Stress Relaxation of Compression Loaded Plasma-Sprayed 7 Wt% Y2O3-ZrO2 Stand-Alone Coatings

Stress Relaxation of Compression Loaded Plasma-Sprayed 7 Wt% Y2O3-ZrO2 Stand-Alone Coatings

Stand‐alone plasma‐sprayed tubes of 7 wt% Y2O3–ZrO2 made from the same starting powder but at two different sites were subject to stress‐relaxation testing in axial compression at temperatures of 25°, 1000°, 1050°, 1100°, and 1200°C and at an initial stress of 10–80 MPa. A time‐dependent stress resp...

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Bibliographic Details
Published in:Journal of the American Ceramic Society Vol. 88; no. 8; pp. 2202 - 2208
Main Authors: Dickinson, Graeme R., Petorak, Chris, Bowman, Keith, Trice, Rodney W.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Science Inc 01-08-2005
Blackwell
Subjects:
Applied sciences
Building materials. Ceramics. Glasses
Ceramic industries
Chemical industry and chemicals
Exact sciences and technology
Miscellaneous
Technical ceramics
Scanning electron microscopy
Tube
Temperature effect
Mechanical properties
Stabilized zirconia
High temperature
Experimental study
Oxide ceramics
Uniaxial compression
Stress relaxation
Zirconium oxide
Thermal barrier coatings
Technical ceramics
Yttrium oxide
Manufacturing
Microstructure
Plasma spraying
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Summary:Stand‐alone plasma‐sprayed tubes of 7 wt% Y2O3–ZrO2 made from the same starting powder but at two different sites were subject to stress‐relaxation testing in axial compression at temperatures of 25°, 1000°, 1050°, 1100°, and 1200°C and at an initial stress of 10–80 MPa. A time‐dependent stress response was observed for both coatings at all temperatures. For example, a 20 MPa stress applied at 1050°C relaxed to ∼3 MPa in 180 min. When the same initial stress was applied at 1200°C, the coating fully relaxed in 32 min. For all experimental conditions evaluated, an initial fast stress‐relaxation regime was observed (<10 min), followed by a slower second stress‐relaxation regime at later times (>10 min). Coatings with higher as‐sprayed densities exhibited a lengthened fast relaxation regime as compared with less dense coatings. A Maxwell model was modified in order to provide an accurate fit to the experimental stress‐relaxation curves. From scanning electron microscopy experiments and mechanical data, the mechanism for stress relaxation from 25°C through 1200°C, particularly during fast relaxation, was proposed to be the formation of cracks parallel with respect to the applied load. In addition to this mechanism, stress relaxation that occurred in specimens tested at 1000°C through 1200°C was proposed to be due to partial or complete closure of cracks oriented perpendicular to the applied stress.
Bibliography:ArticleID:JACE00407
istex:DFAEDAFD77B822AB6ADD3AF61D9A8CD13F726036
ark:/67375/WNG-RTQ2J20D-W
Based in part on the thesis submitted by G. Dickinson for the M.S. Degree in Materials Engineering, Purdue University, West Lafayette, Indiana, 2004.
G. Scherer—contributing editor
This work was supported by the National Science Foundation through DMR‐0134286 and HRD‐0120794.
The plasma arc spraying work at Site 2 was performed by the Materials Preparation Center at the Ames Laboratory, which is supported by U.S. Department of Energy, Office of Science through Iowa State University under Contract No. W‐7405‐ENG‐82.
ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0002-7820
1551-2916
DOI:10.1111/j.1551-2916.2005.00407.x