US3919385A

US3919385A - Process for producing high fluid-holding fiber mass

Info

Publication number: US3919385A
Application number: US309076A
Authority: US
Inventors: Frederick R Smith
Original assignee: FMC Corp
Current assignee: Tambrands Inc; FMC Corp
Priority date: 1972-11-24
Filing date: 1972-11-24
Publication date: 1975-11-11
Anticipated expiration: 1992-11-11

Abstract

Method of making alloy fibers having high fluid-holding capacity, the alloy fibers being comprised of a matrix of nonderivatized regenerated cellulose having regenerated cyanoethyl cellulose and polyvinylpyrrolidone uniformly dispersed therein.

Description

United States Patent 1191 Smith 1 1 PROCESS FOR PRODUCING 111011 FLUID-HOLDING FIBER MASS [75] Inventor: Frederick R. Smith. Wilmington.

Del.

[73] Assignee: FMC Corporation, Philadelphia. P11.

[22] Filed: Nov. 24, 1972 [21] Appl. No.: 309.076

[52] US. Cl 264/184; 128/284; 260/17 R; 260/174 CL; 264/186. 264/188 [51] Int. Cl D01f 7/00; D01f 3/11) [58] Field of Search 260/9. 17.4, 17 R. 17.4 CL. 264/188. 194. 191. 184. 186; 106/165; 128/284 1 1 Nov. 11, 1975 3.146.116 8; 1964 Bates 106/165 3.242.121) 3/1966 Steuhcr 260/9 3.255.275 6/1966 Wallcs e1 :11. 2611,17 R

3.318.990 5/1967 Kujitzmi 264/181! 3.377.412 4/1968 Franks 261117 R 3.509.249 4/1971) Kuzmzlk st 111 264/188 3.525.735 11/1970 Miller 106/165 3.553.306 1/1971 Church 264/188 3.669.103 6/1972 Harper ct 111 128/284 FOREIGN PATENTS OR APPLICATIONS 6.506.343 12/1965 Nclherlz1nd 264/1811 Prinmry liiruminur-Ju) H. Woo

[57] ABSTRACT Method of making 11110 fibers having high fluidholding capacity. the 111111 fibers being comprised of L1 matrix of nowdcrivutized regenerated cellulose having regenerated cyunoethyl cellulose and pol \'\'in \lpyrrolidonc uniformly dispersed therein.

7 Claims. N0 Drawings PROCESS FOR PRODUCING HIGH FLUID-HOLDING FIBER MASS The present invention is directed to a method for making alloy fibers having high fluid-holding capacity.

Known in the art are alloy fibers, consisting of sodium carboxymethyl cellulose and regenerated cellulose, which can be employed in various articles which are intended to absorb body liquids. While the fluidholding capacity of these alloy fibers is greater than that of conventional regenerated cellulose fibers, this advantage is at least partially offset by their higher manufacturing costs.

One mode of making such known alloy fibers involves the mixing of sodium carboxymethyl cellulose into viscose and then converting this mixture into fibers using the conventional viscose spinning system. Drying of the resulting alloy fibers to cardable form is difficult. This objective can be attained, however, by treating the alloy fibers with special finishes, removing water therefrom with alcohol, and then finally drying the alcoholwet fibers. Aside from introducing greater complexity into the manufacturing process, the finishing and drying of the alloy fibers by solvent exchange is a relatively costly procedure. Accordingly, a primary object is to provide new or generally improved and more satisfactory method for making absorbent alloy fibers.

Another object of this invention is to provide a method for making absorbent alloy fibers of regener ated cellulose containing a uniform dispersion of cyanoethyl cellulose and polyvinylpyrrolidone.

Still another object is the provision of a method for making absorbent alloy fibers from a mixture of conventional viscose, cyanoethylated viscose, and polyvinylpyrrolidone in which no special drying procedures are required.

These and other objects are accomplished in accordance with the present invention by a method which provides absorbent alloy fibers, each having a matrix of non-derivatized regenerated cellulose within which regenerated cyanoethyl cellulose and polyvinylpyrrolidone are uniformly dispersed, with the non-derivatized regenerated cellulose being the major portion of the fiber mass.

As employed throughout the description and claims, the terminology alloy fibers refers to cellulose fibers having both regenerated cyanoethyl cellulose and polyvinylpyrrolidone contained therein. Similarly "fluidholding capacity" is a measure of liquid absorbed into the fibers of a mass of alloy fibers together with the liquid retained within the interstices of such fiber mass. The amounts of cyanoethylated viscose and polyvinyl pyrrolidone employed in the manufacture of the fibers of the present invention are set forth as percentages based upon the weight of the non-derivatized cellulose in the fibers.

The alloy fibers of the present invention are prepared by mixing a cyanoethylated viscose and an aqueous solution of polyvinylpyrrolidone with a conventional or non-derivatized filament-forming viscose, shaping the mixture into fibers, coagulating and regenerating the shaped fibers and thereafter drying the same. The nonderivatized viscose constitutes the major portion of the mixture and the shaped alloy fibers are coagulated and regenerated by known means, and preferably in an acid bath containing from about 1 to wt. percent sulfuric acid and about 1 to 25 wt. percent sodium sulfate. Zinc sulfate, up to about 10 wt. percent, is often incorpo- 2 rated in the bath as well as other coagulation modifiers, as desired. No special finishes and/or drying procedures are required to render the alloy fibers in a form which can be carded without difficulty.

The non-derivatized viscose which is employed in making the alloy fibers of the present invention is of a composition as is used in making conventional regenerated cellulose fibers. The composition of such viscose is well documented in the prior art and. in general. is produced by reacting alkali cellulose with carbon disulfide, with the resulting sodium cellulose xanthate being diluted with aqueous caustic to provide the resulting viscose with a desired cellulose and alkali content. For ex ample, viscose compositions containing cellulose ranging from 3 to about 12 wt. percent, caustic from about 3 to 12 wt. percent, and carbon disulfide from about 20 to about 609? based upon the weight of cellulose are satisfactory. Additives or modifiers may be mixed in the viscose if desired.

The terminology cyanoethylated viscose" as used herein refers to a viscose to which acrylonitrile is added or viscose prepared by the simultaneous cyanoethylation and xanthation of alkali cellulose. The latter procedure is preferred from the standpoint of economy and is described in US Pats. Nos. 3,l46.l 16 to A. l. Bates and 3,525,735 to l. K. Miller. Regeneration of such cyanoethylated viscose is accomplished by means of a conventional acidic type coagulating and regenerating bath, as described above. Hydrolysis of the cyanoethyl group on the cellulose during aging and process: ing produces predominantly carboxyethyl substituent groups on the cellulose in place of the cyanoethyl groups in the resulting regenerated product. The term regenerated cyanoethyl cellulose as employed herein refers to a regenerated product as produced by the cyanoethylated viscose describedv Reference to the average degree of substitution (US) of the cyanoethyl cellulose as used herein includes products wherein the anhydroglucose units of the cellulose molecules have an average substitution from about 0.25 to about 0.65 of cyanoethyl groups or chemical groups derived from said cyanoethyl groups by hydrolysis or other chemical change which occurs during manufacture and aging of the material. Thus, the recitation of cyanoethyl cellulose is also meant to include cellulose having carboxyethyl groups and some carboxyamide substituent groups.

To obtain the average degree of substitution prescribed, the amount of acrylonitrile used will vary with the process and conditions employed. Preferably, the simultaneous cyanoethylation and xanthation procedure uses from about 20 to about 50% acrylonitrile based on the weight of the cellulose. Other methods require higher proportions of acrylonitrile to obtain the prescribed degree of substitution.

Polyvinylpyrrolidone which is suitable for use in the present invention has an average molecular weight ranging from about 100,000 to 400,000 and, more desirably, from l60,000 to 360,000 and a preferred K- value of 50-l00. The procedure for determining the K-value of such polymers is known in the art, as disclosed in Modern Plastics, 1945, No. 3, starting on Page 157. Polyvinylpyrrolidone of desired character is commercially available, for example, under the designations of K-60 and K-90, from General Aniline and Film Corporation.

in accordance with the present invention the cyanoethylated viscose and polyvinylpyrrolidone are incorporated into the non-derivatized viscose desirably. but not necessarily. in equal amounts. and preferably in amounts ranging from to 3071. based upon the weight of the cellulose in such viscose. More specifically. the cyanoethylated viscose may be employed in amounts ranging from 5 to while the polyvinylpyrrolidone is present in amounts ranging from about 5 to i592. Using less than about 5% of either cyanoethyl ated viscose of polyvinylpyrrolidone provides fibers which do not differ appreciably from conventional regenerated cellulose fibers in their fluid-holding capacity. Increasing the amount of each of these alloying materials above the range specified generally results in no significant improvement in the fluid-holding capacity of the alloy fibers which are produced.

The polyvinylpyrrolidone described exhibits good solubility in water and, in accordance with the method of the present invention, aqueous solutions of polyvinylpyrrolidone are injected into the non-derivatized viscose as it is pumped to spinnerets for extrusion. The cyanoethylated viscose is also injected into the derivatized viscose during its passage to the spinnerets. either separately ofor simultaneously with the introduction of the aqueous solutions of polyvinylpyrrolidone. If it is found necessary to secure a more uniform dispersion, the alloying materials and non-derivatized viscose may be passed through a blender or homogenizer prior to delivery to the extrusion spinnerets.

After the spinning, coagulation and regeneration stages. the shaped continuous tow of filaments undergoes the usual processing which may include stretching. if desired. and is then dried by conventional means. Generally. before drying the continuous tow of filaments is cut into staple ofa desired length. Usually, the staple fibers experience no apparent bonding during drying and can be subsequently carded with no difficulty by the manufacturer of articles incorporating such fibers.

The alloy fibers made by the method of the present invention are adapted for use in a variety of articles. such as sanitary napkins and tampons, in which high fluid retention is an essential characteristic. In the manufacture of such articles. the alloy fibers necessitate no special techniques or equipment and they may be blended with other fibers which may or may not enhance the absorbent properties of the resulting articles. Fibers with which the alloy fibers of the present invention may be blended include, for example. rayon, cotton. chemically modified rayon or cotton. cellulose acetate. nylon. polyester. acrylic, polyolefin. etc.

The fluid-holding capacity ofthe alloy fibers made by the method of the present invention was determined by a procedure, as follows: a

Sample staple alloy fibers are carded or otherwise well opened and then conditioned. Two and one half grams of fibers in the form of a carded web about 6 inches long and of variable thickness and width was rolled in the direction of its width to give a 6 inch roll and a string was then looped around the middle of it. The roll was folded around the loop of the string and drawn into a /2 inch tube wherein by means of a plunger and clamp. it was compressed to provide a tampon. After suitable compression the tampon is removed, allowed to stand for a period of time, and was then evaluated by a Syngyna test generally as described by G.W. Rapp in a publication of the Department of Research, Loyola University, Chicago, III. in June I958.

4 The following example is provided to further demonstrate the merits of the present invention.

EXAMPLE A conventional. non-derivatized viscose. an aqueous solution of polyvinylpyrrolidone and a cyanoethylated viscose were prepared separately. The composition of the nonderivatized viscose was 9.0 cellulose. 60 sodium hydroxide and 32% carbon disulfide. based on the weight ofthe cellulose. This viscose had a ball fall of56 seconds and its common salt test was 7.

The aqueous solution of polyvinylpyrrolidone was prepared simply by dissolving in water polyvinylpyrrolidone. designated as K-60 (General Aniline and Film Corporation) and having an average molecular weight of about 160.000 and K value of 50-62.

Cyanoethylated viscose was prepared by premixing 8.25 lbs. of carbon disulfide and 10.75 lbs. acrylonitrile (349i and 45%. respectively, based on the weight ofthe cellulose). with the mixture then being charged into an evacuated churn by gravity through a valved stainless steel line. The churn contained a 77 lbs. batch of alkali cellulose crumbs and was kept at a temperature of l5 to 32C during a 2 hour reaction or churning period. Sufficient water and caustic were added to the churn after the 2 hour reaction period to provide a viscose of 8.0% cellulose and 6.0% sodium hydroxide (caustic) based on the weight of the viscose, and 34% carbon disulfide and 45% acrylonitrile based upon the weight of the cellulose. after mixing in the churn for an additional H4 hours. The resulting cyanoethylated viscose had a common salt test of l7-2l and a ball fall of 40-50 seconds.

Using conventional spinning equipment. the alloying materials were injected into the non-derivatized viscose as hereafter set forth, with the resulting mixture being extruded through a 720 hole spinneret into an aqueous spinning bath consisting of 7.5% by weight of sulfuric acid, 18% by weight of sodium sulfate, and 3.5% by weight of zinc sulfate. After passage through the spinning bath. the resulting continuous tow was washed with water, desulfurized, and again washed with water. The still wet tow was cut into staple fibers which were, without any further treatment. dried, conditioned and then carded.

The fluid-holding capacity of sample unalloyed fibers and fibers containing the alloying components individually and in combination was determined using the above described test procedure. The compositions of the dry unalloyed and alloyed fibers and the results of the tests performed therein were as follows:

'nomderivatized cellulose 'regenerated cyanoethylated cellulose "polyvinylpyrrolidone injected, based on the weight of the cellulose in non-derivattzed viscose.

It will be noted that conventional rayon fibers (Sample A). as produced from non-derivatized viscose, ex-

hibit fluid-holding capacities which are less than those of alloy fibers produced from a mixture of conventional viscose and polyvinylpyrrolidone (Samples E and F) and that the fluid-holding capacities of fibers comprised of non-derivatized regenerated cellulose alloyed with regenerated cyanoethyl cellulose increase directly with the regenerated cyanoethyl cellulose content (Samples B, C and D). Significantly, notwithstanding the detrimental effects produced when the lower amounts of cyanoethylated viscose are employed alone as alloying agents. as illustrated by Samples B and C such derivatized viscose. when combined with polyvinylpyrrolidone, does provide for a synergism. as exhibited by the remarkably improved fluid-holding capacities of the three-component alloy fibers indicated as Samples G and H.

I claim:

I. A method for making fluid absorbent alloy fibers comprising mixing a cyanoethylated viscose and an aqueous solution of polyvinylpyrrolidone with a nonderivatized, filament-forming viscose, the latter of which constitutes the major portion of the mixture. shaping the mixture into streams, coagulating and regenerating the mixture forming the streams to provide with the non-derivatized regenerated cellulose being the major portion thereof. and thereafter converting the filaments into dried fibers.

2. A method as defined in claim 1 wherein the polyvinylpyrrolidone has an average molecular weight of from about l00.000 to 400.000, and a K-value of from 50 to I00.

3. A method as defined in claim I wherein the cyanoethylated viscose has an average degree of substitution of from 0.25 to 0.65.

4. A method as defined in claim I wherein the cyanoethylated viscose and polyvinylpyrrolidone are present in generally equal amounts.

5. A method as defined in claim I wherein the cyanoethylated viscose and the polyvinylpyrrolidone are present in amounts ranging from 5 to 15% and 5 to 15%. respectively. based upon the weight of the cellulose in the viscose.

6. A method as defined in claim 2 wherein the cyanoethylated viscose has an average degree of substitution of from 0.25 to 0.65.

7. A method as defined in claim 6 wherein the cyanoethylated viscose and the polyvinylpyrrolidone are present in amounts ranging from 5 to I57: and 5 to 15%, respectively, based upon the weight of the cellulose in the viscose.

Claims

1. A METHOD FOR MAKING FLUID ABSORBENT ALLOY FIBERS COMPRISING MIXING A CYANOETHYLATED VISCOSE AND AN AQUEOUS SOLUTION OF POLYVINYLPYRROLIDONE WITH A NON-DERIVATIZED, FILAMENTFORMING VISCOSE, THE LATTER OF WHICH CONSTITUENTS THE MAJOR PORTION OF THE MIXTURE, SHAPING THE MIXTURE INTO STREAMS COAGULATING AND REGENERATING THE MIXTURE FORMING THE STREAMS TO PROVIDE FILAMENTS COMPRISED OF NON-DERIVATIZED REGENERATED CELLULOSC HAVING UNIFORMLY DISPERSED THEREIN REGENERATED CYNOETHYL CELLULOSE AND POLYVINYLPYRROLIDONE, WITH THE NONDERIVATIZED REGENERATED CELLULOSE BEING THE MAJOR PORTION THEREOF, AND THEREAFTER CONVERTING THE FILAMENTS AND DRIED FIBERS.

2. A method as defined in claim 1 wherein the polyvinylpyrrolidone has an average molecular weight of from about 100,000 to 400,000, and a K-value of from 50 to 100.

3. A method as defined in claim 1 wherein the cyanoethylated viscose has an average degree of substitution of from 0.25 to 0.65.

4. A method as defined in claim 1 wherein the cyanoethylated viscose and polyvinylpyrrolidone are present in generally equal amounts.

5. A method as defined in claim 1 wherein the cyanoethylated viscose and the polyvinylpyrrolidone are present in amounts ranging from 5 to 15% and 5 to 15%, respectively, based upon the weight of the cellulose in the viscose.

7. A method as defined in claim 6 wherein the cyanoethylated viscose and the polyvinylpyrrolidone are present in amounts ranging from 5 to 15% and 5 to 15%, respectively, based upon the weight of the cellulose in the viscose.