Thermo-Mechanical and Low Cycle Fatigue Failure Behavior Relevant to Temperature Regime in a TBCed Superalloy Specimen

Masakazu Okazaki; Satoshi Yamagishi; Yuuki Yonaguni

doi:10.4028/www.scientific.net/MSF.879.2518

Paper Titles

Development of High-Performing Extruded Magnesium Alloy
p.2495

Scalable Methods to Obtain Superhydrophobicity onto Metallic Surface
p.2501

High Temperature Mechanical Properties of Harmonic Structure Designed SUS304L Austenitic Stainless Steel
p.2507

Effect of Misch Metal Addition on Thermal Conductivities and Mechanical Properties of Mg-4Zn-0.5Ca Alloys
p.2512

Thermo-Mechanical and Low Cycle Fatigue Failure Behavior Relevant to Temperature Regime in a TBCed Superalloy Specimen
p.2518

Osteoconductivity of Superhydrophilic Ti- and Zr-Alloy for Biomedical Application
p.2524

Microstructure and Mechanical Properties of Nb Alloyed Steel Processed by Hot Equal Channel Angular Extrusion
p.2528

Study of the Precipitation of Secondary Phases in Duplex and Superduplex Stainless Steel
p.2537

HomeMaterials Science ForumMaterials Science Forum Vol. 879Thermo-Mechanical and Low Cycle Fatigue Failure...

Thermo-Mechanical and Low Cycle Fatigue Failure Behavior Relevant to Temperature Regime in a TBCed Superalloy Specimen

Abstract:

Steady state and non-steady state thermo-mechanical fatigue failure is great concern in this work. At first steady state thermo-mechanical fatigue failure behavior was investigated using the round-bar TBC specimens, after getting basic data of mechanical properties of the bond/top coats and the substrate alloy. The failure behavior was compared with that during isothermal low cycle fatigue (LCF). Next non-steady state TMF tests were carried out in which non-steady state thermal stress was significant in the TBC specimen, compared with the properties under the steady state TMF. The experimental work clearly demonstrated that the TMF failure lives were significantly changed depending on the temperature regime during TMF and LCF. Of particular importance was found in the non-steady state TMF tests. The non-steady state TMF cycling promoted the delamination of ceramic top coat, resulting in a significant reduction in fatigue life.

You might also be interested in these eBooks

View Preview

View Preview

Info:

Periodical:

Materials Science Forum (Volume 879)

Pages:

2518-2523

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.879.2518

Citation:

Cite this paper

Online since:

November 2016

Authors:

Masakazu Okazaki*, Satoshi Yamagishi, Yuuki Yonaguni

Keywords:

Cracking Modes, Failure Mechanisms, Low-Cycle Fatigue, Non-Steady Thermal Stress, Thermal Barrier Coatings (TBCs), Thermal Gradient, Thermo-Mechanical Fatigue

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] H.L. Bernstein T.S. Grant, R.C. McClung and J.M. Allen, Thermomechanical Fatigue Behavior of Materials, (1993) 212-38.

Google Scholar

[2] B.B. Seth, Superalloys 2000 (USA), 2000, 3-16.

Google Scholar

[3] National Research Council Coating for High Temperature Structural Material; Trends and Opportunities National Academy of Sciences, Washington, DC, (1996).

Google Scholar

[4] T. Xu, M.Y. He, A.G. Evans, Acta materialia, 51 (2003) 3807-20.

Google Scholar

[5] M. Okazaki, Y. Yamazaki and K. Take, Thermo-Mechanical Fatigue Behavior of Materials, M.A. McGaw, ASTM STP 1428, (2003) 180-196.

Google Scholar

[6] S. Rajivgandhi, S. Yamagishi and M. Okazaki, Thermo-Mechanical Fatigue Failure of Thermal Barrier Coated Superalloy Specimen, Metallurgical and Materials Transactions. -A, 46 (2015) 3999-4012.

DOI: 10.1007/s11661-015-2996-z

Google Scholar

[7] M. Okazaki, Science and Technology of Advanced Materials, 2 (2001) 357-66.

Google Scholar

[8] M. Okazaki,Y. Yamazaki and K. Namba, Journal of Solid Mechanics and Materials Engineering, 4 (2010) 252-263.

Google Scholar