Fatigue strength of spring steel under axial and torsional loading in the very high cycle regime

International Journal of Fatigue

Volumn 30, Issue 12, 2008, Pages 2057-2063

  Akiniwa, Y ^a   Stanzl Tschegg, S ^b   Mayer, H ^b   Wakita, M ^c   Tanaka, K ^d  

^a NAGOYA UNIVERSITY   (Japan)

^b UNIVERSITY OF NATURAL RESOURCES AND LIFE SCIENCES   (Austria)

^c Chuo Spring Co Ltd   (Japan)

^d MEIJO UNIVERSITY   (Japan)

Author keywords

Axial loading; Giga cycle fatigue; Non damaging defect; Spring steel; Torsional loading

Indexed keywords

CHROMIUM; CRACK PROPAGATION; FATIGUE OF MATERIALS; FATIGUE TESTING; INCLUSIONS; LOADING; MATHEMATICAL TECHNIQUES; SILICON; SPRINGS (COMPONENTS); STATISTICAL METHODS; STEEL; STRUCTURAL LOADS; SURFACE TESTING; TORSIONAL STRESS;

AXIAL LOADING; AXIAL LOADINGS; CR STEELS; CRACK BRANCHING; CRACK LENGTHS; CRITICAL VOLUME; EXTREMAL STATISTICS; FATIGUE PROPERTIES; FATIGUE STRENGTHS; GIGA CYCLE FATIGUE; HIGH CYCLE; INCLUSION SIZES; LOADING CONDITIONS; LONG CRACKS; LONGITUDINAL DIRECTION; NON-DAMAGING DEFECT; SHEAR CRACKS; SPECIMEN SURFACES; SPRING STEEL; SPRING STEELS; STRESS CYCLING; SURFACE STRESSES; TENSION-COMPRESSION; TORSIONAL LOADING; TORSIONAL LOADINGS; ULTRASONIC FATIGUE TESTING; VALVE SPRINGS;

CRACKS;

EID: 50249129619     PISSN: 01421123     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijfatigue.2008.07.004     Document Type: Article

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