Fatigue in magnesium alloy AZ91-γAlumina fiber composite studied by internal friction measurements

Procedia Engineering

Volumn 2, Issue 1, 2010, Pages 2151-2160

  Riehemann, W ^a   Trojanova Z ^b   Mielczarek, A ^a,c  

^a CLAUSTHAL UNIVERSITY OF TECHNOLOGY   (Germany)

^b CHARLES UNIVERSITY   (Czech Republic)

^c VOLKSWAGEN AG   (Germany)

Author keywords

alumina fiber; AZ91; Crack; Damping; Internal friction; Magnesium; Metal matrix composite

Indexed keywords

ADVANCED TECHNOLOGY; ALUMINA FIBER; AMBIENT TEMPERATURES; AMPLITUDE DEPENDENCE; AZ91; BENDING BEAM; CRACK GROWTH; CRACK NUCLEATION; CYCLE NUMBER; CYCLIC BENDING; DAMPING BEHAVIORS; DAMPING CAPACITY; DISLOCATION EFFECTS; FRACTURED SURFACES; INTERNAL-FRICTION MEASUREMENTS; LOGARITHMIC DECREMENT; LOW DENSITY; MAGNESIUM ALLOY AZ91; MAGNESIUM MATRIX COMPOSITE; MAGNESIUM METAL; MATRIX; MATRIX METAL; MECHANICAL CYCLING; METALLIC MATERIAL; NUMBER OF CYCLES; PHYSICAL AND MECHANICAL PROPERTIES; REINFORCING FIBERS; REINFORCING PHASE; RHEOLOGICAL MODELS; ROOM TEMPERATURE; STRAIN AMPLITUDE; THERMAL CHARACTERISTICS; THERMAL EXPANSION COEFFICIENTS; THERMODYNAMIC PROCESS; TRIBOLOGICAL PROPERTIES;

ALLOYS; CASTING; CERAMIC FIBERS; CERAMIC MATRIX COMPOSITES; CRACKS; DAMPING; ELASTIC WAVES; FIBERS; HAND TOOLS; INTERNAL FRICTION; MAGNESIUM; MAGNESIUM ALLOYS; MAGNESIUM CASTINGS; MEASUREMENTS; MECHANICAL PROPERTIES; NUCLEATION; REINFORCEMENT; RHEOLOGY; SQUEEZE CASTING; STIFFNESS MATRIX; THERMAL CYCLING; THERMAL EXPANSION; THERMAL STRESS; THERMOELASTICITY; TRIBOLOGY; WEAR RESISTANCE; YIELD STRESS;

METALLIC MATRIX COMPOSITES;

EID: 77954132246     PISSN: None     EISSN: 18777058     Source Type: Conference Proceeding    
DOI: 10.1016/j.proeng.2010.03.231     Document Type: Conference Paper

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