Classifications

• • D—TEXTILES; PAPER
  • D04—BRAIDING; LACE-MAKING; KNITTING; TRIMMINGS; NON-WOVEN FABRICS
  • D04H—MAKING TEXTILE FABRICS, e.g. FROM FIBRES OR FILAMENTARY MATERIAL; FABRICS MADE BY SUCH PROCESSES OR APPARATUS, e.g. FELTS, NON-WOVEN FABRICS; COTTON-WOOL; WADDING ; NON-WOVEN FABRICS FROM STAPLE FIBRES, FILAMENTS OR YARNS, BONDED WITH AT LEAST ONE WEB-LIKE MATERIAL DURING THEIR CONSOLIDATION
  • D04H1/00—Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres
  • D04H1/40—Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres from fleeces or layers composed of fibres without existing or potential cohesive properties
  • D04H1/54—Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres from fleeces or layers composed of fibres without existing or potential cohesive properties by welding together the fibres, e.g. by partially melting or dissolving

Definitions

• This invention relates to a process for producing a nonwoven fabric in which highly shrinkable polyvinyl alcohol fibers capable of absorbing water to shrink (hereinafter such fibers being referred to as "shirinkable PVA fibers”) are essential constituent fibers.
• shirinkable PVA fibers highly shrinkable polyvinyl alcohol fibers capable of absorbing water to shrink
• Wipers so far used are mainly made of sponges (e.g. foamed polyvinyl formal) or nonwoven fabrics consisting of natural or synthetic fibers.
• sponges e.g. foamed polyvinyl formal
• nonwoven fabrics consisting of natural or synthetic fibers.
• a binder such as a polyacrylate compound or a styrene-butadiene copolymer so that the falling off of fibers from the nonwoven fabrics upon use thereof (friction between them and metals, plastics, chinaware, human skin, etc.) can be prevented.
• the invention provides a process for producing nonwoven fabrics suited for use as wipers which comprises first causing a nonwoven fabric containing, as essential constituent fibers, 60-90 weight percent of highly shrinkable polyvinyl alcohol fibers capable of absorbing water to shrink of which a maximum shrinking temperature in water is within the range of 65-90°C with a maximum shrinkage percentage of not less than 50 percent and 10-40 weight percent of binder fibers having a melting point not higher than 200°C to shrink by warm water treatment to an extent such that the areal reduction amounts to 35-65 percent and further melting the binder fiber surface by heating.
• a first constituent element of the invention consists in that shrinkable PVA fibers are used as main nonwoven fabric-constituting fibers and further in that the nonwoven fabric is caused to shrink by warm water treatment to an extent such that the areal reduction amounts to 35-65 percent.
• a second constituent element of the invention lies in that thermoplastic fibers having a fiber surface melting point not higher than 200°C (hereinafter such fibers being referred to as "binder fibers”) are incorporated in an amount of 10-40 percent into said nonwoven fabric. Said binder fibers, when heated, are partly melted and serve to bond the main component fibers, namely shrinkable PVA fibers, firmly.
• a further characteristic feature of the invention lies in that the nonwoven fabric is improved in wear resistance by applying to said nonwoven fabric a thermoplastic resin mainly consisting of a urethane resin, in an amount of 2-30 percent (resin solid weight/fiber weight).
• the main component fibers constituting the nonwoven fabric are shrinkable PVA fibers and account for 60-90 percent by weight based on the whole web.
• Typical examples of the "shrinkable PVA fibers" as referred to herein are fibers obtained by wet spinning using an aqueous solution of polyvinyl alcohol having a degree of polymerization of 1,200-3,000 and a degree of saponification of not less than 98 mole percent, drawing the resulting continuous fibers at a rate of at least 4:1 in an atmosphere maintained within a temperature range not higher than 130°C in a condition such that said continuous fibers still contain moisture and salts and then heat-treating the continuous fibers in a taut condition so that the maximum shrinking temperature in water (temperature causing a maximum shrinkage of the continuous fibers in water) comes within the range of 65-90°C with a maximum shrinkage percentage of not less than 50 percent.
• PVA fiber species have been so far known. Those intended for general use all have the so-called hot water resistance, namely the maximum shrinking temperature thereof in water exceeds 90°C with a maximum shrinkage percentage of less than 50 percent. Some PVA fiber species for uses that utilize their ready water solubility generally have a maximum shrinking temperature lower than 60°C. With the PV A fiber species so far in general use, therefore, the maximum shrinking temperature in water is either lower than 60°C or higher than 90°C. As will be evident from comparison, the PVA fibers to be used in accordance with the invention are very particular and are quite distinct from the PVA fibers so far used generally in the fields of clothing, materials for industrial use, and so forth.
• the drawing ratio and the drawing and heat treatment temperatures As principal factors which determine the maximum shrinking temperature of PVA fibers in water and the maximum shrinkage percentage, there may be mentioned the drawing ratio and the drawing and heat treatment temperatures. Thus, for example, an increase in the drawing ratio will result in a higher maximum shrinking temperature. Raised drawing and heat treatment temperatures will give a decreased maximum shrinkage percentage and a higher maximum shrinking temperature. Therefore, a desired maximum shrinking temperature and a desired maximum shrinkage percentage can be obtained by varying the drawing ratio and the drawing and heat treatment conditions.
• the binder fibers having a fiber surface melting point of not higher than 200°C account for 10-40 percent by weight based on the web.
• fibers of modified polyester, polypropylene, polyethylene, ethylenepropylene copolymer, modified nylon, and other single polymers having a melting point not higher than 200°C may of course be the so-called core-sheath fibers the core or inside of which is made of a polymer having a melting point not lower than 200°C and the sheath or external layer of which is made of a polymer having a melting point not higher than 200°C.
• They may also be mix-spun fibers composed of a polymer blend containing not less than 50 percent of a polymer having a melting point not higher than 200°C.
• the shrinkable PVA fibers which are the main component fibers, when subjected alone to the shrinking treatment with warm water to be mentioned later herein, undergo pseudoadhesion of said PVA fibers with one another. This leads to hardening of the nonwoven fabric when this is dried. This hardening phenomenon can be prevented by the presence of said binder fibers. For the only purpose of preventing this hardening phenomenon, it would be sufficient to incorporate hydrophobic fibers (for example in an amount of not less than 20 percent) into the web.
• binder fibers having a melting point not higher than 200°C are very effective in increasing the strength of the nonwoven fabric, and preventing napping and falling off of the main component fibers on the occasion of practical use. These effects are produced by subjecting the shrinkable PVA fibers after shrinkage with warm water to heat treatment at a temperature not lower than the melting point of said binder fibers in the course of the subsequent process, to thereby cause the binder fibers to melt partially on the surface thereof and serve as bonding agents for the shrinkable PVA fibers.
• the use of such binder fibers is one of the most important constituent elements of the invention. It is of course possible to add a small amount of hydrophobic fibers which will not melt when the binder fibers are melted thermally.
• the web having such constitution as mentioned above be subjected to warm water treatment for causing shrinkage until the areal reduction amounts to 35-65 percent.
• the resulting nonwoven fabric does not show rubber-like elasticity in a wet condition, hence is unfit for the purpose of the invention.'
• the nonwoven fabric area is reduced to less than 35 percent of the original by warm water treatment, the nonwoven fabric has good rubber-like elasticity in a wet condition but, when dried, assumes a coarse and stiff feeling, hence is not suited for the uses intended by the inventors.
• the nonwoven fabric according to the invention that has been shrinked by warm water treatment to an areal reduction of 35-65 percent has good rubber-like elasticity in a wet condition and shows a soft feeling in a dry condition. Repeated wetting and drying cycles cause little change in its feeling.
• the nonwoven fabric after warm water treatment and binder fiber-melting treatment can be used, as it is or after drying, as a wiper, such as a kitchen napkin, table napkin, automobile wiper, furniture wiper or toilet article, and can function satisfactorily as a product ready for use.
• a wiper such as a kitchen napkin, table napkin, automobile wiper, furniture wiper or toilet article
• the resin to be used in said resin treatment should not impair the feeling (flexibility) of the nonwoven fabric itself but can preferably provide the nonwoven fabric with wear resistance and prevent napping of the nonwoven fabric or falling off of fibers.
• the most suitable example of said resin is a urethane resin because of its good adhesiveness to shrinkable PVA fibers.
• Treatment with a urethane resin can be conducted either by the so-called dry coagulation technique which comprises dipping the nonwoven fabric in or coating the same with a solution of a solvent-type or water-dispersible or water-soluble urethane resin, followed by drying, or by the so-called wet coagulation technique which comprises dipping the nonwoven fabric in or coating the same with a solution of a solvent-type urethane resin and then immersing the same in water for extraction of the solvent to thereby cause coagulation of the urethane resin and formation of a porous structure simultaneously.
• dry coagulation technique which comprises dipping the nonwoven fabric in or coating the same with a solution of a solvent-type or water-dispersible or water-soluble urethane resin, followed by drying
• wet coagulation technique which comprises dipping the nonwoven fabric in or coating the same with a solution of a solvent-type urethane resin and then immersing the same in water for extraction of the solvent to thereby cause coagulation of the ure
• the amount of the urethane resin to be taken up by the nonwoven fabric should preferably be 2-30 percent (based on the fiber weight). An amount of less than 2 percent cannot produce wear resistance improving effect, whereas an amount of more than 30 percent hardens the nonwoven fabric and impairs the feeling thereof.
• this treatment and the above-mentioned shrinking treatment with warm water can rationally be conducted in one step by adjusting the temperature of the aqueous solution or dispersion.
• a finishing agent such as a surfactant or a silicone-based softening agent.
• the step of such active agent treatment may either be carried out as an independent step or be incorporated'into the step of shrinking treatment with warm water and simultaneous treatment with a urethane resin.
• the step of melting the surface of the binder fibers contained in the nonwoven fabric to thereby bonding the shrinkable PVA fibers, which are the main constituents of said nonwoven fabric, with the binder fibers is now described.
• the intended purpose can be attained as well by heat treatment in a hot air oven maintained at a temperature above the melting point of the binder fibers, it is preferable to pass the nonwoven fabric through a calender roll unit the roll surface of which is maintained at a temperature not lower than the melting point of the binder fibers, preferably at a temperature higher than said melting point by at least 20°C, so that the nonwoven fabric can be surface-finished smoothly with reduced surface unevenness.
• the surface appearance of the nonwoven fabric is determined by the ratio of the calender roll clearance to the thickness of the nonwoven-fabric. For obtaining a smooth surface appearance, it is preferable to adjust the calender roll clearance/nonwoven fabric thickness (before passage through the calender) ratio to 1/2 to 1/4.
• Continuous fibers were produced by the wet method by extruding an aqueous solution of PVA with a degree of polymerization of 1,700 and a degree of saponification of 99.9 mole percent into a saturated aqueous solution of Na 2 S0 4 , drawn, at a ratio of 4.5:1, in air at 40°C and in a saturated aqueous solution of Na 2 S0 4 at 90°C and then, in a constant length condition, dried with hot air at 130°C to attain an absolute dry condition and heat-treated in hot air at 180°C to give a maximum in-water shrinking temperature of 80°C.
• these continuous fibers were liable to marked swelling and shrinkage upon exposure to water, they, with a sufficient tension to maintain a constant length, were washed with water at 30°C to remove Na 2 S0 4 retained on fibers, subjected to wet treatment including oiling and, in a taut condition, dried at 80°C until the moisture content reached 40 percent based on the fibers and further in hot air at 120°C. After the subsequent crimping as required in manufacturing nonwoven fabrics, the continuous fibers were cut into staple fibers having a fineness of 1.5 denier and a length of 51 mm.
• a nonwoven fabric having a weight of 100 grams per square meter was produced by the random webber and needle-punching technique (200 punchings per square centimeter) using the shrinkable PVA fibers prepared as above and, as binder fibers, ES fibers (3 denier x 51 mm; produced by Chisso Corporation; core-sheath fibers, the surface portion being of low density polyethylene and the core portion being of polypropylene) in a mixing ratio of 80/20.
• the nonwoven fabric thus produced had a thickness of 2.Q mm.
• Nonwoven fabrics produced in the same manner as above were subjected to shrinking treatment by immersing in warm water at different temperatures for 1 minute to give nonwoven fabrics differing in shrinkage percentage.
• the nonwoven fabrics were then dried at 70°C for 10 minutes.
• a 10% aqueous dispersion of a urethane resin was applied, at ordinary temperature, to the above nonwoven fabrics to cause the urethane resin to be taken up by the fabrics in an amount of 10 percent on the solid (resin) weight/nonwoven fabric weight basis.
• the nonwoven fabric obtained showed good rubber-like elasticity in a wet condition but, once dried, became coarse and rigid as a result of pseudoadhesion among fibers; said fabric thus failed to achieve the expected results from the quality viewpoint.
• those nonwoven fabrics with 10 percent and 30 percent, respectively, of the binder fibers incorporated therein had satisfactorily good quality from both the wet rubber-like elasticity and dry feeling viewpoints.
• Nonwoven fabrics prepared by using the shrinkable PVA fibers produced in Example 1 and the same binder fibers (ES fibers) in a mixing ratio of 80/20 by weight were subjected to warm water shrinking treatment (areal reduction: 50 percent) and urethane resin treatment in the same manner as in Example 1, followed by an investigation as to the conditions of thermal melting of the binder fibers. The results of the investigation are shown in Table 3.
• the nonwoven fabric When the binder fibers were not heat-melted, the nonwoven fabric had very low tensile strength and no good wear resistance although it showed rubber-like elasticity when it was wet. Based on this finding, it is to be understood that thermal melting or binder fibers is a very important factor. When the binder fibers were melted in hot air, the resultant nonwoven fabric had a wavy surface, hence an unfavorable appearance, although it produced nonwoven fabric functions to a satisfactory extent. It is therefore preferable that when the binder fibers are heat-melted in hot air, the nonwoven fabric be again subjected to finishing treatment on a calender roll unit having a surface temperature not lower than the melting point of the binder fibers to thereby improve the appearance of the product nonwoven fabric.
• Needle-punched (200 punchings per square centimeter) nonwoven fabrics having a weight of 100 g/ m 2 were prepared by using the shrinkable PVA fibers and binder fibers (ES fibers) in a mixing ratio of 80/20 and subjected to warm water treatment for attaining an areal reduction of 50 percent in the same manner as in Example 1.
• the same water-dispersible polyurethane resin as mentioned in Example 1 was allowed to be taken up by the nonwoven fabrics in different amounts and the fabrics were then subjected to heat treatment for melting the binder fibers by calendering in the same manner as in Example 1. The results thus obtained are shown in Table 4.
• Example 1 For conducting the warm water treatment and urethane resin impregnation steps simultaneously, an aqueous urethane resin dispersion having a concentration of 10 percent was warmed to 63°C, and a needle-punched web as prepared by the procedure of Example 1 was immersed therein for 1 minute. The web was squeezed on a mangle until the amount of the solution contained in the web was 100 percent (per 100 weight parts of web), then dried at 70°C for 10 minutes, and passed through a calender roll unit having a surface temperature of 140°C in the same manner as in Example 1 to thereby cause melting and adhesion of the binder fibers. The performance characteristics of the resultant nonwoven fabric were comparable to those of sample No. 1-2 as shown in Example 1.
• a nonwoven fabric was produced following the procedure of Example 1 except that commercial Vinylon fibers (maximum shrinkage percentage: 10 percent; maximum shrinking temperature: 95°C) were used as the starting material PVA fibers and that the warm water treatment was conducted at 90°C, and impregnated with a urethane resin. In this case, the areal shrinkage percentage was 16 percent.
• the nonwoven fabric thus obtained showed no rubber-like elasticity in a wet condition at all and, furthermore, had a low water absorbency, hence was unsuited for use as a wiper.
• the warm water treatment temperature was raised to above 90°C, the Vinylon fibers began to melt and failed to give a nonwoven fabric suited for use as a wiper.
• a nonwoven fabric was produced following the procedure of Example 1 except that the so-called readily water-soluble Vinylon fibers with a maximum shrinkage percentage of 55 percent and a maximum shrinking temperature of 50°C were used as the starting PVA fibers, that the warm water treatment was performed at 30°C and that the drying was conducted at 40°C for 30 minutes. In this case, the areal shrinkage percentage was 72 percent.
• the nonwoven fabric obtained had a dry hardness of more than 30 cm, as measured by the cantilever method, and a very coarse and rigid feeling, and, therfore, was quite unsuited for use as a wiper.

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• Engineering & Computer Science (AREA)
• Textile Engineering (AREA)
• Nonwoven Fabrics (AREA)
• Cleaning Implements For Floors, Carpets, Furniture, Walls, And The Like (AREA)
• Treatments For Attaching Organic Compounds To Fibrous Goods (AREA)
• Silicates, Zeolites, And Molecular Sieves (AREA)

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Publications (2)

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• 1984
  • 1984-12-21 JP JP59271561A patent/JPS61152859A/ja active Granted
• 1985
  • 1985-11-19 EP EP85114714A patent/EP0187236A3/de not_active Withdrawn
  • 1985-12-17 NO NO855103A patent/NO855103L/no unknown

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