Engineering properties

Rioherson D W 1992 Modern Ceramic Engineering Properties, Processing, and Use in Design 2nd edn (New York Dekker)... [Pg.2773]

Table 4. Typical Engineering Properties of Commercial Parylenes...

SiHcon nitride (see Nitrides) is a key material for stmctural ceramic appHcations in environments of high mechanical and thermal stress such as in vehicular propulsion engines. Properties which make this material uniquely suitable are high mechanical strength at room and elevated temperatures, good oxidation and creep resistance at high temperatures, high thermal shock resistance, exceUent abrasion and corrosion resistance, low density, and, consequently, a low moment of inertia. Additionally, siHcon nitride is made from abundant raw materials. [Pg.321]

The Engineering Properties of Electroless Nickel Deposits, International Nickel Co., New York, 1977. [Pg.140]

Cladding and backing metals are purchased in the appropriately heat-treated condition because corrosion resistance is retained through bonding. It is customary to supply the composites in the as-bonded condition because hardening usually does not affect the engineering properties. Occasionally, a post-bonding heat treatment is used to achieve properties required for specific combinations. [Pg.150]

J. L. Everhart, Engineering Properties of Nickel and NickelHlloys, Plenum Press, New York, 1971. [Pg.7]

Engineering Properties Guide, Phillips Petroleum Co., BardesviUe, OHa., 1993. [Pg.453]

R. M. Ogorkiewic2, Engineering Properties of Thermoplastics, John Wiley Sons, Inc., New York, 1970, p. 251. [Pg.511]

Engineering Properties of Zinc Alloys, International Lead Ziuc Research Organization, New York, 1980, pp. 1—36. [Pg.417]

As a hard, high melting carbide and possible constituent of UC-fueled reactors, zirconium carbide has been studied extensively. The preparation, behavior, and properties of zirconium and other carbides are reviewed in Reference 132, temperature-correlated engineering property data in Reference 133 (see also Carbides). [Pg.434]

Engineering Property Data on Selected Ceramics, Hoi. II Carbides, Metal and Ceramics Information Center, BatteUe Columbus Laboratory, Columbus, Ohio, 1979. [Pg.443]

D. W. Richerson, Modem Ceramic Engineering Properties, Processing and Use in Design, Marcel Dekker, Inc., New York, 1982. [Pg.328]

The engineering properties of electroless nickel have been summarhed (28). The Ni—P aHoy has good corrosion resistance, lubricity, and especiaHy high hardness. This aHoy can be heat-treated to a hardness equivalent to electrolytic hard chromium [7440-47-3] (Table 2), and the lubricity is also comparable. The wear characteristics ate extremely good, especiaHy with composites of electroless nickel and silicon carbide or fluorochloropolymers. Thus the main appHcations for electroless nickel are in replacement of hard chromium (29,30). [Pg.108]

R. M. Ogorkiewicz, Engineering Design Guide No. 17 The Engineering Properties of Plasties, Oxford University Press, 1977. [Pg.227]

Gambill, W. R., Estimate Engineering Properties— How P and T Change Liquid Viscosity," Chemical Engineering. February 9, 1959. p. 123. [Pg.357]

LeGrow, G.E., Solventless silicone resins. Relation between polymer structure and engineering properties. Soc. Plast. Eng., Tech. Pap., 21, 445-446 (1975). [Pg.706]

Table 1 contains the metal-to-metal engineering property requirements for Boeing Material Specification (BMS) 5-101, a structural film adhesive for metal to metal and honeycomb sandwich use in areas with normal temperature exposure. The requirements are dominated by shear strength tests. Shear strength is the most critical engineering property for structural adhesives, at least for the simplistic joint analysis that is commonly used for metal-to-metal secondary structure on commercial aircraft. Adhesive Joints are purposefully loaded primarily in shear as opposed to tension or peel modes as adhesives are typically stronger in shear than in Mode I (load normal to the plane of the bond) loading. [Pg.1146]

Ogorkiewicz, R.M. Engineering Properties of Plastics, Wiley Inlerscience, London (1970). [Pg.157]

Palmer, K. B., Proceedings of Conference on Engineering Properties and Performance of Modern Iron Castings, BCIRA, 110 (1972)... [Pg.598]

In addition to nickel alloys, nickel also forms an important alloying element in stainless steels and in cast irons, in both of which it confers additional corrosion resistance and improved mechanical and engineering properties, and in Fe-Ni alloys for obtaining controlled physical and magnetic properties (see Chapter 3). With non-ferrous metals nickel also forms important types of alloys, especially with copper, i.e. cupro-nickels and nickel silvers these are dealt with in Section 4.2. [Pg.760]

ILZRO Engineering Properties of Zinc Alloys, 2nd edition, 116, ILZRO (1981)... [Pg.827]

Schmidt, F.F. and Ogden, H.R., The Engineering Properties of Tantalum and Tantalum Alloys, DMIC Report No. 189, DMIC Batelle Memorial Institute, Sept. 13th (1963)... [Pg.904]

Popov VL, Fridman ML (1981) Rheological and engineering properties of filled polymeric materials. NIITEKhim, Moscow... [Pg.62]

In plastics, these correlative properties, together with those that can be used in design equations, generally are called engineering properties. They encompass a variety of situations over and above the basic static strength and rigidity requirements, such as impact, fatigue, flammability, chemical resistance, and temperature. [Pg.16]

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