CN115369596B

CN115369596B - Intelligent transverse door high-temperature high-pressure dyeing machine

Info

Publication number: CN115369596B
Application number: CN202210973594.9A
Authority: CN
Inventors: 刘俊华
Original assignee: Jiangsu Ainuoli Intelligent Equipment Co ltd; Wuxi Yongli Printing & Dyeing Equipment Co ltd
Current assignee: Jiangsu Ainuoli Intelligent Equipment Co ltd; Wuxi Yongli Printing & Dyeing Equipment Co ltd
Priority date: 2022-08-15
Filing date: 2022-08-15
Publication date: 2023-11-10
Anticipated expiration: 2042-08-15
Also published as: CN115369596A

Abstract

The invention relates to an intelligent transverse door high-temperature high-pressure dyeing machine which comprises a dyeing cylinder body, wherein a retaining ring shell is arranged in the middle of the dyeing cylinder body, an adjusting component is arranged at the lower end of the dyeing cylinder body, a feed inlet and a discharge outlet are fixedly arranged on the outer side of the upper part of the dyeing cylinder body, the feed inlet is arranged on one side of the discharge outlet, a support plate is arranged on the side surface of the discharge outlet, a winding component and a transmission component are arranged on the support plate, and the winding component is arranged on one side of the transmission component. The sliding plate slides and sets up in the second guide way, at this moment under the fixed auxiliary bull stick effect that is provided with in reel one side, can make reel and the first motor of one side overcome spring force and take place to remove, when the reel removes to second guide way department, the reel rolling is the most, stops at this moment and stops the reel, takes off along the second guide way can, easy operation is convenient, labour saving and time saving.

Description

Intelligent transverse door high-temperature high-pressure dyeing machine

Technical Field

The invention relates to the technical field of dyeing machines, in particular to an intelligent transverse door high-temperature high-pressure dyeing machine.

Background

The dyeing machine is made of all stainless steel, has the advantages of no noise, convenient speed regulation and the like, and is suitable for hemp, cotton, rayon, blended seamless underwear, silk stockings, silk and the like. The dye liquor is stirred in the forward and reverse directions of the blades, so that the dye is in a float dyeing state, and the dye liquor is uniform in dyeing and strong in penetrating power and is not easy to damage the dye liquor.

The existing dyeing machine has the advantages that the discharging mode is that the dyed textiles are conveyed and piled into a square box through a conveying shaft, when the textiles are processed in the next step, the dyeing space of a dyeing cylinder of the traditional dyeing machine cannot be adjusted. When the number of textiles to be dyed is small and the internal dyeing space is still large, the situation of wasting resources occurs, which is unfavorable for use.

In order to solve the problems, the invention provides an intelligent transverse door high-temperature high-pressure dyeing machine.

Disclosure of Invention

(1) Technical problem to be solved

The invention aims to solve the problems in the prior art, adapt to the actual needs, and provide an intelligent transverse door high-temperature high-pressure dyeing machine so as to solve the technical problems.

(2) Technical proposal

In order to achieve the purpose of the invention, the technical scheme adopted by the invention is as follows: the utility model provides an intelligence is violently opened door high temperature high pressure dyeing machine, includes the dyeing cylinder body, the middle part of dyeing cylinder body is provided with the retainer ring shell, the lower extreme of dyeing cylinder body is equipped with adjusting part, the upper portion outside of dyeing cylinder body is fixed to be provided with feed inlet and discharge gate, the feed inlet sets up in one side of discharge gate, the side of discharge gate is provided with the extension board, is provided with rolling subassembly and drive assembly on this extension board, and this rolling subassembly sets up in one side of drive assembly.

Preferably, a first arc wall and a second arc wall are arranged at the joint of one side of the cylinder body and the holding shell, the second arc wall is arranged at one side of the first arc wall, the outer wall of the holding shell is bent inwards, the outer wall of the holding shell is bent outwards, and the inner wall and the outer wall are elliptical.

Preferentially, the adjusting component comprises a base, the base is arranged on the lower side of the dyeing cylinder body, supporting pieces are arranged on two sides of the base and extend to the lower surface of the dyeing cylinder body, a hydraulic ram is fixedly arranged in the middle of the base, one end of the hydraulic ram is fixedly arranged on the base, and the other end of the hydraulic ram is arranged on the lower surface of the dyeing cylinder body.

Preferentially, the outlet end of the discharge hole is provided with a buckle cover, one end of the buckle cover is rotatably arranged on one side of the discharge hole, one end of the buckle cover is rotatably provided with an arc plate, a limiting plate is slidably arranged on the arc plate, a threaded hole is formed in the limiting plate, an assembly hole is formed in the arc plate, a transmission rod is rotatably arranged in the assembly hole, and the transmission rod penetrates through the assembly hole and the threaded hole.

Preferentially, the support plate comprises an upper support plate and a lower support plate, the upper support plate is arranged on the upper side of the lower support plate, a first guide groove and a second guide groove are formed in the upper support plate, the first guide groove is formed horizontally, and the second guide groove is formed vertically.

Preferentially, the winding assembly comprises a first sliding block, the first sliding block is arranged in the lower support plate in a sliding mode, a supporting block is arranged on the upper surface of the first sliding block in a swinging mode, a winding shaft is arranged at the upper end of the supporting block in a rotating mode, one end of the winding shaft is arranged on the upper side of the supporting block in a rotating mode, the other end of the winding shaft extends into the first guide groove, and an auxiliary rotating rod is arranged on one side of the winding shaft.

Preferentially, the transmission assembly comprises a sliding plate, the sliding plate is arranged in the second guide groove in a sliding mode, a first motor is arranged at two ends of the sliding plate, a second motor is arranged in the middle of the sliding plate, a spring is arranged on one side of the sliding plate, a first friction wheel is arranged on a rotating shaft of the first motor, a second friction wheel is arranged on one side of the first friction wheel, the second friction wheel is fixedly arranged on the winding shaft, and an auxiliary assembly is arranged on the rotating shaft of the second motor.

Preferably, the auxiliary assembly comprises a support column, an auxiliary slide rod is slidably arranged in the support column, a rolling ball is arranged at the end part of the auxiliary slide rod, and a crank slide block mechanism is arranged between the auxiliary slide rod and the second motor.

Preferentially, be equipped with sliding component between slider-crank mechanism with auxiliary slide bar, sliding component is including the fixed rectangle side pipe that sets up on slider-crank mechanism, but rectangle side intraductal be provided with reciprocating motion's rectangle pole, auxiliary slide bar and rectangle pole fixed connection, rectangle pole with fixed be provided with a extension spring between the rectangle side pipe bottom, rectangle side pipe is close to the one end of extension spring sets up to the inclined plane, the inclined plane is close to the one end of extension spring is provided with the triangle fixture block, the inside upside of rectangle side pipe be provided with one with triangle fixture block matched with triangle groove, auxiliary slide bar is close to one side of rolling axle side and is provided with an arcwall face.

Preferentially, the middle part of the winding shaft is hollow, and the outer wall is provided with a through hole.

(3) The beneficial effects are that:

A. one side of the cylinder body is provided with a first arc-shaped wall and a second arc-shaped wall, wherein the second arc-shaped wall is bent towards the inside of the cylinder body to form a certain inclination, when the dyeing cylinder body moves towards the middle part of the holding ring shell through the adjusting component, the inner wall of the holding ring shell is bent outwards from the middle part to form a certain angle, the first arc-shaped wall and the second arc-shaped wall are firmly extruded together, so that a sealing effect is finally realized, and compared with the traditional rubber ring sealing mode, the sealing effect is better, and also, when the dyeing cylinder body moves towards the two ends through the adjusting component, the first arc-shaped wall can be matched with the holding ring shell to realize the sealing effect, so that the outflow of dyeing liquid is prevented, and the dyeing of textiles is influenced;

B. the adjusting component is arranged at the lower side of the dyeing cylinder body, when the dyeing machine works, if the textiles to be dyed are not much, the adjusting component is started to enable the hydraulic jack to act, so that the dyeing cylinder body connected with the adjusting component is driven to move towards the retaining ring shell, and finally, the reduction of the internal space of the dyeing cylinder body is realized, and the heating is more time-saving and energy-saving. When more textiles to be processed and dyed are needed, the adjusting component is started to move the dyeing cylinder body towards two ends, so that the increase of the inner space is realized, and the processing and dyeing efficiency is improved. The adjusting component is arranged to adjust the internal space of the dyeing cylinder body, so that the practicability is greatly improved;

C. the discharge hole is rotationally provided with the buckle cover, when the buckle cover is buckled, the arc-shaped plate is put down, the limiting plate is arranged below the edge of the discharge hole, then the transmission rod is rotated, the limiting plate moves upwards through the threaded hole at the end part of the limiting plate, the limiting plate moves upwards along the axial direction of the transmission rod and can prop against the lower side of the edge of the discharge hole, the transmission rod is rotated again, the limiting plate can not move any more, the buckle cover is closed, the structure replaces the traditional method of realizing the closure of the cover body through screwing by a plurality of threads, the operation is simplified, time and labor are saved, and the production efficiency is benefited;

D. the winding shaft in the winding assembly is rotationally arranged on the supporting block, after the dyeing machine finishes dyeing the textile, the traditional discharging mode is that the dyed textile is conveyed and piled into a square box through the transmission shaft, when the textile is processed in the next step, the winding shaft is very inconvenient, and the dyed textile can be wound regularly through the rotation of the transmission assembly, so that the textile is beneficial to the subsequent processing treatment of the textile;

E. the first motor is started, the rotation direction of the first motor is clockwise, the winding shaft is driven to rotate through the first friction wheel to wind the textile, the diameter of the winding shaft is gradually increased until the wound textile contacts with the auxiliary rotating rod, meanwhile, the spring is arranged on one side of the first motor, certain elastic force is applied to the spring, when the winding shaft winds the textile, the winding shaft and the auxiliary rotating rod are extruded, a large amount of water in the textile can be discharged in the process to ensure dyeing quality, and the regular winding of the textile is convenient for subsequent reprocessing. When the winding shaft moves to the second guide groove, the winding shaft is wound to the maximum and one side of the winding shaft loses support, and at the moment, the first motor rotates clockwise, so that the winding shaft automatically falls down along the second guide groove, the effect of removing the winding shaft which is wound is achieved, the action is achieved automatically through the increasing diameter of the winding shaft in the winding process, independent operation is not needed, and the winding shaft is convenient to take care, saves time and labor;

F. the textile is mostly banded, when carrying out dyeing to the textile, can not guarantee its roughness, can appear the circumstances that the part was folded together, lead to the partial uneven thickness of textile, the width is irregular, consequently, when carrying out the rolling to the textile, can appear the phenomenon that rolling thickness is different everywhere of rolling axle, this auxiliary assembly is during operation, place the spin department with the textile at first, start the second motor afterwards, when the second motor starts rotatory, make supplementary slide bar reciprocate through slider-crank mechanism, simultaneously, the textile is also driven, this result is not only very effectual this drawback of rolling axle rolling thickness of having improved, the mechanism reciprocates in addition, can also extrude the partial water branch of textile and flow from the through-hole.

Drawings

FIG. 1 is a schematic perspective view of an intelligent cross-door high-temperature high-pressure dyeing machine;

FIG. 2 is a schematic view of another angle structure of an intelligent cross-door high-temperature high-pressure dyeing machine according to the present invention;

FIG. 3 is a cross-sectional view of an intelligent cross-door high temperature high pressure dyeing machine according to the present invention;

FIG. 4 is a schematic diagram of the structure of the intelligent cross-door high-temperature high-pressure dyeing machine shown in FIG. 3A;

FIG. 5 is a schematic view of the intelligent cross-door high-temperature high-pressure dyeing machine according to another embodiment of the present invention;

FIG. 6 is a cross-sectional view of an intelligent cross-door high temperature high pressure dyeing machine according to the present invention;

FIG. 7 is another angular cross-sectional view of an intelligent cross-door high temperature high pressure dyeing machine according to the present invention;

FIG. 8 is a schematic diagram of a second guide slot of the intelligent cross-door high-temperature high-pressure dyeing machine;

FIG. 9 is a schematic view of a slide assembly according to the present invention.

The reference numerals are as follows:

the dyeing machine comprises a dyeing cylinder body, 12-first arc walls, 13-second arc walls, 2-retaining ring shells, 3-adjusting components, 31-bases, 32-supporting components, 33-hydraulic jacks, 4-discharging ports, 41-buckle covers, 42-arc plates, 43-limiting plates, 431-threaded holes, 44-assembly holes, 45-rotating rods, 5-supporting plates, 51-upper supporting plates, 511-first guide grooves, 512-second guide grooves, 52-lower supporting plates, 6-rolling components, 61-first sliding blocks, 62-supporting plates, 63-rolling shafts, 631-through holes, 64-auxiliary rotating rods, 7-transmission components, 71-sliding plates, 72-first motors, 721-first friction wheels, 722-second friction wheels, 73-second motors, 74-springs, 8-auxiliary components, 81-supporting columns, 82-auxiliary sliding rods, 83-rolling balls and 84-crank sliding block mechanisms.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

The invention is further illustrated by the following examples in connection with figures 1-9:

in this embodiment, as shown in fig. 1-9, an intelligent horizontal door high temperature high pressure dyeing machine comprises a dyeing cylinder body 1, the middle part of the dyeing cylinder body 1 is provided with a retaining ring shell 2, the lower extreme of the dyeing cylinder body 1 is provided with an adjusting component 3, the upper portion outside of the dyeing cylinder body 1 is fixedly provided with a feed inlet and a discharge outlet 4, the feed inlet is arranged on one side of the discharge outlet 4, the side of the discharge outlet 4 is provided with a support plate 5, a winding component 6 and a transmission component 7 are arranged on the support plate 5, and the winding component 6 is arranged on one side of the transmission component 7. And placing the textile to be dyed along the feeding port, opening the discharging port 4 for discharging after dyeing is finished, placing the textile on the winding component 6, and starting the transmission component 7 to enable the winding component 6 to rotate for winding.

The connecting part of one side of the cylinder body 1 and the holding shell 2 is provided with a first arc-shaped wall 12 and a second arc-shaped wall 13, the second arc-shaped wall 13 is arranged on one side of the first arc-shaped wall 12, the outer wall of the holding shell 2 is bent inwards, the inner wall is bent outwards, and the inner wall and the outer wall are elliptical. One side of the cylinder body 1 is provided with a first arc wall 12 and a second arc wall 13, wherein the second arc wall 13 is bent inwards to form a certain inclination, when the dyeing cylinder body 1 moves towards the middle part retaining ring shell 2 through the adjusting component 3, the inner wall of the retaining ring shell 2 is bent outwards to form a certain angle from the middle part, the inner wall and the retaining ring shell are firmly extruded together, the sealing effect is finally achieved, and compared with the traditional rubber ring sealing mode, the sealing effect is better, and likewise, when the inner space of the dyeing cylinder body 1 increases towards two ends through the adjusting component 3, the first arc wall 12 can be matched with the retaining ring shell 2, the sealing effect is achieved, the outflow of dyeing liquid is prevented, and the dyeing of textiles is affected.

The adjusting component 3 comprises a base 31, the base 31 is arranged on the lower side of the dyeing cylinder body 1, supporting pieces 32 are arranged on two sides of the base 31, the supporting pieces 32 extend to the lower surface of the dyeing cylinder body 1, a hydraulic ram 33 is fixedly arranged in the middle of the base 31, one end of the hydraulic ram 33 is fixedly arranged on the base 31, and the other end of the hydraulic ram is arranged on the lower surface of the dyeing cylinder body 1. The adjusting component 3 is arranged at the lower side of the dyeing cylinder body 1, when the dyeing machine works, if the textiles to be dyed are not much, the adjusting component 3 is started to enable the hydraulic jack 33 to act, so that the dyeing cylinder body 1 connected with the adjusting component is driven to move towards the retaining ring shell 2, and finally, the reduction of the internal space of the dyeing cylinder body 1 is realized, and the heating is more time-saving and energy-saving. When more textiles to be dyed need to be processed, the adjusting component 3 is started to move the dyeing cylinder body 1 towards two ends, namely the increase of the inner space is realized, and the processing dyeing efficiency is improved. The setting of this adjusting part 3 has realized the regulation to dyeing cylinder body 1 inner space, has improved its practicality greatly.

The outlet end of the discharge port 4 is provided with a buckle cover 41, one end of the buckle cover 41 is rotatably arranged on one side of the discharge port 4, one end of the buckle cover 41 is rotatably provided with an arc plate 42, a limiting plate 43 is slidably arranged on the arc plate 42, a threaded hole 431 is formed in the limiting plate 43, an assembly hole 44 is formed in the arc plate 42, a transmission rod 45 is rotatably arranged in the assembly hole 44, and the transmission rod 45 penetrates through the assembly hole 44 and the threaded hole 431. The rotation is provided with buckle closure 41 on discharge gate 4, when this buckle closure 41 is fastened, put down arc 42, make limiting plate 43 place discharge gate 4 mouthful down, then rotatory transfer line 45, transfer line 45 rotates and makes limiting plate 43 upwards move through the screw hole 431 of limiting plate 43 tip, limiting plate 43 moves upwards along transfer line 45 axis direction, can support discharge gate 4 mouthful along the downside, rotatory transfer line 45 again, limiting plate 43 can not take place to remove again, buckle closure 41 is closed, the setting of this structure has replaced traditional closure of realizing the lid through a plurality of screw threads screwing, and is simplified the operation, labour saving and time saving is of value to production efficiency.

The support plate 5 comprises an upper support plate 51 and a lower support plate 52, the upper support plate 51 is arranged on the upper side of the lower support plate 52, a first guide groove 511 and a second guide groove 512 are formed in the upper support plate 51, the first guide groove 511 is formed horizontally, and the second guide groove 512 is formed vertically. Wherein the contact part of the upper support plate 51 and the cylinder body 1 is not fixed, and the arrangement of the upper support plate 51 and the lower support plate 52 ensures the implementation of the invention for movable contact.

The winding assembly 6 comprises a first sliding block 61, the first sliding block 61 is slidably arranged in the lower support plate 52, a supporting block 62 is arranged on the upper surface of the first sliding block 61 in a swinging mode, a winding shaft 63 is rotatably arranged at the upper end of the supporting block 62, one end of the winding shaft 63 is rotatably arranged on the upper side of the supporting block 62, the other end of the winding shaft extends into the first guide groove 511, and an auxiliary rotating rod 64 is arranged on one side of the winding shaft 63. The winding shaft 63 in the winding assembly 6 is rotationally arranged on the supporting block 62, after the dyeing machine finishes dyeing the textile, the traditional discharging mode is that the dyed textile is conveyed and piled into a square box through the transmission shaft, when the textile is processed in the next step, the winding shaft 63 is rotated through the transmission assembly 7, the dyed textile can be wound regularly, and the textile is beneficial to the subsequent processing treatment of the textile.

The transmission assembly 7 comprises a sliding plate 71, the sliding plate 71 is slidably arranged in a second guide groove 512, two ends of the sliding plate 71 are provided with a first motor 72, the middle part is provided with a second motor 73, one side of the sliding plate 71 is provided with a spring 74, a rotating shaft of the first motor 72 is provided with a first friction wheel 721, one side of the first friction wheel 721 is provided with a second friction wheel 722, the second friction wheel 722 is fixedly arranged on the winding shaft 63, and the rotating shaft of the second motor 73 is provided with an auxiliary assembly 8. The sliding plate 71 is slidably disposed in the second guiding groove 512, and one end of the spring 74 applies an elastic force to the sliding plate, so that the first friction wheel 721 and the second friction wheel 722 on the rotating shaft of the first motor 72 fixedly disposed on the sliding plate 71 are in close contact to achieve a transmission effect. The first motor 72 is started, the rotation direction of the first motor is clockwise, the winding shaft 63 is driven to rotate by the first friction wheel 721 to wind the textile, the diameter of the winding shaft 63 is gradually increased until the wound textile contacts with the auxiliary rotating rod 64 during winding, meanwhile, the spring 74 is arranged on one side of the first motor 72 and applies certain elastic force to the winding shaft, so that when the winding shaft 63 winds the textile, the winding shaft 63 is extruded by the winding shaft 63 and the auxiliary rotating rod 64, a large amount of water in the textile can be discharged in the process to ensure the dyeing quality, and the regular winding of the textile can be neatly wound to facilitate subsequent reprocessing. At the same time of this action, the first motor 72 on one side of the winding shaft 63 is abutted against the winding shaft 63 and the auxiliary component 8 which is also fixedly arranged on the sliding plate 71 moves against the elastic force of the spring 74, when the winding shaft 63 moves to the second guide groove 512, the winding shaft 63 is wound up to the maximum and one side loses support, at this time, the winding shaft 63 automatically falls down along the second guide groove 512 due to the clockwise rotation of the first motor 72, so that the effect of removing the winding shaft which is completed in winding is realized.

The auxiliary assembly 8 comprises a support column 81, an auxiliary slide rod 82 is slidably arranged in the support column 81, a rolling ball 83 is arranged at the end part of the auxiliary slide rod 82, and a crank slide block mechanism 84 is arranged between the auxiliary slide rod 82 and the second motor 73.

The sliding component is arranged between the slider-crank mechanism 84 and the auxiliary sliding rod 82, and comprises a rectangular square tube 821 fixedly arranged on the slider-crank mechanism 84, a rectangular rod 820 capable of moving reciprocally is arranged in the rectangular square tube 821, the auxiliary sliding rod 82 is fixedly connected with the rectangular rod 820, a tension spring 822 is fixedly arranged between the rectangular rod 820 and the bottom of the rectangular square tube 821, one end of the rectangular square tube 821, which is close to the tension spring 822, is provided with an inclined surface 827, one end, which is close to the tension spring 822, of the inclined surface 827 is provided with a triangular clamping block 824, a triangular groove 823 which is matched with the triangular clamping block 824 is formed in the upper side of the inner portion of the rectangular square tube 821, and one side surface, which is close to the winding shaft 63, of the auxiliary sliding rod 82 is provided with an arc-shaped surface 828. The fabric is mostly banded, when dyeing the fabric, the situation that can not guarantee its roughness, can appear partly folding together, lead to fabric part thickness uneven, the uneven width is irregular, consequently when rolling the fabric, can appear rolling the phenomenon that the thickness is different in spool 63 everywhere, this auxiliary assembly 8 during operation, place the fabric in spin department at first, start second motor 73 afterwards, wherein, second motor 73 one side slider-crank mechanism 84 comprises rectangle square pipe 821 and connecting rod 825 fixed connection by fixed carousel 874 that sets up in second motor 73 pivot front end and the connecting rod 825 that rotates setting up in carousel one side, the support column 81 is provided with the spout towards one side of connecting rod 825, connecting rod 825 has a spacing portion 826, spacing portion 826 can reciprocate in the spout, thereby drive the bull stick 825 and reciprocate, when second motor 73 starts rotatory, make auxiliary slide bar 82 reciprocate through slider-crank mechanism 84, simultaneously, the fabric is also driven, this result not only very effectively improves the uneven drawback of rolling thickness of spool 63, and the middle part that the mechanism reciprocated still can extrude the fabric from through-hole 631. The auxiliary slide bar 82 can be pushed by the winding shaft 63 along with the movement of the winding shaft 63 through the arrangement of 822, so that the auxiliary slide bar 82 can be always attached to the textile of the winding shaft 63, a good extrusion effect is achieved, and the auxiliary slide bar 82 is prevented from being blocked when the winding shaft 63 moves; when the winding shaft 63 can be wound to the maximum and one side loses support and falls down, the rectangular rod 820 and the auxiliary sliding rod 82 can be turned downwards, the auxiliary sliding rod 82 can be clamped in a downward inclined state but not completely turned over through the cooperation of the triangular clamping block 824 and the triangular groove 823, the winding shaft can be clamped in an inclined state under the cooperation of the arc-shaped surface 828, manual material collection can be facilitated, when the winding shaft is prevented from falling down on the ground completely, part of textiles are separated from the winding shaft 63 when falling down, the part of textiles need to be wound again, and dirt on the ground is also prevented from polluting the textiles.

The middle part of the winding shaft 63 is hollow, and a through hole 631 is arranged on the outer wall. The dyed textile mostly has more water, the middle part of the winding shaft 63 is hollow, and the outer wall is provided with a through hole 631 which is beneficial to the discharge of the water of the textile on the winding shaft.

The invention has the beneficial effects that:

the dyeing cylinder body 1 is provided with a first arc wall 12 and a second arc wall 13 on one side, wherein the second arc wall 13 is bent inwards to form a certain inclination, when the dyeing cylinder body 1 moves towards the middle part retaining ring shell 2 through the adjusting component 3, the inner wall of the retaining ring shell 2 is bent outwards to form a certain angle from the middle part, the first arc wall 12 and the second arc wall are firmly extruded together, so that a sealing effect is finally realized, compared with a traditional rubber ring sealing mode, the sealing effect is better, and also, when the inner space of the dyeing cylinder body 1 moves towards two ends through the adjusting component 3, the first arc wall 12 can be matched with the retaining ring shell 2 to realize the sealing effect, the outflow of dyeing liquid is prevented, and the dyeing of textiles is influenced;

the adjusting component 3 is arranged at the lower side of the dyeing cylinder body 1, when the dyeing machine works, if the textiles to be dyed are not much, the adjusting component 3 is started to enable the hydraulic jack 33 to act, so that the dyeing cylinder body 1 connected with the adjusting component is driven to move towards the retaining ring shell 2, and finally, the reduction of the internal space of the dyeing cylinder body 1 is realized, and the heating is more time-saving and energy-saving. When more textiles to be dyed need to be processed, the adjusting component 3 is started to move the dyeing cylinder body 1 towards two ends, namely the increase of the inner space is realized, and the processing dyeing efficiency is improved. The arrangement of the adjusting component 3 realizes the adjustment of the internal space of the dyeing cylinder body 1, thereby greatly improving the practicability;

the buckle cover 41 is rotatably arranged on the discharge hole 4, when the buckle cover 41 is buckled, the arc-shaped plate 42 is put down, the limiting plate 43 is arranged below the edge of the discharge hole 4, then the transmission rod 45 is rotated, the transmission rod 45 rotates and enables the limiting plate 43 to move upwards through the threaded hole 431 at the end part of the limiting plate 43, the limiting plate 43 moves upwards along the axis direction of the transmission rod 45 and can prop against the lower side of the edge of the discharge hole 4, the transmission rod 45 is rotated again, the limiting plate 43 can not move any more, the buckle cover 41 is closed, the structure replaces the traditional method of realizing the closure of the cover body through screwing a plurality of threads, the operation is simplified, time and labor are saved, and the production efficiency is benefited;

the winding shaft 63 in the winding assembly 6 is rotatably arranged on the supporting block 62, after the dyeing machine finishes dyeing the textile, the traditional discharging mode is that the dyed textile is conveyed and piled into a square box through the transmission shaft, when the textile is processed in the next step, the winding shaft 6 can regularly wind the dyed textile through the rotation of the transmission assembly 7, and the subsequent processing treatment of the textile is facilitated;

the first motor 72 is started, the rotation direction of the first motor is clockwise, the winding shaft 63 is driven to rotate by the first friction wheel 721 to wind the textile, the diameter of the winding shaft 63 is gradually increased until the wound textile contacts with the auxiliary rotating rod 64 during winding, meanwhile, the spring 74 is arranged on one side of the first motor 72 and applies certain elastic force to the winding shaft, so that when the winding shaft 63 winds the textile, the winding shaft 63 is extruded by the winding shaft 63 and the auxiliary rotating rod 64, a large amount of water in the textile can be discharged in the process to ensure the dyeing quality, and the regular winding of the textile can be neatly wound to facilitate subsequent reprocessing. At the same time of this action, the first motor 72 on one side of the winding shaft 63 is abutted against the winding shaft 63 and the auxiliary component 8 which is also fixedly arranged on the sliding plate 71 moves against the elastic force of the spring 74, when the winding shaft 63 moves to the second guide groove 512, the winding shaft 63 is wound up to the maximum and one side loses support, at the same time, the winding shaft 63 automatically falls down along the second guide groove 512 due to the clockwise rotation of the first motor 72, so that the effect of removing the winding shaft which is completed in the winding process is realized, the action is realized automatically through the increasing diameter of the winding shaft 63 in the winding process, independent operation is not needed, and the winding shaft 63 is convenient to take care, saves time and labor;

the textile is mostly banded, when dyeing textile, the roughness can not be guaranteed, the situation that part is folded together can appear, the thickness of the textile part is uneven, the width is uneven, therefore, when the textile is rolled, the phenomenon that the rolling thickness of the rolling shaft 63 is different in all parts can appear, when the auxiliary component 8 is operated, firstly, the textile is placed at the rolling ball, then the second motor 73 is started, wherein, a crank slider mechanism 84 on one side of the second motor 73 consists of a rotating disc at the front end of the rotating shaft of the second motor 73 and a connecting rod on one side of the rotating disc, when the second motor 73 is started to rotate, the auxiliary sliding rod 82 is enabled to move up and down through the crank slider mechanism 84, meanwhile, the textile is also driven, the defect that the rolling shaft 63 is uneven in rolling thickness is effectively improved, and the middle part of the textile can be extruded out of the through hole 631 when the mechanism moves up and down.

Working principle:

the dyeing cylinder body 1 is provided with a first arc-shaped wall 12 and a second arc-shaped wall 13 at one side, wherein the second arc-shaped wall 13 bends inwards to form a certain inclination, when the dyeing cylinder body 1 moves towards the middle part retaining ring shell 2 through the adjusting component 3, the inner wall of the retaining ring shell 2 bends outwards to form a certain angle from the middle part, and the inner wall and the retaining ring shell are firmly extruded together, so that a sealing effect is finally realized; the adjusting component 3 is arranged at the lower side of the dyeing cylinder body 1, when the dyeing machine works, if the textiles to be dyed are not much, the adjusting component 3 is started to enable the hydraulic jack 33 to act, so that the dyeing cylinder body 1 connected with the adjusting component is driven to move towards the retaining ring shell 2, and finally, the reduction of the internal space of the dyeing cylinder body 1 is realized, and the heating is more time-saving and energy-saving. When more textiles to be dyed need to be processed, the adjusting component 3 is started to move the dyeing cylinder body 1 towards two ends, namely the increase of the inner space is realized, and the processing dyeing efficiency is improved. The arrangement of the adjusting component 3 realizes the adjustment of the internal space of the dyeing cylinder body 1, thereby greatly improving the practicability; the buckle cover 41 is rotatably arranged on the discharge hole 4, when the buckle cover 41 is buckled, the arc-shaped plate 42 is put down, the limiting plate 43 is arranged below the edge of the discharge hole 4, then the transmission rod 45 is rotated, the transmission rod 45 rotates and enables the limiting plate 43 to move upwards through the threaded hole 431 at the end part of the limiting plate 43, the limiting plate 43 moves upwards along the axis direction of the transmission rod 45 and can prop against the lower side of the edge of the discharge hole 4, the transmission rod 45 is rotated again, the limiting plate 43 can not move any more, the buckle cover 41 is closed, the structure replaces the traditional method of realizing the closure of the cover body through screwing a plurality of threads, the operation is simplified, time and labor are saved, and the production efficiency is benefited; the winding shaft 63 in the winding assembly 6 is rotatably arranged on the supporting block 62, after the dyeing machine finishes dyeing the textile, the traditional discharging mode is that the dyed textile is conveyed and piled into a square box through the transmission shaft, when the textile is processed in the next step, the winding shaft 6 can regularly wind the dyed textile through the rotation of the transmission assembly 7, and the subsequent processing treatment of the textile is facilitated; the first motor 72 is started, the rotation direction of the first motor is clockwise, the winding shaft 63 is driven to rotate by the first friction wheel 721 to wind the textile, the diameter of the winding shaft 63 is gradually increased until the wound textile contacts with the auxiliary rotating rod 64 during winding, meanwhile, the spring 74 is arranged on one side of the first motor 72 and applies certain elastic force to the winding shaft, so that when the winding shaft 63 winds the textile, the winding shaft 63 is extruded by the winding shaft 63 and the auxiliary rotating rod 64, a large amount of water in the textile can be discharged in the process to ensure the dyeing quality, and the regular winding of the textile can be neatly wound to facilitate subsequent reprocessing. At the same time of this action, the first motor 72 on one side of the winding shaft 63 is abutted against the winding shaft 63 and the auxiliary component 8 which is also fixedly arranged on the sliding plate 71 moves against the elastic force of the spring 74, when the winding shaft 63 moves to the second guide groove 512, the winding shaft 63 is wound up to the maximum and one side loses support, at the same time, the winding shaft 63 automatically falls down along the second guide groove 512 due to the clockwise rotation of the first motor 72, so that the effect of removing the winding shaft which is completed in the winding process is realized, the action is realized automatically through the increasing diameter of the winding shaft 63 in the winding process, independent operation is not needed, and the winding shaft 63 is convenient to take care, saves time and labor; the textile is mostly banded, when dyeing textile, the roughness can not be guaranteed, the situation that part is folded together can appear, the thickness of the textile part is uneven, the width is uneven, therefore, when the textile is rolled, the phenomenon that the rolling thickness of the rolling shaft 63 is different in all parts can appear, when the auxiliary component 8 is operated, firstly, the textile is placed at the rolling ball, then the second motor 73 is started, wherein, a crank slider mechanism 84 on one side of the second motor 73 consists of a rotating disc at the front end of the rotating shaft of the second motor 73 and a connecting rod on one side of the rotating disc, when the second motor 73 is started to rotate, the auxiliary sliding rod 82 is enabled to move up and down through the crank slider mechanism 84, meanwhile, the textile is also driven, the defect that the rolling shaft 63 is uneven in rolling thickness is effectively improved, and the middle part of the textile can be extruded out of the through hole 631 when the mechanism moves up and down.

The auxiliary slide bar 82 can be pushed by the winding shaft 63 along with the movement of the winding shaft 63 through the arrangement of 822, so that the auxiliary slide bar 82 can be always attached to the textile of the winding shaft 63, a good extrusion effect is achieved, and the auxiliary slide bar 82 is prevented from being blocked when the winding shaft 63 moves; when the winding shaft 63 can be wound to the maximum and one side loses support and falls down, the rectangular rod 820 and the auxiliary sliding rod 82 can be turned downwards, the auxiliary sliding rod 82 can be clamped in a downward inclined state but not completely turned over through the cooperation of the triangular clamping block 824 and the triangular groove 823, the winding shaft can be clamped in an inclined state under the cooperation of the arc-shaped surface 828, manual material collection can be facilitated, when the winding shaft is prevented from falling down on the ground completely, part of textiles are separated from the winding shaft 63 when falling down, the part of textiles need to be wound again, and dirt on the ground is also prevented from polluting the textiles.

The embodiments of the present invention are disclosed as preferred embodiments, but not limited thereto, and those skilled in the art will readily appreciate from the foregoing description that various extensions and modifications can be made without departing from the spirit of the present invention.

Claims

1. The utility model provides an intelligent horizontal door high temperature high pressure dyeing machine, includes dyeing cylinder body (1), its characterized in that, the middle part of dyeing cylinder body (1) is provided with keeps ring shell (2), the lower extreme of dyeing cylinder body (1) is equipped with adjusting part (3), the upper portion outside of dyeing cylinder body (1) is fixed to be provided with feed inlet and discharge gate (4), the feed inlet sets up in one side of discharge gate (4), the side of discharge gate (4) is provided with extension board (5), is provided with rolling subassembly (6) and drive assembly (7) on this extension board (5), and this rolling subassembly (6) set up in one side of drive assembly (7); a first arc-shaped wall (12) and a second arc-shaped wall (13) are arranged at the joint of one side of the dyeing cylinder body (1) and the retaining ring shell (2), the second arc-shaped wall (13) is arranged at one side of the first arc-shaped wall (12), the outer wall of the retaining ring shell (2) is bent inwards, the inner wall is bent outwards, and the inner wall and the outer wall are elliptical; the adjusting component (3) comprises a base (31), wherein the base (31) is arranged on the lower side of the dyeing cylinder body (1), supporting pieces (32) are arranged on two sides of the base (31), the supporting pieces (32) extend to the lower surface of the dyeing cylinder body (1), a hydraulic ram (33) is fixedly arranged in the middle of the base (31), one end of the hydraulic ram (33) is fixedly arranged on the base (31), and the other end of the hydraulic ram is arranged on the lower surface of the dyeing cylinder body (1); when the dyeing cylinder body moves to the middle part through the adjusting component, the inner wall of the retaining ring shell is bent outwards to form a certain angle from the middle part, so that the inner wall and the retaining ring shell can be firmly extruded together, the sealing effect is finally achieved, and when the inner space of the dyeing cylinder body is increased to the two ends through the adjusting component, the first arc-shaped wall can be matched with the retaining ring shell to achieve the sealing effect.

2. An intelligent cross door high temperature high pressure dyeing machine as claimed in claim 1, wherein: the utility model discloses a discharge gate (4), including discharge gate (4), buckle closure (41), arc (42) are provided with in one side of discharge gate (4) in the rotation of one end of this buckle closure (41), and the one end is rotated and is provided with limiting plate (43) on this arc (42), has offered threaded hole (431) on this limiting plate (43), set up pilot hole (44) on arc (42), this pilot hole (44) rotation is provided with transfer line (45), and this transfer line (45) run through pilot hole (44) and threaded hole (431).

3. An intelligent cross door high temperature high pressure dyeing machine as claimed in claim 2, wherein: the support plate (5) comprises an upper support plate (51) and a lower support plate (52), the upper support plate (51) is arranged on the upper side of the lower support plate (52), the upper support plate (51) is provided with a first guide groove (511) and a second guide groove (512), the first guide groove (511) is horizontally arranged, and the second guide groove (512) is vertically arranged.

4. An intelligent cross door high temperature high pressure dyeing machine as claimed in claim 3, wherein: the winding assembly (6) comprises a first sliding block (61), the first sliding block (61) is arranged in the lower support plate (52) in a sliding mode, a supporting block (62) is arranged on the upper surface of the first sliding block (61) in a swinging mode, a winding shaft (63) is arranged at the upper end of the supporting block (62) in a rotating mode, one end of the winding shaft (63) is arranged on the upper side of the supporting block (62) in a rotating mode, the other end of the winding shaft extends into the first guide groove (511), and an auxiliary rotating rod (64) is arranged on one side of the winding shaft (63).

5. The intelligent cross door high temperature and high pressure dyeing machine according to claim 4, wherein: the transmission assembly (7) comprises a sliding plate (71), the sliding plate (71) is arranged in a second guide groove (512) in a sliding mode, a first motor (72) is arranged at two ends of the sliding plate (71), a second motor (73) is arranged in the middle of the sliding plate, a spring (74) is arranged on one side of the sliding plate (71), a first friction wheel (721) is arranged on a rotating shaft of the first motor (72), a second friction wheel (722) is arranged on one side of the first friction wheel (721), the second friction wheel (722) is fixedly arranged on a winding shaft (63), and an auxiliary assembly (8) is arranged on a rotating shaft of the second motor (73).

6. The intelligent cross door high temperature and high pressure dyeing machine according to claim 5, wherein: the auxiliary assembly (8) comprises a support column (81), an auxiliary sliding rod (82) is arranged in the support column (81) in a sliding mode, a rolling ball (83) is arranged at the end portion of the auxiliary sliding rod (82), and a crank sliding block mechanism (84) is arranged between the auxiliary sliding rod (82) and the second motor (73).

7. The intelligent cross door high temperature and high pressure dyeing machine according to claim 6, wherein: the utility model provides a crank slider mechanism (84) with be equipped with sliding component between auxiliary slide bar (82), sliding component is including fixed rectangle side pipe (821) that set up on crank slider mechanism (84), but be provided with reciprocating motion's rectangle pole (820) in rectangle side pipe (821), auxiliary slide bar ((82)) and rectangle pole (820) fixed connection, rectangle pole (820) with fixedly be provided with extension spring (822) between rectangle side pipe (821) bottom, rectangle side pipe (821) are close to the one end of extension spring (822) is set up to inclined plane (827), inclined plane (827) are close to the one end of extension spring (822) is provided with triangle fixture block (824), the inside upside of rectangle side pipe (821) be provided with one with triangle fixture block (824) matched with triangle groove (823), auxiliary slide bar (82) are close to one side of rolling axle (63) and are provided with arc face (828).

8. The intelligent cross door high temperature and high pressure dyeing machine according to claim 7, wherein: the middle part of the winding shaft (63) is hollow, and a through hole (631) is formed in the outer wall of the winding shaft.