Engineering Materials and Their ApplicationsThis edition of the classic text/reference book has been updated and revised to provide balanced coverage of metals, ceramics, polymers and composites. The first five chapters assess the different structures of metals, ceramics and polymers and how stress and temperature affect them. Demonstrates how to optimize a material's structure by using equilibrium data (phase diagrams) and nonequilibrium conditions, especially precipitation hardening. Discusses the structures, characteristics and applications of the important materials in each field. Considers topics common to all materials--corrosion and oxidation, failure analysis, processing of electrical and magnetic materials, materials selection and specification. Contains special chapters on advanced and large volume engineering materials plus abundant examples and problems. |
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Page 70
... component ε is 0.002 in./in . ( m / m ) . If less plastic strain can be tolerated , the Єpl yield strength is ... components . The percent elongation at fracture serves several purposes . It is possibly a better index of quality than the ...
... component ε is 0.002 in./in . ( m / m ) . If less plastic strain can be tolerated , the Єpl yield strength is ... components . The percent elongation at fracture serves several purposes . It is possibly a better index of quality than the ...
Page 154
... components , and P = number of phases in equilibrium . This formula is usually written +1 instead of +2 because we ... component gives an additional degree of freedom . Two - phase material A material in which two different phases are ...
... components , and P = number of phases in equilibrium . This formula is usually written +1 instead of +2 because we ... component gives an additional degree of freedom . Two - phase material A material in which two different phases are ...
Page 563
... component failed . For example , components may fail because the stresses imposed during service exceeded the ultimate strength of the material . If this is the case , we say that the part failed because of a tensile overload . If ...
... component failed . For example , components may fail because the stresses imposed during service exceeded the ultimate strength of the material . If this is the case , we say that the part failed because of a tensile overload . If ...
Contents
The Problem of Materials Selection and Development | 3 |
Effects of Stress and Temperature on Simple Metal | 59 |
Problems | 102 |
Copyright | |
41 other sections not shown
Common terms and phrases
alloys aluminum annealed anode atoms austenite bainite bond Calculate carbide carbon cast iron cathode cement ceramics Chapter chemical chromium cold-worked component composition compressive concrete cooling copper corrosion crack crystal curve density diameter diffusion discussed ductility effect elastic electrical electron hole electrons elements elongation energy eutectoid example fatigue Fe2+ ferrite fibers fracture toughness g/cm³ glass grain graphite H H H hardening hardness heat hydrogen important ions layer liquid load magnesium magnetic martensite material matrix melting metal microstructure modulus mold molecules nickel obtain oxide oxygen pearlite percent percentage phase diagram plane plastic polymer polymerization precipitate produce properties quench reaction resistance Sections semiconductor shown in Fig shows silica silicon solid solution specimen stainless steel strain stress structure surface Table tensile strength thermal thermoplastic thermosetting transformation unit cell valence volume wavelength weight yield strength zinc