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Materials at High Temperatures Volume 38, 2021 - Issue 6
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Research Article

Ductility coaxing during creep and tensile deformation of high temperature alloys

R. P. SkeltonConsultant, Guildford, UKCorrespondence[email protected]
Pages 426-451 | Received 23 Nov 2020, Accepted 26 Aug 2021, Published online: 22 Sep 2021

References

  • Monkman FC, Grant NJ. An empirical relationship between rupture life and minimum creep rate in creep-rupture tests. Proc Am Soc Test Mater. 1956;56:593–620.
  • Skelton RP, Webster GA. Axial and diametral cyclic stress-strain response in plain and circumferentially notched cylindrical bars at 550°C. J Strain Anal. 2006;41(4):265–286.
  • NIMS Structural Materials Data Sheets, Creep data Sheet No. 48A. Data sheets on the elevated temperature properties of 9Cr-0.5Mo-1.8W-V-Nb steel tubes for boilers and heat exchangers. NRIM, Japan 2016.
  • Skelton RP. Deformation, diffusion and ductility during creep – continuous void nucleation and creep-fatigue damage. Mater High Temp. 2017;34(2):121–133.
  • Ewald J, Kern T-U. The role of the material parameter uniform elongation. 4th International ECCC Conference. September 2017, Düsseldorf, Germany.
  • Holdsworth SR. Creep-ductility of high temperature steels: a review. Metals. 2019;9(3):342–355.
  • Abe F. Creep deformation behaviour and its effect on creep life and rupture ductility of W-Mo balanced 9Cr steels. Mater High Temp. 2020;37(3):165–177.
  • Abe F. Creep rupture ductility of Gr.91 and Gr.92 at 550°C to 700°C. Mater High Temp. 2020;37(4):243–255.
  • Abe F. Influence of chemical compositions and creep test conditions on UK R5 creep ductility parameter lambda of W-Mo-balanced 9Cr steel. Mater High Temp. 2020;37(5):309–320.
  • Parker JD. Creep ductility considerations for high energy components manufactured from creep strength enhanced steels. Mater High Temp. 2017;34(2):109–120.
  • Ancelet O, Matheron P. Development of a new measurement system for tensile testing. In: Proc ASME pressure vessels and piping division. Vols. PVP2010-25667. 2010. p. 1–9. ASME: Washington.
  • Lim R, Sauzay M, Dalle F, et al. Modelling of necking during creep of grade 91 steel. Fracture of materials and structures. In: Klingbeil D, Vormwald M, Eulitz KG, eds. Dresden Germany: ECF18 Aug. 2010, (DVM 8 2010–2017. Deutscher Verband für Materialforschung.
  • Lim R. Numerical and experimental study of creep of Grade 91 steel at high temperature. PhD thesis, École Nationale Supérieure des Mines de Paris. 2011.
  • Giroux P–F. Experimental study and simulation of cyclic softening of tempered martensite ferritic steels. Materials PhD thesis, École Nationale Supérieure des Mines de Paris, 2011.
  • ISO. 204 Metallic Materials – uniaxial creep testing in tension – method of test. Geneva: International Organisation for Standardisation; 2018.
  • ISO. 6892 Metallic materials- Tensile testing Part 2: method of test at elevated temperature. Geneva: International Organisation for Standardisation; 2018.
  • Conway JB, Stentz RH, Berling JT, et al. Fatigue, tensile and relaxation behaviour of stainless steels. Ohio: US Atomic Energy Commission; 1981. p. 151ff.
  • Garofalo F, Richmond O, Domis WF. Design of apparatus for constant stress or constant load creep tests. J Basic Eng. 1962;84(2):287–293.
  • Loveday MS, King BL. Uniaxial testing apparatus and testpieces. In: Loveday MS, Day MF, Dyson BF, editors. Meaurement of high temperature mechanical properties of materials. London: HMSO; 1982. p. 128–157.
  • Clay BD, Evans HE. The computation of constant-load creep curves. Nucl Eng Design. 1976;39(2–3):289–292.
  • Aktaa J, Schinke B. Creep lifetime under constant load and constant stress: theory and experiment. J Test Eval. 1996;24(4):212–222.
  • Parker JD, Siefert JA. The creep and fracture behaviour of tempered martensitic steels. Mater High Temp. 2018;35(6):491–503.
  • Parker JD. Life assessment of power plant components operating in the creep range. In: 3rd International conference on creep fracture of engineering materials and structures. Inst Metals, London, 1987, pp. 915–927.
  • Bueno LO, Sobrinho JFR. Correlation between creep and hot tensile behaviour for 2.25Cr-1Mo steel from 500°C to 700°C Part 1: an assessment according to usual relations involving stress, temperature, strain rate and rupture time. Revisita Materia. 2012;17(3):1098–1108
  • Skelton RP. Effect of strain rate on the high strain fatigue properties of a 20%Cr/25%Ni/Nb stabilised stainless steel. Mater Sci Eng. 1973;11(4):195–202.
  • Hales R, Holdsworth SR, O’Donnell MP, et al. A code of practice for the determination of cyclic stress-strain data. Mater High Temp. 2002;19(4):165–185.
  • Skelton RP. Bauschinger yield in the range 400-1025°C during cyclic deformation of high temperature alloys. Mater High Temp. 2013;30(4):241–260.
  • Venard JT, Weir JR. In-reactor stress-rupture properties of a 20Cr-25Ni columbium-stabilized steel. In: Weber CE, editor. Flow and fracture of metals and alloys in nuclear environments. Philadelphia: Amer Soc Test Mater; 1965. p. 269–282.
  • Roberts AC, Evans HE. Effects of titanium and silicon additions on creep behaviour of TiN-dispersion-strenghthened 20%Cr25%Ni austenitic steel. In: J. Barford, editor. Mechanical behaviour and nuclear applications of stainless steel at elevated temperatures, Book 280. London: The Metals Society; 1982. p. 51–57.
  • McLaughlin IR. Temperature dependence of steady-state creep in 20%Cr25%Ni/Nb stabilized stainless steel. In: Creep strength in steel and high temperature alloys. London: The Metals Society; 1972. p. 86–90.
  • Brear JM, Jarvis P. Living with creep damage outside the creep range. VTT Symposium 246/247: Life management and maintenance for power plants. Energy Materials. 2007;2:109–116. Helsinki-Stockholm.
  • Alexander JM. Strength of materials, Vol. 1: fundamentals. Chichester: Ellis Horwood; 1981. p. 35 ff.
  • Ramberg W, Osgood WR. Description of stress-strain curves by three parameters. Tech. Note No. 902. NACA; 1943. Washington.
  • Skelton RP, Wee ST, Webster GA. Cyclic stress-strain behaviour of circumferentially notched cylindrical bars at high temperature. Mater High Temp. 2001;18(3):139–152.
  • Dean DW, Editor. Assessment procedure for the high temperature response of structures. Issue 3, Revision 002. Barnwood UK: EDF Nuclear Generation Ltd.; 2014.
  • Takahashi Y. Study on creep-fatigue evaluation procedures for high-chromium steels—Part I: test results and life prediction based on measured stress relaxation. Int J Press Vessels Pip. 2008;85(6):406–422.
  • Takahashi Y. Study on creep-fatigue evaluation procedures for high chromium steels—Part II: sensitivity to calculated deformation. Int J Press Vessels Pip. 2008;85(6):423–440.
  • Mayer K-H, Kern TU, Scholz A, et al. Influence of melting methods on the creep and ductility behaviour of boiler and turbine steels. 4th Int ECCC Conference, September 2017, Düsseldorf, Germany.
  • Woodford DA. Creep damage and the remaining life concept. J Eng Mater Technol. 1979;101(4):311–316.
  • Bueno L-O. On the equivalence between hot tensile data and creep data. In: Proc. 61st Int. Congress of the ABM. Rio de Janeiro; 2006. 2245–2258. (Researchgate Publication 328968826).
  • Xue J, Zhou C, Lu X, et al. Plastic limit load of Grade 91 steel pipe containing local wall thinning defect at high temperature. Eng Fail Anal. 2015(57):171–187.
  • Begum S, Karim ANM, Zamani SM, et al. Wall thinning and creep damage analysis in boiler tube and optimization of operating conditions. J Mechatron. 2013;1:1–6.
  • Bethmont M. Damage and lifetime of fossil power plant components. Mater High Temp. 1998;15(3–4):231–238.
  • Webster GA, Holdsworth SR, Loveday MS, et al. A code of practice for conducting notched bar creep tests and for interpreting the data. Fatigue Fract Eng Mater Struct. 2004;27(4):319–342.
  • Kerr DC, Nikbin KM, Webster GA, et al. Creep strain determinations across the root of a notch. In: Ziebs J, editors. Local strain and temperature measurements in non-uniform fields at elevated temperatures. Cambridge: Woodhead Publishing Ltd.; 1999. p. 263–273.
  • Lupinc V. Creep: introduction and phenomenology. In: bressrs J. editor. Creep and fracture in high temperature alloys. London: Applied Science Publishers Ltd.; 1981. p. 7–40.
  • Osgerby S, Dyson BF. Constant strain-rate testing: prediction of stress-strain curves from constant-load creep data. In: Wilshire B, Evans RW, editors. Proc. 5th Conf. Creep and Fracture of Engineering Materials, and Structures. London: Swansea, Inst Metals; 1993. p. 53–61.

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