Thermomechanical Behavior of Developmental Thermal Barrier Coating Bond Coats

Thermomechanical Behavior of Developmental Thermal Barrier Coating Bond Coats

Thermal expansion, microtensile, and stress relaxation experiments have been performed to contrast and compare the thermal and mechanical response of two experimental (L1 and H1) coatings provided by Honeywell Corporation (Morristown, NY). Thermal expansion experiments reveal that both coatings have...

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Bibliographic Details
Published in:JOM (1989) Vol. 65; no. 4; pp. 542 - 549
Main Authors: Pandey, Amit, Tolpygo, Vladimir K., Hemker, Kevin J.
Format: Journal Article
Language:English
Published: Boston Springer US 01-04-2013
Springer Nature B.V
Subjects:
Chemistry/Food Science
Deformation
Earth Sciences
Engineering
Environment
Experiments
Lasers
Materials science
Measurement techniques
Mechanical properties
Oxidation
Physics
Protective coatings
Strain hardening
Studies
Temperature
Temperature effects
Thermal cycling
Yield stress
United States > US
Bond Coat
Electric Discharge Machine
Digital Image Correlation
Thermally Grow Oxide
Thermal Barrier Coating System
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Summary:Thermal expansion, microtensile, and stress relaxation experiments have been performed to contrast and compare the thermal and mechanical response of two experimental (L1 and H1) coatings provided by Honeywell Corporation (Morristown, NY). Thermal expansion experiments reveal that both coatings have coefficients of thermal expansion (CTE) that vary with temperature and that the CTE mismatch between the coatings and superalloy substrate is significant in the case of L1 as compared to H1. Values of the 0.2% offset yield stress (YS), Young’s modulus ( E ), and hardening exponent ( n ) are reported. Room-temperature microtensile experiments show higher strain hardening and a very low value of failure strain for L1 as compared to H1. At elevated temperatures, there is a significant decrease in the YS of as-received L1 for (924 MPa at room temperature to 85 MPa at 1000°C) as compared to H1. Finally, a power law creep description for high-temperature stress relaxation is developed and the measured values of the stress exponent ( n  = 3) and activation energies ( Q creep  = 200–250 kJ/mol) are shown to be consistent with power law creep.
ISSN:1047-4838
1543-1851
DOI:10.1007/s11837-013-0551-1