Fatigue design of lattice materials via computational mechanics: Application to lattices with smooth transitions in cell geometry

International Journal of Fatigue

Volumn 47, Issue , 2013, Pages 126-136

  Masoumi Khalil Abad, Ehsan ^a   Arabnejad Khanoki, Sajad ^a   Pasini, Damiano ^a  

^a MCGILL UNIVERSITY   (Canada)

Author keywords

Asymptotic homogenization; Fatigue strength; FEM; Lattice materials; Modified Goodman diagram

Indexed keywords

ALTERNATING STRESS; ASYMPTOTIC HOMOGENIZATION; CELL GEOMETRIES; CELL LENGTHS; CELL SHAPES; CYCLIC LOADINGS; FAILURE SURFACE; FATIGUE DESIGN; FATIGUE FAILURES; FATIGUE PERFORMANCE; FATIGUE STRENGTH; GEOMETRIC PRIMITIVES; GOODMAN DIAGRAM; LATTICE MATERIALS; NUMERICAL RESULTS; OPTIMIZED GEOMETRIES; RELATIVE DENSITY; SMOOTH TRANSITIONS; SQUARE LATTICES; STRESS LOCALIZATION; UNIT CELLS;

COMPUTATIONAL MECHANICS; CRYSTAL LATTICES; CURVE FITTING; CYTOLOGY; FINITE ELEMENT METHOD; GEOMETRY; OPTIMIZATION;

CELLS;

EID: 84869501426     PISSN: 01421123     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijfatigue.2012.08.003     Document Type: Article

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