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2012 | OriginalPaper | Chapter

Development of Oxide Dispersion Strengthened Steels for High Temperature Nuclear Structural Applications

Authors : Hanliang Zhu, Tao Wei, Robert Harrison, Lyndon Edwards, Kouichi Maruyama

Published in: Engineering Asset Management and Infrastructure Sustainability

Publisher: Springer London

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Abstract

Oxide dispersion strengthened (ODS) steels are the most promising candidate materials for high temperature nuclear applications. Mechanical alloying and subsequent thermomechanical treatments are applied to manufacture the ODS steels. Recently improved chemical composition and manufacturing processes have been developed to produce ultrafine grain size with high number-density of nanoscale oxide particles and high dislocation density in the microstructure. Usually, fine grains degrade creep resistance at elevated temperatures. However, the fine-grained ODS steels exhibit not only good radiation resistance, but also superior creep properties. The present paper reviews the chemical compositions, manufacturing processing, microstructural features, thermal creep properties and radiation resistance of recently developed ODS steels. Special attention is paid to the effects of the fine-scale microstructural features on thermal creep and radiation resistance.

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previous chapter Handling Incomplete Data in Survival Analysis with Multiple Covariates

Development of radiation resistant reactor core structural materials. http://www.iaea.org/About/Policy/GC/GC51/GC51InfDocuments/English/gc51inf-3-att7_en.pdf. Accessed 29 Sept 2010

Kurtz RJ, Alamo A, Lucon E, Huang Q, Jitsukawa S, Kimura A, Klueh RL, Odette GR, Petersen C, Sokolov MA, Spätig P, Rensman JW (2009) Recent progress toward development of reduced activation ferritic/martensitic steels for fusion structural applications. J Nucl Mater 386–388:411–417CrossRef

Zinkle SJ (2005) Advanced materials for fusion technology. Fusion Eng Des 74:31–40CrossRef

Allen TR, Busby JT, Klueh RL, Maloy SA, Toloczko MB (2008) Cladding and duct materials for advanced nuclear recycle reactors. JOM 60(1):15–23CrossRef

Murty KL, Charit I (2008) Structural materials for Gen-IV nuclear reactors: challenges and opportunities. J Nucl Mater 383:189–195CrossRef

Schneibel JH, Liu CT, Miller MK, Mills MJ, Sarosi P, Heilmaier M, Sturm D (2009) Ultrafine-grained nanocluster-strengthened alloys with unusually high creep strength. Scripta Mater 61:793–796CrossRef

Miller MK, Russell KF, Hoelzer DT (2006) Characterization of precipitates in MA/ODS ferritic alloys. J Nucl Mater 351:261–268CrossRef

West MK (2006) Processing and characterization of oxide dispersion strengthened 14YWT ferritic alloys. Ph.D thesis, The University of Tennessee, Knoxville

Kassner ME, Perez-Prado MT (2004) Fundamentals of creep in metals and alloys. Elsevier Ltd, Oxford

10.

Odette GR, Alinger MJ, Wirth BD (2008) Recent developments in irradiation-resistant steels. Ann Rev Mater Res 38:471–503CrossRef

11.

Ennis PJ, Czyrska-Filemonowicz A (2002) Recent advances in creep resistant steels for power plant applications. Power Plant: Opera Maintence Mater Issues 1(1):1–28

12.

Abe F (2008) Precipitate design for creep strengthening of 9% Cr tempered martensitic steel for ultra-supercritical power plants. Sci Technol Adv Mater 9:013002CrossRef

13.

Hayashi T, Sarosi PM, Schneibel JH, Miller MJ (2008) Creep response and deformation processes in nanocluster-strengthened ferritic steels. Acta Mater 56:1407–1416CrossRef

14.

Klueh RL (2005) Elevated temperature ferritic and martensitic steels and their application to future nuclear reactors. Int Mater Rev 50:287–310CrossRef

15.

Inoure M, Kaito T, Ohtsuka S (2007) Research and development of oxide dispersion strengthened ferritic steels for sodium cooled fast breeder reactor fuels. NATO advanced study institute on materials for generation-IV nuclear reactors, Institut d’Etudes Scientifiques de Cargese—Cargese, CORSICA, France

16.

Ei-Genk MS, Tournier JM (2005) A review of refractory metal alloys and mechanically alloyed-oxide dispersion strengthened steels for space nuclear power systems. J Nucl Mater 340:93–112CrossRef

17.

Oh S, Lee JS, Jang C, Kimura A (2009) Irradiation hardening and embrittlement in high-Cr oxide dispersion strengthened steels. J Nucl Mater 386–388:503–506CrossRef

18.

Takaya S, Furukawa T, Aoto K, Muller G, Weisenburger A, Heinzel A, Inoue M, Okuda T, Abe F, Ohnuki S, Fujisawa T, Kimura A (2009) Corrosion behavior of Al-alloying high Cr-ODS steels in lead-bismuth eutectic. J Nucl Mater 386:507–510CrossRef

19.

Susila P, Sturm D, Heilmaier M, Murty BS, Sarma VS (2010) Microstructural studies on nanocrystalline oxide dispersion strengthened austenitic (Fe-18Cr-8Ni-2 W–0.25Y(2)O(3)) alloy synthesized by high energy ball milling and vacuum hot pressing. J Mater Sci 45:4858–4865CrossRef

20.

Ukai S, Mizuta S, Fujiwara M, Okuda T, Kobayashi T (2002) Development of 9Cr-ODS martensitic steel claddings for fuel pins by means of ferrite to austenite phase transformation. J Nucl Sci Technol 39:778–788CrossRef

21.

Ukai S, Nishida T, Okada H, Okuda T, Fujiwara M, Asabe K (1997) Development of oxide dispersion strengthened ferritic steels for FBR core application (I). Improvement of mechanical properties by recrystallization processing. J Nucl Sci Technol 34:256–263

22.

Okada H, Ukai S, Inoue M (1996) Effects of grain morphology and texture on high temperature deformation in oxide dispersion strengthened ferritic steel. J Nucl Sci Technol 33:936–943

23.

Ukai S, Nishida T, Okuda T, Yoshitake T (1998) R&D of oxide dispersion strengthened ferritic martensitic steels for FBR. J Nucl Mater 258–263:1745–1749CrossRef

24.

Alinger MJ, Odette GR, Hoelzer DT (2009) On the role of alloy composition and processing parameters in nanocluster formation and dispersion strengthening in nanostuctured ferritic alloys. Acta Mater 57:392–406CrossRef

25.

Sakasegawa H, Chaffron L, Legendre F, Boulanger L, Cozzika T, Brocq M, Carlan Y (2009) Correlation between chemical composition and size of very small oxide particles in the MA957 ODS ferritic alloy. J Nucl Mater 384:115–118CrossRef

26.

Ukai S, Fujiwara M (2002) Perspective of ODS alloys application in nuclear environments. J Nucl Mater 307–311:749–757CrossRef

27.

Ukai S, Ohtsuka S (2007) Nano-mesoscopic structure control in 9Cr–ODS ferritic steels. Energy Mater Mater Sci Eng Energy Syst 2(1):26–35CrossRef

28.

Ukai S, Mizuta S, Yoshitake T, Okuda T, Fujiwara M, Hagi S, Kobayashi T (2000) Tube manufacturing and characterization of oxide dispersion strengthened ferritic steels. J Nucl Mater 283–287:702–706CrossRef

29.

Ukai S, Okuda T, Fujiwara M, Kobayashi T, Mizuta S, Nakashima H (2002) Characterization of High Temperature Creep Properties in Recrystallized 12Cr–ODS Ferritic Steel Claddings. J Nucl Sci Technol 39(8):872–879CrossRef

30.

Frajtag P, Charit I, Murty KL (2007) Structural materials for the next generation nuclear reactors—an overview. 2007 International Congress on Advances in Nuclear Power Plants, Nice Acropolis, France, http://icapp.ans.org/icapp07/MONDAY/KN-B/7315Gen%20IV%20Presentation-final.pdf. Accessed 20 Sep 2010

31.

Ruano O, Wadsworth J, Sherby OD (1985) Deformation mechanisms in an austenitic stainless steel (25Cr-20Ni) at elevated temperature. J Mater Sci 20:3735–3744CrossRef

32.

Luthy H, White RA, Sherby OD (1979) Grain boundary sliding and deformation mechanism maps. Mater Sci Eng A Struct Mater Prop Microstruc Process 39:211–216

33.

Pan J, Tong J, Tian M (2002) Fundamental of Materials Science. Qinghua University Publisher, Beijing

34.

Zhu H, Dahle AK, Ghosh AK (2009) Effect of Sc and Zn additions on microstructure and hot formability of Al-Mg sheet alloys. Metallurg Mater Trans A 40(3):598–608CrossRef

35.

Meyers MA, Mishra A, Benson DJ (2006) Mechanical properties of nanocrystalline materials. Prog Mater Sci 51:427–556CrossRef

36.

McClintock DA, Sokolov MA, Hoelzer DT, Nanstad RK (2009) Mechanical properties of irradiated ODS-EUROFER and nanocluster strengthened 14YWT. J Nucl Mater 392:353–359CrossRef

37.

Abe F (2005) Effect of fine precipitation and subsequent coarsening of Fe2 W laves phase on the creep deformation behavior of tempered martensitic 9Cr-W steels. Metallur Mater Trans A 36:321–332CrossRef

38.

Little EA (2006) Development of radiation resistant materials for advanced nuclear power plant. Mater Sci Technol 22(5):491–518CrossRef

39.

Allen TR, Gan J, Cole JI, Miller MK, Busby JT, Shutthanandan S, Thevuthasan S (2008) Radiation response of a 9 chromium oxide dispersion strengthened steel to heavy ion irradiation. J Nucl Mater 375:26–37CrossRef

40.

Nanstad RK, McClintock DA, Hoelzer DT, Tan L, Allen TR (2009) High temperature irradiation effects in selected Generation IV structural alloys. J Nucl Mater 392:331–340CrossRef

41.

Yutani K, Kishimoto H, Kasada R, Kimura A (2007) Evaluation of helium effects on swelling behavior of oxide dispersion strengthened ferritic steels under ion irradiation. J Nucl Mater 367–370:423–427CrossRef

42.

Chen J, Jung P, Hoffelner W, Ullmaier H (2008) Dislocation loops and bubbles in oxide dispersion strengthened ferritic steel after helium implantation under stress. Acta Mater 56:250–258CrossRef

43.

Alamo A, Bertin JL, Shamardin VK, Wident P (2007) Mechanical properties of 9Cr martensitic steels and ODS-FeCr alloys after neutron irradiation at 325 degrees C up to 42 dpa. J Nucl Mater 367–370:54–59CrossRef

44.

Chen J, Pouchon MA, Kimura A, Jung P, Hoffelner W (2009) Irradiation creep and microstructural changes in an advanced ODS ferritic steel during helium implantation under stress. J Nucl Mater 386–388:143–146CrossRef

45.

Chen J, Hoffelner W (2009) Irradiation creep of oxide dispersion strengthened (ODS) steels for advanced nuclear applications. J Nucl Mater 392:360–363CrossRef

46.

McClintock DA, Hoelzer DT, Sokolov MA, Nanstad RK (2009) Mechanical properties of neutron irradiated nanostructured ferritic alloy 14YWT. J Nucl Mater 386–388:307–311CrossRef

47.

Czyrska-Filemonowicz A, Dubiel B (1997) Mechanically alloyed, ferritic oxide dispersion strengthened alloys: Structure and properties. J Mater Process Technol 64:53–64CrossRef

48.

Evans RW, Preston JA, Wilshire B, Little EA (1993) Creep and creep fracture of an oxide-dispersion-strengthened 13-percent chromium ferritic steel. Mater Sci Eng A Struct Mater Prop Microstruct Process 167:65–72CrossRef

49.

Lindau R, Moslang A, Schirra M, Schlossmacher P, Klimenkov M (2002) Mechanical and microstructural properties of a hipped RAFM ODS-steel. J Nucl Mater 307–311:769–772CrossRef

50.

Ukai S, Ohtsuka S, Kaito T, Sakasegawa H, Chikata N, Hayashi S, Ohnuki S (2009) High-temperature strength characterization of advanced 9Cr-ODS ferritic steels. Mater Sci Eng A Struct Mater Prop Microstruct Process 510–511:115–120CrossRef

51.

Ageev VS, Vil’danova NF, Kozlov KA, Kochetkova TN, Nikitina AA, Sagaradze VV, Safronov BV, Tsvelev VV, Chukanov AP (2008) Structure and thermal creep of the oxide-dispersion-strengthened EP-450 reactor steel. Phys Metals Metallogr 106(3):318–325CrossRef

Title: Development of Oxide Dispersion Strengthened Steels for High Temperature Nuclear Structural Applications
Authors: Hanliang Zhu
Tao Wei
Robert Harrison
Lyndon Edwards
Kouichi Maruyama
Publisher: Springer London
Book: Engineering Asset Management and Infrastructure Sustainability
Print ISBN: 978-0-85729-301-5

Electronic ISBN: 978-0-85729-493-7

Copyright Year: 2012
DOI: https://doi.org/10.1007/978-0-85729-493-7_89

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