New 12%Cr-steel for tubes and pipes in power plants with steam temperatures up to 650°C (original) (raw)
Development of new 11%Cr heat resistant ferritic steels with enhanced creep resistance for steam power plants with operating steam temperatures up to 650°C
K. Durst
Materials Science and Engineering: A, 2009
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Development of creep-and corrosion-resistant steels for future steam power plants
Willem Quadakkers
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Long Term Microstructural Evolution of 9-12%Cr Steel Grades for Steam Power Generation Plants
Augusto Di Gianfrancesco
Procedia Engineering, 2013
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Comparison of various 9–12%Cr steels under fatigue and creep-fatigue loadings at high temperature
B. Fournier
Materials Science and Engineering: A, 2011
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Modern martensitic steels for power industry
Mirosław Łomozik
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Short-term creep of advanced re-containing 10% Cr – 3% Co – 3% W martensitic steel at elevated temperature
Nadezhda Dudova
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Some aspects of plant and research experience in the use of new high strength martensitic steel P91
Fred Starr
International Journal of Pressure Vessels and Piping, 2007
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High temperature deformation behavior of as-produced and retired 9–12% Cr power plant steel
Magdy El Rayes
Materials Science and Engineering: A, 2017
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Contributions of different factors to the improvement of the creep rupture strength of creep resistant martensitic steels
Béla Palotás
Periodica Polytechnica Mechanical Engineering, 2007
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Experimental Study On Creep Strength Of The Weld Joints Of 9%Cr Heat Resistant Steels Experimental Study On Creep Strength Of The Weld Joints Of 9%Cr Heat Resistant Steels
Seifallah Fetni
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P91 and Beyond Welding the new-generation Cr-Mo alloys for high-temperature service
Kent Coleman
2007
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Experimental Study On Creep Strength Of The Weld Joints Of 9%Cr Heat Resistant Steels
Seifallah Fetni
2016
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Influence of heat input and post-weld heat treatment on boiler steel P91 (9Cr–1Mo–V–Nb) weld joints Part 1 – Microstructure
mahmoud allam
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Study of the Simulated Heat Affected Zone of Creep Resistant 9–12% Advanced Chromium Steel
Aleksandar Sedmak, Milorad Zrilić, Tomaž Vuherer
Materials and Manufacturing Processes, 2008
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Mechanical Behaviour of Modified 9Cr-1Mo Steel Weld
Deepthi tammana
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The Structure and Properties of 5 % Cr-0.5 % Mo Steel Welded Joints after Natural Ageing and Post-weld Heat Treatment
Raimondas Skindaras
Materials Science, 2012
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Mechanical properties and non-destructive evaluation of chromium–molybdenum ferritic steels for steam generator application
Raman Singh
International Journal of Pressure Vessels and Piping, 2004
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Martensitic/Ferritic Super Heat-resistant 650.DEG.C. Steels. Design and Testing of Model Alloys
G. Inden
ISIJ International, 2002
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Comparative Characterization of P91 and 10CrMo9-10 Creep Resistant Steel Welds
Abdullah Kaymakci
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9%Cr heat resistant steels: Alloy design, microstructure evolution and creep response at 650°C
G. Sauthoff
Materials Science and Engineering: A, 2011
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The Effect of Welding Positions on the Weldability of X20CrMoV11-1 Steels
Bünyamin ÇİÇEK
Hittite Journal of Science & Engineering, 2017
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Tensile Properties Variation Across the Dissimilar Metal Weld Joint Between Modified 9Cr–1Mo Ferritic Steel and 316LN Stainless Steel at RT and 550 °C
Gourav Rao
Metallography, Microstructure, and Analysis, 2018
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Review Type IV cracking in ferritic power plant steels
John Francis
Materials Science and Technology
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Development of Welding P92 Pipes Using the Reduced Pressure Electron Beam Welding Process for a Study of Creep Performance
Chris Punshon
ASME 2014 Symposium on Elevated Temperature Application of Materials for Fossil, Nuclear, and Petrochemical Industries, 2014
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Welding and weldability of candidate ferritic alloys for future advanced ultrasupercritical fossil power plants
Stan David
Science and Technology of Welding and Joining, 2013
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High-Temperature Degradation and Protection of Ferritic and Austenitic Steels in Steam Generators
Dra. Citlalli Gaona Tiburcio
Journal of Materials Engineering and Performance, 1998
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Effects of alloying and processing modifications on precipitation behavior and elevated temperature strength in 9% Cr ferritic/martensitic steels
Ömer Doğan
Materials Science and Engineering: A, 2018
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A Comparison of Creep Rupture Strength of Ferritic/Austenitic Dissimilar Weld Joints of Different Grades of Cr-Mo Ferritic Steels
MD Mathew
Metallurgical and Materials Transactions A, 2012
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Weld Behavior of Martensitic Steels and Ni-based Alloys for High Temperature Components
Magdalena Speicher
Procedia Engineering, 2013
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