US3888965A - Method of increasing the initial modulus and reducing the orientation angle of undrawn poly (para-benzamide) fibers - Google Patents

Method of increasing the initial modulus and reducing the orientation angle of undrawn poly (para-benzamide) fibers Download PDF

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US3888965A
US3888965A US331322A US33132273A US3888965A US 3888965 A US3888965 A US 3888965A US 331322 A US331322 A US 331322A US 33132273 A US33132273 A US 33132273A US 3888965 A US3888965 A US 3888965A
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fibers
polymer
dope
orientation angle
benzamide
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Stephanie Louise Kwolek
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EIDP Inc
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EI Du Pont de Nemours and Co
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    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08GMACROMOLECULAR COMPOUNDS OBTAINED OTHERWISE THAN BY REACTIONS ONLY INVOLVING UNSATURATED CARBON-TO-CARBON BONDS
    • C08G69/00Macromolecular compounds obtained by reactions forming a carboxylic amide link in the main chain of the macromolecule
    • C08G69/02Polyamides derived from amino-carboxylic acids or from polyamines and polycarboxylic acids
    • C08G69/08Polyamides derived from amino-carboxylic acids or from polyamines and polycarboxylic acids derived from amino-carboxylic acids
    • C08G69/12Polyamides derived from amino-carboxylic acids or from polyamines and polycarboxylic acids derived from amino-carboxylic acids with both amino and carboxylic groups aromatically bound
    • 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
    • D01F6/58Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from homopolycondensation products
    • D01F6/60Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from homopolycondensation products from polyamides
    • D01F6/605Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from homopolycondensation products from polyamides from aromatic polyamides

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  • ABSTRACT High molecular weight polymers consisting essentially of recurring units of the formula are useful for the production of fibers having a high initial modulus. The initial modulus is increased and the orientation angle is reduced in the undrawn fibers by heating the fibers at a temperature of at least 350C while under tension. or while relaxed.
  • the most stable dopes to be used for extrusion of the homopolyamide referred to above into filaments contain, on a weight basis, between 4 and 30% of polymer, preferably 5 to from 3 to 22% lithium chloride (LiCl), and the remainder tetramethylurea (TMU). At least 0.5 mol of LiCl should be present per repeating unit of polymer. However, the presence of LiCl is not necessary if the dope is used within a reasonable period after preparation. Thus, to assure that the dope is in proper condition for dryor wet-spinning, either the polymer is prepared in TMU or in TMU-LiCl optionally followed by complete or partial neutralization of the by-product acid, and spun directly (coupled process). It is not necessary that the by-product acid be neutralized, except that it is found to be corrosive to the spinning equipment. In an alternate procedure, the polymer is first prepared and isolated, then combined with TMU-LiCl all as indicated below.
  • LiCl lithium chloride
  • the essentially homopolymeric poly(p-benzamide) in this invention may readily be obtained by certain polymerization techniques from suitable monomers. For example, it may be obtained by the low temperature solution polymerization of p-aminobenzoyl halide salts of the formula Formula I.
  • H3N+ Formula II wherein X represents a member selected from the group consisting of arylsulfonate, alkylsulfonate, acid sulfonate, p-aminobenzoyl chloride toluenesulfonate,
  • paminobenzoyl chloride hydrochloride may be prepared solution of pin, high yield from an ethereal thionylaminobenzoyl chloride by the general procedure of Graf and Langer, .I. prakt. Chem. 148, 161 (1937) under anhydrous conditions.
  • the drying and anhydrous storage of this monomer are preferably performed under room temperature conditions because of the tendency for the compound to polymerize at higher temperatures.
  • POLYMERIZATION CONDITIONS The low temperature, i.e., under 60C. and preferably from 0-20C., solution polymerizations which pro vide the polyamide useful in this invention preferably employ a solvent selected from the group consisting of TMU, hexamethylphosphoramide, N,N- dimethylacetamide, and N-methylpyrrolidone.
  • polystyrene foam N-methylpiperidone, N,N-dimethyl ethylene urea, N,N,N',N-tetramethylmalonamide, N-methylcaprolactam, N- acetylpyrrolidine, N,N-diethylacetamide, N- ethylpyrrolidone, N,N-dimethylpropionamide, N,N-
  • the above-mentioned polymerizations may be carried out by dissolving the desired monomer in the amide solvent and vigorously stirring the resulting solution, externally cooled, until it becomes very viscous.
  • the polyamide may then be isolated by the addition of water.
  • the monomer may first be slurried in a small quantity of an inert organic liquid prior to the addition of the amide solvent.
  • the solvent maybe frozen and mixed, while frozen, with the desired monomer. The solvent is permitted to thaw and the resulting slush stirred until a gel-like mass forms.
  • a suitable chain-terminating agent may be used in these reractions in order to limit the molecular weight of the polymeric product.
  • these polymerizations are performed under strictly anhydrous conditions.
  • the reaction vessel and auxiliary equipment, solvents, and reactants are'carefully dried prior to use and the reaction vessel is continuously swept with a stream of dry, inert gas, e.g., nitrogen, during the polymerization.
  • One such polymerization may be accomplished by first adding, with stirring, a quantity of an anhydrous organic liquid, such as tetrahydrofuran, dioxane, benzene, or acetonitrile, to a quantity of the desired monomer in the gasswept polymerization apparatus.
  • This liquid also contains the calculated amount of the desired chain-terminating agent, e.g., benzoyl chloride, whenever this agent is to be used.
  • the resulting mixture is stirred at an increased rate and a relatively large volume of anhydrous amide solvent, e.g., TMU, N,N- dimethylacetamide, hexamethylphosphoramide, or N- methylpyrrolidone, is then rapidly added to the flask.
  • anhydrous amide solvent e.g., TMU, N,N- dimethylacetamide, hexamethylphosphoramide, or N- methylpyrrolidone
  • the resulting solution extenally cooled, is stirred continuously until there is a substantial increase in the viscosity of the composition.
  • the latter may, if desired, stand overnight or longer at room temperature.
  • the polymerization mixture is combined with water in a suitable blender and then is converted to a fine powder.
  • the powdered polymer after being washed with both water and alcohol, is dried overnight in a vacuum oven at about 8090C. before being stored or dissolved for subsequent processing.
  • chain terminators may be used in these polymerizations.
  • the use of chain terminators contributes to the ease by which subsequent dissolution of the polymer occurs and enhances the stability of the polymer dope for application in the coupled polymerization spinning process.
  • Suitable chain terminators are monofunctional compounds which can react with the acid chloride ends of these polyamides such as ammonia, monoamines (e.g., methylamine, dimethylamine, ethylamine, butylamine, dibutylamine, cyclohexylamine, aniline, etc.), compounds containing a single amide-forming group, such as N,N-diethylethylenediamine, hydroxylic compounds such a methyl alcohol, ethyl alcohol, isopropyl alcohol, phenol, water, etc., and monofunctional compounds which can react with the amine ends of the polyamides such as other acid chlorides (e.g., acetyl chloride), acid anhydrides (e.g., acetic anhydride, phthalic anhyrdide, etc.), and isocyanates (e.g., phenyl isocyanate, m-tolyl isocyanate, ethyl isocyanate, etc.).
  • All useful terminators are especially effective and uniformly distributed if added at the beginning of the polymerization or prior to the addition of any acidneutralizing agent (e.g., lithium hydroxide).
  • any acidneutralizing agent e.g., lithium hydroxide.
  • the essentially homopolymeric poly(p-benzamide) possesses a peak height ratio of below 0.86 and, moreover, no sediment is seen in the tube when the polymer is subjected to the sedimentation test, all-as described below. It has been found that polymer of inherent viscosity 0.80 and meeting these two requirements can be spun into yarns having an extremely high modulus and a low orientation angle. It will be understood, however, that the peak height ratio as measured on polymer that has been spun or heated at elevated temperatures may exceed 0.86. Sedimentation properties may also change on heating or spinning.
  • DOPE PREPARATION The polyamide which has been prepared by the previously described methods and which has been isolated from the polymer preparation system are then incorporated into dopes for spinning, etc.
  • One such method is as follows: a mixture of homopolyamide, TMU, and lithium chloride in proportions earlier defined is placed in a suitable vessel equipped for stirring. The mixture is stirred and heated at about l30-l50C. for at least 1 hour. While the stirred mixture is maintained at this temperature, it generally becomes an extremely viscous, gelatinous mass completely unsuitable for spinning. This material is then cooled to about C. or below in a bath of solid carbon dioxide, or by other spinnable dope.
  • the amount of heating and cooling required to form by this method a dope with the flow characteristics needed for smooth spinning varies with the inherent I or even longer and the mixture is useful as a dope that can be spun or cast. Gelling may begin to occur in from about 0.5 to 2 hours reaction time, depending in part at least upon the degree of polymerization attained. The stability of such dopes may be extended to periods of many days by the addition of chain-terminating agents described earlier.
  • a directly extrudable dope may be obtained where polymerization is continued in TMU for a time in excessof about 0.5 hour or more by adding a quantity of lithium chloride to the TMU medium prior to the polymerization or by adding to the half hour-old reaction system a quantity (up to 2 equivalents of lithium per mole of monomer charged when an acid chloride hydrochloride is employed) of an inorganic salt or salt-forming reagent such as lithium chloride, lithium acetate, lithium hydroxide, lithium carbonate, or lithium oxide; in addition, external heat may be subsequently applied to the contents of the reaction vessel to assist in forming or maintaining the extrudable dope.
  • the above-cited basic materials each react with the hydrogen chloride formed during the polymerization to generate lithium chloride in situ.
  • lithium hydroxide, lithium oxide and like bases be used in amounts not in excess of that required to new tralize the hydrogen chloride or other acids formed in the reaction.
  • spinnerets of platinum-gold construction and reservoirs, filters, conduits, and the like prepared from, for example, corrosion-resistant stainless steel, are particularly suitable. Metals coated with Teflon polyfluorocarbon and glass-lined equipment, as well as acid-, heat-, and solvent-resistant plastic parts may be used.
  • the filaments After being formed, the filaments are passed over a finish-application roll and wound up on bobbins at high speeds. They can be readily back-wound. Development of maximum levels of filament and yarn properties is assisted by soaking the bobbins in water or in mixtures of water and water-miscible inert organic liquids (e.g., TMU, DMAc, acetone, ethyl alcohol, glycerol) to remove residual solvent and salt. The removal of salt and any residual solvent may also be accomplished by passing the yarn through aqueous baths on the run, by flushing the bobbins with water as the yarn is formed, and by washing or soaking skeins, rather than bobbins, or yarn. The yarn is strengthened by washing with even a minor amount of water.
  • water-miscible inert organic liquids e.g., TMU, DMAc, acetone, ethyl alcohol, glycerol
  • the fibers possess high tenacity and a very high initial modulus, i.e., above 200 gpd. and often exceeding 300 gpd., which is necessary for many reinforced plastic applications. They are crystalline and possess an orientation angle of less than about 35.
  • homopolymeric poly(pbenzamide) filaments prepared and treated as described above, possess these unusual and unanticipated tensile properties without being drawn.
  • the freshly extruded filaments are usually of low void content.
  • Use of spin Stretch factors (defined below) approaching one in dry spinning or, on occasion, in wet spinning with such polymers will yield as-spun fibers having an orientation angle of above 35 and a modulus below 200. In that event, the fiber may be heated taut at about 400C. for about 2-5 seconds in nitrogen to bring the orientation angle down and the modulus up.
  • the term as-spun or undrawn describes the filament condition at the wind-up or first roll following extrusion.
  • Spin stretch which is not considered as draw, may occur in the zone preceding the first roll depending on the yarn velocity at the first roll as compared to the velocity of the dope as it passes through the spinneret holes.
  • the yarn may be drawn after it leaves the first roll.
  • Heat treatments of the as-spum filamements under tension or with only a slight amount of drawing produce a significant increase in their tenacity and modu-- lus values.
  • the tensile properties of these filaments can also be enhanced by subjecting the unknown fibers to a heat treatment in the relaxed state.
  • Hot air ovens, hot pins, hot slots, hot plates and liquid heating baths are useful for suchtreatments. Heating is generally carried out above 350C. while drawing said fibers less than about it will be understood that the selection of heating time and temperature will be such as to avoid undue polymer degradation.
  • the chemical and thermal stabilities of filaments and yarns preared from poly(p-benzamide) by the processes of this invenion are excellent.
  • the fibers retain their tensile properties after being heated at the boil for 0.5 hour in aqueous hydrochloric acid (1%) and caustic (1%) silutions.
  • the fibers are essentially unaffected after being soaked for one hour at 60C. in commercially-used dry cleaning solvents such as Perclene" perchlorethylene and Triclene trichlorethylene.
  • the fibers display excellent retention of tensile properties during and after heating in air at 300C. for a prolonged period.
  • the fibers are self-extinguishing when removed from an open flame.
  • the orientation angle of the fiber is determined by the general method described in Krimm and Tobolsky, Textile Research Journal, Vol. 21, pp. 805-22 (1951 A wide angle X-ray diffraction pattern (transmission pattern) of the fiber is made, using nickle-filtered Cu radiation, a fiber-sample thickness of 20 mils (0.05 cm.), a sample-to-film distance of 5 cm., and an exposure time of 45 minutes.
  • the arc length in degrees at the half-maximum intensity of the first equatorial diffraction spot, which is located at 203, 20, is measured and taken as the orientation angle of the sample. Since the intensity trace is an essentially Gaussian curve and the measurement is made at half-maximum intensity, the physical meaning of the orientation angle given by the determination is that approximately 77% of the crystallities are aligned within this angle about the fiber axis.
  • Peak Height Ratio A measure of the relative intensity of the two 'major equatorial diffraction peaks is given by the peak height ratio (PHR).
  • PHR peak height ratio
  • a suitable method for determining the PHR involves the use of a reflection technique to record the intensity trace of the X-ray diffraction pattern with an X-ray diffractometer. Approximately 0.5 gram of waterand TMU-free polymer is pressed into a Phillips sample holder under an applied pressure of 3,125 lb./in. (219.7 X 10 g/cm.
  • a trace of intensity is recorded from 6 to 40, 20, at a scanning speed of 1, 26, per minute, a chart speed of 1 inch per minute (2.54 cm./min.), and a time constant of 2; 20 being the angle between the undiffracted beam and the diffracted beam.
  • the full scale deflection of the recorder is set so that the peak with maximum intensity is at least of the scale, which is a linear scale.
  • a base line is first established on the diffractometer scan by drawing a straight line between the points on the curve at 8 and 38, 20.
  • ninh 1n ('qrel)/C wherein (nrel) represents the relative viscosity and (C) represents a concentration of 0.5 gram of the polymer in 100 ml. of solution.
  • the relative viscosity (nrel) is determined by dividing the flow time in a capillary viscometer of a dilute solution of the polymer by the flow time for the pure solvent.
  • the dilute solutions used herein for determining (nrel) are of the concentration expressed by (C), above; flow times are determined at 30C., using concentrated (95-98%) sulfuric acid as a solvent.
  • Fiber properties of tenacity, elongation, and initial modulus are coded as T/E/Mi and are reported in their conventional units. Denier is coded as Den.
  • the boiling off treatment of fibers prior to physical testing consists of boiling the fibers 30 minutes in 0.1% aqueous sodium lauryl sulfate, rinsing, drying at 40C. for 1 hour, and conditioning at 21C. and 65% r.h. for 16 hours.
  • Tensile properties were determined on yarn samples which measured one inch (2.54 cm.) in length between the jaws of an Instron tester (product of the Instron Engineering Corp., Canton, Mass.) and which are subjected therein to a load sufficient to cause elongation to occur at the rate of 10% per minute measured at 21C. and 65% r.h.
  • Instron tester product of the Instron Engineering Corp., Canton, Mass.
  • Tetrahydrofuran (75 ml., distilled and stored over sodium metal, water content less than 0.000l%) is filtered in the dry-box into an Erlenmeyer flask which is then sealed and cooled in ice.
  • p- Aminobenzoyl chloride hydrochloride (124.0 g., 0.646 mole) is weighed out in the dry-box and transferred to the resin-kettle. The kettle is removed from the dry- 1 box, reconnected with the stirring motor and nitrogen The benzoyl chloride-tetrahydrofuran solution is poured, with moderate stirring, into the .paminobenzoyl chloride hydrochloride and the mixture is stirred for about 1 minute.
  • the stirring rate is increased and the hexamethylphosphoramide is rapidly added.
  • the resulting mixture is stirred for about 1 hour while being cooled in an ice bath.
  • the mixture gradually gels as a result of this treatment.
  • the cooling bath is removed and the polymeric mass is allowed to stand overnight at room temperature.
  • the solid gel is then combined with water and stirred at high speeds in a gallon-size (3.785 liter) blender wherein it is converted to a fine, white powder.
  • the polymer is washed 3 times with water and once with alcohol by means of stirring in a blender and filtration on a sintered-glass mediumpore Buchner funnel.
  • the polymer is dried overnight in a vacuum oven at 90C.
  • the yield of poly(pbenzamide) is 92.3% (ninh 1.35).
  • the polymer had a peak height ratio of 0.78. When subjectedto the sedimentation test, no solid residue remained at the bottom of the tube.
  • Dope Preparation Into a 700 ml. bottle equipped with an air-driven stirrer are placed 20 g. of the polymer and 180 g. of TMU/lithium chloride solution containing 6.5% by weight of the salt. The resulting mixture is stirred and 'heated to 150C. by means of an oil bath. There is obtained an extremely viscous gelatinous mass. This mixture is cooled in solid carbon dioxide for 1 hour. the mixture is then heated at 150C. for 4 hours with stirring, to procude a fluid, somewhat gelatinous hazy dope. The latter is cooled for 1 hour in solid carbon dioxide. The mixture is then stirred and heated for 4 hours at a temperataure of C. to produce a readily-spinnable haze dope which is subsequently cooled in solid carbon dioxide for 1 hour. This smooth, hazy dope flows slowly at room temperature and reflects light upon being stirred.
  • the dope prepared as above is heated to 130C. and extruded at the rate of about 0.9 ml./min., under a pressure of 70 lb./ir1. (4,921 g.cm. through a heated (l40144C.) protrusion-type spinneret having 4 holes of 0.004 inch (0.01 cm.) diameter and a capillary length of 0.008 inch (0.02 cm.), into a drying column'whose wallsare I kept within the range of 202210C. The column is swept with a cocurrent flow (5 ft. /min.; 0.142 m. /min.) of dry nitrogen which enters the column at 265-270C.
  • a cocurrent flow 5 ft. /min.; 0.142 m. /min.
  • the emerging filaments are passed over a small guide roll bearing a finish solution and are wound up on a-bobbin at the rate of about 200 yd./min. (183 m./min.). This constitutes a spin stretch factor of 6.58.
  • the filaments do not stick and'are readily back-wound.
  • These opaque exturded filaments become lustrous white upon being soaked in changes of water (25C.) to remove residual solvent and salt.
  • the inherent viscosity of the polymer in the filaments is 1.32.
  • the water-leached, air-dried (70F. 65(l93)% r.h.) filaments exhibit crystallinity and an orientation angle of 21.
  • a yarn prepared from these filaments exhibits the following T/E/Mi/Den. values (32 filaments; non-boiled-off): 6.02/2.l7/431/58.5. Filaments that have been boiled off display the following T/E/Mi/Den. values: 4.75/l.38/429/l.72.
  • the T/E/Mi/Den. values of the washed and boiled-off fiber are 7.16/2.l6/486/2.80, respectively.
  • the fibers are crystalline and have an orientation angle of 16.
  • the T/E/Mi/Den. values for a boiled-off sample of filaments are 10.7/1.7/695/2.82, respectively.
  • the filaments are highly crystalline and exhibit an orientation angle of 12.
  • EXAMPLE Ill Into a 2-liter resin kettle are placed 153.6 g. (0.8 mole) of p-aminobenzoyl chloride hydrochloride with stirring under nitrogen. A 2% solution of lithium chloride in distilled TMU is prepared, heated at 60C. and topped under vacuum to remove any water which might be present. About 800 g. of this solution are added rapidly to the monomer powder in the resin kettle at 30C. while stirring. After about three-fourths of an hour, the first of three 4 ml. additions of diethylamine is made to stop the polymerization. The second 4 ml. are added 5 minutes later and the final 4 ml. are added 30 minutes after that. About 70 g. (0.946 mole) of lithium carbonate are added 18 minutes later. The
  • EXAMPLE I This example illustrates the preparation of the poly(p-benzamide) fibers of the invention wherein a coupled process of polymer production and filament spinning is employed. It will be noted that the fiber properties are significantly enhanced after heat treatment.
  • the 9% dope as prepared above is pre filtered through a 200-mesh stainless steel screen to remove excess Li CO powder. Approximately 300 g. of the dope are then placed in a spinning cell, then filtered through a sand and screen filter pack before reaching the spinneret.
  • the spinneret has holes, each having a diameter of 0.003 inch (0.076 mm.). They are arranged in three circles within a half-inch (1.27 cm.) diameter overall.
  • the yarn is drawn through a 135 cm.
  • the spin stretch is controlled by varying the wind-up speed of the first bobbin.
  • the minimum wind-up speed possible without yarn build-up in the bath is 32 ft./min. or 384 in./min. 16.26 cm./sec.).
  • the calculated unextracted polymer solution jet velocity is 605 in./min. (25.61 cm./sec.). This indicates a lengthwise extraction shrinkage of 36.5% before wind-up.
  • the optimum wind-up speed is found to be 540 in./min.
  • the as-spun yarn is soaked for 2 hours in water, then allowed to dry on the bobbins.
  • the as-spun yarn has an orientation angle of 27 as determined by X-ray analysis.
  • T/E/Mi/Den values for the as-spun yarn are 5.9/4.8/354/3.l (after boil-off).
  • the yarn is subsequently heat treated by drawing it over a 12-inch (0.03 m.) long grooved hot shoe at 30 ft./min. (15.24 cm./sec.) to give a 2 second contact time. A nitrogen blanket is maintained over the hot zone.
  • the wet-spun sample after various heat treatments has the following properties (boiled-off):
  • This example illustrates the effect of heat treatment on the tenacity and modulus of fibers of poly(1,4- benzamide) and preparation of a laminate from such fibers.
  • a 2-liter resin-making kettle is dried by flaming and allowing to cool in a nitrogen atmosphere.
  • the kettle is fitted with an egg-beater-type alluminum stirrer and nitrogen inlet and outlet devices. While a slow current of dry nitrogen is passed through the kettle, it is charged with 150 g. of p-aminobenzoyl chloride hydrochloride. To this are added rapidily with vigouous stirring, 770 ml. of TMU, precooled to about -lC. (This solvent had previously been dried to a water content of less than 150 parts per million by distillation over calcium hydride). Considerable heat is evolved initially; this is absorbed by surrounding the kettle with an icebath for the intital minutes after reaction was started.
  • anhydrous lithium hydroxide is added and the stirred mixture is raised to a temperature of 120C. by external heating.
  • the highly viscous, rubbery mixture becomes a more free-flowing spin dope as stirring at 120C. is continued for about 30 minutes.
  • the spin dope contains 10.2% polymer content.
  • the polymer is filtered and dried for 15 hours at -80C. in a vacuum oven (20 -40 cm. of mercury) fitted with a nitrogen bleed.
  • the polymer has an inherent viscosity of 1.38, a peak height ration of 0.76, and, under the conditions of the sedimentation test. leaves no polymeric residue on the bottom of the test tube after 48 hours.
  • the above spin dope is dry spun as follows. From the spinning vessel, in which it was kept at 155C, the dope is expressed by a piston under a pressure of 68 lb./in. (4,780 g./cm. through a spinneret adapter (at C), then through a spinneret (at 160C.) The spinneret is of the protrusion type, consisting of nine effective holes, each of 0.004 in. (0.01 cm.) diameter. In the adapter the dope passes through a filter consisting of one 50 mesh screen, three 200 mesh screens, one cotton cloth of 2.4 oz./yd. (81.5 g./m.
  • the dope jets through the spinneret at a rate of 2.92 ml./min. into a cocurrent stream of nitrogen at a temperature of 235C., flowing at 5 it /min. (0.142 m. /min.), in a spinning cell with walls heated at 200C.
  • the fibers issuing from the cell are passed through water and wound up at a rate of yd./min.
  • Extracted and dried yarn of the preceding preparation is passed through a hot stainless steel tube, 0.286 inch (7.26 mm.) inside diameter and 32 inches (81.3 cm.) in length, at 12 ft./min. (3.66 m./min.) under a nitrogen atmosphere without significantly changing its length.
  • the nitrogen is passed through the tube from the yarn entry end at such a rate as to change the atmosphere in the tube once every minute.
  • the tube is heated externally by a 12 inch (0.3 m.) long furnace which was controlled by a thermocouple braised to the external central surface of the pipe and connected to a Minneapolis-Honeywell Pyrovane controller.
  • the nominal heat-treating temperature of the tube given in Table 111 is the temperature indicated by a thermocouple braised to the center of the inside of the tube.
  • a profile of the temperature in the tube for a nominal temperature of 536C. obtained by varying the position of a test thermocouple is given in Table 11.
  • TABLE ll-Continued TEMPERATURE PROFILE OF HEAT-TREATING TUBE flange rests upon shims which are sized to leave a gap of 0.1 in. (0.254 cm.) between the plug and the bottom surface of the mold.
  • the mold and its contents are pisim c?t fr; n E.
  • the press is closed and a total 17 536 pressure of 1.5 tons (1.36 metric tons) is applied to the 13 537 mold.
  • the mold is left in the press for 2.75 hr. before 39 being taken out and cooled to room temperature.
  • the ends of the laminate sample are cut off and hand 221 213 sanded.
  • the sample measures 5.32 X 0.502 X 0.095 in. 32 184 (13.5 X 1.27 X 0.24 cm.),
  • the tangent modulus of elasticity in flexure (i.e., flex modulus) of the sample is Properties of yarns treated at different temperatures measured having a 4 in. (10.16 cm.) long portion are given in Table ill. chosen in the middle of the laminate as the test section.
  • a laminate is prepared from the above fiber as fola density of 2.22 g./cm. lows.
  • a mixture consisting of 10 g. Epon 815 (Shells epoxy resin), 9 g. or Nadic (methyl anhydride curing EXAMPLE V agent Allied Chemical Corporation), and 0.1 g. of benzyldimethylamine is poured into a mold having a cavity Polymer Preparation: A 250-ml. round-bottomed with the following dimensions: length, 5.95 in.; width, fl sk q pp i h a stirrer, ni r g n inlet tube.
  • Th calcium chloride drying tube is flamed with a Bunsen mold and its contents are placed in a vacuum chamber bruner and simultaneously flushed with nitrogen. The for 1 hour to remove gases. The mold is then removed y flask with its attachments is Placed in a y' and from the vacuum chamber. The fiber is cut from the 11-52 gof P-aminobenzoyl Chloride hydrochloride is bobbin and divided into ribbons 5.95 in.
  • the forming for a further 30 minutes for removal of unwanted polymer yields a viscous, somewhat hazy dope. Polygases.
  • the mold is then taken from the vacuum chammer is isolated from a sample of the dope at 4 hours by her and a flanged plug, having dimensions of 5.75 X 0.5 precipitation in water and is found to have an inherent X 1.0 in. t 14.6 X 1.27 X 2.54 cm.), is pushed into the cavity and pressed slowly down upon the resin-fiber mix in order to allow bubbles and excess resin to find their way to the open spaces between the plug ends and viscosity of 1.38.
  • Fiber Preparation A sample of polymer dope, prepared as described above but from a duplicate reaction mixture, is charged into a l5-ml., syringe-type cell havstructed of stainless steel.
  • a -hole spinneret having 0.003 in. (0.076 mm.) holes and constructed of a platinum alloy, is attached to the syringe by a ring-nut over a simple filter pack consisting of a 200-mesh stainless steel screen, a thin layer of fine glass wool and then 50- mesh, 200-mesh, and 50-mesh screens in succession.
  • the dope is extruded at a slow rate into a water bath kept at about 50C. and the fibers are collected on a bobbin at a speed of 61 ft./ min. (18.6 m./min.) after traveling in the bath for about 3 ft. (0.91 m.).
  • the fibers have the following properties:
  • the polymer of the as-spun fiber has an ninh of 1.12 and a peak height ratio of 0.78.
  • Some of the dopes used in this invention may be further characterized by their microscopic birefringent qualities which are manifested by their effect on planepolarized light. Such an observation may be made by the following method.
  • a drop taken from the interior of a dope sample of this invention. is put on a dry, clean strain-free glass slide; a square cover of glass, sup ported on one edge by a glass tube or wire of known thickness (1.3 mm. diameter is convenient) is pressed down on the drop so as to form the roof of a liquid wedge.
  • the edges are sealed with a fast-drying binder avoiding actual contact with the dope.
  • the sharp edge of the wedge is sealed by excess dope which is squeezed out.
  • common care should be taken to avoid evaporation, moisture uptake, excessive shearing actions, dirt, and any suspended solid particles.
  • the wedge is positioned in a light beam, on a micro scope stage between crossed polarizer and analyzer, so that the thickness of the center of the layer of dope through which the light beam passes is 80;.t in thickness.
  • the intensity is measured with polarizer and analyzer crossed (1 (superscript s to denote sample present in wedge) and with analyzer removed (L and the difference I L, is obtained.
  • the transmitted light may be measured by conventional light sensitive detectors (e.g. by photo miltipliers, selenium or cadmium light meters, bolometers, etc.). The same measurements are then made on a similarly constructed wedge containing air, and the difference L" I (superscript c for control) is recorded.
  • EXAMPLE VI The results presented in the following Table V illustrate the effects of using various chain terminators, with and without added lithium hydroxide monohy- 16 drate, in preparing the po1y(p-benzamide) used in this invention. Data for two control runs are also presented.
  • 200 ml. of TMU are placed in an ice-cooled glass reaction vessel and 0.0025 mole of the designated terminator is added thereto.
  • 32 g. (0.17 mole) of paminobenzoyl chloride hydrochloride To these ingredients are added 32 g. (0.17 mole) of paminobenzoyl chloride hydrochloride. The contents of the reaction vessel are stirred for 15 minutes, after which the cooling bath is removed and the contents stirred for another 1.75 hour.
  • Lithium hydroxide monohydrate 12.8 g., 0.31 mole is added to the vessel and the contents are stirred for 30-60 minutes at autogenous temperature. The reaction mixture is then permitted to stand for 20 hours at autogenous temperature before being agitated with water in a blender to precipitate the polymer. The latter is collected, washed three times with water and once with 28 alchol (all done in a blender), and dried in a vacuum oven. The particular terminator employed, the polymers viscosity, and pres- *Added 1 hr. after monomer addition instead of 2 hr. later.
  • EXAMPLE VII This example illustrates that some dopes used in this invention cause an increase in the transmittance of light through crossed polarizers.
  • the apparatus by which the anisotropic character of these dopes is determined consists essentially of an A. 0.
  • Spencer Orthoscope llluminator which contains a tungsten overvoltage microscope lamp (color temperature 3800K.), an optical wedge containing the sample, an optical wedge containing air, a Bausch and Lomb Polarizing Microscope having a Leitz 10X objective and a Leitz 10X ocular Peripian, a Polaroid M 3 Industrial Land Camera and a Gossen Sinarsix exposure meter.
  • the wedge containing the sample is prepared as previously described and is positioned on the microscope stage (i.e., between the polarizer and the analyzer) to provide a sample layer of 80,u.thickness in the path of any light which reaches the analyzer and the light meter.
  • the polarizer and the analyzer are adjusted to provide 90 crossed polarization planes. Light from the lamp which passes the analyzer by the route previously described is projected into the.
  • /l represents the increase in intensity of light transmitted due to the presence in the wedge of the dope being examined.
  • the fibers are excellent for reinforced plastic laminates because of their high modulus. low density. high dimensional stability, high strength, high thermal stability and high flexural rigidity at a given laminate weight. Specific end-uses mayinclude spiral 18 I TABLE VI LIGHT DEPOLARlZATlON BY POLY(p-BENZAMIDE Poly( p-benzamide weight Percent In Dope ninh Wgt. 71 Salt wound pressure vessels, skis, bows, fishing rods, and
  • the high modulus, high strength, fatigue resistance I and impact strength of the fibers render them useful in mechanicalrubber goods such as belts.
  • the fibers are useful in sewing thread. and in uses such as protective clothing, laundry press covers, filtration fabrics, industrial hose, dryer felts, all of which utilize the high thermal stability of the fiber.
  • a method for increasing the initial modulus and reducing the orientation angle of undrawn fibers consisting essentially of poly(p-benzamide having an orientation angle of up to about 55 comprising heating the undrawn fibers at a temperature of at least 350C.

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Abstract

High molecular weight polymers consisting essentially of recurring units of the formula

ARE USEFUL FOR THE PRODUCTION OF FIBERS HAVING A HIGH INITIAL MODULUS. The initial modulus is increased and the orientation angle is reduced in the undrawn fibers by heating the fibers at a temperature of at least 350*C while under tension, or while relaxed.

Description

United States Patent [1 1 Kwolek June 10, 1975 METHOD OF INCREASING THE INITIAL MODULUS AND REDUCING THE ORIENTATION ANGLE OF UNDRAWN POLY (PARA-BENZAMIDE) FIBERS [75] Inventor: Stephanie Louise Kwolek,
Wilmington. Del.
[73] Assignee: E. I. du Pont de Nemours and Company, Wilmington. Del.
[22] Filed: Feb. 9, I973 [21] Appl. No.3 331.322
Related U.S. Application Data [63] Continuation-impart of Ser. No. 30,089, April 20, 1970. abandoned. which is a continuation of Ser. No. 644.851. June 9. 1967, abandoned. which is a continuation-in-part of Ser. No. 556.934. June 13. 1966. abandoned.
[52] US. Cl. 264/342 RE; 264/184; 264/205;
264/346 [51] Int. Cl. B290 25/00 [58] Field of Search 264/184. 205. 235. 346.
264/210 F. 290 N, 342 RE; 161/172 [56] References Cited UNITED STATES PATENTS 3.414.645 12/1968 Morgan, Jr. 264/210 F 3,595,951 7/1971 Logullo 264/211 Primary E.\'aminer-Robert F. White Assistant Examiner-James B. Lowe [57] ABSTRACT High molecular weight polymers consisting essentially of recurring units of the formula are useful for the production of fibers having a high initial modulus. The initial modulus is increased and the orientation angle is reduced in the undrawn fibers by heating the fibers at a temperature of at least 350C while under tension. or while relaxed.
1 Claim, 1 Drawing Figure RELATIVE INTENSITY 0F X-RAY DIFFRACTION METHOD OF INCREASING THE INITIAL MODULUS AND REDUCING THE ORIENTATION ANGLE OF UNDRAWN POLY (PARA-BENZAMIDE) FIBERS CROSS-REFERENCE TO RELATED APPLICATIONS This application is a continuation-in-part of my copending application Ser. No. 30,089, filed Apr. 20, 1970, which in turn is a continuation of my application Ser. No. 644,851, filed June 9, 1967, now abandoned which in turn is a continuation-in-part of my application Ser. No. 556,934, filed June 13, 1966, now abandoned.
DETAILED DESCRIPTION In accordance with this invention, there is provided a process for treating high molecular weight substantially homopolymeric poly(p-benzamide) fibers consisting essentially of recurring units of the formula I! O n In the inherent viscosity range of from about 0.8 to about 2.5 (measured as described hereinafter) this polymer is useful for the production of fibers. At values of inherent viscosity as low as about 0.7, it is useful for the production of films, fibrids, and coatings. These uses require the polymer to be preliminarily in the form of a dope.
The most stable dopes to be used for extrusion of the homopolyamide referred to above into filaments contain, on a weight basis, between 4 and 30% of polymer, preferably 5 to from 3 to 22% lithium chloride (LiCl), and the remainder tetramethylurea (TMU). At least 0.5 mol of LiCl should be present per repeating unit of polymer. However, the presence of LiCl is not necessary if the dope is used within a reasonable period after preparation. Thus, to assure that the dope is in proper condition for dryor wet-spinning, either the polymer is prepared in TMU or in TMU-LiCl optionally followed by complete or partial neutralization of the by-product acid, and spun directly (coupled process). It is not necessary that the by-product acid be neutralized, except that it is found to be corrosive to the spinning equipment. In an alternate procedure, the polymer is first prepared and isolated, then combined with TMU-LiCl all as indicated below.
The essentially homopolymeric poly(p-benzamide) in this invention may readily be obtained by certain polymerization techniques from suitable monomers. For example, it may be obtained by the low temperature solution polymerization of p-aminobenzoyl halide salts of the formula Formula I.
H3N+ Formula II wherein X, represents a member selected from the group consisting of arylsulfonate, alkylsulfonate, acid sulfonate, p-aminobenzoyl chloride toluenesulfonate,
p-aminobenzoyl bromide ethanesulfonate, and paminobenzoyl chloride sulfate. The preferred paminobenzoyl chloride hydrochloride may be prepared solution of pin, high yield from an ethereal thionylaminobenzoyl chloride by the general procedure of Graf and Langer, .I. prakt. Chem. 148, 161 (1937) under anhydrous conditions. The drying and anhydrous storage of this monomer are preferably performed under room temperature conditions because of the tendency for the compound to polymerize at higher temperatures.
POLYMERIZATION CONDITIONS The low temperature, i.e., under 60C. and preferably from 0-20C., solution polymerizations which pro vide the polyamide useful in this invention preferably employ a solvent selected from the group consisting of TMU, hexamethylphosphoramide, N,N- dimethylacetamide, and N-methylpyrrolidone. Other useful polymerization media are N-methylpiperidone, N,N-dimethyl ethylene urea, N,N,N',N-tetramethylmalonamide, N-methylcaprolactam, N- acetylpyrrolidine, N,N-diethylacetamide, N- ethylpyrrolidone, N,N-dimethylpropionamide, N,N-
dimethylbutyramide and N,N-dimethylisobutyramide.
The above-mentioned polymerizations may be carried out by dissolving the desired monomer in the amide solvent and vigorously stirring the resulting solution, externally cooled, until it becomes very viscous. The polyamide may then be isolated by the addition of water. Alternatively, the monomer may first be slurried in a small quantity of an inert organic liquid prior to the addition of the amide solvent. In a variation of the former method, the solvent maybe frozen and mixed, while frozen, with the desired monomer. The solvent is permitted to thaw and the resulting slush stirred until a gel-like mass forms. A suitable chain-terminating agent may be used in these reractions in order to limit the molecular weight of the polymeric product. For the attainment of the highest molecular weights, these polymerizations are performed under strictly anhydrous conditions. The reaction vessel and auxiliary equipment, solvents, and reactants are'carefully dried prior to use and the reaction vessel is continuously swept with a stream of dry, inert gas, e.g., nitrogen, during the polymerization.
One such polymerization may be accomplished by first adding, with stirring, a quantity of an anhydrous organic liquid, such as tetrahydrofuran, dioxane, benzene, or acetonitrile, to a quantity of the desired monomer in the gasswept polymerization apparatus. This liquid also contains the calculated amount of the desired chain-terminating agent, e.g., benzoyl chloride, whenever this agent is to be used. The resulting mixture is stirred at an increased rate and a relatively large volume of anhydrous amide solvent, e.g., TMU, N,N- dimethylacetamide, hexamethylphosphoramide, or N- methylpyrrolidone, is then rapidly added to the flask.
The resulting solution, extenally cooled, is stirred continuously until there is a substantial increase in the viscosity of the composition. The latter may, if desired, stand overnight or longer at room temperature. When the polymer is to be isolated in bulk form, the polymerization mixture is combined with water in a suitable blender and then is converted to a fine powder. The powdered polymer, after being washed with both water and alcohol, is dried overnight in a vacuum oven at about 8090C. before being stored or dissolved for subsequent processing.
As indicated above, chain terminators may be used in these polymerizations. By assisting in the control of v the molecular weight of the polyamide, the use of chain terminators contributes to the ease by which subsequent dissolution of the polymer occurs and enhances the stability of the polymer dope for application in the coupled polymerization spinning process. Among the suitable chain terminators are monofunctional compounds which can react with the acid chloride ends of these polyamides such as ammonia, monoamines (e.g., methylamine, dimethylamine, ethylamine, butylamine, dibutylamine, cyclohexylamine, aniline, etc.), compounds containing a single amide-forming group, such as N,N-diethylethylenediamine, hydroxylic compounds such a methyl alcohol, ethyl alcohol, isopropyl alcohol, phenol, water, etc., and monofunctional compounds which can react with the amine ends of the polyamides such as other acid chlorides (e.g., acetyl chloride), acid anhydrides (e.g., acetic anhydride, phthalic anhyrdide, etc.), and isocyanates (e.g., phenyl isocyanate, m-tolyl isocyanate, ethyl isocyanate, etc.).
All useful terminators are especially effective and uniformly distributed if added at the beginning of the polymerization or prior to the addition of any acidneutralizing agent (e.g., lithium hydroxide).
The essentially homopolymeric poly(p-benzamide) possesses a peak height ratio of below 0.86 and, moreover, no sediment is seen in the tube when the polymer is subjected to the sedimentation test, all-as described below. It has been found that polymer of inherent viscosity 0.80 and meeting these two requirements can be spun into yarns having an extremely high modulus and a low orientation angle. It will be understood, however, that the peak height ratio as measured on polymer that has been spun or heated at elevated temperatures may exceed 0.86. Sedimentation properties may also change on heating or spinning.
DOPE PREPARATION The polyamide which has been prepared by the previously described methods and which has been isolated from the polymer preparation system are then incorporated into dopes for spinning, etc. One such method is as follows: a mixture of homopolyamide, TMU, and lithium chloride in proportions earlier defined is placed in a suitable vessel equipped for stirring. The mixture is stirred and heated at about l30-l50C. for at least 1 hour. While the stirred mixture is maintained at this temperature, it generally becomes an extremely viscous, gelatinous mass completely unsuitable for spinning. This material is then cooled to about C. or below in a bath of solid carbon dioxide, or by other spinnable dope.
The amount of heating and cooling required to form by this method a dope with the flow characteristics needed for smooth spinning varies with the inherent I or even longer and the mixture is useful as a dope that can be spun or cast. Gelling may begin to occur in from about 0.5 to 2 hours reaction time, depending in part at least upon the degree of polymerization attained. The stability of such dopes may be extended to periods of many days by the addition of chain-terminating agents described earlier. A directly extrudable dope may be obtained where polymerization is continued in TMU for a time in excessof about 0.5 hour or more by adding a quantity of lithium chloride to the TMU medium prior to the polymerization or by adding to the half hour-old reaction system a quantity (up to 2 equivalents of lithium per mole of monomer charged when an acid chloride hydrochloride is employed) of an inorganic salt or salt-forming reagent such as lithium chloride, lithium acetate, lithium hydroxide, lithium carbonate, or lithium oxide; in addition, external heat may be subsequently applied to the contents of the reaction vessel to assist in forming or maintaining the extrudable dope. The above-cited basic materials each react with the hydrogen chloride formed during the polymerization to generate lithium chloride in situ. It is preferred that lithium hydroxide, lithium oxide and like bases be used in amounts not in excess of that required to new tralize the hydrogen chloride or other acids formed in the reaction. In spinning those TMU dopes described above, spinnerets of platinum-gold construction and reservoirs, filters, conduits, and the like, prepared from, for example, corrosion-resistant stainless steel, are particularly suitable. Metals coated with Teflon polyfluorocarbon and glass-lined equipment, as well as acid-, heat-, and solvent-resistant plastic parts may be used.
SHAPED ARTICLES AND THEIR PREPARATION Conventional wetand dry-spinning techniques and equipment can be used to prepare the polyamide filaments from the previously described dopes. In wet spinning, an appropriately prepared TMU (or other suitable solvent) dope of the polyamide, whose temperature may vary from room temperature to about C is extruded into a suitable coagulating bath, e.g., a water bath maintained at 6590C. Other useful coagulants include ethylene glycol, glycerol, mixtures of TMU and water, mixtures of alcohol and water, and aqueous salt baths. These are preferably maintained at a temperature of 40-45C. or above. Formation of good fibers (i.e., those with enhanced tensile properties) is assisted by keeping the filaments taut while they are in the coagulating bath. This may be accomplished, for example, by passing the filaments around guides placed in the coagulating bath.
- whereby the TMU is evaporated.
After being formed, the filaments are passed over a finish-application roll and wound up on bobbins at high speeds. They can be readily back-wound. Development of maximum levels of filament and yarn properties is assisted by soaking the bobbins in water or in mixtures of water and water-miscible inert organic liquids (e.g., TMU, DMAc, acetone, ethyl alcohol, glycerol) to remove residual solvent and salt. The removal of salt and any residual solvent may also be accomplished by passing the yarn through aqueous baths on the run, by flushing the bobbins with water as the yarn is formed, and by washing or soaking skeins, rather than bobbins, or yarn. The yarn is strengthened by washing with even a minor amount of water.
The fibers possess high tenacity and a very high initial modulus, i.e., above 200 gpd. and often exceeding 300 gpd., which is necessary for many reinforced plastic applications. They are crystalline and possess an orientation angle of less than about 35. In general, as shown in the examples which follow, homopolymeric poly(pbenzamide) filaments prepared and treated as described above, possess these unusual and unanticipated tensile properties without being drawn. The freshly extruded filaments are usually of low void content. Use of spin Stretch factors (defined below) approaching one in dry spinning or, on occasion, in wet spinning with such polymers will yield as-spun fibers having an orientation angle of above 35 and a modulus below 200. In that event, the fiber may be heated taut at about 400C. for about 2-5 seconds in nitrogen to bring the orientation angle down and the modulus up.
As used herein the term as-spun" or undrawn describes the filament condition at the wind-up or first roll following extrusion. Spin stretch, which is not considered as draw, may occur in the zone preceding the first roll depending on the yarn velocity at the first roll as compared to the velocity of the dope as it passes through the spinneret holes. The yarn may be drawn after it leaves the first roll.
Heat treatments of the as-spum filamements under tension or with only a slight amount of drawing produce a significant increase in their tenacity and modu-- lus values. The tensile properties of these filaments can also be enhanced by subjecting the unknown fibers to a heat treatment in the relaxed state. Hot air ovens, hot pins, hot slots, hot plates and liquid heating baths are useful for suchtreatments. Heating is generally carried out above 350C. while drawing said fibers less than about it will be understood that the selection of heating time and temperature will be such as to avoid undue polymer degradation.
The chemical and thermal stabilities of filaments and yarns preared from poly(p-benzamide) by the processes of this invenion are excellent. The fibers retain their tensile properties after being heated at the boil for 0.5 hour in aqueous hydrochloric acid (1%) and caustic (1%) silutions. The fibers are essentially unaffected after being soaked for one hour at 60C. in commercially-used dry cleaning solvents such as Perclene" perchlorethylene and Triclene trichlorethylene. The fibers display excellent retention of tensile properties during and after heating in air at 300C. for a prolonged period. The fibers are self-extinguishing when removed from an open flame.
It will be understood that the usual additives such as dyes, fillers, UV stabilizers, antioxidants, etc. can be incorporated in with the polymer for the purposes intended prior to fiber preparation.
MEASUREMENTS AND TESTS Orientation Angle: The orientation angle of the fiber is determined by the general method described in Krimm and Tobolsky, Textile Research Journal, Vol. 21, pp. 805-22 (1951 A wide angle X-ray diffraction pattern (transmission pattern) of the fiber is made, using nickle-filtered Cu radiation, a fiber-sample thickness of 20 mils (0.05 cm.), a sample-to-film distance of 5 cm., and an exposure time of 45 minutes. The arc length in degrees at the half-maximum intensity of the first equatorial diffraction spot, which is located at 203, 20, is measured and taken as the orientation angle of the sample. Since the intensity trace is an essentially Gaussian curve and the measurement is made at half-maximum intensity, the physical meaning of the orientation angle given by the determination is that approximately 77% of the crystallities are aligned within this angle about the fiber axis.
Peak Height Ratio: A measure of the relative intensity of the two 'major equatorial diffraction peaks is given by the peak height ratio (PHR). A suitable method for determining the PHR involves the use of a reflection technique to record the intensity trace of the X-ray diffraction pattern with an X-ray diffractometer. Approximately 0.5 gram of waterand TMU-free polymer is pressed into a Phillips sample holder under an applied pressure of 3,125 lb./in. (219.7 X 10 g/cm. Using nickle-filtered Cu radiation, a Philips diffractometer with O.5 slits, and a pulse height analyzer, a trace of intensity is recorded from 6 to 40, 20, at a scanning speed of 1, 26, per minute, a chart speed of 1 inch per minute (2.54 cm./min.), and a time constant of 2; 20 being the angle between the undiffracted beam and the diffracted beam. The full scale deflection of the recorder is set so that the peak with maximum intensity is at least of the scale, which is a linear scale. To calculate the PHR, a base line is first established on the diffractometer scan by drawing a straight line between the points on the curve at 8 and 38, 20. Vertical lines (at constant 26 values) are drawn from the peaks in the vicinity of 203 and 23.4", 20, to the base line, and the height of the peaks, in chart divisions, above the base line is ascertained. The PHR is then calculated from the equation PHR A/B where A height of the peak, approximately located at 20.3, 20, above the base line in chart divisions, B
SEDIMENTATION TEST Polymer powder (0.10 g.), as prepared, is dried, comminuted to pass through a 20-mesh screen, and
placed in a dry test tube. To this added 10.0 ml. of a solution of lithium chloride (6.9% by weight) in tetramethylurea. The tube is stoppered and its contents subjected to mechanical agitation (the tube is rotated at 1 10 rpm about a diametrical axis through its mid-point for 24 hours at 21C.). The tube is then allowed to stand-upright for a further 24 hours. After this time no polymer residue lies settled on the bottom of the tube.
SPIN STRETCH FACTOR merization, 1.20 ml. of benzoyl chloride (distilled) is added to the above-mentioned tetrahydrofuran.
where Vel ..of dope through spinneret Rate of pumping (cu. ft./min.l No. of spinneret holes x cross-sectional area of one hole (sq. ft.)
INl-IERENT VISCOSITY Inherent viscosity (ninh) is defined by the following equation:
ninh 1n ('qrel)/C wherein (nrel) represents the relative viscosity and (C) represents a concentration of 0.5 gram of the polymer in 100 ml. of solution. The relative viscosity (nrel) is determined by dividing the flow time in a capillary viscometer of a dilute solution of the polymer by the flow time for the pure solvent. The dilute solutions used herein for determining (nrel) are of the concentration expressed by (C), above; flow times are determined at 30C., using concentrated (95-98%) sulfuric acid as a solvent.
Fiber properties of tenacity, elongation, and initial modulus are coded as T/E/Mi and are reported in their conventional units. Denier is coded as Den. The boiling off treatment of fibers prior to physical testing consists of boiling the fibers 30 minutes in 0.1% aqueous sodium lauryl sulfate, rinsing, drying at 40C. for 1 hour, and conditioning at 21C. and 65% r.h. for 16 hours.
Tensile properties were determined on yarn samples which measured one inch (2.54 cm.) in length between the jaws of an Instron tester (product of the Instron Engineering Corp., Canton, Mass.) and which are subjected therein to a load sufficient to cause elongation to occur at the rate of 10% per minute measured at 21C. and 65% r.h.
The following nonlimiting examples are illustrative of the practice of the invention.
EXAMPLE I Polymer Preparation: A two-liter resin-making kettle equipped with a stirrer, nitrogen-inlet tube and calcium chloride drying tube is flamed with a Bunsen burner and simultaneously flushed with nitrogen. The kettle is sealed and placed in a dry-box, i.e., a chamber maintained under anhydrouos conditions. Hexamethylphosphoramide (520 ml., distilled from calcium hydride through a spinning band column at reduced pressure and stored over calcium hydride) is filtered in the drybox into a Erlenmeyer flask which is then sealed and cooled in ice. Tetrahydrofuran (75 ml., distilled and stored over sodium metal, water content less than 0.000l%) is filtered in the dry-box into an Erlenmeyer flask which is then sealed and cooled in ice. p- Aminobenzoyl chloride hydrochloride (124.0 g., 0.646 mole) is weighed out in the dry-box and transferred to the resin-kettle. The kettle is removed from the dry- 1 box, reconnected with the stirring motor and nitrogen The benzoyl chloride-tetrahydrofuran solution is poured, with moderate stirring, into the .paminobenzoyl chloride hydrochloride and the mixture is stirred for about 1 minute. The stirring rate is increased and the hexamethylphosphoramide is rapidly added. The resulting mixture is stirred for about 1 hour while being cooled in an ice bath. The mixture gradually gels as a result of this treatment. The cooling bath is removed and the polymeric mass is allowed to stand overnight at room temperature. The solid gel is then combined with water and stirred at high speeds in a gallon-size (3.785 liter) blender wherein it is converted to a fine, white powder. The polymer is washed 3 times with water and once with alcohol by means of stirring in a blender and filtration on a sintered-glass mediumpore Buchner funnel. The polymer is dried overnight in a vacuum oven at 90C. The yield of poly(pbenzamide) is 92.3% (ninh 1.35). The polymer had a peak height ratio of 0.78. When subjectedto the sedimentation test, no solid residue remained at the bottom of the tube.
Dope Preparation: Into a 700 ml. bottle equipped with an air-driven stirrer are placed 20 g. of the polymer and 180 g. of TMU/lithium chloride solution containing 6.5% by weight of the salt. The resulting mixture is stirred and 'heated to 150C. by means of an oil bath. There is obtained an extremely viscous gelatinous mass. This mixture is cooled in solid carbon dioxide for 1 hour. the mixture is then heated at 150C. for 4 hours with stirring, to procude a fluid, somewhat gelatinous hazy dope. The latter is cooled for 1 hour in solid carbon dioxide. The mixture is then stirred and heated for 4 hours at a temperataure of C. to produce a readily-spinnable haze dope which is subsequently cooled in solid carbon dioxide for 1 hour. This smooth, hazy dope flows slowly at room temperature and reflects light upon being stirred.
Fiber Preparation by Dry Spinning: The dope prepared as above is heated to 130C. and extruded at the rate of about 0.9 ml./min., under a pressure of 70 lb./ir1. (4,921 g.cm. through a heated (l40144C.) protrusion-type spinneret having 4 holes of 0.004 inch (0.01 cm.) diameter and a capillary length of 0.008 inch (0.02 cm.), into a drying column'whose wallsare I kept within the range of 202210C. The column is swept with a cocurrent flow (5 ft. /min.; 0.142 m. /min.) of dry nitrogen which enters the column at 265-270C. The emerging filaments, each of approximately 2 denier and having an oval cross-section, are passed over a small guide roll bearing a finish solution and are wound up on a-bobbin at the rate of about 200 yd./min. (183 m./min.). This constitutes a spin stretch factor of 6.58. The filaments do not stick and'are readily back-wound. These opaque exturded filaments become lustrous white upon being soaked in changes of water (25C.) to remove residual solvent and salt. The inherent viscosity of the polymer in the filaments is 1.32. The water-leached, air-dried (70F. 65(l93)% r.h.) filaments exhibit crystallinity and an orientation angle of 21. A yarn prepared from these filaments exhibits the following T/E/Mi/Den. values (32 filaments; non-boiled-off): 6.02/2.l7/431/58.5. Filaments that have been boiled off display the following T/E/Mi/Den. values: 4.75/l.38/429/l.72.
Heat Treatment of Fibers: The filaments or yarn prepared as above are passed taut over a 3-inch (7.62 cm.) plate maintained at 438C. in a single stage operation so as to increase their length by O-17r. Residence time over the hot plate was about seconds. The resulting fibers exhibit crystallinity and have an orientation angle of 13. Filaments have the following T/E/Mi/Den. properties (boiled off fiber): 7.66/l.2/599/1.87.
Other filaments prepared as above were subjected to heat treatments in both the relaxed and taut states. It was noted that the tensile properties of the filaments were improved.
The following Table l summarized improvements obtained in the tensile properties of water-leached, airdried undrawn poly(p-benzamide) fibers prepared similarly but not exactly as above. The fibers are given the indicated heat treatments in both the relaxed and taut stages for a 1 hour period. Contrasting data is shown for a control sample. All values shown are for boiling off filaments and are obtained after the filaments are returned to room conditions (70F., 65% r.h.).
TABLE 1 The above-described dope is dry-spun under the following conditions: spinneret adapter temperature. 120C.; pressure on dope 100 psi (7,031 g./cm. spinneret, 3 holes of 0.004 inch (0.01 cm.) diameter, each; spinneret temperature. 135140C.; column-wall temperature, 195203C.; wind-up speed, 200 yd./min. (183 m./min.). the speed stretch factor was 6.13. The yarn on bobbins is soaked in repeated changes of water at room temperature until essentially free of TMUv and lithium chloride.
The T/E/Mi/Den. values of the washed and boiled-off fiber are 7.16/2.l6/486/2.80, respectively. The fibers are crystalline and have an orientation angle of 16.
After passing the washed, dry fiber over a hot plate at 43 8C., the T/E/Mi/Den. values for a boiled-off sample of filaments are 10.7/1.7/695/2.82, respectively. The filaments are highly crystalline and exhibit an orientation angle of 12.
EXAMPLE Ill Into a 2-liter resin kettle are placed 153.6 g. (0.8 mole) of p-aminobenzoyl chloride hydrochloride with stirring under nitrogen. A 2% solution of lithium chloride in distilled TMU is prepared, heated at 60C. and topped under vacuum to remove any water which might be present. About 800 g. of this solution are added rapidly to the monomer powder in the resin kettle at 30C. while stirring. After about three-fourths of an hour, the first of three 4 ml. additions of diethylamine is made to stop the polymerization. The second 4 ml. are added 5 minutes later and the final 4 ml. are added 30 minutes after that. About 70 g. (0.946 mole) of lithium carbonate are added 18 minutes later. The
Post-treatment Tensile Properties Observed Treatment Relaxed Fiber Taut Fiber Sample Conditions T B Mi T E Mi A 200C. hot air oven 6.88 1.75 476 7.34 1.92 473 B 250C. hot air oven 7.38 1.67 491 7.45 1.72 456 C l98210C. glycerol bath 6.79 1.79 457 6.17 1.62 443 D 235-268C. Silicone-550 6.61 1.48 506 7.50 1.74 503 oil bath E Control T/F/Mi: 5.85/1 .69/426 Designation for a fluid. heat-stable silicone product of the Dow-Corning Corporation.
EXAMPLE I] This example illustrates the preparation of the poly(p-benzamide) fibers of the invention wherein a coupled process of polymer production and filament spinning is employed. It will be noted that the fiber properties are significantly enhanced after heat treatment.
In a 250 ml. round bottom flask (dried by flaming, filled with dry nitrogen, equipped with a stirrer, drying tube, and nitrogen inlet, and immersed in an ice-water bath) are combined 1 1.5 g. of p-aminobenzoyl chloride hydrochloride and 61 ml. of cold TMU. Immediately solution results. The mixture is stirred for 2 hours at approximately 0C. and for 16 hours at 26C. During this time the polymer separates as a swollen precipitate. Lithium hydroxide (2.87 g.) is added as an anhydrous powder and stirred in. There is considerable heat of neutralization and shortly thereafter a nearly clear, viscous dope of polymer containing now LiCl results, which at l00120C., has the required consistency for facile dry-spinning. (The inherent viscosity of an isolated polymer sample is 1.12. It has a peak height ratio of 0.73 and passes the sedimentation test.)
resulting viscoussmix is then heated in an oil bath at l 15-120C., diluted with 150 m1. of TMU and stirred under vacuum to distill off water formed in the neutralization and excess solvent. F inal polymer concentration is about 9%.
One portion of the mix is diluted in dimethylformamide/lithium chloride /5 and coagulated in water. The precipitated polymer is washed in distilled water three times and finally in acetone. It was then dried at 60C. under vacuum. It has an inherent viscosity of 0.97, a peak height ratio of 0.80, and when subjected to the sedimentation test, leaves no solid polymer residue at the bottom of the tube.
Fiber Preparation by Wet Spinning: The 9% dope as prepared above is pre filtered through a 200-mesh stainless steel screen to remove excess Li CO powder. Approximately 300 g. of the dope are then placed in a spinning cell, then filtered through a sand and screen filter pack before reaching the spinneret. The spinneret has holes, each having a diameter of 0.003 inch (0.076 mm.). They are arranged in three circles within a half-inch (1.27 cm.) diameter overall. The spinneret jets into a 65C. bath of distilled water which is continuously recirculated and filtered. The bathis also, continuously diluted with fresh water to prevent excessive build-up of salt and solvent in the bath. The yarn is drawn through a 135 cm. bath and over a 3.75 inch (9.53 cm.) diameter bobbin and wound up on a second 3.75 inch (9.53 cm.) bobbin. The spin stretch is controlled by varying the wind-up speed of the first bobbin. The minimum wind-up speed possible without yarn build-up in the bath is 32 ft./min. or 384 in./min. 16.26 cm./sec.). The calculated unextracted polymer solution jet velocity is 605 in./min. (25.61 cm./sec.). This indicates a lengthwise extraction shrinkage of 36.5% before wind-up. The optimum wind-up speed is found to be 540 in./min. (22.86 cm./sec.) and the maximum wind-up speed at which continuous spinning was possible was 635 in./min. (26.88 cm./sec.). These values correspond to spin stretch values of 1.4 and 1.65, respectively, based on the normalized value of 384 in. min. (16.26 cm./sec.) at spin stretch of 1.0. Based on jet velocity they are 0.893 and 1.05, respectively.
The as-spun yarn is soaked for 2 hours in water, then allowed to dry on the bobbins. The as-spun yarn has an orientation angle of 27 as determined by X-ray analysis. T/E/Mi/Den values for the as-spun yarn are 5.9/4.8/354/3.l (after boil-off).
The yarn is subsequently heat treated by drawing it over a 12-inch (0.03 m.) long grooved hot shoe at 30 ft./min. (15.24 cm./sec.) to give a 2 second contact time. A nitrogen blanket is maintained over the hot zone.
The wet-spun sample after various heat treatments has the following properties (boiled-off):
This example illustrates the effect of heat treatment on the tenacity and modulus of fibers of poly(1,4- benzamide) and preparation of a laminate from such fibers.
A 2-liter resin-making kettle is dried by flaming and allowing to cool in a nitrogen atmosphere. The kettle is fitted with an egg-beater-type alluminum stirrer and nitrogen inlet and outlet devices. While a slow current of dry nitrogen is passed through the kettle, it is charged with 150 g. of p-aminobenzoyl chloride hydrochloride. To this are added rapidily with vigouous stirring, 770 ml. of TMU, precooled to about -lC. (This solvent had previously been dried to a water content of less than 150 parts per million by distillation over calcium hydride). Considerable heat is evolved initially; this is absorbed by surrounding the kettle with an icebath for the intital minutes after reaction was started. After stirring the kettles contents for about 2 hours at about 21C., 38.0 g. of powdered, anhydrous lithium hydroxide is added and the stirred mixture is raised to a temperature of 120C. by external heating. The highly viscous, rubbery mixture becomes a more free-flowing spin dope as stirring at 120C. is continued for about 30 minutes. By distilling off about 50 ml. of solvent under a vacuum of about cm. of mercury, most of the water, introduced by reaction of lithium hydroxide, is removed. The spin dope contains 10.2% polymer content.
Approximately 5 g. of spin dope are added to 200 ml.
water in a Waring blender. After stirring this for 5 minrated polymer. A further 200 ml. water are added and stirring continued for a further 5 minutes. The treatment is repeated, using 200 ml. ethanol in place of the water. The polymer is filtered and dried for 15 hours at -80C. in a vacuum oven (20 -40 cm. of mercury) fitted with a nitrogen bleed. The polymer has an inherent viscosity of 1.38, a peak height ration of 0.76, and, under the conditions of the sedimentation test. leaves no polymeric residue on the bottom of the test tube after 48 hours.
Spinning: The above spin dope is dry spun as follows. From the spinning vessel, in which it was kept at 155C, the dope is expressed by a piston under a pressure of 68 lb./in. (4,780 g./cm. through a spinneret adapter (at C), then through a spinneret (at 160C.) The spinneret is of the protrusion type, consisting of nine effective holes, each of 0.004 in. (0.01 cm.) diameter. In the adapter the dope passes through a filter consisting of one 50 mesh screen, three 200 mesh screens, one cotton cloth of 2.4 oz./yd. (81.5 g./m. woven in a plain weave with 148 pics per inch and 160 ends per inch, and one table felt pad of 2.8 oz.- /yd. (95 g./m. and a density of 7.8 lbs/ft. (0.125 g./cm. at atmospheric pressure. The dope jets through the spinneret at a rate of 2.92 ml./min. into a cocurrent stream of nitrogen at a temperature of 235C., flowing at 5 it /min. (0.142 m. /min.), in a spinning cell with walls heated at 200C. The fibers issuing from the cell are passed through water and wound up at a rate of yd./min. (123.5 m./min.), (spin stretch factor is 3.2 The fiber is wound up at this rate for 1 hour. The yarn cake is then immersed in a large excess of distilled water at 21C. for 15 hours to extract salt and solvent. The wet cake is stored in a polyethylene bag. The as-spun and extracted yarn exhibits T/E/Mi/Den. 8.22/3.1/509/3.06, after being dried.
Extracted and dried yarn of the preceding preparation is passed through a hot stainless steel tube, 0.286 inch (7.26 mm.) inside diameter and 32 inches (81.3 cm.) in length, at 12 ft./min. (3.66 m./min.) under a nitrogen atmosphere without significantly changing its length. The nitrogen is passed through the tube from the yarn entry end at such a rate as to change the atmosphere in the tube once every minute. The tube is heated externally by a 12 inch (0.3 m.) long furnace which was controlled by a thermocouple braised to the external central surface of the pipe and connected to a Minneapolis-Honeywell Pyrovane controller. The nominal heat-treating temperature of the tube given in Table 111 is the temperature indicated by a thermocouple braised to the center of the inside of the tube. A profile of the temperature in the tube for a nominal temperature of 536C. obtained by varying the position of a test thermocouple is given in Table 11.
TABLE 11 TEMPERATURE PROFILE OF HEAT-TREATING TUBE Distance from Entrance 1n. (Multiply X 2.54 for distance in cm.) Temperature, C.
TABLE ll-Continued TEMPERATURE PROFILE OF HEAT-TREATING TUBE flange rests upon shims which are sized to leave a gap of 0.1 in. (0.254 cm.) between the plug and the bottom surface of the mold. The mold and its contents are pisim c?t fr; n E. |it r i}t-e placed in a Pasadena press, the platens of which have g f g Temperature Q been heated to 150C. The press is closed and a total 17 536 pressure of 1.5 tons (1.36 metric tons) is applied to the 13 537 mold. The mold is left in the press for 2.75 hr. before 39 being taken out and cooled to room temperature. 55 The ends of the laminate sample are cut off and hand 221 213 sanded. The sample measures 5.32 X 0.502 X 0.095 in. 32 184 (13.5 X 1.27 X 0.24 cm.), The tangent modulus of elasticity in flexure (i.e., flex modulus) of the sample is Properties of yarns treated at different temperatures measured having a 4 in. (10.16 cm.) long portion are given in Table ill. chosen in the middle of the laminate as the test section.
TABLE 111 Nominal Heat Trent. Fiber Fiber Orient. Peak Temp. Den. Ten. Elong. Mod. Den. lnh Angle Height Sample "C Fil. g/tl g/tl g/c1n.3 Vis Ratio 1 Room 3.060 8.22 3.1 509 141x 1.67 18 .63
Temp.
Preparation of a Laminate: Yarn from the preceding The sample is mounted as a supported beam with load spin is heat-treated by passing the yarn through a hot applied in the center in an lnstron testing machine. tube at a nominal temperature of 536C. and a speed The load member is deflected at the rate of 0.02 in./- of 11.58 ft./min. (3.53 m./min.). It is wound up on a min. (0.508 mm./min.) until a load of 20 lb. (9.07 kg.) bobbin of 4.13 in. (10.5 cm.) diameter as a thin cake 40 is applied. The flex modulus is found to be 14.41 X 10 approximately 1.5 in. (3.81 cm.) wide. The traversing lb./in. (10.13 X 10 g./cm. By comparison, commerrate at the wind-up is 1 stroke/11 revolutions; the yarn cial aluminum with a modulus of 10 to 20 X 10 filaments in the cake are nearly parallel. A test specilb./in. (70.3 to 140.6 X 10 g./cm. has a density of men of the yarn has Denier/T/E/Mi values of 2.56 g./cm. Laminates ofE glass have a theoretical 2,967 16.17 1 7 1096 modulus limit of 8 x 10 lb./in. (56.2 X 10 g./cm.'-") at A laminate is prepared from the above fiber as fola density of 2.22 g./cm. lows. A mixture consisting of 10 g. Epon 815 (Shells epoxy resin), 9 g. or Nadic (methyl anhydride curing EXAMPLE V agent Allied Chemical Corporation), and 0.1 g. of benzyldimethylamine is poured into a mold having a cavity Polymer Preparation: A 250-ml. round-bottomed with the following dimensions: length, 5.95 in.; width, fl sk q pp i h a stirrer, ni r g n inlet tube. n 5 i d h, ()9 i (152 x 1 27 x 2,29 Th calcium chloride drying tube is flamed with a Bunsen mold and its contents are placed in a vacuum chamber bruner and simultaneously flushed with nitrogen. The for 1 hour to remove gases. The mold is then removed y flask with its attachments is Placed in a y' and from the vacuum chamber. The fiber is cut from the 11-52 gof P-aminobenzoyl Chloride hydrochloride is bobbin and divided into ribbons 5.95 in. (15.2 cm.) add The flas s then tta d to a ng motor long) hi h are arranged i a stack i h h fib band nitrogen source and stirring and slow nitrogen flow stantially parallel to the long axis to the ribbon. The started while the flask is cooled in an ice bath. Cold fiber weighs 4.84 g. The fiber is placed on top of the TMU (58.7 ml.) is added quickly in a single portion. resin and gently pressed in, care being taken to pre- The monomer immediately dissolves and polymerizaserve the parallel orientation of the fibers. The mold tion starts. Stirring is continued for 2 hours with ice and its contents are returned to the vacuum chamber cooling and for 2 hours without cooling. The forming for a further 30 minutes for removal of unwanted polymer yields a viscous, somewhat hazy dope. Polygases. The mold is then taken from the vacuum chammer is isolated from a sample of the dope at 4 hours by her and a flanged plug, having dimensions of 5.75 X 0.5 precipitation in water and is found to have an inherent X 1.0 in. t 14.6 X 1.27 X 2.54 cm.), is pushed into the cavity and pressed slowly down upon the resin-fiber mix in order to allow bubbles and excess resin to find their way to the open spaces between the plug ends and viscosity of 1.38.
Fiber Preparation: A sample of polymer dope, prepared as described above but from a duplicate reaction mixture, is charged into a l5-ml., syringe-type cell havstructed of stainless steel. A -hole spinneret, having 0.003 in. (0.076 mm.) holes and constructed of a platinum alloy, is attached to the syringe by a ring-nut over a simple filter pack consisting of a 200-mesh stainless steel screen, a thin layer of fine glass wool and then 50- mesh, 200-mesh, and 50-mesh screens in succession. The dope is extruded at a slow rate into a water bath kept at about 50C. and the fibers are collected on a bobbin at a speed of 61 ft./ min. (18.6 m./min.) after traveling in the bath for about 3 ft. (0.91 m.). The fibers have the following properties:
The polymer of the as-spun fiber has an ninh of 1.12 and a peak height ratio of 0.78.
Some of the dopes used in this invention may be further characterized by their microscopic birefringent qualities which are manifested by their effect on planepolarized light. Such an observation may be made by the following method. A drop taken from the interior of a dope sample of this invention. is put on a dry, clean strain-free glass slide; a square cover of glass, sup ported on one edge by a glass tube or wire of known thickness (1.3 mm. diameter is convenient) is pressed down on the drop so as to form the roof of a liquid wedge. The edges are sealed with a fast-drying binder avoiding actual contact with the dope. The sharp edge of the wedge is sealed by excess dope which is squeezed out. In the operation, common care should be taken to avoid evaporation, moisture uptake, excessive shearing actions, dirt, and any suspended solid particles.
The wedge is positioned in a light beam, on a micro scope stage between crossed polarizer and analyzer, so that the thickness of the center of the layer of dope through which the light beam passes is 80;.t in thickness. The intensity is measured with polarizer and analyzer crossed (1 (superscript s to denote sample present in wedge) and with analyzer removed (L and the difference I L, is obtained. The transmitted light may be measured by conventional light sensitive detectors (e.g. by photo miltipliers, selenium or cadmium light meters, bolometers, etc.). The same measurements are then made on a similarly constructed wedge containing air, and the difference L" I (superscript c for control) is recorded. When these dopes of this invention are placed in the wedge, the expression (If I (I 31 1 will be greater than zero, and greater than can be accounted for by experimental error. It represents the increase in light transmittance through the analyzer due to the presence of the sample. The magnitude of (If 1 -(l 1 will vary with the solvent being used, polymer concentration, and concentration of dissolved salt, and the units in which light intensity is measured.
EXAMPLE VI The results presented in the following Table V illustrate the effects of using various chain terminators, with and without added lithium hydroxide monohy- 16 drate, in preparing the po1y(p-benzamide) used in this invention. Data for two control runs are also presented. In each of these polymerizations, 200 ml. of TMU are placed in an ice-cooled glass reaction vessel and 0.0025 mole of the designated terminator is added thereto. To these ingredients are added 32 g. (0.17 mole) of paminobenzoyl chloride hydrochloride. The contents of the reaction vessel are stirred for 15 minutes, after which the cooling bath is removed and the contents stirred for another 1.75 hour. Lithium hydroxide monohydrate 12.8 g., 0.31 mole) is added to the vessel and the contents are stirred for 30-60 minutes at autogenous temperature. The reaction mixture is then permitted to stand for 20 hours at autogenous temperature before being agitated with water in a blender to precipitate the polymer. The latter is collected, washed three times with water and once with 28 alchol (all done in a blender), and dried in a vacuum oven. The particular terminator employed, the polymers viscosity, and pres- *Added 1 hr. after monomer addition instead of 2 hr. later.
EXAMPLE VII This example illustrates that some dopes used in this invention cause an increase in the transmittance of light through crossed polarizers.
In this example, the apparatus by which the anisotropic character of these dopes is determined consists essentially of an A. 0. Spencer Orthoscope llluminator which contains a tungsten overvoltage microscope lamp (color temperature 3800K.), an optical wedge containing the sample, an optical wedge containing air, a Bausch and Lomb Polarizing Microscope having a Leitz 10X objective and a Leitz 10X ocular Peripian, a Polaroid M 3 Industrial Land Camera and a Gossen Sinarsix exposure meter. The wedge containing the sample is prepared as previously described and is positioned on the microscope stage (i.e., between the polarizer and the analyzer) to provide a sample layer of 80,u.thickness in the path of any light which reaches the analyzer and the light meter. The polarizer and the analyzer are adjusted to provide 90 crossed polarization planes. Light from the lamp which passes the analyzer by the route previously described is projected into the.
camera and is measured in the image plane (at the ground glass level) by the exposure meter (1 The same measurement is made with the analyzer removed (L This is repeated with the control wedge of air M. thick to give 1 and L The light readings from the Sinarsix exposure meter may be converted to light intensities by multiplying them by 0.301 (i.e. by log 2) and then determining the antilog of this product. These I I values are designated IQ" l3" 1 and L" Y v The expression l,.' /l is the ratio of light intensities transmitted by the dope being examined. The ratio I /I is the ratio of light transmitted by the control wedge. The difference (lfi' /l (L,""
/l represents the increase in intensity of light transmitted due to the presence in the wedge of the dope being examined.
Since the theoretical maximum value of 13" /l I," /I 0.5 an index of the increase of light transmittance may be conveniently taken asv 2(l /l IL" X 100 since in this way,
End Uses: The fibers are excellent for reinforced plastic laminates because of their high modulus. low density. high dimensional stability, high strength, high thermal stability and high flexural rigidity at a given laminate weight. Specific end-uses mayinclude spiral 18 I TABLE VI LIGHT DEPOLARlZATlON BY POLY(p-BENZAMIDE Poly( p-benzamide weight Percent In Dope ninh Wgt. 71 Salt wound pressure vessels, skis, bows, fishing rods, and
golf club shafts.
The high modulus, high strength, fatigue resistance I and impact strength of the fibers render them useful in mechanicalrubber goods such as belts.
The fibers are useful in sewing thread. and in uses such as protective clothing, laundry press covers, filtration fabrics, industrial hose, dryer felts, all of which utilize the high thermal stability of the fiber.
What is claimed is:
1. A method for increasing the initial modulus and reducing the orientation angle of undrawn fibers consisting essentially of poly(p-benzamide having an orientation angle of up to about 55 comprising heating the undrawn fibers at a temperature of at least 350C.
While under tension or, while relaxed.

Claims (1)

1. A METHOD FOR INCREASING THE INITIAL MODULUS AND READUCING THE ORIENTATION ANGLE OF UNDRAWN FIBERS CONSISTING ESSENTIALLY OF POLY(P-BENZAMIDE HAVING AN ORIENTATION ANGLE OF UP TO ABOUT 55* COMPRISING HEATING THE UNDRAWN FIBERS AT A TEMPERATURE OF AT LEAST 350*C. WHILE UNDER TENSION OR, WHILE RELAXED.
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US4021209A (en) * 1975-07-23 1977-05-03 Federal-Mogul Corporation Aramid fiber reinforced abrasive wheel
US4082731A (en) * 1973-02-12 1978-04-04 Avtex Fibers Inc. Method for producing a high modulus polyester yarn
US4183895A (en) * 1975-04-29 1980-01-15 E. I. Du Pont De Nemours And Company Process for treating anisotropic melt-forming polymeric products
US4224271A (en) * 1975-11-25 1980-09-23 Tse Woon W Process for biconstituent polymer compositions
US4247514A (en) * 1975-05-05 1981-01-27 E. I. Du Pont De Nemours And Company Process for strengthening a shaped article of a polyester
EP0050854A1 (en) * 1980-10-27 1982-05-05 Hitachi, Ltd. Composite fibrous product
US4749071A (en) * 1982-04-22 1988-06-07 Tayco Developments, Inc. Fluid energy absorber device with composite plastic casing
US4987215A (en) * 1988-10-18 1991-01-22 Hoechst Aktiengesellschaft Wholly aromatic polyamide, process for preparing same and structure thereof.
US4987217A (en) * 1988-10-18 1991-01-22 Hoechst Aktiengesellschaft Wholly aromatic polyamide
WO1992019804A1 (en) * 1991-04-26 1992-11-12 E.I. Du Pont De Nemours And Company Tension-free heat-treatment of aramid fiber and fibrids
US5243021A (en) * 1991-07-17 1993-09-07 Lever Brothers Company, Division Of Conopco, Inc. Water-dispersible copolymer containing UVA and UVB light-absorbing monomers
US5330672A (en) * 1991-07-17 1994-07-19 Lever Brothers Company, Division Of Conopco, Inc. Fabric care composition comprising water soluble or water-dispersible copolymer containing UV-absorbing monomer
US5466406A (en) * 1992-12-11 1995-11-14 United States Surgical Corporation Process of treating filaments
US20070056195A1 (en) * 2001-11-12 2007-03-15 Charles Schmeichel Snow plow having catch structure
WO2010009360A3 (en) * 2008-07-18 2010-04-22 Fields Thomas W Securing device
US9056656B2 (en) 2008-07-18 2015-06-16 Thomas W. Fields Mooring loop
US11597476B2 (en) 2020-08-25 2023-03-07 Thomas W. Fields Controlled failure point for a rope or mooring loop and method of use thereof

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US3595951A (en) * 1969-06-27 1971-07-27 Du Pont Process for spinning poly(p-benzamide)

Cited By (19)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4082731A (en) * 1973-02-12 1978-04-04 Avtex Fibers Inc. Method for producing a high modulus polyester yarn
US4183895A (en) * 1975-04-29 1980-01-15 E. I. Du Pont De Nemours And Company Process for treating anisotropic melt-forming polymeric products
US4247514A (en) * 1975-05-05 1981-01-27 E. I. Du Pont De Nemours And Company Process for strengthening a shaped article of a polyester
US4021209A (en) * 1975-07-23 1977-05-03 Federal-Mogul Corporation Aramid fiber reinforced abrasive wheel
US4224271A (en) * 1975-11-25 1980-09-23 Tse Woon W Process for biconstituent polymer compositions
EP0050854A1 (en) * 1980-10-27 1982-05-05 Hitachi, Ltd. Composite fibrous product
US4749071A (en) * 1982-04-22 1988-06-07 Tayco Developments, Inc. Fluid energy absorber device with composite plastic casing
US4987217A (en) * 1988-10-18 1991-01-22 Hoechst Aktiengesellschaft Wholly aromatic polyamide
US4987215A (en) * 1988-10-18 1991-01-22 Hoechst Aktiengesellschaft Wholly aromatic polyamide, process for preparing same and structure thereof.
WO1992019804A1 (en) * 1991-04-26 1992-11-12 E.I. Du Pont De Nemours And Company Tension-free heat-treatment of aramid fiber and fibrids
US5243021A (en) * 1991-07-17 1993-09-07 Lever Brothers Company, Division Of Conopco, Inc. Water-dispersible copolymer containing UVA and UVB light-absorbing monomers
US5330672A (en) * 1991-07-17 1994-07-19 Lever Brothers Company, Division Of Conopco, Inc. Fabric care composition comprising water soluble or water-dispersible copolymer containing UV-absorbing monomer
US5466406A (en) * 1992-12-11 1995-11-14 United States Surgical Corporation Process of treating filaments
US20070056195A1 (en) * 2001-11-12 2007-03-15 Charles Schmeichel Snow plow having catch structure
WO2010009360A3 (en) * 2008-07-18 2010-04-22 Fields Thomas W Securing device
US20110061519A1 (en) * 2008-07-18 2011-03-17 Fields Thomas W Securing Device
US8365646B2 (en) 2008-07-18 2013-02-05 Fields Thomas W Securing device
US9056656B2 (en) 2008-07-18 2015-06-16 Thomas W. Fields Mooring loop
US11597476B2 (en) 2020-08-25 2023-03-07 Thomas W. Fields Controlled failure point for a rope or mooring loop and method of use thereof

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