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Chemical resistance also

The chemical resistance also depends on the molecular weight and the hardness. [Pg.695]

In 1998, PTT was finally introduced to the market by Shell Chemicals under the trade name Corterra, since an economical process for the production of PDO had been developed. PTT fibers are commercially produced today by DuPont and Shell. PTT has special characteristics as a fiber. It is particularly interesting in carpet fibers, where it has shown outstanding resiliency and chemical resistance. Also, this polymer shows potential in the field of engineering thermoplastic polymers and fabrics. [Pg.422]

Inorganic Colored Pigments. Inorganic pigments do not have the brilliance of some of the organic ones, but they have the better weathering properties and good chemical resistance. Also, they can be low in cost. They are used in low concentrations lest they unfavorably influence the performance properties of the vulcanizates. [Pg.287]

Thermosetting polymers based on epoxy resins often display superior tensile strength and chemical resistance when compared with their thermoplastic counterparts. Such attributes make epoxy polymers ideal matrices for adhesives and composites. However the applicability of epoxy polymers as matrices for adhesives and composites are often limited by an inherent weakness - low flaw tolerance. Ironically, the same crosslinked chemical structure that imparts high strength and superior chemical resistance also promotes brittle behavior. [Pg.406]

FEP Copolymer of tetrafluoroethylenene and hexafluorpropen, which is a plastic-like material used in protective elothing because of its excellent chemical resistance. Also called Teflon-FEP . [Pg.237]

Nowadays lanthanum ferrites and chromiiun doped lantlianide aluminates with perovskite structure are used as ceramic pigments because they have colorimetric properties, high thermal stability, line particle size and chemical resistance. Also, the ferrites have interesting magnetic properties and the aluminates are materials having photoluminescence properties. [Pg.546]

Polybutylene exhibits high tear, impact, and puncture resistance. It also has low creep, excellent chemical resistance, and abrasion resistance with coilability. [Pg.1021]

An extensive new Section 10 is devoted to polymers, rubbers, fats, oils, and waxes. A discussion of polymers and rubbers is followed by the formulas and key properties of plastic materials. Eor each member and type of the plastic families there is a tabulation of their physical, electrical, mechanical, and thermal properties and characteristics. A similar treatment is accorded the various types of rubber materials. Chemical resistance and gas permeability constants are also given for rubbers and plastics. The section concludes with various constants of fats, oils, and waxes. [Pg.1287]

Bisphenol A. One mole of acetone condenses with two moles of phenol to form bisphenol A [80-05-07] which is used mainly in the production of polycarbonate and epoxy resins. Polycarbonates (qv) are high strength plastics used widely in automotive appHcations and appHances, multilayer containers, and housing appHcations. Epoxy resins (qv) are used in fiber-reinforced larninates, for encapsulating electronic components, and in advanced composites for aircraft—aerospace and automotive appHcations. Bisphenol A is also used for the production of corrosion- and chemical-resistant polyester resins, polysulfone resins, polyetherimide resins, and polyarylate resins. [Pg.99]

SAN resins possess many physical properties desked for thermoplastic appHcations. They are characteristically hard, rigid, and dimensionally stable with load bearing capabiHties. They are also transparent, have high heat distortion temperatures, possess exceUent gloss and chemical resistance, and adapt easily to conventional thermoplastic fabrication techniques (7). [Pg.191]

Polyimides (PI) were among the eadiest candidates in the field of thermally stable polymers. In addition to high temperature property retention, these materials also exhibit chemical resistance and relative ease of synthesis and use. This has led to numerous innovations in the chemistry of synthesis and cure mechanisms, stmcture variations, and ultimately products and appHcations. Polyimides (qv) are available as films, fibers, enamels or varnishes, adhesives, matrix resins for composites, and mol ding powders. They are used in numerous commercial and military aircraft as stmctural composites, eg, over a ton of polyimide film is presently used on the NASA shuttle orbiter. Work continues on these materials, including the more recent electronic apphcations. [Pg.530]

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]

Polymers. Ion implantation of polymers has resulted in substantial increases of electrical conductivity (140), surface hardness (141), and surface texturing (142). A four to five order of magnitude increase in the conductivity of polymers after implantation with 2 MeV Ar ions at dose levels ranging from 10 -10 ions/cm has been observed (140). The hardness of polycarbonate was increased to that of steel (141) when using 1 MeV Ar at dose levels between 10 -10 ions/cm. Conductivity, oxidation, and chemical resistance were also improved. Improvements in the adhesion of metallizations to Kapton and Teflon after implantation with argon has been noted (142). [Pg.398]

Pigments and Extenders. Pigments are selected for use in house paints based on thek appearance and performance quaUties. Appearance includes color and opacifying abiUty. Performance quaUties include ultraviolet light resistance, fade resistance, exterior weatherabiUty, chemical resistance, as well as particle size and shape. Toxicity profiles and safety and health related properties are also important criteria in pigment selection. [Pg.541]

In general, polycarbonate resins have fair chemical resistance to aqueous solutions of acids or bases, as well as to fats and oils. Chemical attack by amines or ammonium hydroxide occurs, however, and aUphatic and aromatic hydrocarbons promote crazing of stressed molded samples. Eor these reasons, care must be exercised in the choice of solvents for painting and coating operations. Eor sheet appHcations, polycarbonate is commonly coated with a sihcone—sihcate hardcoat which provides abrasion resistance as well as increased solvent resistance. Coated films are also available. [Pg.279]

CPA. Copolymer alloy membranes (CPAs) are made by alloying high molecular weight polymeries, plasticizers, special stabilizers, biocides, and antioxidants with poly(vinyl chloride) (PVC). The membrane is typically reinforced with polyester and comes in finished thicknesses of 0.75—1.5 mm and widths of 1.5—1.8 m. The primary installation method is mechanically fastened, but some fully adhered systems are also possible. The CPA membranes can exhibit long-term flexibiHty by alleviating migration of the polymeric plasticizers, and are chemically resistant and compatible with many oils and greases, animal fats, asphalt, and coal-tar pitch. The physical characteristics of a CPA membrane have been described (15). [Pg.213]

Health and Safety Factors. MSC has a vapor toxicity on mice of LD q 4.7 mg/L. It is a lachrymator and in order to prevent contact with eyes, goggles should be worn. It is also corrosive to skin and therefore chemically resistant gloves and protective clothing should be worn to prevent contact with skin. Containers should only be opened where there is adequate ventilation. [Pg.153]


See other pages where Chemical resistance also is mentioned: [Pg.949]    [Pg.580]    [Pg.65]    [Pg.949]    [Pg.580]    [Pg.65]    [Pg.186]    [Pg.196]    [Pg.407]    [Pg.378]    [Pg.425]    [Pg.371]    [Pg.389]    [Pg.72]    [Pg.73]    [Pg.253]    [Pg.328]    [Pg.399]    [Pg.532]    [Pg.233]    [Pg.372]    [Pg.432]    [Pg.432]    [Pg.5]    [Pg.236]    [Pg.320]    [Pg.368]    [Pg.444]    [Pg.456]    [Pg.456]    [Pg.42]    [Pg.328]    [Pg.214]    [Pg.311]    [Pg.354]   


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Chemical resistance

Chemical resistance (also aromatic polymers

Chemical resistance (also combustion

Chemical resistance (also condensation polymers

Chemical resistance (also crosslinking

Chemical resistance (also dependencies

Chemical resistance (also oxidation

Chemical resistance (also plasticizer

Chemical resistance (also polyolefins

Chemical resistance (also radiation

Chemical resistance (also solubility parameters

Chemical resistance (also solvent

Chemical resistance (also state

Chemical resistance (also structure

Chemical resistance (also surface

Chemical resistance (also temperature

Chemical resistance (also tests

Polyamides (also chemical resistance

Polyesters (also chemical resistance

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