CH422711A - Process for improving the dyeability of textile cellulose fibers - Google Patents

Description

  

      Method for improving the dyeability of textile cellulose fibers The invention relates to a method for improving the dyeability of textile cellulose fibers, which is characterized in that

   that the cellulose fibers are treated first with an aqueous alkali solution and then with a solution that contains a hydrocarbon sultone.



  It is already known to treat sodium cellulose with hydrocarbon sultones. This gives a white, light mass with a fiber structure which is easily soluble in water.

   It was therefore surprising that with the method according to the invention it was possible to obtain cellulose fibers whose dyeability was considerably better than that of untreated fibers or fibers treated only with sodium hydroxide, without the fibers noticeably losing their other textile properties.



  The method according to the invention can be used for treating textile cellulose fibers of any type. These fibers can be in the form of woven and non-woven goods, threads, gauze, yarn, corduroy, cord, netting and the like. The process also includes the treatment of textile cellulose fibers that have already been pretreated, e.g. B. were merverized.

   You can according to the invention treat fibers that contain any, preferably at least 30 percent, proportion of cellulose substances such as natural cellulose, eg. B. cotton or linen, or other cellulosic materials, such as viscose or copper ammonia rayon, regenerated cellulbs or cellulose acetate. If appropriate, the cellulose fibers can be mixed with wool and synthetic fibers, for.

   B. with fibers made of acrylonitrile (Orlon, a 100% acrylonitrile polymer) or from vinylidenecyanide polymers or polyamides {nylon, from polyester-polyamides, from polymers of corn protein and formaldehyde, or from copolymers of the above-mentioned Mo nomeren, such.

   B. Acrilan (85% acrylonitrile and <B> 15% </B> vinyl acetate), Dynel (60% vinyl chloride and 40% acrylonitrile), Saran (85% vinylidene chloride and 15% vinyl chloride). Also other synthetic materials or fibers made from polyalkylenes, such as polyethylene or polypropylene, polyurethane,

          Mineral fibers (fiberglass) or alginic acid substances such as alginate redone can be used as additives to the cellulose fibers.



  Preferred for use in the method of the invention are u. a. Textile fibers with at least 60 percent cellulose, which can consist in particular of cotton, rayon and cellulose acetate.



  It has been found that, by using the method according to the invention, the cellulose-containing fiber material can be modified in such a way that it has a greatly increased reactivity towards other substances, such as basic dyes. The fibers treated according to the invention react with these without further ado and the dyeings obtained are deeper and more resistant to fading during exposure and washing.



  When carrying out the method according to the invention, the cellulose fiber material to be treated is brought into contact with an aqueous alkali solution, preferably with a sodium hydroxide solution, which, however, can also be replaced by a potassium hydroxide or another alkali or alkaline earth solution can. The strength of the alkali solution can vary widely;

   Concentrations between 1 and 30, in particular from 5 to 20% by weight are preferred. In the usual mercerization processes, alkali solutions are used in a concentration of 16 to 18%, which are also ideally suited for the process according to the invention.

       In practice, the second stage of the process can immediately follow the mercerization stage and is therefore part of the normal wet treatment of textiles.



  The impregnation or impregnation with the aqueous alkali can be carried out in any way, e.g. B. by dipping, spraying or padding. It is preferred to pull the material through the aqueous solution, as in the known padding technique. The amount of wet absorbed varies depending on the case; it is preferably from 20 to 100 parts of solution per 100 parts of dry material.



  The temperature of the alkali solution and that of the material to be soaked. can be different; preferably both correspond approximately to the room temperature. Mercerization temperatures between 10 and 40 C are generally preferred.



  The material soaked with the alkali solution is then treated with a solution of a sulton.

    The sultones to be used according to the invention are intermolecular cyclic esters of hydroxysulfonic acids and can be derived from aliphatic, cycloaliphatic or aromatic acids.

       Examples of sulfones which can be used according to the invention are the 1,3-propane sultones, the 1,4 butane sultones, the 1,3-hexane sultones and the benzyl and toluysultones, as well as mixtures thereof.

   The sultones to be used can be the gamma sultones such as 1,3-propanesukone. The sultones can be prepared in a conventional manner, e.g.

   B. by sulfochlorination of chlorinated hydrocarbons, where the resulting chlorosulfonic acid is then used for the formation of the sultones. The Sulton solutions can be prepared in any way, e.g.

   B. by mixing the sultone with water, acetone or alcohol or mixtures thereof. In general, it is preferred to use an aqueous solution.

   The concentration of the sultone solutions can be varied within a wide range; The use of solutions containing 1 to 25 percent by weight sultone is preferred.



  It may be advantageous to add wetting agents, for which a large number of different compounds of cationic, anionic or nonionic character are available. Preferred are the ionic agents and in particular those with a polar structure,

       in which a charged ionic group is bound to a hydrophilic (predominantly hydrocarbon) residue.

   Such anionic surface-active compounds are u. a. the alkali and ammonium soaps of higher fatty acids, such as potassium or sodium myristate, laurate, palmitate, oleate or stearate or ammonium stearate;

      The salts of long-chain aliphatic amines and quaternary ammonium bases, such as laurylamine hydrochloride and stearylamine hydrochloride, are also suitable. Examples of nonionic agents include: a. the partial esters of polyhydric alcohols and fatty acids, such as the hexitanes and hexitide esters, e.g. B.

         Sorbitan monolaurate, the hydroxypolyoxyalkylene ethers of the above partial esters z. B. the polyethylene glycol ethers of sorbitan monolaurate, or the hydroxypolyoxyalkylene ethers of phenols, such as the reaction product of ethylene oxide and bisphenol-A or mixtures of the substances mentioned.

   The wetting agents are preferably added in amounts of 0.1 to 5% by weight, in particular 0.5 to 3% by weight.



  The impregnation of the alkali-pretreated fiber material can be done in any way, e.g. B. by dipping, spraying or padding. In general, it is useful to pull the fiber material through the sultoul solution, as is done with padding. The amount of solution absorbed can vary depending on the circumstances, but is preferably between 10 and 100%



  The temperature of the Sulton and that of the soaked, alkaline pretreated fiber material can be varied within wide limits, for. B. between 15 and 90 C and is preferably between 20 and 70 C.



  The time necessary for the reaction with the sulton depends on the temperature and the concentration of the solution. At elevated temperature, the reaction is complete in most cases within one or two hours.



  After removing the impregnated material from the sultone solution, it is washed to remove the still adhering reactants, dried and is then immediately ready for dyeing. Washing is preferably carried out with water, to which cleaning agents (detergents) can optionally be added. Drying is best carried out at temperatures between room temperature and 125 C.

           Example <I> 1 </I> A cotton fabric was treated for 15 minutes at 24 ° C. with 20% strength sodium hydroxide solution and then for 60 minutes at 49 ° C. with a 10% strength propane sulfone solution.

       Cotton swatches measuring 7.5 × 7.5 cm were then dyed by semi-permanent boiling with 0.1% methylene blue and 0.1% acetic acid. The percentage reflection was determined; it is given in the table in comparison with that of the untreated goods and the goods treated only with alkali.

   The following results were obtained:
EMI0003.0001
  
    reflection
<tb> goods <SEP> color <SEP> in
<tb> untreated <SEP> royal blue <SEP> 44
<tb> only <SEP> with <SEP> 20% <SEP> NaOH <SEP> darker <SEP> blue
<tb> treats <SEP> as <SEP> above
<tb> treats <SEP> with <SEP> 20% <SEP> very <SEP> dark <SEP> blue
<tb> NaOH, <SEP> aftertreated
<tb> with <SEP> 10% <SEP> propane sulton <I> Example 2 </I> In further test series, the improved color absorption capacity of treated cotton fibers was shown,

   using a less concentrated ribbon and varying amounts of propane sulton. The 7.5 x 7.5 cm swatches were boiled in 0.01% methylene blue with 0.01% acetic acid for 30 minutes. The results are shown in the table.

    
EMI0003.0015
  
    Treatment, <SEP> min / cl <SEP> C <SEP> color <SEP> reflection
<tb> in
<tb> untreated <SEP> light blue <SEP> 69
<tb> 20% <SEP> NaOH, <SEP> 60/49 <SEP> light blue <SEP> 69
<tb> 20% <SEP> NaOH, <SEP> 60/49 <SEP> dark blue <SEP> 20 25% <SEP> propane sultone, <SEP> 90/24
<tb> 20% <SEP> NaOH, <SEP> 15/24 <SEP> dark blue <SEP> 19
<tb> <B> 10% </B> <SEP> propane sultone, <SEP> 80/38
<tb> 201-0 <SEP> NaOH, <SEP> 15/24 <SEP> dark blue <SEP> 22
<tb> <B> 10% </B> <SEP> propane sultone, <SEP> 30/49
<tb> 20% <SEP> NaOH, <SEP> 15/24 <SEP> dark blue <SEP> 23.5
<tb> <B> 10% </B> <SEP> propane sultone, <SEP> 60/49
<tb> 20% <SEP> NaOH, <SEP> 15/24 <SEP> dark blue <SEP> 21
<tb> <B> 10% </B> <SEP> propane sultone, <SEP> 15/71
<tb> 20% <SEP> NaOH, <SEP> 15/49 <SEP> dark blue <SEP> 25.5
<tb> 5 <SEP>% <SEP> propane sultone, <SEP> 30/49
<tb> 20% <SEP> NaOH,

   <SEP> 15/24 <SEP> dark blue <SEP> 24
<tb> <B> 25% </B> <SEP> propane sultone, <SEP> 30/49

 

Claims (1)

PATENT CLAIM Process for improving the dyeability of textile cellulose fibers, characterized in that the cellulose fibers are first mixed with; an aqueous alkali solution and then treated with a solution containing a hydrocarbon sultone. SUBCLAIMS 1. Method according to claim, characterized in that the alkali solution is a sodium hydroxide solution. 2. The method according to claim, characterized in that the alkali solution holds 1 to 30 wt.%, Preferably 5 to 20 wt.% Alkali hydroxide ent. 3. The method according to claim, characterized in that the temperature of the alkali solution is between 10 and 40 C. 4th Method according to claim, characterized in that an aqueous solution of a hydrocarbon sultone is used. 5. The method according to claim, characterized in that the hydrocarbon sultone is 1,3-propane sultone. 6. The method according to claim, characterized in that the hydrocarbon; sersboffsulton is present in the solution in a concentration of 1 to 25% by weight. 7th Method according to claim, characterized in that a wetting agent is additionally used. B. The method according to dependent claim 7, characterized in that the wetting agent is used in an amount of 0.1 to 5% by weight. 9. The method according to claim, characterized in that the cellulose-containing fibers soaked with an aqueous alkali solution are introduced into the sulphon solution and passed through it. 10. The method according to any one of the dependent claims 4 to 9, characterized in that the temperature of the sultone solution is 20 to 70 C. <B> cited </B> writings and images <I> German patent specification no. <B> 743570 </B> </I>