US3359061A - Process for making alkoxyethylsulfonylethyl ethers of cellulose - Google Patents

Description

United States Patent 3 359 061 rnocnss FOR MAKING ALKOXYETHYLSULFO- NYLETHYL ETHERS 0F CELLULOSE Clark M. Welch, New Orleans, La., assignor to the United States of America as represented by the Secretary of Agriculture No Drawing. Filed Dec. 19, 1961, Ser. No. 160,673 12 Claims. (Cl. 8-120) A non-exclusive, irrevocable, royalty-free license in the invention herein described, throughout the world for all purposes of the United States Government, with the power to grant sublicenses for such purposes, is hereby granted to the Government of the United States of America.

This invention relates to the attachment of organic alcohols to cellulose with divinyl sulfone to give hitherto unknown alkoxyethylsulfonylethyl ethers of cellulose, with the simultaneous formation of crosslinks in the cellulose by divinyl sulfone present as such or as its addition products with alcohols. The process affords a method of durably attaching to cellulosic materials, such as cotton textiles those water repellents, rotproofing agents, flame retardants and other textile finishing agents which are alcohols. Simultaneous with such attachment, crosslinking of the cellulose occurs and the cellulosic fibers are rendered insoluble in cuprammonium hydroxide solution. Durable wrinkle resistance in the wet state, or in both the wet and dry state, can be imparted to cellulosic fabrics, along with increased dimensional stability.

The process consists of two competing reactions, (a) and (b), which are as follows:

(a) X ROH CH2=CHSOzCH=OH2 HO-cellulose ao ornornso,cmorn o cellulose CHZ=CHSOZCH=CH2 2H O-cellulose cellulose O-CH2CH2S02CH2CH:O cellulose ROH is a primary, secondary or tertiary alcohol, HO-cellulose is a portion of the celluose chain and X is a base used as the catalyst. The process may be carried out in a single step by applying the reagents and catalyst in one solution to the cellulose, followed by curing at elevated temperatures. Alternatively, it may be conducted as a two step process as follows:

Step 1 X ROH CHz=CHSO2CH=CHz ROCH2CHzsO2CH=CH2 Step 2 X ROCH2OH2SO2CH=CH2 HO-cellulose ROCH2CH3SO2CH2CH:O cellulose X, heat X 2=CHSOiOH=CHi ZHO-cell '2 cell OCH2OH2SO2CH2CH:O cellulose When a monohydric alcohol is employed, Step 1 is carried out in such a way as to give a 1: 1 adduct as shown; i.e., the alcohol and divinyl sulfone are made to combine in a mole ratio of 1:1. Such adducts may be prepared separately and stored for later use. They are a new class of compound. The only previously reported adducts of monohydric alcohols with divinyl sulfone have 2 moles of the alcohol combined with each mole of divnyl sulfone (Alexander and McCombie, J. Chem. Soc. 1913 (1931)). Such 2:1 adducts of monohydric alcohols lack free vinyl groups, and are less reactive toward cellulose. The formation of the 2:1. adducts, which are undesirable for the process of this invention, is minimized by keeping the mole used below 1.5 :1, and preferably below 1.05:1.

In the case of polyhydric alcohols, a large number of combining ratios may be obtained. With ethylene glycol products having the following structure are obtained:

wherein X is a member of the group consisting of the structures HOCH CH O- and and Y is a member of the group consisting of and H. Thus the ethylene glycol and divinyl sulfone may combine in glycol/sulfone mole ratios of 1:1, 1:2, 2:2, 2:1, 2:3, 3:3, 3:2, 3:4, 4:4, 4:3, 4:5, 5:5, 5:4 The series of adducts so formed range from low molecular weight compounds to high polymers. Alcohols having more than two hydroxyl groups per molecule give, in addition to the above series of combining ratios, still others. In all cases however, alcohol/divinyl sulfone combining ratios of 1.0 or less represent adducts which have free vinyl groups and are reactive toward cellulose. Such combining ratios may be obtained by keeping the mole ratio of alcohol to divinyl sulfone actually used at less than 1.2 and preferably less than 1.05. When alcohol/ divinyl sulfone mole ratios less than 0.66 are used, the proportion of water-insoluble adducts in the case of diols and triols becomes too large for convenience in application to textiles.

Neither the adducts mentioned above nor mixtures of alcohols with divinyl sulfone have hitherto been applied to cellulose in the presence of a catalyst to form alkoxyethylsulfonylethyl ethers of cellulose, with simultaneous crosslinking of the cellulose.

Many of the adducts, particularly those of polyhydric alcohols, are soluble in water, and their aqueous solutions are odorless in contrast to divinyl sulfone which alone or in solution is highly poisonous, lachrymatory, and irritating to the mucous membrane. For this reason it is frequently advantageous to prepare the adduct first and carry out its application to the cellulose subsequently (the twostep method).

Regardless of which method of application is chosen, it is possible to exercise some control over the extent to which attachment of alkoxyethylsulfonylethyl groups occur, as compared With the crosslinking reaction that also takes place. In the one-step method, alcohol/divinyl sulfone mole ratios between 0 and 0.8 favor crosslinking while ratios between 0.8 and 3.0 favor attachment. Higher ratios suppress both reactions with cellulose. The type of alcohol or adduct used, as well as the catalyst and curing temperature are other controlling factors in the two methods.

The process is applicable both to monohydric and polyhydric alcohols; however, it has been found that the efiiciency of the crosslinking and attachment reactions increases as the number of hydroxyl groups in the alcohol molecule is increased. Polymeric alcohols such as polyvinyl alcohol and starch are readily attached. Long-chain alcohols, as well as branched-chain alcohols may be used, although adducts of these alcohols with divinyl sulfone react with cellulose less efficiently than do the adducts of other types of alcohols.

Where the number of free hydroxyl groups remaining in the alcohol-divinyl sulfone adduct is two or more for every vinyl group in the adduct, as can be the case with trihydric alcohols for example, a graft polymerization of the adduct readily occurs on cellulose in the presence of heat and alkaline catalysts, regardless of whether the process is carried out in one step or in two. Graft polymerization is advantageous for increasing both the overall reaction efficiency and the degree of Wrinkle resistance obtained in the case of textile treatment. Graft polymerization also results in higher strength retention than is normally observed in crosslinked and wrinkle-resisant cellulosic fabrics.

Catalysts which may be used in treating cellulose by the above methods are such bases as alkali metal carbonates and bicarbonates, alkali or alkaline earth metal hydroxides, and organic quaternary ammonium carbonates, bicarbondates and hydroxides. Where the catalyst is applied to the cellulose from the same solution as the alcohol and the divinyl sulfone or the alcohol-divinyl sulfone adduct, the catalyst concentration should not be so hgh that it causes the latter materials to precipitate or the divinyl sulfone to react with water. Catalyst concentrations of 05-30% may be used, with the preferred concentrations being 1.0-2.5 The higher concentrations are useful where the catalyst is applied to the cellulose separately. Water-insoluble alcohols and adducts may be applied from inert organic solvents followed by drying to remove the solvent. The catalyst alone or with divinyl sulfone is in such cases applied separately from aqueous solution. After the reagents and catalyst have been applied, the fabric is kept at 20170 C. for 0.530 minutes. The stronger the base used as catalyst, the lower the temperature needed for rapid reaction.

The preparation of alcohol-divinyl sulfone adducts is simple and rapid. The base used as a catalyst for the adduct preparation is preferably one that is soluble in the alcohol-dinvyl sulfone reaction mixture. Bases suitable with monohydric alcohols are alkali metal hydroxides, alkoxides, and phenoxides, quaternary ammonium hydroxides, tertiary amines, and tetramethylguanidine. Tetramethylguanidine tends to impart yellowing when cured with fabric, and should therefore be removed completely from the adduct prior to fabric treatment. With certain of the polyhydric alcohols, the use of a base that is too strong may cause undesired polymerization of the adduct, and may also cause the reaction to become uncontrollably exothermic. Preferred bases in such cases are tertiary amines, alkali metal bicarbonates and alkali metal carbonates, with the bicarbonates particularly preferred over the carbonates because of their greater solubility in polyhydric alcohols. Good control of the reaction is obtained by using low concentrations (0.1-5 of catalyst.

The reaction of the alcohol with divinyl sulfone may be carried out by adding the alcohol containing the dissolved catalyst to the sulfone, followed by warming the mixture until exothermic reaction sets in. The temperatures required for reaction fall in the range of 20-140" 0, the optimum values depending on the alcohol used and the catalyst concentration. The preparation of the adducts may also be carried out by adding the catalyst to a mixture of the alcohol and divinyl sulfone followed by heating. As another variant, addition of divinyl sulfone to a mixture of the alcohol and catalyst can be carried out. This last named order of reagent addition is desirable when heating is subsequently required to initiate reaction, but is undesirable when reaction occurs immediately as the sulfone is added, since it will cause a varying mole ratio of dinvyl sulfone to the alcohol as the reaction proceeds. Inert diluents such as N,N-dimethylformamide; N,N-dimethylacetamide, or tetrahydrofuran may be used to increase the solubility of solid alcohols and of polar catalysts; as well as to dissipate the heat evolved and moderate the rate of reaction. The resulting adduct may be isolated by ordinary methods or may be stored in solution.

The following examples illustrate the many procedures that are possible in obtaining various degrees of cellulose substitution and crosslinking. Crease recovery angles cited are double the values measured in the warp direction by the Monsanto crease recovery test. The adaptation of Lawrence and Phillips, Am. Dyestufr Reptr., 45 P548-(l956) was used for crease recovery tests in the wet state. Stiffness was determined with a Tinius Olsen tester. A Scott tester was used for breaking strength determinations. The fabric used was desized, scoured and bleached x 80 cotton print cloth, except where otherwise specified.

Example 1 The 1:1 adduct of methanol with divinyl sulfone was prepared in aqueous solution as follows: to 10 m1. (11.8 g., 0.10 mole) of divinyl sulfone was added slowly, and with sufiicient cooling to keep the temperature at 4'0-45 C., a solution of 3.7 ml. (2.93 g., 0.092 mole) of methanol and 0.8 ml. of 40% benzyltrimethylammonium hydroxide in 4 ml. of tetrahydrofuran. The addition required 5-10 minutes, after which heat evolution ceased. The mixture was kept at 50 C. for 10 minutes, after which it was stirred with ml. of Water. The solution was filtered free of a gummy polymer, the yield of polymer being 1.2 g. Shaking the filtrate ml.) with half its volume of benzene to extract traces of unreacted divinyl sulfone gave a clear aqueous solution (107 ml.) free of the irritating divinyl sulfone odor.

The application of the 12% aqueous adduct to 80 x 80 print cloth was carried out as follows: to 24 ml. of the aqueous adduct was added 0.80 g. of sodium bicarbonate. The solution was applied in one dip, one nip to the fabric giving a wet pickup of 91%. The fabric was cured at 135 C. for 5 minutes in a forced draft oven. It was washed in running water at 60 C. for 15 minutes, was oven-dried and equilibrated with the atmosphere. It had the following properties: weight gain3.4%; sulfur content-1.03%; braking strength loss-18%. Fibers of the treated cotton were insoluble in cupriethylenediamine solution, indicating the cellulose had been crisslinked.

Example 2 The 1:1 adduct of t-butyl alcohol with divinyl sulfone was prepared as follows: 0.10 g. of sodium was reacted with 9.5 ml. (0.10 mole) of boiling t-butyl alcohol. The solution was made up to 9.5 ml. with additional t-butyl alcohol to replace evaporation losses. The solution at phases. These were separated and the two most dense layers were each shaken with 25 ml. of water, causing an organic liquid of density greater than water to separate. The combined organic material was treated with 25 ml. of benzene, causing a polymeric solid impurity to separate. The solution was decanted from the solid and freed of solvent by evaporation, giving 8.75 g. of crude adduct. A 3 ml. (3.3 g.) quantity of this was treated with ml. of boiling water to extract the desired product. The solution was decanted from a viscous gum, and was evaporated to a volume of 15 ml. It was extracted with 15 ml. of ether. Evaporation of the ether extract gave 1.05 g. of mobile, nearly colorless liquid whose sulfur content was 17.9%.

A solution containing 20% by volume of the crude adduct in toluene was applied in one dip and one nip to 80 x 80 print cloth to a wet pickup of 74%. The fabric was dried at 80 C. for 3 minutes, and was equilibrated in air. It was then treated with a solution containing 2% sodium hydroxide and 1% sodium lauryl sulfate in one dip and one nip to a wet pickup of 77%. It was cured at C. for 5 minutes, washed in running water at 60 C. for 15 minutes, oven-dried and airequilibrated. The weight gain was 1.2%. Fibers of the cotton were insoluble in cupriethylenediamine solution, indicating that crosslinking had occurred.

Example 3 The 1:1 adduct of n-octadecyl alcohol and divinyl sulfone was prepared as follows: sodium phenoxide was made by warming a mixture of 0.94 g. (0.01 mole) phenol and 0.40 g. (0.01 mole) of sodium hydroxide pellets while grinding up the solid base, until the entire mixture solidified. The solid sodium phenoxide was cooled and powdered. To a solution of 6.7 g. (0.025 mole) of octadecyl alcohol and 3.8 ml. (0.038 mole) of divinyl sulfone in 10 ml. of N,N-dimethylformamide at 45 C. was added 0.20 g. of the sodium phenoxide. The temperature rose spontaneously to 60 C. The base went into solution when stirred. The mixture was allowed to stand for 40 minutes, after which 0.20 ml. of glacial acetic acid was added. The solid reaction mixture was dissolved in 100 ml. of boiling methanol, the solution was decanted from a small amount of insoluble material, and was diluted with an additional 200 ml. of methanol. To the boiling solution was added 6 g. of decolorizing charcoal. After -10 minutes of boiling, the mixture was filtered under suction. The charcoal was treated with two 75 ml. portions of boiling methanol which was also filtered. The combined filtrates were cooled to 25 C. and filtered to remove by-products. The filtrate was chilled to 4 C. and the solid products collected by filtration. Additional solid was obtained by adding water to the filtrate and re-filtering. The combined solids were freed of methanol by aspiration and were dissolved in 100 ml. of boiling ether. The solution was filtered and then chilled to 8 C. with stirring. Filtration removed solid byproducts. The filtrate was concentrated to 50 ml. and chilled to 8 .C. with stirring. Suction filtration gave solid products (A) and a filtrate (B). Solids (A) were stirred with 25 ml. of boiling ether, were cooled to 15 C. and filtered. The filtrate was evaporated to dryness giving 3.04 g. of crude product melting at 45.047.5 C. It contained 9.0% sulfur. Evaporation of filtrate (B) gave an additional 2.04 g. of crude product melting at 44.5- 46.5 C. and containing 9.0% sulfur. This material was suitable for use in textile finishing, but could be further purified as follows: a 1.00 g. sample of the crude product was dissolved in 50 ml. of petroleum ether (B.P. 30-60) and cooled with stirring to 15 C. It was filtered rapidly by suction. The filtrate was diluted to 50 ml. with additional petroleum ether and chilled to 8 C. with stirring. After suction filtration, the filtrate was again diluted to 50 ml. with petroleum ether, and was chilled to 34 C. with stirring, followed by suction filtration. The dilution, chilling and filtration were repeated. The filtrate was concentrated, and the resulting product was dried. The yield was 0.60 g. of solid melting at 48.0-49.0 C., and containing 8.0% sulfur. The theoretical sulfur content for the 1:1 adduct is 8.2%.

Application to 80 x 80 print cloth of the crude adduct as its 2% solution in toluene was carried out in one dip and one nip to a wet pickup of 84%. The'fabric was oven-dried and air-equilibrated. It was then treated in one dip and one nip with a solution containing 2% sodium hydroxide and 1% sodium lauryl sulfate in water, to a wet pickup of 93%. It was cured at 135 C. for 5 minutes, washed in running water at 60 C. for 15 minutes, oven-dried, extracted with boiling toluene, acetone, and tetrahydrofuran to remove any organic material present merely as a coating. It was again oven-dried and airequilibrated. The cloth had a spray rating of 50 (AATCC Test Method 22-1952) indicating moderate water repellency caused by attachment of the long-chain alcohol.

Example 4 The 1:1 adduct of ethylene glycol with divinyl sulfone was prepared as follows: to 5.6 ml. (6.2 g., 0.1 mole) of ethylene glycol was added 0.05 g. of sodium hydroxide. The mixture was warmed to 60 C. and the sodium hydroxide crushed. After the alkali had dissolved, the mixture was cooled to room temperature and added to 10 ml. (11.8 g., 0.10 mole) of divinyl sulfone in a 50 ml. beaker. The resulting mixture was stirred and warmed to 35 C., whereupon the temperature rose spontaneously. After 5 minutes it reached 55 C. and the beaker was immediately cooled in an ice bath to keep the temperature below 60 C. After 10 minutes longer, heat evolution ceased. The reaction mixture was warmed to C. for 5 minutes and then cooled. It was a highly viscous syrup completely miscible with water. The addition of 36 ml. of water gave 50 ml. of solution which was shaken with three 50 ml. portions of benzene to remove any unreacted divinyl sulfone. Evaporation of the benzene extracts gave only 0.67 g. of divinyl sulfone. The aqueous phase containing the adduct was placed under an air jet to remove small amounts of benzene, after which it was odorless.

The 33% aqueous adduct was applied to 80 x 80 print cloth as follows: to 25 ml. of the solution was added 0.80 g. of sodium bicarbonate. The solution wan applied in one dip, one nip to a wet pickup of 116%. The fabric was cured at C. for 5 minutes. It was washed in running water at 60 C. for 15 minutes, and after being oven-dried, was equilibrated with the atmosphere. The fabric properties were as follows: weight gain11%; sulfur content-3.11%; wet crease recovery angle255 for untreated fabric); dry crease recovery-271 for untreated fabric); breaking strength loss- 38%.

Example 5 The 1:1 adduct of glycerol with divinyl sulfone was prepared as follows: to 9.2 g. (0.10 mole) of glycerol in a 50 ml. beaker was added 0.10 g. of sodium bicarbonate. The mixture was warmed to 60 C. with stirring until nearly all of the solid had dissolved. The solution was cooled to 30 C. and 10 ml. (0.1 mole) of divinyl sulfone was added. The mixture was warmed to 75 C. whereupon the two liquid phases merged and the temperature rose spontaneously to 85 C. The beaker was immediately cooled in an ice bath so as to keep the temperature at 75-80 C. After 10 minutes, heat evolution ceased. The solution was warmed to keep it at 80 for 5 minutes longer, and then was cooled. The product was a highly viscous, clear, water-soluble syrup. It was dissolved in 20 ml. of water to give 35 ml. of solution which was then shaken with three 30 ml. portions of benzene to remove any unreacted divinyl sulfone. Evaporation of the benzene extracts gave only 0.04 g. of divinyl sulfone. The aqueous phase (34 ml.) containing the adduct was diluted to 50 ml. with 16 ml. of water and placed under an air jet to remove traces of benzene. It was then clear and odorless.

Application of the adduct solution to 80 x 80 print cloth was carried out as follows: the 36% solution was diluted with water and 3.3% of sodium bicarbonate was added. The fabric was treated in one dip and one nip to a wet pickup of 8692%. It was cured at 135 C. for 5 minutes, was washed in runnning water at 60 for 15 minutes, was oven-dried and air-equilibrated. The fabric properties are given in the following table:

1 Decrease in breaking strength as compared with untreated fabric.

Example 6 The 1:1 adduct of glycerol with divinyl sulfone was prepared in the following way: A mixture of 9.2 g. (0.10 mole) glycerol and 0.05 g. of sodium methoxide powder in a 50 ml. beaker was warmed to 50 C. and stirred until solution was complete. Then 10 ml. (0.10 mole) of divinyl sulfone was added. The mixture was heated to 90 C., causing the two liquid phases to merge, and then to 115 whereupon the temperature rose spontaneously to 140 C. Sufiicient cooling was applied to keep the temperature from rising further. After minutes, heat evolution ceased. The mixture was warmed to keep it at 130 for 5 minutes longer. The product at room temperature was a highly viscous, water-soluble syrup. It was diluted with ml. of water and shaken with three 20 ml. portions of benzene to remove unreacted divinyl sulfone. Evaporation of the benzene extracts gave only 0.04 g. of the divinyl sulfone. The aqueous phase (33 ml.) was diluted to 50 ml. with water, giving a 36% solution of the adduct. This was odorless after traces of benzene were evaporated from it.

Application of the adduct at a concentration of 18% to 80 x 80 print cloth was similar to that of Example 4. The weight gain was 16% using a wet pickup of 115%. The fabric properties were as follows: sulfur content2.14%; wet crease recovery301; dry crease recovery257; breaking strength loss-28%. The wet and dry crease recovery of untreated fabric were 160 and 165 respectively.

Repetition of the above adduct preparation using twice as much sodium methoxide catalyst resulted in uncontrollable heat evolution and polymerization at 50 C.

Example 7 The adduct preparation of Example 6 was repeated using only 6.9 g. (0.075 mole) of glycerol, so as to give a glycerol/divinyl sulfone mole ratio of 3:4. The adduct in ml. of water was shaken with benzene as usual, after which it existed as two aqueous phases. These were merged after separation from the benzene layer, by addition of 11 ml. of tetrahydrofuran to give a total volume of 52 ml. The adduct concentration was approximately 32%.

The solution was diluted with varying amounts of aqueous tetrahydrofuran (33% by volume), and sodium bicarbonate was added to the extent of 3% of the total weight of the mixture. The solution was applied to 80 x 80 print cloth as in Example 4, a wet pickup of 111-1 12% being used. The fabric properties obtained were as follows:

Adduct Wt. Gain, Wet Crease Dry Crease B.S. Sulfur Cone, percent Recovery, Recovery, Loss, Content, percent deg. deg. percent percent 0 Untreated 160 165 Example 8 Mole ratio glycerol/sulfone 2 0 0. 50 Percent weight gain 10 19 Example 9 The attachment of sorbitol to cellulose with divinyl sulfone was carried out in the same way as for glycerol in Example '8. A weight gain of 23% was obtained at a sorbitol/sulfone mole ratio of 0.5,

8 Example 10 Pentaerythritol was attached to cellulose with divinyl sulfone by the method used with glycerol in Example 8. A sample of x 80 print cloth so treated showed a weight gain of 17% whereas in the absence of pentaerythritol the treatment produced a weight gain of only 7.5%. The test sample had high wet and dry wrinkle resistance.

Example 11 Polyvinyl alcohol was attached to cellulose by the onestep method, as follows: a mixture of 1.0 g. polyvinyl alcohol in 15 ml. of water was heated to boiling and stirred for 10 minutes. The solution was cooled to room temperature, and a solution of 0.8 g. sodium bicarbonate in 10 ml. of water was added. The mixture was stirred until homogeneous. Then 0.50 ml. of divinyl sulfone was added. The rather viscous solution was used to treat 80 x 80 print cloth in 2 dips and 2 nips, care being taken to obtain thorough wetting of the fabric. The wet pickup was The fabric was cured at C. for 5 minutes, and washed in running water at 60 C. for 30 minutes. It was oven-dried and equilibrated with the atmosphere. It then exhibited a highly starched feel. The weight gain was 6%.

Fabric properties observed were: wet crease recovery-- 267 (untreated fabric-156), stiffness (bending m0- ment)--44.02 X10- lbs. (untreated fabric-525 X10 breaking strength loss16%.

Example 12 Starch was attached to cellulose as follows: 1.0 g. of potato starch powder was added to 25 ml. of boiling water and the mixture was boiled for 15 minutes. The solution was cooled to room temperature and 0.8 g. of sodium bicarbonate was added. After this dissolved, 0.50 ml. of divinyl sulfone was added. The resulting solution was stable at room temperature, in contrast to solutions containing starch and divinyl sulfone at a pH of 10 or above. The latter solutions quickly gelled due to crosslinking of the starch by the divinyl sulfone. The starchsulfone-bicarbonate solution was applied to 80 x 80 print cloth in one dip, one nip to a wet pickup of 91%. Curing was at 135 C. for 10 minutes. The fabric was washed in running water at 60 for 30 minutes, and was ovendried prior to equilibration with the atmosphere. The weight gain of 4.5% was unaffected by 2 /2 hours in running Water at 60 C., or by 30 minutes in boiling water. Fabric treated as above except that the divinyl sulfone was omitted showed a 2% weight gain, but this was entirely removed by extended washing followed by the treatment with boiling water.

The fabric properties were then as follows:

Stifiness (bending moment), lb.

Wet Crease Recovery, deg.

Breaking Strength Gain, percent Untreated Example 13 Polyvinyl alcohol was attached to cellulose in the following way: a mixture of 1.0 g. of polyvinyl alcohol and 24 ml. of water was heated to boiling for 10 minutes. The solution was cooled and 0.50 ml. of divinyl sulfone was added. The resulting solution was applied in one dip and one nip to 80 x '80 print cloth to a wet pickup of 100%. The cloth was dried at 70 C. for 3 minutes. It was then soaked for 5 minutes in 20% aqueous sodium hydroxide at room temperature. The treated fabric was thoroughly washed, and was kept in boiling water for one hour to remove any unattached polyvinyl alcohol. The dried and air-equilibrated fabric showed a weight 9 increase of 6.5% and a crisp starched feel. When wet, it had high wrinkle resistance.

I claim:

1. A process for the preparation of a crosslinked alkoxyethylsulfonylethyl ether of cellulose that in the form of textile fabrics exhibit wet and dry wrinkle resistance and enhanced dimensional stability which process comprises wetting the cellulose with a solution that contains from about 0.5% to about 30% by weight of an alkaline cataylst, an alcohol selected from the group consisting of glycerol, sorbitol, and pentaerythritol and divinyl sulfone, the alcohol and the divinyl sulfone being present in a mole ratio less than 3:1, and subsequently keeping the wetted cellulose at a temperature of from 20 to 170 C. for 0.5 to 30 minutes to produce a crosslinked alkoxyethylsulfonylethyl ether of cellulose.

2. The process of claim 1 wherein the alcohol is glycerol.

3. The process of claim 1 wherein the alcohol is sorbitol.

4. The process of claim 1 wherein the alcohol is pentaerythritol.

5. A process for the preparation of a crosslinked alkoxyethylsulfonylethyl ether of cellulose that in the form of textile fabrics exhibit wet and dry wrinkle resistance and enhanced dimensional stability, which process comprises wetting the cellulose with a solution that contains from about 0.5% to about 30% by weight of an alkaline catalyst together with the adduct of divinyl sulfone with an alcohol selected from the group consisting of t-butyl alcohol, n-octadecyl alcohol, and glycerol wherein the mole ratio of divinyl sulfone and the alcohol in combination in the adduct is 1:1, and keeping the wetted cellulose at a temperature of from 20 to 170 C. for from 0.5 to 30 minutes to produce a crosslinked alkoxyethylsulfonylethyl ether of cellulose.

6. The process of claim 5 wherein the alcohol is t-butyl alcohol.

7. The process of claim 5 wherein the alcohol is n-octadecyl alcohol.

8. The process of claim 5 wherein the alcohol is glycerol.

9. A process for the preparation of a crosslinked alkoxyethylsulfonylethyl ether of cellulose that in the form of textile fabrics exhibit wet and dry wrinkle resistance and enhanced dimensional stability, which process comprises wetting the cellulose with an inert, volatile, nonaqueous solvent that contains an adduct of divinyl sulfone with an alcohol selected from the group consisting of n-octadecyl alcohol and t-butyl alcohol wherein the mole ratio of divinyl sulfone and the alcohol in combination in the adduct is 1:1, then removing the solvent by 10 volatilization, and subsequently Wetting the fabric with an aqueous solution that contains from about 0.5% to about 30% by weight of an alkaline catalyst, and keeping the wetted cellulose at a temperature of from 20 to C. for from 0.5 to 30 minutes to produce a crosslinked alkoxyethylsulfonylethyl ether of cellulose.

10. The process of claim 9 wherein the alcohol is n-octadecyl alcohol.

11. The process of claim 9 wherein the alcohol is t-butyl alcohol.

12. A process for the preparation of a crosslinked alkoxyethylsulfonylethyl ether of cellulose that in the form of textile fabrics exhibit wet and dry wrinkle resistance and enhance dimensional stability, which process comprises wetting the cellulose with a solution that contains from about 0.5% to about 30% by weight of an alkaline catalyst together with the adduct of divinyl sulfone and glycerol wherein the mole ratio of glycerol to divinyl sulfone used in preparing the adduct is in the range of from 0.66:1 to 12:1 and keeping the wetted cellulose at a temperature of from 20 to 170 C. for from 0.5 to 30 minutes to produce a crosslinked alkoxyethylsulfonylethyl ether of cellulose.

References Cited UNITED STATES PATENTS 2,539,704 1/1951 Schoene et al. 8--116 3,000,762 9/ 1961 Tesoro. 3,031,435 4/1962 Tesoro. 3,068,123 12/ 1962 Feldmann 8-1 16 2,505,366 4/ 1950 Schoene. 2,524,400 10/ 1950 Schoene. 3,046,075 7/1962 Kantner et al. 3,106,439 10/1963 Valentine et a1 8-120 2,524,399 10/1950 Schoene et al. 8-1 16 2,988,417 6/1961 Emmons 81 16 2,470,077 5/1949 Fincke 260607 2,573,580 10/1951 Ladd 260607 FOREIGN PATENTS 93 6,479 9/ 1963 Great Britain. 255,967 2/ 1960 Spain.

OTHER REFERENCES Welch et al.: Textile Research Journal, vol. 31, pp. 84-86, January 1961.

NORMAN G. TORCHIN, Primary Examiner.

JULIAN S. LEVITT, ABRAHAM H. WTNKELSTEIN,

Examiners.

J. TRAVIS BROWN, I. CANNON, Assistant Examiners.

Claims (2)

1. A PROCESS FOR THE PREPARATION OF A CROSSLINKED ALKOXYETHYLSULFONYLETHYL ETHER OF CELLULOSE THAT IN THE FORM OF TEXTILE FABRICS EXHIBIT WET AND DRY WRINKLE RESISTANCE AND ENHANCED DIMENSIONAL STABILITY WHICH PROCESS COMPRISES WETTING THE CELLULOSE WITH A SOLUTION THAT CONTAINS FROM ABOUT 0.5% TO ABOUT 30% BY WEIGHT OF AN ALKALINE CATAYLST, AN ALCOHOL SELECTED FROM THE GROUP CONSISTING OF GLYCEROL, SORBITOL, AND PENTAERYTHRITOL AND DIVINYL SULFONE, THE ALCOHOL AND THE DIVINYL SULFONE BEING PRESENT IN A MOLE RATIO LESS THAN 3:1, AND SUBSEQUENTLY KEEPING THE WETTED CELLULOSE AT A TEMPERATURE OF FROM 20 TO 170*C. FOR 0.5 TO 30 MINUTES TO PRODUCE A CROSSLINKED ALKOXYETHYLSULFONYLETHYL ETHER OF CELLULOSE.

5. A PROCESS FOR THE PREPARATION OF A CROSSLINKED ALKOXYETHYLSULFONYLETHYL ETHER OF CELLULOSE THAT IN THE FORM OF TEXTILE FABRICS EXHIBIT WET AND DRY WRINKLE RESISTANCE AND ENHANCED DIMENSIONAL STABILITY, WHICH PROCESS COMPRISES WETTING THE CELLULOSE WITH A SOLUTION THAT CONTAINS FROM ABOUT 0.5% TO ABOUT 30% BY WEIGHT OF AN ALKALINE CATALYST TOGETHER WITH THE ADDUCT OF DIVINYL SULFONE WITH AN ALCOHOL SELECTED FROM THE GROUP CONSISTING OF T-BUTYL ALCOHOL, N-OCTADECYL ALCOHOL, AND GLYCEROL WHEREIN THE MOLE RATIO OF DIVINYL SULFONE AND THE ALCOHOL IN COMBINATION IN THE ADDUCT IS 1:1, AND KEEPING THE WETTED CELLULOSE AT A TEMPERATURE OF FROM 20 TO 170*C. FOR FROM 0.5 TO 30 MINUTES TO PRODUCE A CROSSLINKED ALKOXYETHYLSULFONYLETHYL ETHER OF CELLULOSE.