Development of Advanced Ultra Supercritical Fossil Power Plants in Japan: Materials and High Temperature Corrosion Properties

Yuji Fukuda

doi:10.4028/www.scientific.net/MSF.696.236

Paper Titles

Superheater Fireside Corrosion Mechanisms of SA192 and AISI 316L in WtE Environment: Lab-Scale and Industrial Results
p.212

Detailed Studies on the High Temperature Corrosion Reactions between Potassium Chloride and Metallic Chromium
p.218

KCl-Induced High Temperature Corrosion of the Austenitic Stainless Steel 304L – The Influence of SO₂
p.224

Technological Archives of R & D Activities about Corrosion-Resistant Materials and Protective Coating Systems at High Temperatures in Japan - Historical Retrospection and Future Prospect -
p.230

Development of Advanced Ultra Supercritical Fossil Power Plants in Japan: Materials and High Temperature Corrosion Properties
p.236

Improvement of the High-Temperature Erosion-Corrosion Resistance of Incoloy 800 by Cladding of 25.35.4CNB Reinforced by SiC
p.242

Influence of Gas Tungsten Arc Welding Parameters on the High-Temperature Erosion-Corrosion Resistance of Incoloy 800 Cladded by Stellite 12 for the Application as Thermowell
p.248

High Temperature Corrosion of M-40Cr-0.5Ce Alloys as Inert Anodes in Aluminium Electrolysis
p.254

Classification of Corrosion Behavior of Water Wall Tube Materials in Simulated Coal Combustion Atmospheres Including H₂S
p.260

HomeMaterials Science ForumMaterials Science Forum Vol. 696Development of Advanced Ultra Supercritical Fossil...

Development of Advanced Ultra Supercritical Fossil Power Plants in Japan: Materials and High Temperature Corrosion Properties

Abstract:

Japanese government project of the A-USC technology was started in 2008 August. 700°C class boiler, turbine and valve technologies, which include high temperature material technology, will be developed. This report provides the present state of the art and technical background of this development effort for A-USC in Japan, especially focusing the high temperature corrosion and the steam oxidation behavior of available and developmental materials for boiler.

You might also be interested in these eBooks

High-Temperature Oxidation and Corrosion 2010

View Preview

Info:

Periodical:

Materials Science Forum (Volume 696)

Pages:

236-241

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.696.236

Citation:

Cite this paper

Online since:

September 2011

Authors:

Yuji Fukuda

Keywords:

A-USC Coal Fired Boiler, Fe-Ni Based Alloys, Fireside Corrosion, Ni-Based Alloy, Steam Oxidation

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] R. Viswanathan, and R. Purgert, Paper No. Creep2007-26826, 8th International Conference on Creep and Fatigue at Elevated Temperatures, San Antonio, Texas (July 2007).

Google Scholar

[2] H. Tschaffon, Paper No. 2, 34th MPA-SEMINAR and VGB-Symposium on Materials and Components Behaviour in Energy & Plant Technology, Stuttgart, Germany (October 2008).

Google Scholar

[3] R. Blum, Paper No. 1, 8th International NIMS-MPA-IfW-Workshop on Advances in High Temperature Materials for High Efficiency Power Plants, Tsukuba, Japan (March 2010).

Google Scholar

[4] M. Fukuda, Paper No. 2, 8th International NIMS-MPA-IfW-Workshop on Advances in High Temperature Materials for High Efficiency Power Plants, Tsukuba, Japan (March 2010).

Google Scholar

[5] M. Fukuda, 9th Liège Conference (September 2010).

Google Scholar

[6] R.B. Dooley, Boiler Tube Failures: Theory and Practice, ISBN 0-8033-5058-9, EPRI (1995).

Google Scholar

[7] Y. Fukuda and M. Shimizu, Material Science Forum Vols. 522-523, August 2006, p.189.

Google Scholar

[8] M. Shimizu, G. Bao and Y. Fukuda, Paper No. 09250, CORROSION 2009, Atlanta, GA　　　　　(March 2009).

Google Scholar

[9] T. Sato, Y. Fukuda, K. Tamura and K. Mitsuhata, Proc. of 4th International Conf. on Advances in Materials Tech. for Fossil Power Plants, EPRI, Hilton Head Island (2004) pp.182-195.

Google Scholar