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Heat resistance, fibers

In other areas, POD has been used to improve the wear resistance of a mbber latex binder by incorporation of 25% of Oksalon fibers. Heat-resistant laminate films, made by coating a polyester film with POD, have been used as electrical insulators and show good resistance to abrasion and are capable of 126% elongation. In some instances, thin sheets of PODs have been used as mold release agents. For this appHcation a resin is placed between the two sheets of POD, which is then pressed in a mold, and the sheets simply peel off from the object and mold after the resin has cured. POD-based membranes exhibit salt rejection properties and hence find potential as reverse osmosis membranes in the purification of seawater. PODs have also been used in the manufacturing of electrophotographic plates as binders between the toner and plate. These improved binders produce sharper images than were possible before. [Pg.535]

Keywords Inorganic fiber Oxide fiber Silicon carbide fiber Heat resistance Photocatalyst... [Pg.117]

OTHER COMMENTS used in dye and dyestuff intermediates for hair, fur, leather, cotton, and synthetics used in accelerating vulcanization, as an antioxidant, and stabilizer used in the preparation of antioxidants for petroleum fuels also used in the preparation of grease thickeners, electrical insulators, and rust removers useful as a catalyst and as an analytical reagent use in preparation of epoxy resins, synthetic fibers, heat-resistant polymers, and coatings for leather, paper, and textiles. [Pg.831]

Modified epoxy - phenolic -glass fiber (heat resistant 5 x 10 epoxy)... [Pg.844]

Polyamide 11 30% glass fiber Heat-resistant components... [Pg.104]

Applications animal cages, chemical tubes, cosmetic caps and tubes, fibers, heat resistant nonwoven, LED molds, laboratory wares, mandrels and sheaths for rubber hose production, medical equipment, nanopatterned photonic materials, release film, release paper for synthetic leather, syringes, tubing ... [Pg.474]

Dimensional Stability. The wet heat resistance of PVA fiber is indicated by the wet softening temperature (WTS) at which the fiber shrinks to a specified ratio. At one time, the WTS was not more than 95°C for nonacetalized PVA fiber, but improvement of WTS has been achieved by improvement in heat-drawing and -treating techniques other methods proposed include suppression of polymerization temperature of vinyl acetate (36) and employment of alkafi spinning (37). [Pg.341]

Chemically Resistant Fibers. Fibers with exceUent chemical resistance to corrosive and/or chemical warfare agents or extreme pH conditions (eg, very acidic or very alkaline) were initially used for protective clothing. However, appHcations for filtration of gases and Hquids in numerous industrial faciHties are now the more important. For example, PPS is suitable for use in filter fabrics for coal-fired boilers because of its outstanding chemical and heat resistance to acidic flue gases and its exceUent durabUity under these end use conditions. Many high tenacity fibers are also chemically inert or relatively unaffected under a variety of conditions. Aramids, gel spun polyethylene, polypropylene, fluorocarbon, and carbon fibers meet these criteria and have been used or are being considered for appHcations where chemical resistance is important. [Pg.70]

In addition to carbon and glass fibers ia composites, aramid and polyimide fibers are also used ia conjunction with epoxy resias. Safety requirements by the U.S. Federal Aeronautics Administration (FAA) have led to the development of flame- and heat-resistant seals and stmctural components ia civiUan aircraft cabias. Wool blend fabrics containing aramids, poly(phenylene sulfide), EDF, and other inherently flame-resistant fibers and fabrics containing only these highly heat- and flame-resistant fibers are the types most frequently used ia these appHcations. [Pg.72]

In addition to aerospace uses, sihca fibers can be twisted into sewing threads and yams for weaving into fabrics. These fabrics are used extensively for heat-resistant clothing, flame curtains for furnace openings, thermocouple protection, and electrical insulation. The cloth can also be used to encapsulate other fibers to produce flexible sheets. [Pg.56]

Most processors of fiber-reinforced composites choose a phenol formaldehyde (phenoHc) resin because these resins are inherently fire retardant, are highly heat resistant, and are very low in cost. When exposed to flames they give off very Htde smoke and that smoke is of low immediate toxicity. PhenoHc resins (qv) are often not chosen, however, because the resole types have limited shelf stabiHty, both resole and novolac types release volatiles during their condensation cure, formaldehyde [50-00-0] emissions are possible during both handling and cure, and the polymers formed are brittle compared with other thermosetting resins. [Pg.19]

Ring Liners. Liners are either cellulose, which readily absorbs water, or ceramic, which does not absorb water or investment Uquid (123). Both are available in many si2es. Ceramic liners are made from fibers of alumino-siUcate glass derived from kaolin. The principal components in the glass are alumina, 47—65 wt %, and siUca, 35—50 wt %. Ceramic liners are highly heat resistant to 1300°C. Reports suggest that the fiber from ceramic ring liners may be a possible health risk (124). [Pg.478]

Compression and injection molding are used with amino resins to produce articles such as radio cabinets, buttons, and cover plates. Because melamine resins have lower water absorption and better chemical and heat resistance than urea resins, they are used to produce dinnerware and laminates used to cover furniture. Almost ah molded objects use fillers such as cellulose, asbestos, glass, wood flour, glass fiber and paper. The 1997 U.S. production of amino resins was 2.6 billion pounds. [Pg.349]

The high chemical stability of many polymers is both a blessing and a curse. Heat resistance, wear resistance, and long life are valuable characteristics of clothing fibers, bicycle helmets, underground pipes, food wrappers, and many other items. Yet when those items outlive their usefulness, disposal becomes a problem. [Pg.1218]

Fig. 6-14 specific modulus = modulus/density. Plastics include use of the heat-resistant TPs such as the polimides, polyamide-imide, and others. Table 6-21 provides data on the thermal properties of RPs. To date at least 80 wt % are glass fiber and about 60 wt% of those are polyester (TS) type RPs. [Pg.356]

Different materials can be used such as nylon, polyester (TS), and epoxy, but TS polyurethane (PUR) is predominantly used. Almost no other plastic has the range of properties of PUR. Modulus of elasticity range in bending is 200 to 1,400 MPa (29,000-203,000 psi) and heat resistance from 90 to over 200°C (122-392°F). The higher values are for chopped glass-fiber-reinforced RIM (RRIM). [Pg.528]

See other pages where Heat resistance, fibers is mentioned: [Pg.99]    [Pg.5240]    [Pg.844]    [Pg.844]    [Pg.99]    [Pg.5240]    [Pg.844]    [Pg.844]    [Pg.232]    [Pg.285]    [Pg.310]    [Pg.535]    [Pg.65]    [Pg.70]    [Pg.304]    [Pg.307]    [Pg.86]    [Pg.143]    [Pg.253]    [Pg.342]    [Pg.355]    [Pg.194]    [Pg.208]    [Pg.331]    [Pg.333]    [Pg.301]    [Pg.30]    [Pg.132]    [Pg.182]    [Pg.1236]    [Pg.432]    [Pg.578]    [Pg.87]    [Pg.18]    [Pg.26]   
See also in sourсe #XX -- [ Pg.109 ]



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