000			02184cam a2200301zu 4500
001			88965979
003			FRCYB88965979
005			20250429184240.0
006			m o d
007			cr un
008			250429s2019 fr | o|||||0|0|||eng d
020			_a9780128161319
035			_aFRCYB88965979
040			_aFR-PaCSA _ben _c _erda
100	1		_aJordon, J. Brian
245	0	1	_aFatigue in Friction Stir Welding _c['Jordon, J. Brian', 'Amaro, Robert', 'Allison, Paul']
264		1	_bButterworth-Heinemann _c2019
300			_a p.
336			_btxt _2rdacontent
337			_bc _2rdamdedia
338			_bc _2rdacarrier
650		0	_a
700	0		_aJordon, J. Brian
700	0		_aAmaro, Robert
700	0		_aAllison, Paul
856	4	0	_2Cyberlibris _uhttps://international.scholarvox.com/netsen/book/88965979 _qtext/html _a
520			_aFatigue in Friction Stir Welding provides knowledge on how to design and fabricate high performance, fatigue resistance FSW joints. It summarizes fatigue characterizations of key FSW configurations, including butt and lap-shear joints. The book's main focus is on fatigue of aluminum alloys, but discussions of magnesium, steel, and titanium alloys are also included. The FSW process-structure-fatigue performance relationships, including tool rotation, travel speeds, and pin tools are covered, along with sections on extreme fatigue conditions and environments, including multiaxial, variable amplitude, and corrosion effects on fatigue of the FSW. From a practical design perspective, appropriate fatigue design guidelines, including engineering and microstructure-sensitive modeling approaches are discussed. Finally, an appendix with numerous representative fatigue curves for design and reference purposes completes the work. - Provides a comprehensive characterization of fatigue behavior for various FSW joints and alloy combinations, along with an in-depth presentation on crack initiation and growth mechanisms - Presents the relationships between process parameters and fatigue behavior - Discusses modeling strategies and design recommendations, along with experimental data for reference purposes
999			_c1331309 _d1331309