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Textile blends

Rabbit or coney textile blends Australia, domesticated all over the world... [Pg.493]

Part of the preliminary examination of textile blends consists of dissolving out one fibre component and examining the residual fibre to see which fibre components are damaged. The following methods of separation have proved useful ... [Pg.151]

Importantly, fibres are commonly blended together in order to give fabric more desirable qualities appropriate for apparel applications. For example, cotton and polyester blends have the breathability and wearability of cotton but will crease less and so require less pressing. A smaU percentage of petrochemical-based fibre elastane is often blended with other fibres for added stretch in both wovens and knits. This wide variety of fibres and fibre blends used in textiles for apparel makes effective recycling difficult due to the complexity of separating and sorting constituent fibres from textile blends. [Pg.105]

Methods of biological utilisation of polyester/cellulose textile blends are based exclusively on the application of cellulolytic enzymes, like cellulases, catalysing the hydrolytic degradation of cellulose to a sugar mixture like glucose or ceUobiose. The recovered polyester components were tested to be recycled in the melt process. ... [Pg.112]

This is grown mainly for the fibres in the stem which are present as long bundles around a woody core. Traditionally, flax has been grown for the linen market (long fibre) whereas UK-produced fibre is classified as short fibre and is used for textile blends and for industrial markets. There has been an increased interest in both long and short fibre as a natural product with a low carbon footprint compared with imported material. [Pg.349]

The elongation of a stretched fiber is best described as a combination of instantaneous extension and a time-dependent extension or creep. This viscoelastic behavior is common to many textile fibers, including acetate. Conversely, recovery of viscoelastic fibers is typically described as a combination of immediate elastic recovery, delayed recovery, and permanent set or secondary creep. The permanent set is the residual extension that is not recoverable. These three components of recovery for acetate are given in Table 1 (4). The elastic recovery of acetate fibers alone and in blends has also been reported (5). In textile processing strains of more than 10% are avoided in order to produce a fabric of acceptable dimensional or shape stabiUty. [Pg.292]

Since the early 1980s, the viscose-based staple fibers have, like the cuprammonium and viscose filament yams in the 1970s, ceased to be commodities. They have been repositioned from the low cost textile fibers that were used in a myriad of appUcations regardless of suitabUity, to premium priced fashion fibers dehvering comfort, texture, and attractive colors in ways hard to achieve with other synthetics. They are stiU widely used in blends with polyester and cotton to add value, where in the 1980s they would have been added to reduce costs. [Pg.354]

Usage of phosphoms-based flame retardants for 1994 in the United States has been projected to be 150 million (168). The largest volume use maybe in plasticized vinyl. Other use areas for phosphoms flame retardants are flexible urethane foams, polyester resins and other thermoset resins, adhesives, textiles, polycarbonate—ABS blends, and some other thermoplastics. Development efforts are well advanced to find appHcations for phosphoms flame retardants, especially ammonium polyphosphate combinations, in polyolefins, and red phosphoms in nylons. Interest is strong in finding phosphoms-based alternatives to those halogen-containing systems which have encountered environmental opposition, especially in Europe. [Pg.481]

THPOH—Ammonia—Tris Finish. By far the most effective finish for polyester—cotton textiles was a system based on the THPOH—NH treatment of the cotton component either foUowed or preceded by the appUcation of Tris finish to the polyester component. This combined treatment appeared to be effective on almost any polyester—cotton blend. A large amount of fabric treated in this way was sold throughout the United States and much of the rest of the world. Shortly after the introduction of Tris finishing, Tris was found to be a carcinogen. Most of the Tris treated production was in children s sleepwear, and this created a situation in which almost aU chemical fire-retardant-treated textiles were unfairly condemned as dangerous. Manufacturers mshed to replace chemically treated textiles with products produced from inherently flame-resistant fibers. Nowhere was the impact more severe than in the children s sleepwear market. New, safer materials have been introduced to replace Tris. Thus far none has been as completely effective. [Pg.491]

Phosphonium Salt—Urea Precondensate. A combination approach for producing flame-retardant cotton-synthetic blends has been developed based on the use of a phosphonium salt—urea precondensate (145). The precondensate is appUed to the blend fabric from aqueous solution. The fabric is dried, cured with ammonia gas, and then oxidized. This forms a flame-resistant polymer on and in the cotton fibers of the component. The synthetic component is then treated with either a cycUc phosphonate ester such as Antiblaze 19/ 19T, or hexabromocyclododecane. The result is a blended textile with good flame resistance. Another patent has appeared in which various modifications of the original process have been claimed (146). Although a few finishers have begun to use this process on blended textiles, it is too early to judge its impact on the industry. [Pg.491]

In conjunction with the increased use of synthetic fibers and blends of synthetic and natural fibers, and the modernisation of appHcation processes which has taken place simultaneously, the technique of textile whitening has been improved considerably. [Pg.119]

Solvents for A-type inks are aUphatic hydrocarbons, for example, hexane, textile spidts, Apco Thinner, lactane, VM P (varnish makers and painters ) naphtha, and mineral spirits. Aromatic hydrocarbons such as toluene and xylene are solvents for B-type inks. Generally, a blend of aUphatic and aromatic hydrocarbons is commonly used for this type of ink. [Pg.252]

Typical textile fibers used, for example, in a needle-punched filter fabric, are a blend of 3.3- and 6.6-dtex (3- and 6-denier) polyester staple. These fibers are - 5 cm long, have diameters ranging from 18 to 25 pm, mass-per-unit-length or linear density values ranging from - 350 to 650 mg per 1000 m, and length-to-width ratios in the order of 1000 to 1. [Pg.147]

Textile Flame Retardants. The first known commercial appHcation for phosphine derivatives was as a durable textile flame retardant for cotton and cotton—polyester blends. The compounds are tetrakis(hydroxymethyl)phosphonium salts (10) which are prepared by the acid-cataly2ed addition of phosphine to formaldehyde. The reaction proceeds ia two stages. Initially, the iatermediate tris(hydroxymethyl)phosphine [2767-80-8] is formed. [Pg.319]

Sulfur dyes are used mainly for dyeing textile ceUulosic materials or blends of ceUulosic fibers (qv) with synthetic fibers such as acryUc fibers, polyamides (nylons), and polyesters. They are also used for sHk (qv) and paper (qv) in limited quantities for specific appHcations. Solubilized sulfur dyes are used on certain types of leathers (qv). [Pg.162]

The sulfur dyes are widely used in piece dyeing of traditionally woven cotton goods such as drill and corduroy fabrics (see Textiles). The ceUulosic portion of polyester—cotton and polyester—viscose blends is dyed with sulfur dyes. Their fastness matches that of the disperse dyes on the polyester portion, especiaUy when it is taken into account that these fabrics are generaUy given a resin finish. [Pg.172]

There is no question that the bane of textile chemists in the area of cross-linking for smooth-dry performance is the loss of abrasion resistance. This has been a continuing problem when durable press is pushed to high levels of performance. Numerous approaches to this problem have been explored (32). However, the simplest solution has been to blend cotton with synthetic fibers. A 50—50 cotton—polyester fabric can have exceUent smooth-dry performance and yet be able to endure numerous launderings. [Pg.443]

M. A. White, iu Proceedings of a Conference on Recent Developments in Wool and Wool Blend Processing CSIRO Division of Textile Industry, Geelong,... [Pg.356]

See other pages where Textile blends is mentioned: [Pg.106]    [Pg.1030]    [Pg.5]    [Pg.131]    [Pg.132]    [Pg.2600]    [Pg.2815]    [Pg.106]    [Pg.1030]    [Pg.5]    [Pg.131]    [Pg.132]    [Pg.2600]    [Pg.2815]    [Pg.432]    [Pg.265]    [Pg.265]    [Pg.345]    [Pg.486]    [Pg.73]    [Pg.481]    [Pg.303]    [Pg.192]    [Pg.57]    [Pg.438]    [Pg.439]    [Pg.453]    [Pg.460]    [Pg.487]    [Pg.289]    [Pg.295]    [Pg.447]    [Pg.150]    [Pg.521]    [Pg.295]    [Pg.296]    [Pg.298]   


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