Microstructure fatigue

Microstructures. See also Microstructure fatigue properties and, 73 484-486 in lotus effect surfaces, 22 117-120 Microsuspension polymerization, of PVC, 25 670... [Pg.586]

P. Pao, R. Fonda, H. Jones, C. Feng, B. Connolly, and A. Davenport, Microstructure, Fatigue Crack Growth, and Corrosion in Friction Stir Welded A1 5456, Friction Stir Welding and Processing III,... [Pg.108]

Taylor, D., Knott, J.F. Fatigue crack propagation of short cracks the effect of microstructure. Fatigue Fract. Eng. Mater. Struct. 4, 147-155 (1981)... [Pg.71]

T. Hoshide, K. Kusuura. Life prediction by simulation of crack growth in notched components with different microstructures and under multiaxial fatigue. Fatigue Fract Eng Mater Struct 27 201, 1998. [Pg.926]

T. Hoshide. Simulation of microstructural effects on cracking behavior in biaxial fatigue. Mater Sci Res Int 5 119, 1997. [Pg.929]

The amorphous orientation is considered a very important parameter of the microstructure of the fiber. It has a quantitative and qualitative effect on the fiber de-formability when mechanical forces are involved. It significantly influences the fatigue strength and sorptive properties (water, dyes), as well as transport phenomena inside the fiber (migration of electric charge carriers, diffusion of liquid). The importance of the amorphous phase makes its quantification essential. Indirect and direct methods currently are used for the quantitative assessment of the amorphous phase. [Pg.847]

Devereux, O. F., McEvily, A. J. and Staehle, R. W., (Eds.) Corrosion fatigue chemistry, mechanics and microstructure , NACE-2, National Association of Corrosion Engineers (1972)... [Pg.1324]

Stoloff, N. S. and Duquette, D. J., Microstructural effects in the fatigue behaviour of metals and alloys , CRC Critical Reviews in Solid Slate Sciences, 4, 615-87 (1974)... [Pg.1324]

The forgings were evaluated by density, microstructure, surface finish, tensile strength, notched impact strength, ductility, and fatigue strength measurements... [Pg.839]

Karger-Kocsis J. (1991). Microstructural aspects of fracture and fatigue behavior in short fiber-reinforced, injection-molded PPS-, PEEK- and PEN-composites. Poiym. Bulletin 27, 109-116. [Pg.275]

Greater amounts of copper increase the proportion of needles or stars of Cu Sn in the microstructure. Increase in antimony above 7.5% results in antimony—tin cubes. Hardness and tensile strength increase with copper and antimony content ductility decreases. Low percentages of antimony (3—7%) and copper (2—4%) provide maximum resistance to fatigue cracking in service. Since these low alloy compositions are relatively soft and weak, compromise between fatigue resistance and compressive strength is often necessary. [Pg.3]

M.M. Shenoy et al Estimating fatigue sensitivity to polycrystalline Ni-base superalloy microstructures using a computational approach. Fatigue Fract Eng. Mat. Struct 30, 889-904 (2007)... [Pg.128]

S. Johnston et al Three-dimensional finite element simulations of microstructurally small fatigue crack growth in 7,075 aluminium alloy. Fatigue Fract. Eng. Matl. Struct. 29,597-605 (2006)... [Pg.129]

B. Zhang et al Microstructural effects on high-cycle fatigue-crack initiation in A356.2 casting alloy. Metall. Matls. Trans. A 30, 2659—2666 (1999)... [Pg.131]

D.L. McDowell et al Microstructure-based fatigue modeling of cast A356-T6 alloy. Eng. Fracture Mech. 70, 49-80 (2003)... [Pg.134]

Y. Xue et al Microstructure-based multistage fatigue modeling of aluminum alloy 7,075-T651. Eng. Fract. Mech. 74, 2810-2823 (2007)... [Pg.134]

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