CN112210932B

CN112210932B - Textile water-saving dyeing machine based on electromagnetic adsorption technology

Info

Publication number: CN112210932B
Application number: CN202011279700.0A
Authority: CN
Inventors: 程建坤
Original assignee: Gaoyao Zicai Socks Industry Co ltd
Current assignee: GAOYAO ZICAI SOCKS INDUSTRY Co.,Ltd.
Priority date: 2020-11-16
Filing date: 2020-11-16
Publication date: 2021-05-14
Anticipated expiration: 2040-11-16
Also published as: CN112210932A

Abstract

The invention discloses a textile water-saving dyeing machine based on an electromagnetic adsorption technology, which comprises a dyeing machine tool, wherein a dyeing cavity with a forward opening and a left-right penetrating through is arranged in the dyeing machine tool, and a dropping groove with an upward opening is arranged in the bottom wall of the dyeing cavity; the dyeing tank is different from the traditional dyeing tank, a dyeing cavity capable of dyeing textile threads is formed in the film through the gravity of the film and the dye, the film is taken out after the dyeing work is finished, the phenomenon that the dye is remained in the wall of the dyeing tank due to long-time dyeing work, the color of the dye is impure can be avoided, the wall of the tank is not required to be cleaned after the dyeing work is finished, and water resources are saved; still be equipped with the device of changeing the line, can carry out the weaving line that dyes with needs and carry out the removal that lasts when carrying out dyeing work, ensure that the weaving line colour that dyes is the same, can not dye out the weaving line that the colour degree of depth is different because of the difference of dye concentration in the dyeing pond.

Description

Textile water-saving dyeing machine based on electromagnetic adsorption technology

Technical Field

The invention relates to the technical field of spinning, in particular to a spinning water-saving dyeing machine based on an electromagnetic adsorption technology.

Background

When the clothes are made, the textile yarns need to be dyed by using dyes to obtain required colors, in the dyeing process, because the dyeing time is generally longer, the dyes in the dyeing tank can be layered up and down, the concentrations of the dyes at different depths of the dyeing tank can be different, and the dyeing colors of the textile yarns dyed in the dyeing tank under the condition can be different. And because the dyeing pond is long-time dyeing work, dyes possibly remain in the wall, and cannot be removed after being continued for a long time, so that the subsequent dyeing work is influenced, and the color is different. And the wall of the tank needs to be washed after the dyeing work is finished, and a large amount of water resources are needed in the process. .

Disclosure of Invention

The invention aims to provide a textile water-saving dyeing machine based on an electromagnetic adsorption technology, which is used for overcoming the defects in the prior art.

The invention relates to a textile water-saving dyeing machine based on an electromagnetic adsorption technology, which comprises a dyeing machine tool, wherein a dyeing cavity with a forward opening and penetrating left and right is arranged in the dyeing machine tool, a falling groove with an upward opening is arranged in the bottom wall of the dyeing cavity, a taking-out groove penetrating through the front side surface of the dyeing machine tool is communicated in the front wall of the falling groove, four slide ways are arranged in the inner ring of the bottom wall of the dyeing cavity outside the falling groove, slide bars are arranged in the slide ways, slide blocks are connected on the slide bars in a sliding manner, the side surfaces of the slide blocks, which are close to the falling groove, are fixedly connected with the side walls of the slide ways, which are close to the falling groove, through reset springs, moving blocks are fixedly arranged on the slide blocks, first passing grooves with upward openings and penetrating left and right are arranged in the left and right two moving blocks, second passing grooves with openings, which, the second through groove and the first through groove are communicated with each other to form a first sliding groove, a clamping device capable of fixing the film is arranged in the first sliding groove, a film discharging box is fixedly arranged on the bottom wall of an opening at the left side of the dyeing cavity, a film discharging device capable of discharging the film is arranged in the film discharging box, a hydraulic cavity with a downward opening and opposite to the position of the falling groove is arranged in the top wall of the dyeing cavity, a hydraulic pump is fixedly arranged on the top wall of the hydraulic cavity, a hydraulic pipe is arranged on the bottom surface of the hydraulic pump, a rotating box is fixedly arranged on the bottom surface of the hydraulic pipe, a first rotating cavity is arranged in the rotating box, three groups of wire rotating devices capable of driving the spinning wire to rotate continuously are arranged in the first rotating cavity, sliding cavities symmetrical to the front and back of the hydraulic cavity are arranged in the dyeing machine tool, a first motor is fixedly arranged in the left wall of the sliding cavity, and a first threaded shaft rotatably connected with the right wall of the sliding, the dyeing machine tool is characterized in that a first moving block is connected to the first threaded shaft in a threaded manner, a connecting rod extending into the dyeing cavity is fixedly arranged on the bottom surface of the first moving block, the connecting rod is fixedly connected with the top surface of the electromagnetic absorber, and the dyeing machine tool is further provided with a feeding device for adding dye.

Optionally, the clamping device includes a second motor fixedly disposed in the top wall of the first sliding groove, a second threaded shaft is mounted on the bottom surface of the second motor, and a pressing block slidably connected to the first sliding groove is connected to the second threaded shaft through a thread.

Optionally, the film discharging device includes a second rotating cavity with a forward opening, a first rotating shaft is rotatably connected to the rear wall of the second rotating cavity, clamping blocks with symmetrical positions are fixedly arranged on the first rotating shaft, a sleeve is sleeved outside the first rotating shaft, a film is wound on the sleeve, clamping grooves with symmetrical positions and connected with the clamping blocks in a sliding manner are arranged on the inner side surface of the sleeve, a third rotating cavity is communicated with the right side of the second rotating cavity, a power cavity is arranged in the rear wall of the third rotating cavity, a second rotating shaft extending into the third rotating cavity is rotatably connected in the power cavity, a propelling wheel is fixedly arranged on the second rotating shaft in the third rotating cavity, a first gear meshed with each other is fixedly arranged on the second rotating shaft in the power cavity, and the second rotating shaft above the third rotating cavity is arranged on the front side surface of a third motor fixedly arranged on the rear wall of the power cavity, the third rotates the chamber right wall in-connection and is equipped with and runs through the delivery chute of play membrane case right flank, it is connected with the case lid to go out the rotation of membrane case front side.

Optionally, the device of changeing the line set up including rotating connect in the first third axis of rotation that rotates in the chamber antetheca, the third axis of rotation runs through forward rotate the case front surface, third axis of rotation front side end has set firmly the reel, and is left the third axis of rotation install set firmly in the fourth motor leading flank of first rotation chamber back wall, the right side is two the third axis of rotation with first rotation chamber back wall rotates and is connected, set firmly intermeshing's second gear on the third axis of rotation, the reel top rotate the case front surface and rotate and be connected with the intermediate wheel, the reel with around having the weaving line of waiting to dye on the intermediate wheel.

Optionally, feeding device including set up in deposit the chamber in the dyeing machine tool, be equipped with in depositing the chamber trailing flank and run through the filling tube of dyeing machine tool trailing flank, it is equipped with the water pump in the chamber roof to deposit, the water pump bottom surface is installed and is deepened deposit the drainage tube in chamber, the water pump top surface is installed and is extended to in the dyeing chamber and with the drain pipe that the lower slot position is relative.

Optionally, friction pads opposite to the pressing block are fixedly arranged on the bottom walls of the first through groove and the second through groove.

Optionally, the bottom surface of the dyeing machine tool is fixedly provided with a supporting foot.

The invention has the beneficial effects that:

firstly, different from the traditional dyeing tank, the dyeing tank can form a dyeing cavity capable of dyeing textile threads in the film through the gravity of the film and the dye, and the film is taken out after the dyeing work is finished, so that the phenomenon that the dye is remained in the tank wall of the dyeing tank due to long-time dyeing work and the color of the dye is impure can be avoided;

secondly, because the thin film is used for replacing the tank wall, the tank wall does not need to be cleaned after the dyeing work is finished, and water resources are saved;

thirdly, the invention is provided with the thread turning device, which can continuously move the textile thread to be dyed while dyeing, ensure the same color of the dyed textile thread and avoid the textile thread with different color depth due to the difference of dye concentration in the dyeing tank.

Drawings

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

FIG. 1 is a schematic structural diagram of a textile water-saving dyeing machine based on electromagnetic adsorption technology;

FIG. 2 is a schematic view of the structure of the film discharging box in FIG. 1;

FIG. 3 is a schematic view of the structure at A-A in FIG. 2;

FIG. 4 is a schematic view of the structure at B-B in FIG. 2;

FIG. 5 is a schematic view of the structure at C-C in FIG. 1;

FIG. 6 is a schematic view of the structure of FIG. 1 at D-D;

fig. 7 is a schematic view of the structure of the moving block in fig. 6.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1-7, the textile water-saving dyeing machine based on the electromagnetic adsorption technology according to the embodiment of the present invention includes a dyeing machine 11, a dyeing cavity 17 having a forward opening and penetrating left and right is disposed in the dyeing machine 11, a dropping groove 22 having an upward opening is disposed in a bottom wall of the dyeing cavity 17, a taking-out groove 70 penetrating a front side surface of the dyeing machine 11 is disposed in a front wall of the dropping groove 22, four slide ways 34 are disposed in an inner ring of a bottom wall of the dyeing cavity 17 outside the dropping groove 22, a slide bar 37 is disposed in the slide way 34, a slide block 35 is slidably connected to the slide bar 37, a side surface of the slide block 35 close to the dropping groove 22 is fixedly connected to a side wall of the slide way 34 close to the dropping groove 22 through a return spring 36, a moving block 38 is fixedly disposed on the slide block 35, a first through groove 40 having an upward opening and penetrating left and right is disposed in the left, a second through groove 64 with an opening facing the direction of the falling groove 22 and penetrating left and right is arranged in the front and rear moving blocks 38, a first sliding groove 43 is arranged in the top wall of the second through groove 64 and the first through groove 40 in a communicating manner, a clamping device 102 capable of fixing a thin film is arranged in the first sliding groove 43, a film discharging box 24 is fixedly arranged on the bottom wall of the opening at the left side of the dyeing cavity 17, a film discharging device 101 capable of discharging the thin film is arranged in the film discharging box 24, a hydraulic cavity 18 with a downward opening and opposite to the falling groove 22 is arranged in the top wall of the dyeing cavity 17, a hydraulic pump 19 is fixedly arranged on the top wall of the hydraulic cavity 18, a hydraulic pipe 20 is arranged on the bottom surface of the hydraulic pump 19, a rotating box 21 is fixedly arranged on the bottom surface of the hydraulic pipe 20, a first rotating cavity 52 is arranged in the rotating box 21, and three groups of rotating line devices capable of driving the textile line to continuously, the dyeing machine tool 11 is internally provided with a sliding cavity 15 which is symmetrical with the front and back of the hydraulic cavity 18, a first motor 13 is fixedly arranged in the left wall of the sliding cavity 15, a first threaded shaft 16 which is rotatably connected with the right wall of the sliding cavity 15 is arranged on the right side surface of the first motor 13, a first moving block 14 is connected onto the first threaded shaft 16 in a threaded manner, a connecting rod 12 which extends into the dyeing cavity 17 is fixedly arranged on the bottom surface of the first moving block 14, the connecting rod 12 is fixedly connected with the top surface of an electromagnetic absorber 45, and the dyeing machine tool 11 is further provided with a feeding device for adding dye.

Preferably, the clamping device 102 includes a second motor 44 fixedly disposed in the top wall of the first sliding groove 43, a second threaded shaft 42 is mounted on the bottom surface of the second motor 44, a pressing block 41 slidably connected to the first sliding groove 43 is threadedly connected to the second threaded shaft 42, when the second motor 44 is started, the second threaded shaft 42 is driven to rotate, and the pressing block 41 moves downward along with the rotation of the second threaded shaft 42 to press the film.

Preferably, go out membrane device 101 and rotate chamber 25 including the forward second of opening, it is connected with first rotation axis 29 to rotate on the second rotation chamber 25 rear wall, the fixture block 28 of symmetry in position has set firmly on first rotation axis 29, first rotation axis 29 overcoat has sleeve 26, around having the film on the sleeve 26, sleeve 26 medial surface be equipped with the symmetry in position and with fixture block 28 sliding connection's draw-in groove 27, second rotation chamber 25 right side intercommunication is equipped with third rotation chamber 30, be equipped with power chamber 48 in the third rotation chamber 30 rear wall, power chamber 48 internal rotation is connected with and extends to second rotation axis 50 in the third rotation chamber 30, in the third rotation chamber 30 set firmly propulsion wheel 31 on second rotation axis 50, in the power chamber 48 set firmly intermeshing's first gear 49 on the second rotation axis 50, the top the second rotation axis 50 install set firmly in third motor 47 front side on power chamber 48 rear wall The face, third rotation chamber 30 right side wall in-connection is equipped with and runs through output groove 33 of play membrane case 24 right flank, it is connected with case lid 51 to go out the rotation of membrane case 24 leading flank, when third motor 47 starts, through the top second axis of rotation 50 drives the first gear 49 rotation of top, and the first gear 49 of top drives the second axis of rotation 50 rotation of below through the first gear 49 of below, and second axis of rotation 50 drives two propulsion wheels 31 antiport, exports the film from output groove 33.

Preferably, the thread turning device comprises a third rotating shaft 55 rotatably connected and arranged in the front wall of the first rotating cavity 52, the third rotating shaft 55 forwardly penetrates through the front surface of the rotating box 21, a reel 57 is fixedly arranged at the front end of the third rotating shaft 55, the left third rotating shaft 55 is arranged on the front side surface of a fourth motor 53 fixedly arranged on the rear wall of the first rotating cavity 52, the two right third rotating shafts 55 are rotatably connected with the rear wall of the first rotating cavity 52, a second gear 54 meshed with each other is fixedly arranged on the third rotating shaft 55, an intermediate gear 63 is rotatably connected to the front surface of the rotating box 21 above the reel 57, the textile threads to be dyed are wound on the reel 57 and the intermediate gear 63, and when the fourth motor 53 is started, the left third rotating shaft 55 is driven to rotate, the left third rotating shaft 55 drives the intermediate second gear 54 to rotate through the left second gear 54, the middle second gear 54 drives the middle third rotating shaft 55 to rotate, the middle second gear 54 drives the right third rotating shaft 55 to rotate through the right second gear 54, the third rotating shaft 55 drives the reel 57 to rotate, the textile thread wound on the reel 57 is driven to continuously move, and the difference of the colors of the textile thread dyed due to the different concentrations caused by the dye precipitation can be avoided.

Preferably, the feeding device comprises a storage cavity 61 arranged in the dyeing machine tool 11, a feeding pipe 60 penetrating through the rear side surface of the dyeing machine tool 11 is arranged in the rear side surface of the storage cavity 61, a water pump 59 is arranged in the top wall of the storage cavity 61, a drainage pipe 62 penetrating into the storage cavity 61 is arranged on the bottom surface of the water pump 59, a drain pipe 58 extending into the dyeing cavity 17 and opposite to the position of the falling groove 22 is arranged on the top surface of the water pump 59, a user can add dyes into the storage cavity 61 from the feeding pipe 60, and when dyeing work is required, the water pump 59 is started to feed the dyes in the storage cavity 61 into the dyeing cavity 17 through the drainage pipe 62 and the drain pipe 58.

Preferably, the bottom walls of the first passing groove 40 and the second passing groove 64 are fixedly provided with a friction pad 39 opposite to the pressing block 41, and the friction pad 39 can prevent the film from sliding after the dye is filled in the film.

Preferably, the bottom surface of the dyeing machine 11 is fixedly provided with a supporting foot 23.

In the initial state, the first moving block 14 is located at the leftmost side of the sliding chamber 15, the pressing block 41 is completely located in the first sliding groove 43, and the return spring 36 is in a compressed state.

When the spinning thread dyeing work is required, the spinning thread is wound on the winding wheel 57, then the third motor 47 is started to output the film from the output groove 33, the electromagnetic absorber 45 is started to absorb the film, then the first motor 13 is started to drive the first threaded shaft 16 to rotate, the first moving block 14 moves rightwards along with the rotation of the first threaded shaft 16, the electromagnetic absorber 45 is driven to move rightwards through the connecting rod 12, the film is driven to pass through the first passing groove 40 and the second passing groove 64, then the second motor 44 is started to drive the second threaded shaft 42 to rotate to press the film, then the water pump 59 is started to introduce the dye in the storage cavity 61 into the dyeing cavity 17 through the drainage tube 62 and the drain tube 58, the film is driven to recess downwards due to the gravity of the dye and enters the lower drop groove 22, and then the sliding block 35 is driven to move towards the direction close to the lower drop groove 22 through the moving block 38, so that the film sinks deeply into the drop groove 22 to form a film pool capable of being dyed, then the hydraulic pump 19 is started, the rotating box 21 is driven by the hydraulic pipe 20 to move downwards to enter the drop groove 22, then the fourth motor 53 is started, the spinning thread wound on the reel 57 is driven to move continuously, and the spinning thread is dyed.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides a weaving water conservation dyeing machine based on electromagnetic adsorption technique, includes dyeing machine, its characterized in that: a dyeing cavity with a forward opening and penetrating left and right is arranged in the dyeing machine tool, a falling groove with an upward opening is arranged in the bottom wall of the dyeing cavity, a taking-out groove penetrating through the front side surface of the dyeing machine tool is communicated in the front wall of the falling groove, four slide ways are arranged in the inner ring of the bottom wall of the dyeing cavity outside the falling groove, a slide bar is arranged in each slide way, a slide block is connected on each slide bar in a sliding manner, the side surface of each slide block, which is close to the falling groove, is fixedly connected with the side wall of each slide way, which is close to the falling groove, through a reset spring, a moving block is fixedly arranged on each slide block, a first passing groove with an upward opening and penetrating left and right is arranged in each of the left and right two moving blocks, a second passing groove with an opening facing the falling groove and penetrating left and right is arranged in the front and back two moving blocks, a clamping device capable of fixing a film is arranged in the first sliding groove, a film discharging box is fixedly arranged on the bottom wall of an opening at the left side of the dyeing cavity, a film discharging device capable of discharging the film is arranged in the film discharging box, a hydraulic cavity with a downward opening and opposite to the position of the falling groove is arranged in the top wall of the dyeing cavity, a hydraulic pump is fixedly arranged on the top wall of the hydraulic cavity, a hydraulic pipe is arranged on the bottom surface of the hydraulic pump, a rotating box is fixedly arranged on the bottom surface of the hydraulic pipe, a first rotating cavity is arranged in the rotating box, three groups of spinning devices capable of driving a spinning thread to continuously rotate are arranged in the first rotating cavity, a sliding cavity with symmetrical front and back positions relative to the hydraulic cavity is arranged in the dyeing machine tool, a first motor is fixedly arranged in the left wall of the sliding cavity, a first threaded shaft rotationally connected with the right wall of the sliding cavity is arranged on the right side surface of the first motor, the bottom surface of the first moving block is fixedly provided with a connecting rod extending into the dyeing cavity, the connecting rod is fixedly connected with the top surface of the electromagnetic absorber, and the dyeing machine tool is further provided with a feeding device for adding dye.

2. The textile water-saving dyeing machine based on the electromagnetic adsorption technology as claimed in claim 1, is characterized in that: the clamping device comprises a second motor fixedly arranged in the top wall of the first sliding groove, a second threaded shaft is mounted on the bottom surface of the second motor, and a pressing block in sliding connection with the first sliding groove is in threaded connection with the second threaded shaft.

3. The textile water-saving dyeing machine based on the electromagnetic adsorption technology as claimed in claim 1, is characterized in that: the film discharging device comprises a second rotating cavity with a forward opening, a first rotating shaft is rotatably connected to the rear wall of the second rotating cavity, clamping blocks with symmetrical positions are fixedly arranged on the first rotating shaft, a sleeve is sleeved outside the first rotating shaft and wound with a film, clamping grooves with symmetrical positions and connected with the clamping blocks in a sliding manner are arranged on the inner side surface of the sleeve, a third rotating cavity is communicated with the right side of the second rotating cavity, a power cavity is arranged in the rear wall of the third rotating cavity, a second rotating shaft extending into the third rotating cavity is rotatably connected in the power cavity, a propelling wheel is fixedly arranged on the second rotating shaft in the third rotating cavity, a first gear meshed with each other is fixedly arranged on the second rotating shaft in the power cavity, and the second rotating shaft above the third rotating shaft is arranged on the front side surface of a third motor fixedly arranged on the rear wall of the power cavity, the third rotates the chamber right wall in-connection and is equipped with and runs through the delivery chute of play membrane case right flank, it is connected with the case lid to go out the rotation of membrane case front side.

4. The textile water-saving dyeing machine based on the electromagnetic adsorption technology as claimed in claim 1, is characterized in that: the line rotating device comprises a third rotating shaft which is rotatably connected and arranged in the front wall of the first rotating cavity, the third rotating shaft penetrates through the front surface of the rotating box forward, a reel is fixedly arranged at the tail end of the front side of the third rotating shaft, the third rotating shaft is arranged on the front side of a fourth motor of the rear wall of the first rotating cavity, the third rotating shaft is arranged on the right side of the fourth motor of the rear wall of the first rotating cavity, two third rotating shafts are rotatably connected with the rear wall of the first rotating cavity, a second gear meshed with each other is fixedly arranged on the third rotating shaft, the upper portion of the reel is rotatably connected with the front surface of the rotating box, and the reel and the middle wheel are wound with a spinning line to be dyed.

5. The textile water-saving dyeing machine based on the electromagnetic adsorption technology as claimed in claim 1, is characterized in that: the feeding device comprises a storage cavity arranged in the dyeing machine tool, a feeding pipe penetrating through the rear side surface of the dyeing machine tool is arranged in the rear side surface of the storage cavity, a water pump is arranged in the top wall of the storage cavity, the bottom surface of the water pump is installed to penetrate into the drainage pipe of the storage cavity, and the top surface of the water pump is installed with a liquid outlet pipe extending into the dyeing cavity and opposite to the position of the liquid outlet pipe of the liquid outlet groove.

6. The textile water-saving dyeing machine based on the electromagnetic adsorption technology as claimed in claim 2, characterized in that: and friction pads opposite to the pressing block are fixedly arranged on the bottom walls of the first passing groove and the second passing groove.

7. The textile water-saving dyeing machine based on the electromagnetic adsorption technology as claimed in claim 1, is characterized in that: the bottom surface of the dyeing machine tool is fixedly provided with supporting legs.