sliding connection with the supporting ring, and a connecting rod which is in rotary connection with the toothed ring through a rotating shaft, wherein one end of the connecting rod, which is far away from the toothed ring, is connected with the adjacent extrusion valve through the rotating shaft, and the connecting rod is pushed to displace through the rotation of the toothed ring.

Further, be equipped with a plurality of guide slots on the casing of ring gear, every the inside of guide slot is all sliding connection has the guide post, the guide post is installed in adjacent the upper surface of support ring, and the support ring is through the slip of its upper guide post in the guide slot to the guide ring gear uses the axis of support ring as the center of rotation to rotate.

Further, the power component comprises a speed reducer arranged on the lower surface of the supporting table, a motor connected with a driving shaft of the speed reducer, and a rotating shaft connected with an output shaft of the speed reducer, wherein two gears are sequentially arranged on the outer surface of the rotating shaft from top to bottom, the gears are in meshed connection with the corresponding toothed rings, the gears are driven to rotate through the rotating shaft, and accordingly the toothed rings meshed with the gears are driven to rotate through rotation of the gears.

Further, the upper surface mounting of supporting bench have a plurality of with the corresponding toper water conservancy diversion platform of through-hole, the upper surface of toper water conservancy diversion platform is connected with the rubber extrusion section of thick bamboo, the inside of toper water conservancy diversion platform is equipped with a plurality of squeeze poles, the squeeze pole runs through in proper order from top to bottom and corresponds with one side the extrusion lamella, promotes toper water conservancy diversion platform and its upper rubber extrusion section of thick bamboo and opens through the squeeze pole on the extrusion lamella to make prick cloth can be quick smooth carry out the dip dyeing.

Further, the cloth bundling lifting mechanism comprises a plurality of lifting cylinders arranged on the outer surface of the dip dyeing box, lifting jacks connected with the top ends of the piston rods of the lifting cylinders, a linear module arranged on the lower surface of the lifting jacks, and a mechanical claw used for clamping and taking the cloth bundling, wherein the mechanical claw is driven to translate through the linear module, so that the mechanical claw can clamp and clamp the cloth bundling to move to a proper position.

Further, the upper surface of the guide frame is provided with an organ type guide sheet, the top end of the guide frame is connected with the lower surface of the lifting top through the organ type guide sheet, and the guide frame is matched with the guide frame through the organ type guide sheet, so that air in the guide frame flows out.

Further, the induced air mechanism comprises a guide plate arranged at one end of the guide frame, and a plurality of induced fans embedded in the guide plate shell, the induced fans are supported by the guide plate, and the completion of tie dyeing is accelerated by air flow generated by the induced fans.

Further, the air-drying assembly of water conservancy diversion still includes the chamfer of locating brace table top both sides, and wears to locate a plurality of honeycomb ducts of water conservancy diversion frame both sides, the honeycomb duct is kept away from the one end of water conservancy diversion frame extends to outside, and the brace table is through the dyestuff outflow that extrudees in its upper chamfer guide bundle cloth, and dyestuff on the brace table flows to the external world along the honeycomb duct.

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

firstly, the invention can effectively squeeze out the redundant dye in the binding cloth after the binding dyeing, prevent the redundant dye from dripping to the outside and affecting the outside environment, and specifically comprises the following steps: the opening of the supporting ring is controlled, the cloth is clamped through the extrusion valve, the toothed ring is driven to rotate continuously, the toothed ring pushes the supporting ring to rotate, the extrusion valve for clamping the cloth is made to revolve around the axis of the supporting ring, the cloth is screwed tightly, and dye in the cloth is made to flow out, so that the dye is prevented from polluting the environment.

Secondly, the extrusion rod on the extrusion flap pushes the conical flow guiding table and the upper rubber extrusion cylinder to open so that the cloth can be quickly and smoothly dip-dyed, and when the extrusion rod releases pushing the conical flow guiding table and the upper rubber extrusion cylinder, the conical flow guiding table and the upper rubber extrusion cylinder are used for clamping the cloth so that dye extruded in the cloth can flow away through the conical flow guiding table and the upper rubber extrusion cylinder.

The invention will be explained in detail below with reference to the drawings and specific embodiments.

Drawings

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

FIG. 2 is a top view of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is an enlarged view of the structure of the area A in FIG. 3;

figure 5 is a schematic view of the structure of the wringing component of the present invention;

figure 6 is an exploded view of the wringing component of the present invention;

FIG. 7 is a schematic view of the structure of the support table and cloth bundling lifting mechanism of the present invention;

fig. 8 is a schematic structural view of a diversion air-drying assembly according to the present invention.

In the figure: 10. a dip dyeing box; 20. a dyeing disc; 30. a cloth bundling lifting mechanism; 31. a lifting oil cylinder; 32. lifting the roof; 33. a linear module; 34. a mechanical claw; 40. a dye extrusion mechanism; 41. a support table; 411. a conical diversion table; 412. a rubber extrusion cylinder; 413. an extrusion rod; 42. a rotary extrusion assembly; 421. a through hole; 422. a power component; 4221. a speed reducer; 4222. a motor; 4223. a rotation shaft; 4224. a gear; 423. wringing out the parts; 4231. a support chamber; 4232. a support ring; 4233. extruding the petals; 4234. a toothed ring; 4235. a connecting rod; 4236. a guide groove; 4237. a guide post; 43. the diversion air-drying assembly; 431. a flow guiding frame; 432. an induced draft mechanism; 433. organ type flow deflector; 434. and a flow guiding pipe.

Detailed Description

In order that the invention may be more fully understood, a more particular description of the invention will be rendered by reference to the appended drawings, in which several embodiments of the invention are illustrated, but which may be embodied in different forms and are not limited to the embodiments described herein, which are, on the contrary, provided to provide a more thorough and complete disclosure of the invention.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to the other element, it may be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly connected to one of ordinary skill in the art to which this invention belongs, and the knowledge of terms used in the description of this invention herein for the purpose of describing particular embodiments is not intended to limit the invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

1-8, an intelligent cloth continuous tie-dyeing machine comprises a dip-dyeing box 10, wherein a plurality of dyeing discs 20 are sequentially arranged inside the dip-dyeing box 10, a tie-cloth lifting mechanism 30 is arranged outside the dip-dyeing box 10, and a dye extrusion mechanism 40 is arranged at the top end of the dip-dyeing box 10;

the dye extruding mechanism 40 comprises a supporting table 41 arranged on the outer surface of the top end of the dip dyeing box 10, a rotary extruding assembly 42 sequentially arranged on the shell of the supporting table 41, and a diversion air-drying assembly 43 arranged on the top end of the supporting table 41;

the rotary extrusion assembly 42 includes a through hole 421 sequentially provided on the housing of the support table 41 and through which the cloth is inserted, a wringing member 423 embedded in the housing of the support table 41 and corresponding to the through hole 421, and a power member 422 connected to the driving end of the wringing member 423;

the air-guiding and drying assembly 43 includes an air-guiding frame 431 mounted on the upper surface of the support table 41, and an air-guiding mechanism 432 disposed on one side of the air-guiding frame 431.

Specifically, referring to fig. 3, 4 and 5, the wringing member 423 includes a supporting chamber 4231 sequentially disposed on the housing of the supporting table 41 from top to bottom, a supporting ring 4232 rotatably connected to the bottom end inside the supporting chamber 4231, a pressing flap 4233 rotatably connected to the supporting ring 4232 through a rotation shaft, two adjacent pressing flaps 4233 are closed end to form a ring shape, the wringing member 423 further includes a toothed ring 4234 slidably connected to the supporting ring 4232, and a connecting rod 4235 rotatably connected to the toothed ring 4234 through a rotation shaft, wherein one end of the connecting rod 4235 far away from the toothed ring 4234 is connected to the adjacent pressing flap 4233 through a rotation shaft;

in this embodiment, the support chamber 4231 provides support for the support ring 4232, and the pressing petals 4233 rotate around the rotation axis of the pressing petals 4233 on the support ring 4232, so that the opening size of the support ring 4232 can be controlled by the pressing petals 4233, and the binding cloth can be clamped by the pressing petals 4233;

further, the connecting rod 4235 is pushed to displace by the rotation of the toothed ring 4234, and since one end of the connecting rod 4235 far away from the toothed ring 4234 is connected with the adjacent extrusion valve 4233 through a rotation shaft, the extrusion valve 4233 is pushed to rotate by taking the rotation shaft on the support ring 4232 as the rotation center.

Specifically, referring to fig. 3, 4 and 5, a plurality of guide grooves 4236 are provided on a housing of the ring gear 4234, a guide post 4237 is slidably connected in each guide groove 4236, the guide post 4237 is mounted on an upper surface of an adjacent support ring 4232, the power component 422 includes a speed reducer 4221 mounted on a lower surface of the support table 41, a motor 4222 connected with a driving shaft of the speed reducer 4221, and a rotation shaft 4223 connected with an output shaft of the speed reducer 4221, two gears 4224 are sequentially mounted on an outer surface of the rotation shaft 4223 from top to bottom, the gears 4224 are in meshed connection with corresponding tooth rings 4234, a plurality of conical guide tables 411 corresponding to the through holes 421 are mounted on an upper surface of the support table 41, a rubber extrusion cylinder 412 is connected on an upper surface of the conical guide tables 411, a plurality of extrusion rods 413 are provided in the interior of the conical guide tables 411, and the extrusion rods 413 sequentially penetrate through the extrusion petals 33 from top to bottom in sequence;

in this embodiment, the support ring 4232 slides in the guide groove 4236 through the guide post 4237, so as to guide the toothed ring 4234 to rotate about the axis of the support ring 4232;

further, the motor 4222 drives the speed reducer 4221 to operate through the output shaft thereof, the torque output by the motor 4222 is increased through the speed reducer 4221, the rotation shaft 4223 is driven to rotate through the speed reducer 4221, the gear 4224 is driven to rotate through the rotation shaft 4223, and the toothed ring 4234 meshed with the gear 4224 is driven to rotate through the rotation of the gear 4224;

further, when the squeezing flaps 4233 do not clamp the cloth, the squeezing rods 413 on the squeezing flaps 4233 push the conical flow guiding table 411 and the rubber squeezing cylinder 412 on the conical flow guiding table 411 to open, so that the cloth can be quickly and smoothly dip dyed;

when the squeezing flaps 4233 clamp the cloth bundle, the squeezing rod 413 releases the pushing of the conical guide table 411 and the upper rubber squeezing cylinder 412, so that the cloth bundle is clamped by the conical guide table 411 and the upper rubber squeezing cylinder 412, and the dye squeezed in the cloth bundle flows away through the conical guide table 411 and the upper rubber squeezing cylinder 412.

Specifically, referring to fig. 1, 7 and 8, the cloth bundling lifting mechanism 30 includes a plurality of lifting cylinders 31 mounted on the outer surface of the dip-dyeing tank 10, a lifting top 32 connected to the top ends of piston rods of the plurality of lifting cylinders 31, a linear module 33 mounted on the lower surface of the lifting top 32, a gripper 34 for gripping the bundling cloth connected to an execution end of the linear module 33, an organ type deflector 433 mounted on the upper surface of the deflector frame 431, the top end of the deflector frame 431 connected to the lower surface of the lifting top 32 through the organ type deflector 433, the air guiding mechanism 432 includes a deflector 4321 mounted on one end of the deflector frame 431, a plurality of air guiding fans 4322 embedded in a housing of the deflector 4321, the air guiding and drying assembly 43 further includes a chamfer angle provided on two sides of the top end of the support table 41, and a plurality of guide pipes 434 penetrating through two sides of the deflector frame 431, and one end of the deflector frame 431 far from the deflector frame 431 extends to the outside;

it should be noted that, in this embodiment, the linear module 33 drives the gripper 34 to translate, so that the gripper 34 can clamp the cloth to move to a proper position;

further, the guide frame 431 is adapted to the lifting of the lifting roof 32 through the organ type guide sheet 433 to prevent the collision between the lifting roof 32 and the guide frame 431, and the air in the guide frame flows out through the organ type guide sheet 433 matched with the guide frame 431;

further, the guide plate 4321 provides support for the induced fan 4322, and the completion of tie dyeing is accelerated by the air flow generated by the induced fan 4322;

further, the supporting table 41 guides the extruded dye in the binding cloth to flow out through the upper chamfer thereof, and the dye on the supporting table 41 flows out to the outside along the flow guide tube 434.

The specific operation mode of the invention is as follows:

the linear module 33 drives the mechanical claw 34 to translate, so that the mechanical claw 34 can clamp the bound cloth to move to a proper position, and the lifting cylinder 31 drives the mechanical claw 34 to lift, so that the bound cloth can enter the dyeing disc 20 for dip dyeing;

after dip dyeing is completed, the cloth bundling is driven to ascend, the motor 4222 drives the speed reducer 4221 to operate through the output shaft of the motor 4222, the torque output by the motor 4222 is improved through the speed reducer 4221, the rotating shaft 4223 is driven to rotate through the speed reducer 4221, the gear 4224 is driven to rotate through the rotating shaft 4223, the toothed ring 4234 meshed with the gear 4224 is driven to rotate through the rotation of the gear 4224, the connecting rod 4235 is pushed to displace through the rotation of the toothed ring 4234, and one end of the connecting rod 4235 far away from the toothed ring 4234 is connected with the adjacent extrusion valve 4233 through the rotating shaft so as to push the extrusion valve 4233 to rotate by taking the rotating shaft of the extrusion valve 4233 on the supporting ring 4232 as a rotating center;

support is provided for the support ring 4232 through the support chamber 4231, the extrusion valve 4233 rotates by taking the rotating shaft of the extrusion valve 4233 on the support ring 4232 as a rotation center, so that the extrusion valve 4233 can control the opening size of the support ring 4232, the cloth is clamped through the extrusion valve 4233, the toothed ring 4234 is continuously driven to rotate, the toothed ring 4234 pushes the support ring 4232 to rotate, the extrusion valve 4233 clamping the cloth revolves around the axis of the support ring 4232, the cloth is screwed, and the dye in the cloth flows out, so that the dye is prevented from polluting the environment;

when the dye of the binding cloth is extruded, the binding cloth can be driven to lift and translate, so that the binding cloth can be kept horizontal, and the dye left along the gravity is prevented from affecting the binding dyeing effect of the binding cloth.

While the invention has been described above with reference to the accompanying drawings, it will be apparent that the invention is not limited to the embodiments described above, but is intended to be within the scope of the invention, as long as such insubstantial modifications are made by the method concepts and technical solutions of the invention, or the concepts and technical solutions of the invention are applied directly to other occasions without any modifications.

Claims (4)

1. The intelligent cloth continuous tie-dyeing machine comprises a dip-dyeing box (10), and is characterized in that a plurality of dyeing discs (20) are sequentially arranged in the dip-dyeing box (10), a cloth-binding lifting mechanism (30) is arranged outside the dip-dyeing box (10), and a dye extrusion mechanism (40) is arranged at the top end of the dip-dyeing box (10);

the dye extruding mechanism (40) comprises a supporting table (41) arranged on the outer surface of the top end of the dip dyeing box (10), a rotary extruding assembly (42) sequentially arranged on a shell of the supporting table (41), and a diversion air-drying assembly (43) arranged on the top end of the supporting table (41);

the rotary extrusion assembly (42) comprises a through hole (421) which is sequentially arranged on the supporting table (41) shell and is used for penetrating a binding cloth, a wringing component (423) which is embedded on the supporting table (41) shell and corresponds to the through hole (421), and a power component (422) which is connected with the driving end of the wringing component (423);

the wringing component (423) comprises a supporting chamber (4231) which is sequentially arranged on a shell of the supporting table (41) from top to bottom, a supporting ring (4232) which is rotationally connected with the bottom end inside the supporting chamber (4231), and extrusion petals (4233) which are rotationally connected with the supporting ring (4232) through a rotating shaft, wherein two adjacent extrusion petals (4233) are connected end to end and are closed into a ring shape;

the wringing component (423) further comprises a toothed ring (4234) which is in sliding connection with the supporting ring (4232), and a connecting rod (4235) which is in rotary connection with the toothed ring (4234) through a rotating shaft, wherein one end of the connecting rod (4235) far away from the toothed ring (4234) is connected with the adjacent extrusion valve (4233) through the rotating shaft;

a plurality of guide grooves (4236) are formed in the shell of the toothed ring (4234), guide columns (4237) are connected inside each guide groove (4236) in a sliding mode, and the guide columns (4237) are installed on the upper surfaces of the adjacent support rings (4232);

a plurality of conical guide tables (411) corresponding to the through holes (421) are mounted on the upper surface of the supporting table (41), a rubber extrusion cylinder (412) is connected to the upper surface of the conical guide tables (411), a plurality of extrusion rods (413) are arranged in the conical guide tables (411), and the extrusion rods (413) sequentially penetrate through the same side from top to bottom and correspond to the extrusion petals (4233);

the diversion air-drying assembly (43) comprises a diversion frame (431) arranged on the upper surface of the supporting table (41), and an air inducing mechanism (432) arranged on one side of the diversion frame (431);

the cloth bundling lifting mechanism (30) comprises a plurality of lifting cylinders (31) arranged on the outer surface of the dip dyeing box (10), lifting tops (32) connected with the top ends of piston rods of the lifting cylinders (31), and a linear module (33) arranged on the lower surface of the lifting tops (32), wherein the executing end of the linear module (33) is connected with a mechanical claw (34) for clamping the bundling cloth;

the upper surface of the flow guiding frame (431) is provided with an organ type flow guiding sheet (433), and the top end of the flow guiding frame (431) is connected with the lower surface of the lifting top (32) through the organ type flow guiding sheet (433).

2. The intelligent cloth continuous tie-dyeing machine according to claim 1, wherein the power component (422) comprises a speed reducer (4221) mounted on the lower surface of the supporting table (41), a motor (4222) connected with a driving shaft of the speed reducer (4221), and a rotating shaft (4223) connected with an output shaft of the speed reducer (4221), two gears (4224) are sequentially mounted on the outer surface of the rotating shaft (4223) from top to bottom, and the gears (4224) are in meshed connection with the corresponding toothed rings (4234).

3. The intelligent cloth continuous tie dyeing machine according to claim 1, wherein the air guiding mechanism (432) comprises a guide plate (4321) arranged at one end of the guide frame (431), and a plurality of air guiding fans (4322) embedded in a shell of the guide plate (4321).

4. The intelligent cloth continuous tie dyeing machine according to claim 1, wherein the diversion air drying assembly (43) further comprises chamfers arranged at two sides of the top end of the supporting table (41), and a plurality of diversion pipes (434) penetrating through two sides of the diversion frame (431), and one end of each diversion pipe (434) far away from the diversion frame (431) extends to the outside.