Transient finite-volume analysis of a graded cylindrical shell under thermal shock loading

Mechanics of Advanced Materials and Structures

Volumn 18, Issue 1, 2011, Pages 53-67

  Cavalcante, Marcio A A ^a   Marques, Severino P C ^b   Pindera, Marek Jerzy ^a  

^a University of Virginia   (United States)

^b FEDERAL UNIVERSITY OF ALAGOAS   (Brazil)

Author keywords

finite volume theory; functionally graded materials; spallation mechanism; thermal barrier coatings; thermal shock

Indexed keywords

CERAMIC TOP COAT; CYLINDRICAL SHELL; DURABILITY TEST; FAILURE MECHANISM; FINITE-VOLUME; FINITE-VOLUME THEORY; FUNCTIONALLY GRADED; GROWTH MANAGEMENT; HOOP STRESS; METALLIC BONDS; OUTER SURFACE; POTENTIAL FAILURE MODES; RAPID COOLING; RAPID-HEATING; SPALLATION MECHANISM; STRESS FIELD; THERMAL COATINGS; THERMAL CYCLIC LOADING; THERMAL SHOCK LOADING; THREE-LAYER; TRANSIENT EFFECT; TRANSIENT RESPONSE; TRANSITION REGIONS; TRANSVERSE CRACK;

CERAMIC MATERIALS; COATINGS; CRACKS; CYLINDERS (SHAPES); FAILURE ANALYSIS; FUNCTIONALLY GRADED MATERIALS; LOADING; PLATES (STRUCTURAL COMPONENTS); RESIDUAL STRESSES; SHOCK PROBLEMS; SHOCK TESTING; SPALLING; STEEL SHEET; SURFACE TESTING; THERMAL SHOCK;

THERMAL BARRIER COATINGS;

EID: 79551505816     PISSN: 15376494     EISSN: 15376532     Source Type: Journal    
DOI: 10.1080/15376494.2010.519225     Document Type: Article

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