KR101737875B1 - Supercritical carbon dioxide dyeing bath for improvement of level dyeing - Google Patents

Abstract

The present invention relates to a supercritical carbon dioxide dyeing bath for the improvement of level dyeing, which comprises the following: a dyeing chamber in a container form having an opening and closing cover on one side; a dyeing beam installed on the inner center of the dyeing chamber toward the axis direction, and having a plurality of spraying holes along the circumferential direction or the axis direction for spraying supercritical carbon dioxide with a dye dissolved in the outer perimeter into the dyeing chamber; and a circulation pump circulating the supercritical carbon dioxide inside the dyeing chamber toward the dyeing beam. A plurality of inlets and outlets are arranged asymmetrically on the outer perimeter of the dyeing chamber, so the supercritical carbon dioxide including the dye sprayed through the dyeing beam cam uniformly flow and the dyeing can be uniformly performed on the entire portion of a fabric.

Description

{SUPERCRITICAL CARBON DIOXIDE DYEING BATH FOR IMPROVEMENT OF LEVEL DYEING}

The present invention relates to a supercritical carbon dioxide dyeing tank for improving the leveling, more specifically, a dyeing chamber is provided with a plurality of inflow / outflow ports, and the diameter of the dye injection hole of the dyeing beam is relatively increased And the end portion located at a great distance from the inflow portion is linearly variable so as to be a relatively small size so that when the supercritical carbon dioxide dissolved in the dyeing beam in the mixing tank passes through the fabric, And in order to circulate the supercritical carbon dioxide in which the dye is dissolved in the opposite direction, the inlet / outlet arrangement of the dyeing chamber is arranged asymmetrically and the spiral guide vents are formed on the inner wall of the dyeing chamber, The same pressure was applied to the fabric and the same amount of dye was supplied to make it uniform It relates to Article supercritical dyeing for improving salt.

In general, the temperature and the vapor pressure in a state in which the two states of liquid and gas can not be distinguished are called critical points. When the critical state is exceeded, that is, in the critical state, it becomes a gas and not liquid state. (Supercritical Fluid).

This supercritical fluid has inherent properties different from ordinary gases and liquids.

The supercritical fluid has a physical property such as a medium property between a gas and a liquid, which can change abruptly depending on a slight change in pressure and temperature, has good spreading power, and has a high mass transfer rate.

Supercritical CO ₂ (supercritical CO ₂ ) has similar diffusivity and viscosity to gas, but it has recently been applied to various industrial processes because it has density close to that of liquid.

For example, in a supercritical carbon dioxide dyeing machine, supercritical carbon dioxide is appropriately used, and a new dyeing method in which a dye is mixed with supercritical carbon dioxide to permeate the fiber is used. This method is different from a water dyeing machine using water It is a dyeing method.

In general, in the case of water-based dyeing, a dye is mixed with water to penetrate the fiber. Since the liquid such as water is not excellent in diffusibility, it takes a considerable time for dyeing, and also occurs in the drying process and dyeing process of the dye after dyeing Problems of wastewater treatment, and deterioration of dyes that occur over a long period of time when the dyed fibers are washed with water.

Compared with water-based dyeing, supercritical carbon dioxide dyeing is advantageous in that it can penetrate the dye into the interior of the fiber structure by utilizing the thermal properties of supercritical carbon dioxide without using water at all, In addition, since no water is used in the dyeing process, there is no fear of desorption of dye occurring in the drying process or washing.

The following Patent Document 1 discloses an industrial supercritical fluid dyeing machine.

The industrial supercritical fluid dyeing machine of Patent Document 1 is a dyeing machine in which a spindle to which a hydrophobic fiber can be wound is fixed; a flow converting means for converting the flow of supercritical fluid to the wound fiber to make uniform and rapid dyeing; A circulating pump means for circulating the supercritical fluid to increase the frequency of contact between the dye and the fiber dissolved in the supercritical carbon dioxide, a heat exchanger for heating or cooling the supercritical fluid, a dyeing device for cooling the carbon dioxide stored in the storage tank And a high-pressure dyeing means connected to the high-pressure piping through carbon dioxide recovery means for decompressing and cooling the carbon dioxide after completion of the dyeing process and recovering the recovered carbon dioxide into a storage tank by a recovery pump.

1 is a configuration diagram of a supercritical carbon dioxide dyeing machine to which the present invention is related.

The supercritical carbon dioxide dyeing machine 10 includes a liquid carbon dioxide storage tank 11, a carbon dioxide cooler 12, a high pressure carbon dioxide pump 13, a preheating heater 14, a mixing tank 15, a dyeing tank 16, 17, a gas carbon dioxide storage tank 18, and the like.

Liquid carbon dioxide supplied from the liquid carbon dioxide storage tank 11 in the supercritical carbon dioxide dyeing machine 10 to which the present invention is related is supplied to the preheating heater 14 through the carbon dioxide cooler 12 and the high pressure carbon dioxide pump 13. [

The preheating heater 14 heats the liquid carbon dioxide to produce supercritical carbon dioxide at a desired operating temperature and pressure and supplies it to the mixing tank 15.

The mixing tank 15 mixes the dyestuff into carbon dioxide in the supercritical state and supplies it to the dyeing tank 16.

In dyeing tank 16, a mixture of supercritical carbon dioxide and dye is fed to the fabric, where supercritical carbon dioxide permeates the dye into the fabric.

Supercritical carbon dioxide used in the dyeing tank 16 is supplied to the separator 17, which evaporates the carbon dioxide to remove excess dye and residues.

The gaseous carbon dioxide separated from the separator 17 is stored in the gas carbon dioxide storage tank 18 and reused.

1, reference numeral 19 denotes a circulating pump.

In the supercritical carbon dioxide dyeing machine 10, the dye is mixed with the carbon dioxide in the supercritical state in the mixing tank 15 and supplied to the dyeing beam installed in the center of the dyeing tank 16.

When the fabric is dyed, the fabric is wound around the outer periphery of the dyeing beam, and then the dye dissolved by the supercritical carbon dioxide is supplied to the fabric through a plurality of dye injection holes formed in the dyeing beam.

That is, the supercritical carbon dioxide including the dye is supplied to the entrance of the dyeing beam and flows through the plurality of injection holes to the fabric, and the dye penetrates into the fiber in the course of the supercritical carbon dioxide.

In addition, although a method of refluxing supercritical carbon dioxide containing dyestuffs from a dyeing tank through a fabric to a dyeing beam is employed, this method is not suitable because the dye is biased toward a specific region due to the heterogeneous flow of supercritical carbon dioxide flowing from the dyeing beam In this case, it is often the case that the current salinity is deteriorated due to the flow of current.

Korean Registered Patent No. 10-0570333 (registered on Apr. 05, 2006)

Since the supercritical carbon dioxide dyeing tank according to the prior art has a form in which the supercritical carbon dioxide supplied in the axial direction of the dyeing beam collects in one place of the dyeing chamber, in the case of a large dyeing amount, Resulting in deterioration of product quality.

The object of the present invention is to solve the problems of the prior art supercritical carbon dioxide dyeing tank described above and to make the flow of the supercritical carbon dioxide including the dye penetrated into the fabric uniform, The present invention is to provide a supercritical carbon dioxide dyeing tank for improving the leveling so as to make it possible to perform a uniform coloring.

In order to achieve the above-mentioned object, a supercritical carbon dioxide staining tank for improving the leveling according to the present invention comprises: a tubular dyeing chamber having a cover on one side; A dyeing beam axially installed in the center of the interior of the dyeing chamber and provided with a plurality of injection holes arranged circumferentially and axially so as to inject supercritical carbon dioxide dissolved in dye dye into the dyeing chamber; And a circulation pump for circulating the supercritical carbon dioxide of the dyeing chamber toward the dyeing beam, and a plurality of inflow / outflow ports arranged asymmetrically in the axial direction on the outer periphery of the dyeing chamber.

The supercritical carbon dioxide staining tank for improving the leveling according to the present invention is characterized in that each inlet / outlet of the dyeing chamber is connected to the staining beam through a manifold and a circulation pipe, and a circulation pump capable of normal and reverse operation is installed in the circulation pipe.

The supercritical carbon dioxide dyeing tank for improving the leveling according to the present invention is characterized in that a plurality of guide vats are axially provided on the inner circumferential surface of the dyeing chamber so as to rotate the supercritical carbon dioxide dissolved in the dye in the circumferential direction.

The supercritical carbon dioxide dyeing tank for improving the leveling according to the present invention is characterized in that the diameters of the injection holes of the dyeing beam are the same diameter in the circumferential direction and the diameters in the axial direction are from the supercritical carbon dioxide- Is formed to be linearly reduced.

According to the supercritical carbon dioxide dyeing tank for improving the leveling according to the present invention, the diameter of the injection hole of the dyeing beam is linearly decreased from the inlet toward the end, the outer diameter of the dyeing beam is kept the same, The inner diameter of the beam is linearly reduced from the inflow portion toward the end portion so that the amount of supercritical carbon dioxide injected into the fabric in all the injection holes of the dyeing beam can be made uniform, So that the dyeing quality can be greatly improved.

According to the supercritical carbon dioxide dyeing tank for improving the leveling according to the present invention, the dyeing chamber is provided with a plurality of inflow / outflow ports to discharge supercritical carbon dioxide uniformly through the fabric in the entire length of the dyeing chamber, It is possible to prevent the occurrence of the unevenness and to improve the dyeing quality.

According to the supercritical carbon dioxide dyeing tank for improving the leveling according to the present invention, the supercritical carbon dioxide can be rotated before being discharged to the inflow / outflow port through the guide feathers provided on the inner peripheral surface of the dyeing chamber, When the dye is circulated in the opposite direction, it is possible to arrange the inlet / outlet arrangement asymmetrically and to form a spiral guide vane on the inner wall of the dyeing tank to supply the same pressure and dye amount as the fabric from the inner surface of the dyeing tank So that it can be leveled.

1 is a schematic view of a supercritical carbon dioxide dyeing machine to which the present invention is related;
FIG. 2 is a schematic view of a supercritical carbon dioxide dyeing tank for improving the leveling according to a preferred embodiment of the present invention. FIG.
FIG. 3 is a conceptual view showing the position of the inlet / outlet of the supercritical carbon dioxide dyeing chamber for improving the leveling of the present invention and the action of the inner flag of the dyeing chamber,
FIG. 4A is a state diagram showing a change in diameter size of the injection hole of the supercritical carbon dioxide dyed beam for the improvement of the leveling according to the present preferred embodiment,
FIG. 4B is a sectional view showing the outer diameter and the inner diameter of the staining beam of FIG. 4A,
FIG. 5A is a graph showing the degree of saltiness of the supercritical carbon dioxide staining tank according to the prior art,
FIG. 5B is a graph showing the level of homogeneity of a supercritical carbon dioxide dyeing tank for improving the leveling according to a preferred embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a supercritical carbon dioxide dyeing tank for improving the leveling according to the present invention will be described in detail with reference to the accompanying drawings.

In the following, the terms "upward", "downward", "forward" and "rearward" and other directional terms are defined with reference to the states shown in the drawings.

2 is a configuration diagram of a supercritical carbon dioxide dyeing tank for improving the leveling according to a preferred embodiment of the present invention.

The supercritical carbon dioxide staining tank 100 for improving the leveling according to a preferred embodiment of the present invention includes a dyeing chamber 110, a staining beam 120, and a circulation pump 130.

The dyeing chamber 110 constitutes a dyeing space, and is a tubular type in which an opening / closing cover 111 is provided on one side.

Each inlet / outlet 112 of the dyeing chamber 110 is connected to the dyeing beam 120 through a manifold 141 and a circulation line 142.

The dyeing beam 120 is axially installed at the center of the interior of the dyeing chamber 110 and a plurality of injection holes 121 are formed circumferentially and axially on the outer circumference of the dyeing beam 120.

The injection hole 121 of the dyed beam 120 may supply supercritical carbon dioxide dissolved in the dye to the dyeing chamber 110 or circulate supercritical carbon dioxide dissolved in the dye in the dyeing chamber 110 ) ≪ / RTI > dye into the supercritical carbon dioxide.

A dye mixing chamber 200 for dissolving a dye through supercritical carbon dioxide is connected to one end of the dyeing beam 120 drawn out of the dyeing chamber 110.

In Fig. 2, reference numeral 123 denotes an opening / closing valve.

FIG. 3 is a conceptual view illustrating the position of the inlet / outlet of the supercritical carbon dioxide dyeing chamber for enhancing the leveling according to the preferred embodiment, and the action of the inner guide collar of the dyeing chamber.

The dyeing chamber 110 is provided with a plurality of inlet / outlet ports 112 through which supercritical carbon dioxide can be discharged to the outside in the circumferential direction, and each inlet / outlet port 112 is provided with an on / off valve 113.

The inflow / outflow opening 112 provided in the dyeing chamber 110 allows the supercritical carbon dioxide having the dye dissolved therein to pass through the injection hole 121 of the dyeing beam 120 during the initial operation of the dyeing apparatus, Supercritical carbon dioxide which has flowed out through the inlet / outlet 112 and has dissolved therein the dye for a predetermined time at a predetermined pressure is supplied to the fabric through the injection hole 121 of the dyeing beam 120, The function of an inlet and an outlet which serve to flow the supercritical carbon dioxide through the plurality of inlet / outlet ports 112 to the fabric so as to dye the fabric and flow out into the injection hole 121 of the dyeing beam 120 do.

The inlet / outlet 112 provided in the dyeing chamber 110 is spaced apart from the inlet / outlet 112 at an intermediate position between the inlet / outlet 112 and the inlet / outlet 112, 112). The inlet / outlet 112 of the other side is positioned between the two inlet / outlet ports 112 arranged at one side in the axial direction so that the inlet / outlet 112 of the other side is located at one side and the other side At the 180 ° position, there is an asymmetrical relationship with each other.

Inside the dyeing chamber 110, a circular spiral guide vane 114 is formed on the entire inner surface.

As shown in FIG. 4A, a plurality of injection holes 121 are provided circumferentially and axially on the outer circumference of the staining beam 120 to allow the supercritical carbon dioxide, in which the dye is dissolved, to be injected into the fabric P.

The diameters of the injection holes 121 of the dyed beams 120 are formed to have the same diameter in the circumferential direction.

The diameter of the injection hole 121 of the dyed beam 120 is formed such that the diameter is linearly reduced from the supercritical carbon dioxide inflow portion in which the dye is dissolved in the axial direction to the end direction, The amount of the dye of the supercritical carbon dioxide can be made uniform.

As shown in FIG. 4B, the outer diameter of the dyeing beam 120 is the same, and the inner diameter is formed in a conical shape whose diameter is linearly reduced from the supercritical carbon dioxide inflow portion in which the dye is dissolved in the axial direction to the end direction, The axial length of the staining beam 120 is linearly changed in the axial direction of the diameter of the hole 121 and in the axial direction of the inner diameter of the staining beam, The amount of the dye of the carbon dioxide can be made uniform, and the fabric can be uniformly dyed, thereby greatly improving the dyeing quality.

A fabric (P) to be stained is wound around the outer periphery of the staining beam (120).

The circulation pump 130 circulates the supercritical carbon dioxide discharged from the dyeing beam 120 toward the dyeing chamber 110 and then discharged to the inlet / outlet 112 via the fabric P, 141 and the dyeing beam 120. The circulation pipe 142 is connected to the staining beam 120 and the circulation pipe 142,

The circulation pump 130 is capable of normal and reverse driving and is capable of performing forward and reverse circulation in which supercritical carbon dioxide discharged from the dyeing chamber 110 is supplied again to the dyeing beam 120 as well as to the inlet and outlet 112 of the dyeing chamber 110 And the supernatant carbon dioxide is supplied to the inside of the dyeing chamber 110, and then the dyeing beam 120 is recovered.

The supercritical carbon dioxide dyeing tank 100 for improving the leveling according to the preferred embodiment of the present invention is a supercritical carbon dioxide dyeing tank 100 for supercritical carbon dioxide dyeing tank 100 in which a dye P is wound around an outer periphery of a dyeing beam 120, When carbon dioxide dissolved dyes are supplied into the dyeing beam 120, supercritical carbon dioxide in which the dye is dissolved is injected toward the fabric P through each injection hole 121 of the dyeing beam 120, And dyeing is performed.

Supercritical carbon dioxide having passed through the fabric P is discharged to the manifold 141 through the inflow / outflow ports 112 of the dyeing chamber 110 and the circulation pump 130 installed in the circulation pipe 142 To the dyeing beam 120 or through the separator and stored in the gaseous carbon dioxide storage tank.

The diameter of the injection hole of the dyeing beam in the prior art is uniformly formed on all the surfaces of the dyeing beam 120 and the inner diameter thereof is also constant so that a large amount of dye is discharged at the end of the dyeing beam 120, A small amount of dye is discharged and the density becomes thicker from the entrance side to the end side of the dyeing beam 120, causing a problem that the dyeing density of the fabric becomes uneven.

The operation of the supercritical carbon dioxide staining tank 100 for improving the leveling according to the preferred embodiment of the present invention will be described.

First, when the fabric P is wound on the dyeing beam 110 and placed in the dyeing chamber 120, supercritical carbon dioxide is supplied to dissolve the dye, and supercritical carbon dioxide in which the dye is dissolved is irradiated with a dyeing beam 120). At this time, the diameter of the injection hole 121 of the dyeing beam 120 is formed to be the same diameter in the circumferential direction, and the diameter is linearly decreased in the axial direction from the supercritical carbon dioxide inflow portion in which the dye is dissolved, The outer diameter of the dyeing beam 120 is the same as the diameter of the dyeing beam 120. The inner diameter of the dyeing beam 120 is conically formed in the axial direction so that the diameter of the dyeing beam 120 linearly decreases from the supercritical carbon dioxide inflow portion in which the dye is dissolved, ) Dyes of supercritical carbon dioxide injected into the fabric from the dyeing beam 120 as a whole along the axial length of the dyeing beam 120 through a linear change in the axial direction of the diameter and a linear change in the axial direction of the inner diameter of the dyeing beam Of the total amount of water.

Supercritical carbon dioxide in which the dye is dissolved is supplied for a predetermined time at a predetermined pressure, for example, 150 bar. The supercritical carbon dioxide through which the dye has dissolved after passing through the fabric is discharged through a plurality of inflow / outflow ports 112 in a state where pressure is equalized between the fabric and the spiral guide vents 114 formed inside the dyeing chamber 110.

At this time, the supercritical carbon dioxide in which the dye is dissolved is rotated through the spiral guide vents 114 formed inside the dyeing chamber 110 and moved to the neighboring vanes 114, thereby moving the fabric and the dyeing chamber 110 And the pressure is equalized between the inner surfaces. Also, since the plurality of inflow / outflow openings 112 are arranged asymmetrically with respect to each other at a position of 180 degrees from each other, it is effective to uniformize the dye passing through the fabric in the axial direction by flowing out while forming pressure equalization.

The dye through the staining beam 120 stops the dissolved supercritical carbon dioxide feed and circulates in the opposite direction.

When supercritical carbon dioxide in which dye is dissolved is supplied through a plurality of asymmetrically arranged inflow / outflow ports 112, the separation distance between the dyeing chamber 110 and the fabric is short, so that the dye supplied at a high pressure of about 150 bar Critical carbon dioxide is transferred to the neighboring spiral guide vanes 114 while colliding with the fabric, and is instantaneously equalized between the dyeing chamber 110 and the fabric as it is orbited in the circumferential direction along the guide vanes 114. Since supercritical carbon dioxide in which the supplied dye is dissolved has a large number of inflow / outflow ports 112 arranged asymmetrically at 180 ° with respect to each other, it flows out more effectively forming a uniform pressure, thereby uniformizing the dye passing through the fabric in the axial direction It is effective and can achieve a leveling on the fabric.

As described above, the dye in the forward and reverse directions is fed 2-3 times to further improve the level of saltiness. At this time, the guide feathers 114 provided on the inner circumferential surface of the dyeing chamber 110 are dissolved in the dye The supercritical carbon dioxide is rotated so that the dyeing quality can be improved and the dyeing time can be shortened.

FIG. 5A is a graph showing the degree of staining according to the inner length of the dyeing vessel when the dyeing beam of the prior art has injection holes of the same diameter, FIG. 5B is a graph showing the degree of dyeing in the supercritical carbon dioxide dyeing tank for improving the leveling agent according to the preferred embodiment of the present invention FIG.

As shown in FIG. 5A, in the case of the supercritical carbon dioxide dye tank according to the prior art, since the flow of the supercritical carbon dioxide injected into the injection hole of the dyeing beam is stronger toward the end portion, uniform dyeing of the fabric is not performed, So that an agricultural salt is generated.

In comparison with this, in the supercritical carbon dioxide dyeing tank 100 for improving the leveling according to the preferred embodiment of the present invention, the diameters of the injection holes 121 of the dyeing beam 120 are formed to be the same diameter in the circumferential direction, The diameter of the dyeing beam 120 is the same as the diameter of the dyeing beam 120. The inner diameter of the dyeing beam 120 is the same as the diameter of the supercritical carbon dioxide in which the dye is dissolved in the axial direction The linear variation of the diameter of the injection hole 121 in the axial direction and the linear variation of the inner diameter of the staining beam in the axial direction are formed by the conical shape whose diameter is linearly reduced from the inflow portion toward the end, 120) It is possible to uniformly supply the amount of supercritical carbon dioxide in which the dye injected into the fabric is dissolved on the entire surface, and to supply a large number of asymmetrically arranged inflow / Supercritical carbon dioxide in which the dye is dissolved through the outlet 112 is short, the supercritical carbon dioxide dissolved in the dye supplied at a high pressure of about 150 bar collides with the fabric because the separation distance between the dyeing chamber 110 and the fabric is short Is moved to the neighboring spiral guide vanes 114 and is moved in the circumferential direction along the guide vanes 114 to instantaneously equalize pressure between the dyeing chamber 110 and the fabric and to arrange them asymmetrically, So that it is effective in uniformizing the dye passing through the fabric in the circumferential direction and achieving a leveling on the fabric.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

100: dyeing tank
110: Dye chamber
112: inlet / outlet
120: Dye beam
121: injection hole
130: circulation pump

Claims (4)

A cylindrical dyeing chamber 110 having an opening / closing cover 111 at one side thereof;
A plurality of injection holes 121 axially disposed at the center of the interior of the dyeing chamber 110 and capable of injecting supercritical carbon dioxide dissolved in dye dye into the dyeing chamber 110 are arranged in the circumferential direction and in the axial direction A staining beam 120 provided;
And a circulation pump 130 for circulating the supercritical carbon dioxide of the dyeing chamber 110 toward the dyeing beam 120,
A plurality of inflow / outflow ports 112 arranged asymmetrically in the circumferential direction on the outer circumference of the dyeing chamber 110,
Characterized in that a plurality of guide vanes (114) are provided axially in the inner circumferential surface of the dyeing chamber (110) so that supercritical carbon dioxide in which dye is dissolved can be rotated circumferentially. The method according to claim 1,
The inlet and outlet ports 112 of the dyeing chamber 110 are connected to the dyeing beam 120 through the manifold 141 and the circulation pipe 142 and are connected to the circulation pump 130, And a supercritical carbon dioxide dyeing tank for improving the leveling. delete The method according to claim 1,
The diameter of the injection hole 121 of the dyeing beam 120 is formed to be the same diameter in the circumferential direction and is formed so as to linearly decrease in diameter from the supercritical carbon dioxide inflow portion in which the dye is dissolved in the axial direction Characterized in that the supercritical carbon dioxide dyeing tank for improving the leveling is provided.

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