DE4332219A1 - Dyeing woollen, silk and esp. cotton fabric with dispersion dyes - by pretreating with hydrophobic finishing agent and then dyeing with dispersion dye in supercritical carbon di:oxide. - Google Patents

Abstract

A process for dyeing wool-, silk- or cellulose-contg. textile materials (I) with dispersion dyes (II) comprises pretreating (I) with a hydrophobic finishing agent (III) and then dyeing with (II) in supercritical CO2 (IV). Also claimed are textiles dyed by this process. Pref. (III) is an additive for improving crease and shrink properties, an additive for crease-free and shrink-free finishing, a waterproofing agent or a fire retardant. Suitable (III) are opt. etherated N-methylol derivs. of N-contg. cpds. (pref. opt. etherated N-methylol-urea or -melamine cpds), carbamide (pre)condensates, derivs. of isocyanic acid or cyanamide, polyethylene (co)polymers acrylic (co)polymers, silicones, polysiloxanes, halogenated polymers, esp. fluoropolymers, paraffins, or organic P, P/N, S/N or ammonium cpds. esp. opt. modified N-methylol-hydroxyethylene-urea cpds. methylolation prods. based on propyleneurea or ethylenurea/melamine, or opt. modified melamine/formaldehyde condensates. USE/ADVANTAGE - The process is useful for dyeing cotton textile materials (claimed). The above pretreatment enables cotton-based textiles to be dyed with dispersion dyestuffs in the presence of (IV) (until now this method could only be used with polyester fabric). W.r.t. aq. dye baths, dyeing with (II) in (IV) enables faster mass transfer in the dyeing process and more homogeneous colouring with no agglomeration of dyestuff; there is no effluent contaminated with dye or additives, and the CO2 can be reused.

Description

The present invention relates to a method for dyeing woolen or cellulose-containing textile materials with disperse dyes.

Textile materials made from cellulose and wool are usually made from aqueous dye brisk colored. Complete bath exhaustion never occurs. H. the color fabrics do not quantitatively pull onto the substrate to be colored. This leads to the dye liquor remaining after the dyeing process, depending on the respective lige dyes and substrates, contains more or less large amounts of dye. Therefore, relatively large amounts of colored waste water accumulate during dyeing, which is expensive need to be cleaned.

From DE-A 39 06 724 it is already known that polyester fabrics from overcritical CO ₂ can be dyed with disperse dyes by the textile material and the disperse dye under a CO ₂ pressure of about 190 bar for about 10 minutes at about 130 ° C heated and then increased in volume, causing the CO _{2 to} expand.

However, it is not possible to use this method to make textile material from wool, silk or Cellulose with the acid or reactive commonly used for such material to dye dyes. Even with disperse dyes you only get one completely unsatisfactory dyeing, in many cases even just soiling the textile materials.

It has now been found that textile material made of cellulose, silk or wool made of supercritical CO ₂ can be dyed with disperse dyes if the textile material is pretreated with a hydrophobic finishing agent.

The present invention thus relates to a process for dyeing wool, silk or cellulose-containing textile material with disperse dyes, which is characterized in that the textile material is pretreated with a hydrophobic finishing agent and then dyed from supercritical CO ₂ with a disperse dye.

Surprisingly, textile material can be achieved using the process according to the invention to dye from cellulose, silk or wool with disperse dyes, with many Dyes even deep shades can be obtained.

The process according to the invention has a number of advantages over dyeing processes from an aqueous liquor. Due to the fact that the CO _{2 used} does not get into the wastewater but is used again after the dyeing, no wastewater pollution occurs in the process according to the invention. In addition, in the process according to the invention, the mass transfer processes required for dyeing the textile substrate take place considerably faster in comparison to aqueous systems. This in turn means that the textile substrate to be dyed can be flowed through particularly well and quickly. When using the method according to the invention, there are no irregularities with regard to the flow through the winding body during the coloring of winding bodies, which, for example in the conventional method for tree coloring of flat structures, are to be regarded as the causes of edge sequences or length sequences. Likewise, no disperse dyes can undesirably agglomerate in the process according to the invention, as is sometimes the case with conventional disperse dyeings, so that by using the process according to the invention, the brightening of disperse dyes known in conventional dyeing processes in aqueous systems and thus corresponding stain formation can be avoided.

Another advantage of the method according to the invention is that Dis Persion dyes can only be used from the actual dye exist and do not contain the usual dispersants and adjusting agents.

The term supercritical CO ₂ is understood to mean CO ₂ in which the pressure and the temperature of the CO _{2 are} above the critical pressure and the critical temperature. Here, the supercritical CO _{2 has} approximately the viscosity of the corresponding gas and a density that is approximately comparable with the density of the correspondingly liquefied gas.

As hydrophobic finishing agents such compounds come into question, one cause hydrophobic modification of the cotton and wool fibers and thus the Increase the possibility of anchoring the fiber for the dyes used. Examples are agents for improving the creasing and shrinking behavior, additives for creasing and non-shrinking equipment, water repellents and flame retardants, such as those e.g. B. from the Textile Aids Catalog 1991, Konradin Verlag R. Kohlhammer, Leinfelden-Echter things 1991, are known.

The hydrophobic finishing agents can e.g. B. following classes of chemical Compounds include: optionally etherified N-methylol derivatives of nitrogen-containing compounds, carbamide condensates or pre-condensates, Descendants of isocyanic acid or cyanamide, polyethylene (co) polymers, Acrylic (co) polymers, silicones, polysiloxanes, halogen-containing polymers, e.g. B. Fluorocarbon polymers, paraffins and organic phosphorus, phosphorus nitrogen, Sulfur nitrogen or ammonium compounds.

Suitable N-methylol derivatives of nitrogen-containing compounds for the process are e.g. B. optionally etherified N-methylol-urea or N-methylol-melamine Compounds, the term N-methylol-urea compounds also being N-methylol Includes compounds of urea derivatives. As urea derivatives for example cyclic ethylene or propylene ureas in the alkylene group may also contain substituents such as hydroxyl groups, urones and optionally Substituted triazone resins called. Modified are preferred where appropriate N-methylol-hydroxyethylene urea compounds such as. B. 1,3-dimethylol-4,5-di hydroxy ethylene urea, methylolation products based on propylene urea or Ethylene urea / melamine and optionally modified (e.g. etherified) Melamine / formaldehyde condensation products.

These auxiliaries are used in an amount of about 5 to 60% by weight, preferably about 10 up to 30 wt .-%, based on the weight of the textile material used. Possible are also mixtures of two or more different auxiliaries.

The pretreatment with the auxiliaries can be carried out from an aqueous liquor, for. B. by if necessary, the textile material in an aqueous solution of the auxiliary Treated with heat or padded with an aqueous solution of the auxiliary, squeezed and then dried under conditions such that the hydrophobic  Finishing agent hardens or cross-links.

But you can also take the treatment with the aid in supercritical CO ₂ , for example by placing the textile material and the aid in an autoclave in supercritical CO ₂ at an elevated temperature, e.g. B. heated to a temperature between about 90 and 200 ° C, preferably at a pressure between about 73 and 400 bar, in particular between about 150 and 250 bar. After relaxing and opening the autoclave, the textile material is dry and can be dyed directly.

The dyeing process is carried out, for example, in such a way that the cellulose or wool textile material pretreated with the hydrophobic finishing agent is added together with the disperse dye to a pressure-resistant dyeing apparatus and heated to the dyeing temperature under CO ₂ pressure or by heating and then heating Sets CO ₂ pressure.

The dyeing temperature used in the process according to the invention depends on essentially according to the substrate to be colored. Usually it is around 90 and 200 ° C, preferably between about 90 and 170 ° C.

The pressure to be used must be at least so high that the CO _{2 is} in a supercritical state. In general, the higher the pressure, the greater the solubility of the dyes in CO ₂ , but the greater the expenditure on equipment. The pressure is preferably between about 73 and 400 bar, in particular between about 200 and 350 bar. At the preferred dyeing temperature for cellulose material of approximately 140 ° C., the pressure is approximately 300 bar. Wool is preferably dyed at a temperature of approx. 100 ° C and a pressure of approx. 400 bar.

The liquor ratio (mass ratio of textile material: CO ₂ ) when dyeing by the process according to the invention depends on the goods to be treated and their presentation.

It usually varies between a value of 1: 2 to 1: 100, preferably about 1: 5 to 1:75. Should, for example, cotton yarns that are attached to appropriate packages are wrapped, dyed according to the inventive method, this is done preferably with relatively short liquor ratios, i.e. H. Fleet ratios between 1: 2 to 1: 5. Such short liquor ratios usually prepare for this  Conventional dyeing processes in the aqueous system have difficulties because of this due to the high dye concentration there is often the risk that the finely dispersed Systems agglomerate. However, this does not occur in the method according to the invention on.

After reaching the dyeing temperature, the desired pressure is set, if this was not achieved as a result of the temperature increase. The temperature and the Pressure is then applied for some time, e.g. B. kept constant for 0.5 to 60 minutes, one through appropriate measures, e.g. B. stirring or shaking, or especially by Circulation of the dye liquor for an intensive mixing of textile material and "Dyeing liquor" ensures. The length of time is generally not critical, but it has been shown that times of more than 15 minutes mostly no improvement in dyeing yield bring.

The pressure is then reduced, which is most easily done by opening a valve and releasing the excess CO ₂ pressure. After opening the autoclave, the dyed textile material is in a dry state and only needs to be freed of any loosely adhering dye, e.g. B. by rinsing with an organic solvent.

A variant of the dyeing process according to the invention is that the pressure is reduced in several stages, preferably in 2 to 100 stages. Due to the rapid expansion, cooling takes place in every stage, ie, it is quasi adiabatically expanded. In addition, the density of the CO _{2 is} changed by the reduction in pressure. After closing the valve, the temperature rises again to the ambient temperature, so the pressure rises again isochorically. After approx. 30 seconds to a few minutes, when the pressure and temperature practically no longer rise, the pressure is reduced again and the process described above is repeated. This mode of operation is preferably controlled automatically by a pressure and / or density and / or temperature program.

The pressure in each stage is preferably around 0.1 to 20 bar, in particular 1 to 10 bar and especially lowered by 2 to 5 bar.

It is also preferred to set the pressure in steps from a pressure between 200 and To decrease 300 bar to 100 to 130 bar. Then you can print the Relax 130 bar in one step.  

Since the density of the supercritical CO ₂ decreases more at lower temperatures when the pressure is reduced, it has proven to be advantageous to take this into account by reducing the pressure levels.

The textile material is then removed from the dyeing machine and can be used without further cleaning if necessary. However, it generally proves advantageous to dye the colored material with a solvent which has a high solubility for disperse dyes, e.g. B. with acetone, so as to remove unfixed dye from the fiber surface. The colored material can also be cleaned by flushing with supercritical CO ₂ at low temperatures.

There are several options for cleaning the CO ₂ after coloring. You can e.g. B. ad- or absorb the remaining dye in the supercritical CO ₂ via appropriate filters. The known silica gel, diatomaceous earth, carbon, zeolite and aluminum oxide filters are particularly suitable for this.

In addition, there is the possibility of removing the dyes remaining in the supercritical CO ₂ after coloring by increasing the temperature and / or reducing the pressure and / or increasing the volume. This results in a density reduction, the reduced density may still be in the supercritical range. But you can also continue this until the supercritical CO ₂ converts into the corresponding gas, which is then collected and used again after transferring to the supercritical state to color other substrates. Here, the dyes separate out as liquid or solid dyes, which can be collected accordingly and used for further dyeings.

The method according to the invention is suitable for dyeing natural textile material Licher and regenerated cellulose, such as. B. hemp, linen, jute, viscose silk, rayon and especially cotton, silk and wool. You can also use mixed fibers Color cellulose or wool and synthetic organic material, for example Mixed fibers made of cotton and polyamide fibers or cotton and polyester fibers.

The fiber materials can be in various processing stages, for example as threads, flakes, yarn, fabrics, fleece or knitted fabrics or as ready-made Would.  

Dispersion paints in particular come as dyes for the process according to the invention fabrics, d. H. dyes which are sparingly soluble or almost insoluble in water, where as dyes also compounds that do not absorb in the visible range in Come into consideration, e.g. B. optical brighteners or NIR-absorbing compounds.

There are z. B. Dyes from the following classes in question:
Nitro dyes, e.g. B. nitrodiphenylamine dyes, methine dyes, quinoline dyes, amino naphthoquinone dyes, coumarin dyes, tricyanovinyl dyes and in particular special anthraquinone dyes and azo dyes such as monoazo and disazo dyes.

The dyes are preferably free of sulfo and carboxy groups and have a molecular weight below 600.

The following examples illustrate the invention without restricting it.

Pretreatment of the fiber materials with a hydrophobic finishing agent example 1

A strip of bleached, mercerized cotton fabric or wool fabric is immersed in a 10% dicyclohexylcarbodiimide solution in CHCl _{3 for} about 10 minutes, then removed and air-dried.

Example 2

A strip of cotton is immersed in an aqueous solution containing 50 g / l of a urea-formaldehyde condensation product, 10 g / l of MgCl ₂ .6H ₂ O and 0.5 g / l of citric acid and then after squeezing for about 1 minute at 170 ° C condensed.

Example 3

Viscose tissue is immersed in an aqueous solution containing 120 g / l of a methylolation product based on glyoxalmonourein, 5 g / l MgCl ₂ and 0.5 g / l citric acid and then condensed at 170 ° C. for 270 seconds.

Examples 4-7

The procedure is as described and used in Examples 2 or 3 instead of the equipment used there, the products listed in the table also obtain usable hydrophobic finished textile materials:

(4) 80 g / l melamine crosslinker (e.g. Lyofix®CHN)
(5) 80 g / l urea crosslinker (e.g. Knittex®FRP)
(6) 140 g / l formaldehyde-free crosslinker (e.g. Knittex®FF)
(7) Mixture of 80 g / l melamine crosslinker (e.g. Lyofix®CHN) and 320 g / l of a covalently bound phosphorus derivative (e.g. Pyrovates®CP conc.)

Coloring Example 8

An autoclave with a volume of 300 ml with built-in pressure and Temperature sensor, a stirrer shaft and a perforated steel cylinder, which as Bracket for the tissue is used with one of the examples 1-7 pretreated cotton or viscose fabric and 1.5 wt .-%, based on the Tissue, the dye of the formula

filled. The dye is placed on the bottom of the autoclave and the system is brought to a working temperature of 140 ° C. Then CO ₂ is introduced into the autoclave by a compressor until a working pressure of approx. 300 bar is reached.

Working temperature and pressure are kept constant for 15 minutes and then with Expanded 10 bar / min to 130 bar. The residual pressure is released in one step. The scarlet colored samples are taken dry from the autoclave and then rinsed with acetone.

Claims (17)

1. A process for dyeing wool, silk or cellulose-containing textile material with disperse dyes, characterized in that the textile material is pretreated with a hydrophobic finishing agent and then dyed from supercritical CO ₂ with a disperse dye. 2. The method according to claim 1, characterized in that as hydrophobic Finishing agent a means of improving the creasing and shrinking behavior, an additive for crease and shrink free finishing, a water repellent or a Flame retardant used. 3. The method according to claim 1 or 2, characterized in that as hydrophobic finishing agent optionally etherified N-methylol derivatives of nitrogen-containing compounds, carbamide condensates or pre-condensates, Descendants of isocyanic acid or cyanamide, polyethylene (co) polymers, Acrylic (co) polymers, silicones, polysiloxanes, halogen-containing polymers such as in particular Fluorocarbon polymers, paraffins or organic phosphorus, phosphorus nitrogen, Sulfur nitrogen or ammonium compounds used. 4. The method according to claim 3, characterized in that it is in the etherified N-methylol derivatives of nitrogen-containing compounds if necessary etherified N-methylol-urea or N-methylol-melamine compounds. 5. The method according to any one of claims 1 to 4, characterized in that optionally modified N-methylol-hydroxyethylene urea compounds, Methylolation products based on propylene urea or ethylene urea / melamine or optionally modified melamine / formaldehyde condensation products as hydrophobic finishing agent used. 6. The method according to any one of claims 1 to 5, characterized in that one auxiliaries promoting dye absorption in an amount of 5 to 60% by weight, preferably 10 to 30 wt .-%, based on the cellulose material used. 7. The method according to any one of claims 1 to 6, characterized in that as Disperse dye uses a dye that is free of sulfo and carboxy groups  and has a molecular weight below 600. 8. The method according to claim 8, characterized in that an or azo Anthraquinone dye used. 9. The method according to any one of claims 7 or 8, characterized in that one Disperse dye used, which is free of additives, in particular free of adjusting agents and Is dispersant. 10. The method according to any one of claims 1 to 9, characterized in that for dyeing the pretreated textile material at temperatures between about 70 ° C and about 200 ° C, preferably between about 90 ° C and about 170 ° C, heated. 11. The method according to any one of claims 1 to 10, characterized in that at a pressure between about 73 bar and about 400 bar, preferably between about 200 bar and about 350 bar, works. 12. The method according to any one of claims 1 to 11, characterized in that the substrate initially in a liquor ratio between about 1: 2 to about 1: 100, preferably between about 1: 5 and about 1:75. 13. The method according to any one of claims 1 to 12, characterized in that the supercritical CO _{2 used is} cleaned after dyeing and used again for dyeing. 14. The method according to claim 13, characterized in that the supercritical CO _{2 is} cleaned by means of a filter. 15. The method according to any one of claims 13 or 14, characterized in that the supercritical CO ₂ is cleaned by increasing the temperature and / or reducing the pressure and / or increasing the volume. 16. Application of the method according to claim 1 for dyeing textile material Cotton. 17. The textile material dyed by the method according to claim 1.