CN111996704A

CN111996704A - Efficient uniform dyeing method for textile fabric

Info

Publication number: CN111996704A
Application number: CN202010648011.6A
Authority: CN
Inventors: 刘琳
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-07
Filing date: 2020-07-07
Publication date: 2020-11-27

Abstract

The invention discloses a high-efficiency uniform dyeing method for textile fabric, which comprises the following steps; s1, blending; s2; s3, dyeing; s4, drying; the dyeing method comprises a dyeing box, a heating ring is embedded in the inner wall of the dyeing box, discharge holes are symmetrically formed in the side wall of the dyeing box, a plurality of driving rollers are symmetrically and rotatably connected to the inner wall of the dyeing box through rotating shafts, a vertical rod is rotatably connected to the bottom in the dyeing box, and a plurality of stirring rods are fixedly connected to the side wall of the vertical rod. According to the invention, the temperature in the groove reaches the critical value on the first temperature control sheet, so that the electromagnet generates magnetism, the electromagnet drives the toothed plate to slide leftwards under the action of the magnetic attraction force of the permanent magnet block to drive the first gear to rotate, the stirring rod rotates to stir the dye in the dyeing box, the electromagnet works through the heat energy generated in the dyeing box, the stirring rod is driven to rotate by the magnetic force, the driving of power equipment is not needed, and the energy is saved.

Description

Efficient uniform dyeing method for textile fabric

Technical Field

The invention relates to the technical field of textile fabric processing, in particular to an efficient and uniform dyeing method for textile fabrics.

Background

When the textile fabric is produced and processed, in order to make the produced fabric more diversified, the textile fabric needs to be dyed, so that the fabric can be in various colors.

The dyestuff when dyeing at present all is that multiple primary color dyestuff mixes the configuration and forms, carrying out the constant temperature heating to the dyestuff, and then accelerate the dyeing to the surface fabric, because contain a certain amount of powder in the dyestuff, and then make the dyestuff can take place the precipitation phenomenon after the dyestuff stews for a period of time, consequently need carry out timely stirring to the dyestuff of dyeing incasement, adopt the motor to stir the dyestuff as actuating mechanism at present, adopt this kind of method not only extravagant electric power resource, and the vibrations that produce when the motor rotates are great, cause noise pollution easily, and can give off a large amount of heats when heating the dyestuff, and do not carry out effective utilization to these heats, cause the waste of resource.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides an efficient and uniform dyeing method for textile fabric.

In order to achieve the purpose, the invention adopts the following technical scheme:

an efficient uniform dyeing method for textile fabric comprises the following steps;

s1, blending, namely adding the dyeing liquid into a dyeing box for blending according to the required color of the fabric;

s2, heating, namely electrifying the heating ring to enable the heating ring to heat the dye to a proper temperature for dyeing the fabric;

s3, dyeing, namely, passing the fabric in a dyeing box through a driving roller, and controlling the contact time of the fabric and dye to enable the fabric to be stained with corresponding pigment;

and S4, drying, namely putting the dyed fabric into a drying box for low-temperature drying.

The dyeing method process also relates to dyeing equipment which comprises a dyeing box, wherein a heating ring is embedded in the inner wall of the dyeing box, discharge holes are symmetrically formed in the side wall of the dyeing box, a plurality of driving rollers are symmetrically and rotatably connected to the inner wall of the dyeing box through rotating shafts, a vertical rod is rotatably connected to the bottom of the dyeing box, a plurality of stirring rods are fixedly connected to the side wall of the vertical rod, a groove is formed in the lower end of the dyeing box, the lower end of the vertical rod penetrates through the lower end of the dyeing box and is fixedly connected with a first gear, a first temperature control sheet is fixedly connected to the inner wall of the dyeing box through a telescopic spring, an electromagnet is fixedly connected to the side wall of the first temperature control sheet and is coupled with the electromagnet, a toothed plate meshed with the first gear is fixedly connected to the side wall of the electromagnet, the toothed plate is slidably connected with the inner wall of the groove, and a permanent magnet block is rotatably connected to the, and the permanent magnet blocks are attracted with the electromagnets, the lower end of the dyeing box is provided with a sliding cavity, and a driving mechanism for driving the permanent magnet blocks to rotate back and forth is arranged in the sliding cavity.

Preferably, actuating mechanism includes the second gear with the coaxial fixed connection of permanent magnetism piece, the smooth intracavity wall passes through reset spring fixedly connected with second temperature control piece, second temperature control piece lateral wall fixedly connected with electromagnetic plate, second temperature control piece and electromagnetic plate coupling are connected, electromagnetic plate lateral wall fixedly connected with and the rack of second gear engagement, reset spring's inner wall fixedly connected with permanent magnet is kept away from to smooth intracavity, the permanent magnet attracts mutually with the electromagnetic plate, the inner wall fixedly connected with fin that the smooth intracavity is close to the permanent magnet.

Preferably, the bottom in the dyeing box is respectively connected with the groove and the inner wall of the sliding cavity through a heat conducting rod.

The invention has the following beneficial effects:

1. by arranging the first temperature control sheet, the electromagnet, the toothed plate and the first gear, the heat conducting rod transmits heat in the dyeing box into the groove, when the temperature in the groove reaches a critical value on the first temperature control sheet, the first temperature control sheet enables a circuit on the electromagnet to be conducted at the moment, the electromagnet is enabled to generate magnetism, the permanent magnets and the electromagnet are enabled to attract each other, the electromagnet drives the toothed plate to slide leftwards under the action of magnetic attraction of the permanent magnets, the first gear is driven to rotate, the stirring rod is enabled to rotate to stir dye in the dyeing box, the electromagnet is enabled to work through heat energy generated in the dyeing box, the stirring rod is driven to rotate through magnetic force, electric power equipment is not needed for driving, and energy is saved;

2. by arranging the second temperature control piece, the electromagnetic plate, the rack, the second gear and the permanent magnet, the temperature in the dyeing box is raised through the heat conducting rod, so that the second temperature control piece is conducted on a circuit on the electromagnetic plate, the permanent magnet attracts the electromagnetic plate, the electromagnetic plate drives the rack to slide on the inner wall of the sliding cavity, the second gear is driven to rotate by 180 degrees, the permanent magnet rotates to repel with the electromagnet, the electromagnet slides rightwards under the action of the magnetic repulsion force of the permanent magnet, the toothed plate drives the first gear to rotate again, and the stirring rod rotates again to stir the dye;

3. when the electromagnetic plate slides to the limit position under the action of the permanent magnet, the second temperature control sheet is opposite to the radiating sheet at the moment, so that the radiating sheet radiates heat on the second temperature control sheet, the temperature on the second temperature control sheet is reduced to be below a critical value, the magnetism on the electromagnetic plate disappears, the electromagnetic plate is pulled by the reset spring to slide to the original position, the rack is matched with the second gear again, the second gear rotates 180 degrees again, the permanent magnet rotates to attract the electromagnet, the electromagnet slides leftwards again under the action of the magnetic attraction force of the permanent magnet, the toothed plate drives the first gear to rotate again, the stirring rod rotates again to stir the dye, when the second temperature control sheet returns to the original position, the temperature on the second temperature control sheet rises to enable the magnetism on the electromagnetic plate to be generated again, and the electromagnetic plate slides again, make the second gear rotate 180 once more for the electro-magnet slides to the normal position once more under the magnetic repulsion effect of permanent magnetism piece, so relapse, when dyeing incasement temperature risees, can make the puddler constantly make a round trip to rotate at the dyeing incasement, carry out even stirring to the dyestuff, avoid the dyestuff to deposit the dyeing quality of influence to the surface fabric, make the dyeing of surface fabric more even.

Drawings

FIG. 1 is a schematic structural diagram of an efficient and uniform dyeing method for textile fabrics, which is provided by the invention;

FIG. 2 is an enlarged view of the structure at A in FIG. 1;

FIG. 3 is an enlarged view of the structure at B in FIG. 1;

fig. 4 is a schematic top view of a driving mechanism in the efficient uniform dyeing method for the textile fabric provided by the invention.

In the figure: 1 dyeing box, 2 heating rings, 3 driving rollers, 4 vertical rods, 5 stirring rods, 6 grooves, 7 first gears, 8 telescopic springs, 9 first temperature control sheets, 10 electromagnets, 11 toothed plates, 12 heat conducting rods, 13 sliding cavities, 14 permanent magnetic blocks, 15 second gears, 16 reset springs, 17 second temperature control sheets, 18 electromagnetic plates, 19 racks, 20 permanent magnets and 21 radiating fins.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, but rather should be construed as broadly as the present invention is capable of modification in various respects, all without departing from the spirit and scope of the present invention.

Referring to fig. 1-4, a high-efficiency uniform dyeing method for textile fabric comprises the following steps;

s1, blending, namely adding the dyeing liquid into the dyeing box 1 for blending according to the required color of the fabric;

s2, heating, namely electrifying the heating ring 2, so that the heating ring 2 heats the dye to a proper temperature for dyeing the fabric;

s3, dyeing, namely, passing the fabric in the dyeing box 1 through the driving roller 3, and controlling the contact time of the fabric and dye to enable the fabric to be stained with corresponding pigment;

The dyeing method process also relates to dyeing equipment, which comprises a dyeing box 1, wherein a heating ring 2 is embedded in the inner wall of the dyeing box 1, discharge holes are symmetrically formed in the side wall of the dyeing box 1, a plurality of driving rollers 3 are symmetrically and rotatably connected to the inner wall of the dyeing box 1 through rotating shafts, a vertical rod 4 is rotatably connected to the bottom in the dyeing box 1, a plurality of stirring rods 5 are fixedly connected to the side wall of the vertical rod 4, a groove 6 is formed in the lower end of the dyeing box 1, the lower end of the vertical rod 4 penetrates through the lower end of the dyeing box 1 and is fixedly connected with a first gear 7, a first temperature control sheet 9 is fixedly connected to the inner wall of the dyeing box 1 through a telescopic spring 8, an electromagnet 10 is fixedly connected to the side wall of the first temperature control sheet 9, the first temperature control sheet 9 is coupled with the electromagnet 10, a toothed plate 11 meshed with the first gear 7 is fixedly connected to the side wall of the electromagnet 10, the toothed plate 11 is slidably connected with the inner wall of the groove 6, at this time, the first temperature control sheet 9 conducts a circuit on the electromagnet 10, so that magnetism is generated on the electromagnet 10, the permanent magnet 14 is rotatably connected to the inner wall, away from the extension spring 8, of the groove 6 through the rotating shaft, and the permanent magnet 14 and the electromagnet 10 attract each other, as shown in fig. 2 and 3, in an initial state, the left side of the electromagnet 10 is an S pole, the right side of the electromagnet 10 is an N pole, the left side of the permanent magnet 14 is an S pole, the right side of the permanent magnet is an N pole, at a normal temperature, a magnetic pole, opposite to the permanent magnet 14, of the electromagnet 10 is a heteropole, the lower end of the dyeing box 1 is provided with a sliding cavity 13, and a driving mechanism for driving the permanent.

The driving mechanism comprises a second gear 15 coaxially and fixedly connected with the permanent magnet 14, the inner wall of the sliding cavity 13 is fixedly connected with a second temperature control sheet 17 through a reset spring 16, the side wall of the second temperature control sheet 17 is fixedly connected with an electromagnetic plate 18, the second temperature control sheet 17 is coupled with the electromagnetic plate 18, further, when the temperature of the sliding cavity 13 is higher than the critical value of the second temperature control sheet 17, the second temperature control sheet 17 conducts the circuit on the electromagnetic plate 18, and further the electromagnetic plate 18 generates magnetism, the side wall of the electromagnetic plate 18 is fixedly connected with a rack 19 meshed with the second gear 15, the inner wall of the sliding cavity 13 far away from the reset spring 16 is fixedly connected with a permanent magnet 20, the permanent magnet 20 and the electromagnetic plate 18 attract each other, it should be noted that, when the toothed plate 11 slides to enable the first gear 7 to be close to the electromagnet 10, the rack 19 drives the second gear 15 to rotate through the second gear 15, so as to drive the permanent magnet 14 to rotate, the electromagnet 10 is subjected to the repulsive force of the permanent magnet 14, so that the electromagnet 10 drives the toothed plate 11 to slide leftwards, the stirring rod is continuously driven to rotate, and the inner wall of the sliding cavity 13 close to the permanent magnet 20 is fixedly connected with the radiating fins 21.

The bottom in the dyeing box 1 is respectively connected with the inner walls of the groove 6 and the sliding cavity 13 through a heat conducting rod 12.

In the invention, a textile fabric passes through a dyeing box 1 through a driving roller 3 and is positioned below a dye, the dye is heated through a heating ring 2, the dyeing efficiency of the textile fabric is accelerated, when the temperature of the dye in the dyeing box 1 rises, a heat conducting rod 12 can transfer the temperature in the dye into a groove 6 and a sliding cavity 13, and further when the temperature in the groove 6 reaches a critical value on a first temperature control sheet 9, electricity is conducted on an electromagnet 10 to generate magnetism, and the electromagnet 10 drives a toothed plate 11 to slide leftwards under the action of the magnetic attraction force of a permanent magnet block 14, so as to drive a first gear 7 to rotate, so that a vertical rod 4 drives a stirring rod 5 to rotate to stir the dye in the dyeing box 1, meanwhile, the temperature in the sliding cavity 13 reaches a critical value on a second temperature control sheet 17, electricity is conducted on an electromagnetic plate 18 to generate magnetism, and further the electromagnetic plate 18 drives a rack 19 to slide leftwards under the action of the magnetic attraction force of a permanent magnet 20, when the toothed plate 11 slides to enable the first gear 7 and the electromagnet 10 to approach each other, at the moment, the rack 19 passes through the second gear 15 to drive the second gear 15 to rotate, so as to drive the permanent magnet 14 to rotate, so that the left side of the permanent magnet 14 is an N pole, the right side of the permanent magnet 14 is an S pole, and further magnetic repulsion force is generated between the permanent magnet 14 and the electromagnet 10, so that the electromagnet 10 drives the toothed plate 11 to slide rightwards, so that the toothed plate 11 drives the first gear 7 to rotate again, and further the stirring rod 5 rotates again to stir the dye;

when the electromagnetic plate 18 moves to a position close to the heat radiating fins 21, the heat radiating fins 21 begin to radiate the heat of the second temperature control sheet 17, so that the temperature on the second temperature control sheet 17 is reduced to be below a critical value, further, the magnetism on the electromagnetic plate 18 disappears, the electromagnetic plate 18 slides to the original position under the action of the reset spring 16, the second gear 15 rotates again, further, the magnetic poles on the permanent magnets 14 rotate to the initial state, further, the electromagnet 10 is attracted again, further, the stirring rod 5 rotates again, at the moment, the second temperature control sheet 17 is far away from the heat radiating fins 21, further, the temperature on the second temperature control sheet 17 is raised, further, the operations are repeated, further, when the temperature in the dyeing box 1 is raised, the stirring rod 5 can rotate back and forth in the dyeing box 1 under the action of the magnetic force, the dye is uniformly stirred, and the dyeing quality of the fabric is prevented from being influenced by dye precipitation, so that the dyeing of the fabric is more uniform.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. An efficient uniform dyeing method for textile fabric is characterized by comprising the following steps;

s1, blending, namely adding the dyeing liquid into a dyeing box (1) for blending according to the required color of the fabric;

s2, heating, namely electrifying the heating ring (2) to enable the heating ring (2) to heat the dye to a proper temperature for dyeing the fabric;

s3, dyeing, namely, passing the fabric in a dyeing box (1) through a driving roller (3), and controlling the contact time of the fabric and dye to enable the fabric to be stained with corresponding pigment;

The dyeing method process also relates to dyeing equipment, which comprises a dyeing box (1), wherein a heating ring (2) is embedded in the inner wall of the dyeing box (1), discharge holes are symmetrically formed in the side wall of the dyeing box (1), the inner wall of the dyeing box (1) is symmetrically and rotatably connected with a plurality of driving rollers (3) through rotating shafts, a vertical rod (4) is rotatably connected to the inner bottom of the dyeing box (1), a plurality of stirring rods (5) are fixedly connected to the side wall of the vertical rod (4), a groove (6) is formed in the lower end of the dyeing box (1), the lower end of the vertical rod (4) penetrates through the lower end of the dyeing box (1) and is fixedly connected with a first gear (7), a first temperature control piece (9) is fixedly connected to the inner wall of the dyeing box (1) through a telescopic spring (8), an electromagnet (10) is fixedly connected to the side wall of the first temperature control piece (9), and the first temperature control piece (9) is coupled with the electromagnet (10, electromagnet (10) lateral wall fixedly connected with and first gear (7) meshed pinion rack (11), pinion rack (11) and recess (6) inner wall sliding connection, rotate through the pivot on the inner wall of expanding spring (8) is kept away from in recess (6) and be connected with permanent magnetism piece (14), just permanent magnetism piece (14) and electromagnet (10) inhale mutually, sliding chamber (13) have been seted up to dyeing case (1) lower extreme, install drive permanent magnetism piece (14) in sliding chamber (13) and make a round trip pivoted actuating mechanism.

2. The efficient and uniform dyeing method for the textile fabric is characterized in that the driving mechanism comprises a second gear (15) coaxially and fixedly connected with a permanent magnet block (14), the inner wall of the sliding cavity (13) is fixedly connected with a second temperature control sheet (17) through a return spring (16), the side wall of the second temperature control sheet (17) is fixedly connected with an electromagnetic plate (18), the second temperature control sheet (17) is coupled with the electromagnetic plate (18), the side wall of the electromagnetic plate (18) is fixedly connected with a rack (19) meshed with the second gear (15), the inner wall of the sliding cavity (13) far away from the return spring (16) is fixedly connected with a permanent magnet (20), the permanent magnet (20) is attracted with the electromagnetic plate (18), and the inner wall of the sliding cavity (13) near the permanent magnet (20) is fixedly connected with a cooling fin (21).

3. A highly efficient uniform dyeing method for textile fabric according to claim 1 characterized in that the bottom of the dyeing box (1) is connected with the inner wall of the groove (6) and the sliding cavity (13) through the heat conducting rod (12).