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Polymeric materials oxygen

The limiting oxygen index of Tefzel as measured by the candle test (ASTM D2863) is 30%. Tefzel is rated 94 V-0 by Underwriters Laboratories, Inc., in their burning test classification for polymeric materials. As a fuel, it has a comparatively low rating. Its heat of combustion is 13.7 MJ/kg (32,500 kcal/kg) compared to 14.9 MJ /kg (35,000 kcal/kg) for poly(vinyHdene fluoride) and 46.5 MJ /kg (110,000 kcal/kg) for polyethylene. [Pg.370]

Initiation. Free-radical initiators are produced by several processes. The high temperatures and shearing stresses required for compounding, extmsion, and molding of polymeric materials can produce alkyl radicals by homolytic chain cleavage. Oxidatively sensitive substrates can react directly with oxygen, particularly at elevated temperatures, to yield radicals. [Pg.222]

Silicone—Fluorosilicone Lenses. Sdicone mbber has long been considered a unique contact lens material (55), and the development of sdicone mbber lenses has been reviewed in earHer editions of the Eniyclopedia. The oxygen permeabdity of sdicone mbber, >300 barrers, is virtually unsurpassed by any other polymeric material considered for contact lens appHcations. [Pg.105]

Cross-hnking efficiency of a polymeric material also depends whether the irradiation is carried out in the presence or absence of air, e.g., oxygen has been found to increase the... [Pg.862]

EB irradiation of polymeric materials leads to superior properties than the 7-ray-induced modification due to the latter having lower achievable dose rate than the former. Because of the lower dose rate, oxygen has an opportunity to diffuse into the polymer and react with the free radicals generated thus causing the greater amount of chain scissions. EB radiation is so rapid that there is insufficient time for any significant amount of oxygen to diffuse into the polymer. Stabilizers (antirads) reduce the dose-rate effect [74]. Their effectiveness depends on the abUity to survive irradiation and then to act as an antioxidant in the absence of radiation. [Pg.863]

Various polymeric materials were tested statically with both gaseous and liquefied mixtures of fluorine and oxygen containing from 50 to 100% of the former. The materials which burned or reacted violently were phenol-formaldehyde resins (Bakelite) polyacrylonitrile-butadiene (Buna N) polyamides (Nylon) polychloroprene (Neoprene) polyethylene polytriflu-oropropylmethylsiloxane (LS63) polyvinyl chloride-vinyl acetate (Tygan) polyvinylidene fluoride-hexafluoropropylene (Viton) polyurethane foam. Under dynamic conditions of flow and pressure, the more resistant materials which binned were chlorinated polyethylenes, polymethyl methacrylate (Perspex) polytetraflu-oroethylene (Teflon). [Pg.1519]

Some bead materials possess porous structure and, therefore, have very high surface to volume ratio. The examples include silica-gel, controlled pore glass, and zeolite beads. These inorganic materials are made use of to design gas sensors. Indicators are usually adsorbed on the surface and the beads are then dispersed in a permeation-selective membrane (usually silicone rubbers). Such sensors possess high sensitivity to oxygen and a fast response in the gas phase but can be rather slow in the aqueous phase since the gas contained in the pores needs to be exchanged. Porous polymeric materials are rarer and have not been used so far in optical nanosensors. [Pg.203]

Similarly to bulk oxygen sensors, optical nanosensors rely on dynamic quenching of luminescence. Numerous indicators and polymeric materials were found suitable... [Pg.207]

Using UV-visible and IR spectroscopies, thermal analyses and scanning electron microscopes measurements, Young and Slemp studied the performance of several polymeric materials after exposure to an outer-space environment . PEN exhibited good environmental resistance to the oxygen-induced erosion, UV-induced degradation and spacecraft-induced contamination in such an environment [33],... [Pg.346]

These Ionic reactions or electron transfer reactions are not what generally occur in the structure of both natural and synthetic polymers. In polymers it is the covalent bond that dominates, and in a covalently bonded structure there is no transfer of electrons from one atom to another. Instead the electrons are shared between the adjacent atoms In the molecule. The commercial polymeric materials that will be covered In this text will generally be based on seven atomic species silicon, hydrogen, chlorine, carbon, oxygen, nitrogen, and sulfur. Figure 2.4 shows these atoms with the number of outer valance electrons. [Pg.30]

Polymeric materials that act as fuels and oxidizers are composed of nitrogen, oxygen, carbon, and hydrogen atoms. The hydrocarbon structures act as fuel components, and the oxidizer fragments, such as -C-NOj, -O-NOj, -O-NO, or -N-NO2, are attached to the hydrocarbon structures through covalent chemical bonds. [Pg.77]

See other pages where Polymeric materials oxygen is mentioned: [Pg.314]    [Pg.502]    [Pg.155]    [Pg.323]    [Pg.436]    [Pg.640]    [Pg.488]    [Pg.490]    [Pg.205]    [Pg.34]    [Pg.75]    [Pg.49]    [Pg.122]    [Pg.166]    [Pg.274]    [Pg.343]    [Pg.51]    [Pg.66]    [Pg.263]    [Pg.1519]    [Pg.501]    [Pg.227]    [Pg.213]    [Pg.266]    [Pg.401]    [Pg.239]    [Pg.277]    [Pg.50]    [Pg.301]    [Pg.47]    [Pg.47]    [Pg.78]    [Pg.36]    [Pg.197]    [Pg.3]    [Pg.164]    [Pg.82]    [Pg.95]   
See also in sourсe #XX -- [ Pg.319 ]



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Materials polymerization

Oxygen polymerization

Polymeric materials

Polymerized materials

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