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US3296341A - Method for impregnating acrylonitrile polymer fibers to improve dyeability - Google Patents

Method for impregnating acrylonitrile polymer fibers to improve dyeability Download PDF

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US3296341A
US3296341A US295135A US29513563A US3296341A US 3296341 A US3296341 A US 3296341A US 295135 A US295135 A US 295135A US 29513563 A US29513563 A US 29513563A US 3296341 A US3296341 A US 3296341A
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filaments
polymer
fibers
fiber
acrylonitrile
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Herman P Briar
Rupert B Hurley
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Dow Chemical Co
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    • DTEXTILES; PAPER
    • D06TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
    • D06PDYEING OR PRINTING TEXTILES; DYEING LEATHER, FURS OR SOLID MACROMOLECULAR SUBSTANCES IN ANY FORM
    • D06P7/00Dyeing or printing processes combined with mechanical treatment
    • D06P7/005Dyeing combined with texturising or drawing treatments
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01FCHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
    • D01F6/00Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof
    • D01F6/02Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from homopolymers obtained by reactions only involving carbon-to-carbon unsaturated bonds
    • D01F6/18Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from homopolymers obtained by reactions only involving carbon-to-carbon unsaturated bonds from polymers of unsaturated nitriles, e.g. polyacrylonitrile, polyvinylidene cyanide
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01FCHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
    • D01F6/00Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof
    • D01F6/28Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from copolymers obtained by reactions only involving carbon-to-carbon unsaturated bonds
    • D01F6/38Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from copolymers obtained by reactions only involving carbon-to-carbon unsaturated bonds comprising unsaturated nitriles as the major constituent

Definitions

  • Herman 1 Brian BY Ruper/ 5 Hur/ey Mzm United States Patent 9 This invention contributes to the synthetic fiber art and has particular reference to enhancing the dyeability of synthetic fibers. Particularly, it relates to a method for impregnating wet-spun acrylonitrile polymer fibers while they are in a freshly formed gel condition with a dye assistant to improve the dyeability of the fiber.
  • Synthetic fibers including acrylonitrile polymer fibers
  • Another method sometimes employed, is to add color, generally in the form of a pigment, into the spinning solution, frequently called spinning dope.
  • This method has the inherent disadvantage of contaminating the polymer handling and conveying systems with colored bodies which must be dealt with when plain white fibers are subsequently to be manufactured in the same equipment.
  • dye assistant One means that has been rather successfully employed to overcome some of the above-indicated disadvantages when acrylonitrile polymers are wet-spun is to impregnate the freshly spun fiber while it is in a gel condition with a dye receptive additive, such as a polymer (which will hereinafter be referred to as dye assistant).
  • a dye receptive additive such as a polymer (which will hereinafter be referred to as dye assistant).
  • dye assistant One difficulty that has been observed with this method is that frequently the running length of fibers are not uniformly impregnated along the length of the fibers, and additionally, the dye assistant does not penetrate the gel structure but remains only on the periphery of the fiber surface or at best only slightly penetrates the gel'structure. This results in ring dyeing of the fiber, i.e., dyeing on the surface.
  • a method for incorporating a dye assistantin acrylonitrile polymer gel or aquagel filaments comprising spinning a solution of a polymer of an ethylenically unsaturated monomeric material containing at least about weight percent polymerized acrylonitrile into an aqueous coagulating bath to form acrylonitrile polymer filaments; washing the filaments essentially free of any residual acrylonitrile polymer solvent, partially stretching the washed filaments in an aqueous medium at 110 C., immersing the washed and partially stretched filaments in a liquid bath at between about 90-l 10 C.
  • dye assistant agent capable of enhancing the dyeability of the filaments and relaxing the filaments therein, stretching the impregnated filaments at between about 90-100 C., and subsequently, irreversibly drying the impregnated and stretched filaments to a textile fiber.
  • the fibers prepared in accordance with the present invention possess excellent physical properties in addition to being made through dyeable to excellent deep shades of coloration throughout the cross section as well as along the length of the fibers. They ex-hi-bit outstanding resistance to fading from exposure to washing and light as well as to whitening and fibrillation.
  • the present inventive method provides a highly expedient and efficient means for continuously, rapidly, uniformly and reproduceably preparing acrylonitrile fibers that can be dyed with a wide variety of dyestuffs.
  • the residence time of the gel fiber in the impregnating bath is extremly short, i.e., usually on the order of to second, although much longer times can be employed if desired.
  • the fiber is uniformly impregnated frequently throughout the crosssection of thefiber as well as lineally.
  • each filament uniformly impregnated throughout, but the complete tow which may consist of thousands of filaments and be of 100,000 or so total denier is uniformly impregnated throughout. That is, fiber-to fiber variation 'is usually minimal.
  • the present invention takes advaa-ntage of the finding that the particular sequence of steps employed provides a gel structure excellently adapted for the purpose of accepting a dye assistant throughout the structure.
  • Another feature that points up the novelty of the invention is that, strange as it may seem, if the dye assistant is present in the first stretch bath, i.e., the pre-impregnation stretch bath, in addition to being in the relaxing impregnation bath, the penetration of the dye assistant is apparently interfered with so that inferior results are obtained.
  • the pre-impregnation stretch is carried out in aqueous medium, which may 'be' steam, but preferably water, at about 90-1 10 C.
  • aqueous medium which may 'be' steam, but preferably water, at about 90-1 10 C.
  • Higher temperatures can be employed but ordinarily do not materially enhance the results of the invention and may introduce deleterious effects.
  • Penetration of the dye assistant tends to decrease quite readily when temperatures of much less than 90 C., e.g., 70 C., are maintained in the pre-impregnation stretch.
  • the stretch imparted to the gel filament in the pre-impregnation stretch may be from about 2 to about 12 times, beneficially a stretch between about 4 and 8 times, i.e., a stretch ratio of 4:1 to 8:1, is utilized. Any suitable means may be employed to effect the stretch which is most conveniently accomplished by stretching the filaments between two sets of pinch rolls with the down-stream set of rolls being driven at a faster rate than the up-s'treamgolls.
  • the gel filaments are ordinarily passed directly to the relaxing impregnation bath.
  • the impregnation bath is advantageously an aqueos bath maintained at between 90 and about 110 C. Pressure may be applied to attain the higher temperatures or other solvents inert to the acrylonitrile polymer may 'be added to raise the 'boiling point or aid in dissolution of the dye assistant, or the dye assistant itself may elevate the boiling point of the solution. Beneficially, temperatures near the boil of the solution are employed. While the gel filaments are in the impregnation bath they are completely relaxed, that is, they are maintained at zero tension.
  • the degree of relax will depend somewhat on the composition of the gel and the dye assistant, and the time it is desired to keep the gel filament in the impregnating solution.
  • the relax can be expressed in terms of stretch ratios and, beneficially, a stretch of between about 0.2 and 0.9 times is used. This means that the gel filaments are removed from the impregnating bath at 0.2 to 0.9 times as fast as they enter.
  • This stretch influences the impregnation, but is principally directed to impart the final orientation to the filament molecules to the point where they will have acceptable physical properties. This will be determined in large part on the amount of stretch given in the pre-impregnation step. Ordinarily, this stretch will range from greater than one up to 6 to 8 times so that the filament will have a total stretch from about 8 to 20 times its washed length.
  • the post-impregnation stretch is carried out in an aqueous medium which i may be steam but is preferably a water bath maintained at to C.
  • the invention is applicable to treating acrylonitrile polymer fibers which are fabricated from fiber forming acrylonitrile polymers that contain in the polymer molecule at least about 80 weight percent of polymerized acrylonitrile, and is especially applicable to the treating of homopolymeric acrylonitrile, which are wet spun in and 'with systems, that are adapted to utilize aqueous coagulating liquids in the spinning operation, such as systems wherein ethylene glycol, dimethylformamide, di-
  • methylsulfoxide, butyrolactone and the like or the various saline polyacrylonitrile-dissolving solvents are employed as spinning solution solvents for the polymer and are also present in non-polymer dissolving quantities in the aqueous coagulating liquid used in the spin bath.
  • aqueous saline solvents for the various fiber forming acrylonitrile polymers and polyacrylonitrile include zinc chloride, the various thiocyanurates such as calcium and sodium thiocyanate, lithium bromide, salt mixtures of the so-called lyotropic series, and others recognized by the art as has been disclosed, among other places, in United States Letters Patent Nos. 2,140,921; 2,245,192; 2,648,592; 2,648,593; 2,648,646; 2,648,648; 2,648,649; and 2,949,435.
  • aqueous zinc choride solutions are used for the purpose.
  • Exemplary of some of the monomeric material that may. be employed with the acrylonitrile in the preparation of the acrylonitrile polymer. and copolymer fiber forming systems and treated in accordance with the practice of the present invention include allyl alcohol, vinyl acetate, acrylamide, methacrylamide, methyl acrylate, vinyl pyridine, ethylene sulfonic acid and its alkali metal salts, vinyl benzene sulfonic acid and its salts, 2-sulfoethylmethacrylate and its salts, vinyl lactams such as vinyl caprolactam and vinyl pyrrolidone, etc. and mixtures thereof.
  • Thoroughly washed acrylonitrile polymer aquagel fibers, incidentally, are usually found to contain up to about 6 parts by weight of Water (including residual extrinsic or exterior water associated therewith) for each part by weight of dry polymer therein. More frequently, washed acrylonitrile aquagel polymer fibers are found to contain from about 3 to 4 parts by weight of water for each part by weight of polymer.
  • the present invention can be carried out conveniently in standard spinning trains. That is, no major alterations to a conventional fiber forming process need be undertaken except to provide the necessary stretch and dye assistant impregnation baths. Because of the extreme speed at which the fibers can be impregnated in practicing the present invention, the ordinary and commercially useful spinning speeds can be employed while simultaneously obtaining an excellent dye receptive fiber.
  • the dye assistant is water soluble or at least water dispersible so that it can be applied from a water.
  • the impregnation bath is maintained at about 90-l00 C.
  • the amount of the dye assistant that is applied to and impregnated in the acrylonitr'ile polymer gel is usually about at least 1.0 weight percent, based on dry fiber weight.
  • the impregnation bath usually contains relatively dilute solutions of the dye assistant.
  • concentrations up to the saturation point of the assistant in the solvent can be used. Any conditions that tend to cause agglomeration of the dye assistant should be avoided for obvious reasons.
  • Exemplary of the types of dye assistants that can be impregnated in the gel fiber in accordance with the invention include:
  • Water-soluble amine salts including:
  • Octadecyl ammonium acetate Octadecyl ammonium chloride Di-n-amyl ammonium chloride Tri-n-amyl ammonium chloride N-2-[2-(2,2,3,3-tetramethylbutyl phenoxy) ethoxy] ethyl- N,N-dimethyl ammonium chloride N-2-(octadecyloxy)ethyl-N-N-dimethyl ammonium chloride N-Z-(decyloxy)ethyl-N,N-dimethyl ammonium chloride N-Z-(heptoxy)ethyl-N,N-dimethyl ammonium chloride N-oxtadecyl-N,N-di-(Z-hydroxyethyl) ammonium chloride N-dodecyl-N,N-di-(Z-hydroxyethyl)ammonium chloride 2-n-nonyl pyridine hydrochloride 5-
  • Para-styrene sulfonic acid Sodium para-styrene sulfonate Methyl para-styrene sulfonate 2-chloro-4-vinyl benzene sulfonic acid (7)
  • Polymers of alkenyl sulfonic acid compounds including:
  • a tow of polyacrylonitrile aquagel fiber which fibers contained from about 4 to 5 parts by weight of Water in the gel phase to each part by weight of dry polymer in the aquagel 5 structure, was obtained by extruding a spinning solution Lsulfoethylmethacrylate methyl ester comprised of about parts of polyacrylonitrile dissolved Polymers 0f y y taulihe and homolog in about 90 parts of a 60 weight percent aqueous solution pounds including: of zinc chloride into an aqueous coagulating bath that ac W1 01 taufine contained about 44 weight percent of zinc chloride dis- N-methwyloyl amine methyl ester i33 $55 51;a?Zd t eiZdin a?
  • the tow bundle was either allowed to relax, or was are the V311, Sulfur, difeet, 'metalliled, basic acid, aZOie, stretched while in the impregnating solution. acetate, reactive, ingrain and the like classes Of dyestuffs.
  • the tow of aquagel' filaments was withdrawn from the AS mentioned, When the acrylonitrile P y P impregnation bath and passed directly to the post-impreglarly polyacrylonitrile, fibers are being manufa u Zine nation stretch bath where the filaments were stretched in chloride may most advantageously be utilized as the sole, water at about 100 C.
  • the fibers were or at least the principal saline solute in the spinning sOlirreversibly dried in a hot air oven at about 140 C. for vent employed for the polymer.
  • the 7 9 minutes t textile fibers, aqueous solution of zinc chloride in the spinning solution The dried fibers were dyed with a 3% Irgalon Blue RL may advantageously be in a concentration range of from dye solution (based on dry fiber weight), a 2:1 metal 55 to 65, preferably about 60 weight percent, based on complex dyestuif after which random samples were se-.- the weight of the aqueous solution.
  • non-polymer-dissolving coagulation concentration of at least about 25 weight percent; advantageously from about 30 to 50 percent by weight and preferably between about 40 and percent by weight.
  • aqueous zinc chloride systems for acrylonitrile polymers wherein the freshly wet spun polymer is generally obtained in an aquagel form, it is generally desirable for the spinning solution that is extruded to contain between about 4 and 20 percent by weight of dissolved polymer; more advantageously from about 6 to 15 weight percent of dissolved polymer; and preferably particularly when polyacrylonitrile fibers are being manufactured, from about 8.1 to 11.5 percent by weight of fiber-forming polymeric solids in the spinning solution.
  • Aqueous zinc chloride spinning solutions of fiber-forming acrylonitrile polymers are beneficially extruded at a spinning temperature from 0 to 0, preferably from about 10 to 30 G, into an aqueous zinc chloride coagulating liquid that is maintained at a coagulating temperature of 0 to 30 (1.; preferably from about 10 to 20 C.
  • a method for improving through dyeability of acrylonitrile polymer fibers comprising (a) spinning a solution of a polymer of an ethyleni- 9 (e) stretching said impregnated filaments in an aqueous medium at about 901l0 C.; and, (f) subsequently, irreversibly drying said filaments to textile fibers.
  • said acrylonitrile polymer is polyacrylonitrile.

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Description

Jan. 3, 1967 H. P. BRIAR ET AL 3,296,341
METHOD FOR IMPREGNATING ACRYLONITRILE POLYMER FIBERS TO IMPROVE DYEABILITY Filed July 15, 1963 1 1/67 5 m acr /0n/'//'/'/e 0/ mar la in o 56/ f'i/amnf W056 ff/am en 74%? e from res/au a/ so/ven Pa 2" 5/ e/c/z 14/0/7723 f5 af so //0"c Re/a! ff/amen/s in dye asslls/an/ So/u/fon 0/ 90//0c INVENTORS. Herman 1 Brian BY Ruper/ 5 Hur/ey Mzm United States Patent 9 This invention contributes to the synthetic fiber art and has particular reference to enhancing the dyeability of synthetic fibers. Particularly, it relates to a method for impregnating wet-spun acrylonitrile polymer fibers while they are in a freshly formed gel condition with a dye assistant to improve the dyeability of the fiber.
Synthetic fibers, including acrylonitrile polymer fibers,
have always been difiicultly dyeable in contrast to the commonly available natural fibers, e.g., cotton and Wool. Several methods have been pursued in attempting to solve the inherent and attendant difiiculties encountered with acrylonitrile polymer or acrylic fiber dyeability. Among these have been the development of dyestuffs or particular dyeing procedures specifically designed for or especially suited to the polymer structure. Other schemes include building into the polymer structure sites which are receptive to dyestuffs such as might 'be accomplished by certain additaments that are copolymerized with acrylonitrile to fiber forming polymers, or by incorporating in the acrylonitrile polymer a dye receptive polymer by blending the two polymers prior to extruding or spinning the polymer composition to form the filament or fiber.
Although the foregoing means have frequently led to better dyed or dyeable fibers, there are certain attendant disadvantages associated with each. For instance, when dyestuffs are especially synthesized for polyacrylonitrile, the dyestuffs are apt to be quite expensive, and additionally, the range of shades and colors is usually limited or lacking in desirable fastness properties. Or, particularly when dye receptive sites are built into the polymer chain through copolymerization of another monomer with acrylonitrile there is most always observed a sacrificial loss in some of the inherent properties so desirable in the polyacrylonitrile backgone, such as tensile strength. Blending a dye-receptive polymer with the polyacrylonitrile prior to spinning presents mixing problems to attain uniformity and may require rather large energy requirements. Another method sometimes employed, is to add color, generally in the form of a pigment, into the spinning solution, frequently called spinning dope. This method, however, has the inherent disadvantage of contaminating the polymer handling and conveying systems with colored bodies which must be dealt with when plain white fibers are subsequently to be manufactured in the same equipment.
One means that has been rather successfully employed to overcome some of the above-indicated disadvantages when acrylonitrile polymers are wet-spun is to impregnate the freshly spun fiber while it is in a gel condition with a dye receptive additive, such as a polymer (which will hereinafter be referred to as dye assistant). One difficulty that has been observed with this method is that frequently the running length of fibers are not uniformly impregnated along the length of the fibers, and additionally, the dye assistant does not penetrate the gel structure but remains only on the periphery of the fiber surface or at best only slightly penetrates the gel'structure. This results in ring dyeing of the fiber, i.e., dyeing on the surface. This in itself is not always had since often times good coloration is achieved when the fiber is dyed. The deficiencies of the method ordinarily make themselves known when the dyed fibers are subjected to abraid- 'ice ing forces, such as those induced during the wearing by an individual of a garment made of the fibers, or those induced during some of the textile processing treatments. The result is that the fibers tend to objectionably whiten or become lighter in shade, particularly at wear points. This may be a result of the color lying on the surface of the fiber being worn off and exposing the undyed portions of the fiber underneath, or, sometimes, it may be a result of the dye assistant build-up on the fiber surface weakening, as for instance by tending to plasticize the acrylonitrile polymer, such that actual fibrils may peel back from the surface. This has the dual effect of exposing the undyed portions of'the fiber and of the fibrils dispersing the incident light so that a frosted appearance is presented. A secondary drawback of any surface build-up of the dye assistant on the gel fiber surface is that oftentimes the adjacent fibers will fuse during the drying of the fibers causing objectionable large fibers or sticks to form.
Accordingly, it is the chief aim and primary object of the present invention to provide an improved and highly efiicient method for incorporating a dye assistant in acrylonitrile polymer gel'fibers whereby the dye assistant is uniformly and deeply and frequently thoroughly penetrated throughout the cross-section of the fiber and uniformly distributed along the fiber length so that the fibers in an irreversibly dried form can be dyed to excellent shades of coloration having good resistance to whitening and fibrillation.
In accordance with the present invention, a method is provided for incorporating a dye assistantin acrylonitrile polymer gel or aquagel filaments comprising spinning a solution of a polymer of an ethylenically unsaturated monomeric material containing at least about weight percent polymerized acrylonitrile into an aqueous coagulating bath to form acrylonitrile polymer filaments; washing the filaments essentially free of any residual acrylonitrile polymer solvent, partially stretching the washed filaments in an aqueous medium at 110 C., immersing the washed and partially stretched filaments in a liquid bath at between about 90-l 10 C. containing dye assistant agent capable of enhancing the dyeability of the filaments and relaxing the filaments therein, stretching the impregnated filaments at between about 90-100 C., and subsequently, irreversibly drying the impregnated and stretched filaments to a textile fiber.
The sequence of steps of the invention is schematically illustrated in the sole figure of the drawing.
The fibers prepared in accordance with the present invention possess excellent physical properties in addition to being made through dyeable to excellent deep shades of coloration throughout the cross section as well as along the length of the fibers. They ex-hi-bit outstanding resistance to fading from exposure to washing and light as well as to whitening and fibrillation. The present inventive method provides a highly expedient and efficient means for continuously, rapidly, uniformly and reproduceably preparing acrylonitrile fibers that can be dyed with a wide variety of dyestuffs.
The residence time of the gel fiber in the impregnating bath is extremly short, i.e., usually on the order of to second, although much longer times can be employed if desired. Despite-this unusually short cycle, the fiber is uniformly impregnated frequently throughout the crosssection of thefiber as well as lineally. Not only is each filament "uniformly impregnated throughout, but the complete tow which may consist of thousands of filaments and be of 100,000 or so total denier is uniformly impregnated throughout. That is, fiber-to fiber variation 'is usually minimal.
The reasons for the marked improvement in penetration of the dye assistant into the gel filament structure with practice of the present invention is not fully understood. It is evidently related to the morphological phenomena that take place during the transformation of the polymer in solution to the stretched gelled filament. Thus, the combination of pre-and post-impregnation stretch combined with the intermediate relax in the dye assistant solution allows for and enhances uptake and penetration of the assistant even when the dye assistant itself is a high molecular weight polymer. There are apparently several factors that may influence the uptake and penetration of the dye assistant. It has been noted that stretching the gel filament to the point where it has normally acceptable physical properties, i.e., stretched to times, that a rather dense structure including outer skin, is presented which tends to inhibit penetration. Likewise, if the gel filament is not stretched at all the structure is likely to 'be in a skin-core state with a semi-soft core, but tight skin again resisting penetration. If impregnation is carried on during stretching other unknown factors tend to prohibit penetration. The present invention takes advaa-ntage of the finding that the particular sequence of steps employed provides a gel structure excellently adapted for the purpose of accepting a dye assistant throughout the structure.
Another feature that points up the novelty of the invention is that, strange as it may seem, if the dye assistant is present in the first stretch bath, i.e., the pre-impregnation stretch bath, in addition to being in the relaxing impregnation bath, the penetration of the dye assistant is apparently interfered with so that inferior results are obtained.
The pre-impregnation stretch is carried out in aqueous medium, which may 'be' steam, but preferably water, at about 90-1 10 C. Higher temperatures can be employed but ordinarily do not materially enhance the results of the invention and may introduce deleterious effects. Penetration of the dye assistant tends to decrease quite readily when temperatures of much less than 90 C., e.g., 70 C., are maintained in the pre-impregnation stretch. Depending somewhat on the composition of the acrylonitrile polymer and spinning conditions, e.g., solvent, coagulant and temperature, the stretch imparted to the gel filament in the pre-impregnation stretch may be from about 2 to about 12 times, beneficially a stretch between about 4 and 8 times, i.e., a stretch ratio of 4:1 to 8:1, is utilized. Any suitable means may be employed to effect the stretch which is most conveniently accomplished by stretching the filaments between two sets of pinch rolls with the down-stream set of rolls being driven at a faster rate than the up-s'treamgolls.
After the pre-impregnation stretch the gel filaments are ordinarily passed directly to the relaxing impregnation bath. As indicated, the impregnation bath is advantageously an aqueos bath maintained at between 90 and about 110 C. Pressure may be applied to attain the higher temperatures or other solvents inert to the acrylonitrile polymer may 'be added to raise the 'boiling point or aid in dissolution of the dye assistant, or the dye assistant itself may elevate the boiling point of the solution. Beneficially, temperatures near the boil of the solution are employed. While the gel filaments are in the impregnation bath they are completely relaxed, that is, they are maintained at zero tension. The degree of relax will depend somewhat on the composition of the gel and the dye assistant, and the time it is desired to keep the gel filament in the impregnating solution. The relax can be expressed in terms of stretch ratios and, beneficially, a stretch of between about 0.2 and 0.9 times is used. This means that the gel filaments are removed from the impregnating bath at 0.2 to 0.9 times as fast as they enter.
Following the impregnation of the filaments with the dye assistant they are generally passed directly to the postimpregnation stretch and there given an ultimate stretch.
4 This stretch influences the impregnation, but is principally directed to impart the final orientation to the filament molecules to the point where they will have acceptable physical properties. This will be determined in large part on the amount of stretch given in the pre-impregnation step. Ordinarily, this stretch will range from greater than one up to 6 to 8 times so that the filament will have a total stretch from about 8 to 20 times its washed length. As with the pre-im-pregnation stretch, the post-impregnation stretch is carried out in an aqueous medium which i may be steam but is preferably a water bath maintained at to C.
The invention is applicable to treating acrylonitrile polymer fibers which are fabricated from fiber forming acrylonitrile polymers that contain in the polymer molecule at least about 80 weight percent of polymerized acrylonitrile, and is especially applicable to the treating of homopolymeric acrylonitrile, which are wet spun in and 'with systems, that are adapted to utilize aqueous coagulating liquids in the spinning operation, such as systems wherein ethylene glycol, dimethylformamide, di-
methylsulfoxide, butyrolactone and the like or the various saline polyacrylonitrile-dissolving solvents are employed as spinning solution solvents for the polymer and are also present in non-polymer dissolving quantities in the aqueous coagulating liquid used in the spin bath.
The utile, known aqueous saline solvents for the various fiber forming acrylonitrile polymers and polyacrylonitrile include zinc chloride, the various thiocyanurates such as calcium and sodium thiocyanate, lithium bromide, salt mixtures of the so-called lyotropic series, and others recognized by the art as has been disclosed, among other places, in United States Letters Patent Nos. 2,140,921; 2,245,192; 2,648,592; 2,648,593; 2,648,646; 2,648,648; 2,648,649; and 2,949,435. Advantageously, aqueous zinc choride solutions are used for the purpose.
Exemplary of some of the monomeric material that may. be employed with the acrylonitrile in the preparation of the acrylonitrile polymer. and copolymer fiber forming systems and treated in accordance with the practice of the present invention include allyl alcohol, vinyl acetate, acrylamide, methacrylamide, methyl acrylate, vinyl pyridine, ethylene sulfonic acid and its alkali metal salts, vinyl benzene sulfonic acid and its salts, 2-sulfoethylmethacrylate and its salts, vinyl lactams such as vinyl caprolactam and vinyl pyrrolidone, etc. and mixtures thereof.
As indicated, after acrylonitrile polymer fibers have.
been wet spun they are most frequently Water washed or washed with an aqueous inert solution to remove any. residual polymer solvent from the freshly formed fila-, ments, thus forming an intermediate fiber product often referred to as a gel or aquagel filament. Thoroughly washed acrylonitrile polymer aquagel fibers, incidentally, are usually found to contain up to about 6 parts by weight of Water (including residual extrinsic or exterior water associated therewith) for each part by weight of dry polymer therein. More frequently, washed acrylonitrile aquagel polymer fibers are found to contain from about 3 to 4 parts by weight of water for each part by weight of polymer.
The present invention can be carried out conveniently in standard spinning trains. That is, no major alterations to a conventional fiber forming process need be undertaken except to provide the necessary stretch and dye assistant impregnation baths. Because of the extreme speed at which the fibers can be impregnated in practicing the present invention, the ordinary and commercially useful spinning speeds can be employed while simultaneously obtaining an excellent dye receptive fiber.
Essentially any additive that will enhance the dyeability of the acrylonitrile polymer fiber can be incorporated in the gel in accordance with the present invention. Beneficially, the dye assistant is water soluble or at least water dispersible so that it can be applied from a water.
bath; however, other solvents or mixtures of solvents may be employed for dissolving or dispersing the dye assistant. If the dye assistant is a liquid itself, it can be used at full strength, although more dilute solutions are preferred. Any suitable temperature can be employed for the impregnation, for example, from room temperature up to the boiling temperature of the particular solution in use. When water is used, advantageously, the impregnation bath is maintained at about 90-l00 C.
The amount of the dye assistant that is applied to and impregnated in the acrylonitr'ile polymer gel is usually about at least 1.0 weight percent, based on dry fiber weight. Preferably, between about 2 and 15 percent of the additive is impregnated in the fiber, based on dry fiber weight, but amounts up to 30-40 percent can be utilized in some instances without deleterious efiects. The impregnation bath usually contains relatively dilute solutions of the dye assistant. For most purposes, between about 1 and weight percent of the assistant, based on solution weight, is adequate to obtain the desired level of additive in the fiber, but concentrations up to the saturation point of the assistant in the solvent can be used. Any conditions that tend to cause agglomeration of the dye assistant should be avoided for obvious reasons.
Exemplary of the types of dye assistants that can be impregnated in the gel fiber in accordance with the invention include:
(1) Water-soluble amine salts, including:
Octadecyl ammonium acetate Octadecyl ammonium chloride Di-n-amyl ammonium chloride Tri-n-amyl ammonium chloride N-2-[2-(2,2,3,3-tetramethylbutyl phenoxy) ethoxy] ethyl- N,N-dimethyl ammonium chloride N-2-(octadecyloxy)ethyl-N-N-dimethyl ammonium chloride N-Z-(decyloxy)ethyl-N,N-dimethyl ammonium chloride N-Z-(heptoxy)ethyl-N,N-dimethyl ammonium chloride N-oxtadecyl-N,N-di-(Z-hydroxyethyl) ammonium chloride N-dodecyl-N,N-di-(Z-hydroxyethyl)ammonium chloride 2-n-nonyl pyridine hydrochloride 5-ethyl-2-n-nonyl pyridine hydrochloride N-n-octadecylpiperidine hydrochloride 2-heptadecyl-3-(2-hydroxy ethyl)glyoxalidine hydrochloride 2-heptadecyl-3-butyl glyoxalidine hydrochloride 2-heptadecyl glyoxalidine hydrochloride Di-(carboxymethyl)dodecyl ammonium chloride (2) Quaternary ammonium salts, including:
n-Nonyltrimethyl ammonium bromide n-Decyltrimethyl ammonium bromide n-Dodecyltrimethyl ammonium chloride n-Hexadecyltrimethyl ammonium chloride nOctadecyltrimethyl ammonium chloride n-Dodecylbenzyltrimethyl ammonium chloride n-Dodecyltolylmethyltrimethyl ammonium chloride n-Decyloxyethyltrimethyl ammonium iodide 11 [2 (2,2,3,3-tetramethylbutylphenoxy)ethoxy] ethyltrimehtyl ammonium iodide Carboxymethyl dimethyl tetradecyl ammonium chloride Benzylhexadecyldimethyl ammonium chloride Benzyl (2,2,3,3 tetramethylbutylphenoxy) ethyldimethyl ammonium chloride 2-hydroxyethyl-n-octadecyldimehtyl ammonium bromide n-Dodecyl-bis-(Z-hydroxyethyl) methyl ammonium bromide Bis-(Z-hydroxyethyl)methyl-n-octadecyl ammonium bromide Benzyl-Z-[Z-(2,3,4,6-tetrachlorophenoxy)ethoxy] ethyl morpholinum chloride Ethyl-n-octadecyl morpholinium ethosulfate n-Dodecyl pyridinium chloride n-Hexadecyl pyridinium chloride n-Dodecyl isoquinolinium bromide Bis-(polyoxyethylene oleate) ethyl methyl ammonium ethosulfate Trimethylene bis(dimethyl-n-tetradecyl ammonium bromide) Trimethylene bis [n-dodecyl-di-(Z-hydroxyethyl) ammonium bromide] Trimethylene bis [2,2,3,3 tetramethylbutyl phenoxyethoxy) ethyl dimmethyl ammonium chloride] Tetramethylene bis(n-dodecyldimethyl ammonium chloride) Pentamethylene bis(n-dodecyldimethyl ammonium chloride) Poly-4-methyltrimethyl ammonium stearyl chloride Dimethyl Z-hydroxyethyl stearamidopropyl ammonium chloride (3) Water-soluble sulfonium salts, including:
n-Dodecyl dimethyl sulfonium chloride, bromide or methosulfate n-Dodecyl ethyl methyl sulfonium halide or alkylsulfate n-Dodecyl methyl octyl sulfonium methosulfate n-Tetradecyl ethyl methyl sulfonium metho'sulfate 2[2-(2-biphenyloxy)ethoxy]ethyl butyl methyl sulfonium methosulfate Di-n-dodecyl methyl sulfonium methosulfate Di-(Z-hydroxye-thyl)methyl sulfonium methosulfate, clicapric ester Di-n dodecyl dimethyl ethylene disulfonium' di-methosulfate n-Octadecyl dimethyl sulfoniumbromide n-Dodecyl benzyl methyl sulfonium methosulfate Cetyl p-tolyl methyl sulfonium methosulfate n-Octadecyl Z-(diethyl methyl ammonium)ethyl methyl sulfonium dimethosulfate Cetyl dimethyl sulfonium methosulfate n-Dodecyl 2-chloroethyl methyl sulfonium 2-chloroethyl sulfate 2[2-(4-cyclohexylphenoxy)ethoxy] ethyl diethyl sulfonium ethosulfate (4) Water-soluble phosphonium halides, including:
Triethyl n-octyl phosphonium iodide n-Dodecyl trimethyl phosphonium bromide Cetyl trirnethyl phosphonium chloride Trimethyl n-octyl phosphonium chloride Benzyl tri-n-butyl phosphonium chloride I Benzyl n-dodecyl dimethyl phosphonium bromide Benzyl cetyl dimethyl phosphonium iodide Dichlorobenzyl triphenyl phosphonium chloride (5 Water-soluble polymers of N-vinyl pyrrolidone and related compounds, including:
N-vinyl n-methyl formamide N-vinyl N-ethyl formamide N-vinyl N-methyl acetamide N-vinyl N-ethyl acetamide N-vinyl valerolactam N-vinyl caprolactam N-vinyl morpholinone N-vinyl oxazolidinone N-vinyl-S-methyl-oxazolidinone (6) Polymers of aromatic alkenyl-containing sulfonic acid compounds including:
Para-styrene sulfonic acid Sodium para-styrene sulfonate Methyl para-styrene sulfonate 2-chloro-4-vinyl benzene sulfonic acid (7) Polymers of alkenyl sulfonic acid compounds including:
Ethylene sulfonic acid Sodium ethylene sulfonate Methyl ethylene sulfonate l-butylene-3-sulfonic acid (8) Polymers of sulfoalkylacrylate compounds in cluding:
Sulfomethylacrylate 2-sulfoethylacrylate In order to further illustrate the invention, a tow of polyacrylonitrile aquagel fiber, which fibers contained from about 4 to 5 parts by weight of Water in the gel phase to each part by weight of dry polymer in the aquagel 5 structure, was obtained by extruding a spinning solution Lsulfoethylmethacrylate methyl ester comprised of about parts of polyacrylonitrile dissolved Polymers 0f y y taulihe and homolog in about 90 parts of a 60 weight percent aqueous solution pounds including: of zinc chloride into an aqueous coagulating bath that ac W1 01 taufine contained about 44 weight percent of zinc chloride dis- N-methwyloyl amine methyl ester i33 $55 51;a?Zd t eiZdin a? Sill-Z1 53323; Methyl Nqnethacryloylammomethane sulfonate through a spinnerette having about 500 round, 3 mil diam- Pfeferahly, the Water Soluble of Water dispefsfhle P eter orifices. The coagulated tow bundle after emerging mel'ie y assistants are p y in the Praetlee of the from the coagulating bath was washed substantially free invention. The polymeric assistants tend to have better f l by passing i through sequential water b th resistance to Washing and other Processing treatments, and at ambient temperature. It was then wet stretched in a a water solution is more conveniently handled and is less hot water trough, some f hi h Contained a d i t t, hazardous and expensive than conventional organic solto partially Orient h l fiber F ll i h i l VelltS- profitably, P y of y Pyrrohdone and orienting or stretching of the fibers, the aquagel tow bun- N-vinyl m0rph01in0n ar H dle was passed into and impregnated with a dye assistant Depending n t ye assistant p y P solution consisting of an aqueous solution of poly-N- Hated can he y with one of several of a Wide vinyl-Z-pyrrolidone, (PVP), maintained at about 100 C. Variety of dyestuffs, among those that y mentioned The tow bundle was either allowed to relax, or was are the V311, Sulfur, difeet, 'metalliled, basic acid, aZOie, stretched while in the impregnating solution. acetate, reactive, ingrain and the like classes Of dyestuffs. The tow of aquagel' filaments was withdrawn from the AS mentioned, When the acrylonitrile P y P impregnation bath and passed directly to the post-impreglarly polyacrylonitrile, fibers are being manufa u Zine nation stretch bath where the filaments were stretched in chloride may most advantageously be utilized as the sole, water at about 100 C. Subsequently, the fibers were or at least the principal saline solute in the spinning sOlirreversibly dried in a hot air oven at about 140 C. for vent employed for the polymer. In such instances, the 7 9 minutes t textile fibers, aqueous solution of zinc chloride in the spinning solution The dried fibers were dyed with a 3% Irgalon Blue RL may advantageously be in a concentration range of from dye solution (based on dry fiber weight), a 2:1 metal 55 to 65, preferably about 60 weight percent, based on complex dyestuif after which random samples were se-.- the weight of the aqueous solution. The quantity of sublected from each group of fibers of which cross-sections stantially pure water passed countercurrent to the filawere examined under a microscope to determine the. ments in the coagulation bath, should be sufiicient, when penetration of the dyestuff into the crosssection. The such aqueous zinc chloride spinning solutions are emconditions used for the fiber preparation and results obployed, so as to maintain the concentration of zinc chlotained are set forth in the following table.
Pre-Impregnaiion Stretch (and Impregnation) Impregnation Bath Post Impregnation Stretch Sample '1" T st t h P t T s h (as ea;- (S 33 lit s. ee see an estate 7. 0 100. 0 16X None 1 10. 0 1. 5 1. 06X 17. 0X 75 13.3 100.0 8X None 1 10.0 1.5 2.12X 170K 09 1.3 70.0 8X None 1 10.0 1.5 2.12X 17.0X Ring 2 2. 4 70. 0 4X None 1 10. 0 1. 5 4. 25X 17. UK 25-50 24 67 4X 6. 0 7. 5 None 1. 04X 12. 5X Ring 24. 0 67 4X 6. 0 20. 0 4. 0 5. 2X 12. 5X 75 24. 0 30 4X 6.0 20. 0 4. 0 4. 8X 12. 5X 50 1 Tow samples were taken from pre-impregnation stretch and hand relaxed in impregnation bath, then hand stretched to 17X in post-impregnation stretch to obtain independent times in the second pan.
2 Short times in preirnpregnation stretch were obtained by utilizing only part of the trough.
ride in the portion of the liquid in the spinning zone at a non-polymer-dissolving coagulation concentration of at least about 25 weight percent; advantageously from about 30 to 50 percent by weight and preferably between about 40 and percent by weight. In such aqueous zinc chloride systems for acrylonitrile polymers, wherein the freshly wet spun polymer is generally obtained in an aquagel form, it is generally desirable for the spinning solution that is extruded to contain between about 4 and 20 percent by weight of dissolved polymer; more advantageously from about 6 to 15 weight percent of dissolved polymer; and preferably particularly when polyacrylonitrile fibers are being manufactured, from about 8.1 to 11.5 percent by weight of fiber-forming polymeric solids in the spinning solution.
Aqueous zinc chloride spinning solutions of fiber-forming acrylonitrile polymers are beneficially extruded at a spinning temperature from 0 to 0, preferably from about 10 to 30 G, into an aqueous zinc chloride coagulating liquid that is maintained at a coagulating temperature of 0 to 30 (1.; preferably from about 10 to 20 C.
Similar excellent results to the foregoing are obtained when other acrylonitrile polymer and other of the dye assistants are employed in accordance with the invention.
What is claimed is:
1. A method for improving through dyeability of acrylonitrile polymer fibers comprising (a) spinning a solution of a polymer of an ethyleni- 9 (e) stretching said impregnated filaments in an aqueous medium at about 901l0 C.; and, (f) subsequently, irreversibly drying said filaments to textile fibers. 2. The, method of claim 1, wherein said acrylonitrile polymer is polyacrylonitrile.
3. The method of claim 1, wherein said solution is an aqueous zinc chloride solution.
4. The method of claim 1, wherein said aqueous medium of (c) is water at 95-100 C. V
5. The method of claim 1, wherein said filaments are partially. stretched in (c) between about 4 and 8 times their washed length.
6. The method of claim 1, wherein said liquid bath of (d) is an aqueous bath.
7. The method of claim 1, wherein said liquid bath References Cited by the Examiner UNITED STATES PATENTS 2,899,262 8/1959 Stanton et al 264-182 X 3,097,054 7/ 1963 Routson et al 264182 X 3,104,934 9/1963 Blumenkopf 264182 X ALEXANDER H. BRODMERKEL, Primary Examiner.
B. SNYDER, Assistant Examiner.

Claims (1)

1. A METHOD FOR IMPROVING THROUGH DYEABILITY OF ACRYLONITRILE OLYMER FIBERS COMPRISING (A) SPINNING A SOLUTION OF A POLYMER OF AN ETHYLENICALLY UNSATURATED MONOMERIC MATERIAL CONTAINING AT LEAST ABOUT 80 WEIGHT PERCENT OF POLYMERIZED ACRYLONITRILE INTO AN AQUEOUS COAGULATING BATH TO FORM FILAMENTS OF SAID POLYMER; (B) WASHING SAID FILAMENTS ESSENTIALLY FREE OF ANY RESIDUAL SPINNING SOLUTION SOLVENT; (C) PARTIALLY STRETCHING SAID WASHED FILAMENTS IN AN AQUEOUS MEDIUM AT ABOUT 90-110*C.; (D) RELAXING SAID PARTIALLY STRETCHED FILAMENTS AT BETWEEN ABOUT 90* AND 110*C. IN A LIQUID BATH OF A DYE ASSISTANT AGENT CAPABLE OF ENHANCING THE DYEABILITY OF SAID FILAMENTS AND IMPREGNATING SAID FILAMENTS THEREWITH; (E) STRETCHING SAID IMPREGNATED FILAMENTS IN AN AQUEOUS MEDIUM AT ABOUT 90* AND 110*C.; AND, (F) SUBSEQUENTLY, IRREVERSIBLY DRYING SAID FILAMENTS TO TEXTILE FIBERS.
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0241054A2 (en) * 1986-03-07 1987-10-14 ENICHEM FIBRE S.p.A. Improvements in methods for producing in-line dyed acrylic fibres
US20090224420A1 (en) * 2008-03-05 2009-09-10 Wilkinson W Kenneth Apparatus and process for preparing superior carbon fiber
US20110059314A1 (en) * 2009-09-10 2011-03-10 International Fibers, Ltd. Process and apparatus for preparing superior carbon fiber
US10407802B2 (en) 2015-12-31 2019-09-10 Ut-Battelle Llc Method of producing carbon fibers from multipurpose commercial fibers
US12146242B2 (en) 2021-03-09 2024-11-19 Ut-Battelle, Llc System for producing carbon fibers from multipurpose commercial fibers

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2899262A (en) * 1959-08-11 Method and composition for rendering
US3097054A (en) * 1960-08-26 1963-07-09 Dow Chemical Co Method of making high-shrink textile fibers
US3104934A (en) * 1959-07-28 1963-09-24 Gen Aniline & Film Corp Polypyrrolidone treatment of polyacrylonitrile gel fibers and the product thereof

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2899262A (en) * 1959-08-11 Method and composition for rendering
US3104934A (en) * 1959-07-28 1963-09-24 Gen Aniline & Film Corp Polypyrrolidone treatment of polyacrylonitrile gel fibers and the product thereof
US3097054A (en) * 1960-08-26 1963-07-09 Dow Chemical Co Method of making high-shrink textile fibers

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0241054A2 (en) * 1986-03-07 1987-10-14 ENICHEM FIBRE S.p.A. Improvements in methods for producing in-line dyed acrylic fibres
EP0241054A3 (en) * 1986-03-07 1989-08-23 Enichem Fibre S.P.A. Improvements in methods for producing in-line dyed acrylic fibres
US20090224420A1 (en) * 2008-03-05 2009-09-10 Wilkinson W Kenneth Apparatus and process for preparing superior carbon fiber
US7964134B2 (en) * 2008-03-05 2011-06-21 International Fibers, Ltd. Process for preparing superior carbon fiber
US20110059314A1 (en) * 2009-09-10 2011-03-10 International Fibers, Ltd. Process and apparatus for preparing superior carbon fiber
US8372323B2 (en) * 2009-09-10 2013-02-12 International Fibers, Ltd. Process of making polyacrylonitrile fibers
US10407802B2 (en) 2015-12-31 2019-09-10 Ut-Battelle Llc Method of producing carbon fibers from multipurpose commercial fibers
US10961642B2 (en) 2015-12-31 2021-03-30 Ut-Battelle, Llc Method of producing carbon fibers from multipurpose commercial fibers
US12146242B2 (en) 2021-03-09 2024-11-19 Ut-Battelle, Llc System for producing carbon fibers from multipurpose commercial fibers

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