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Experimental Mechanics

Erschienen in:

25.02.2016

Special Testing Equipment and Validation of Measurement Methodologies for High Temperature Low Cycle Fatigue Testing of Miniature Metallic Specimens

verfasst von: M. D. Callaghan, S. R. Humphries, M. Law, P. Bendeich, W. Y. Yeung

Erschienen in: Experimental Mechanics | Ausgabe 6/2016

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Abstract

A technique for high temperature low cycle fatigue testing of metallic materials has been developed, to determine fatigue behaviour through the testing of miniature specimens. The miniature specimen geometry was specifically designed, such that it could be manufactured from a small volume of material removed by chain-drilling extraction. An extensometry method to measure and control strain at the specimen shoulders during testing was adopted. This was undertaken to minimise the deleterious contact effects that can occur via extensometry attached at the gauge length of specimens, hence leading to premature failure and inaccurate fatigue data. By the application of this technique, the high temperature low cycle fatigue behaviour of 2.25Cr-1Mo steel was successfully characterised at 540 °C, under a fully reversed strain-controlled regime. The fatigue properties of the steel obtained from testing miniature specimens were shown to correlate well with existing literature for the material under comparable conditions, as determined by the testing of conventional standard-sized specimens.

Vorheriger Artikel Estimation of Phase and Its Higher Order Derivatives from a Single Complex Interferogram

Nächster Artikel Effect of Notch-Tip Radius on Dynamic Brittle Fracture of Polycarbonate

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Callaghan MD, Yeung WY, Ripley MI, Carr DG (2004) Measurement of fracture toughness of hydrided Zircaloy - 4. Materials Forum 27:68–73

Callaghan MD, Yeung WY, Ripley MI, Carr DG (2005) An analysis of deformation and fracture behaviour of Zircaloy-4 alloy using small punch test. Mater Sci Forum 475–479:1415–1420CrossRef

Nogami S, Nishimura A, Wakai E, Tanigawa H, Itoh T, Hasegawa A (2013) Development of fatigue life evaluation method using small specimen. J Nucl Mater 441(1–3):125–132CrossRef

Jaske CE (1987) Techniques for Examination and metallurgical damage assessment of pressure vessels. In: Performance and evaluation of light water reactor pressure vessels. Presented at the 1987 Pressure Vessels and Piping Conference, San Diego, CA, USA. ASME, p 103–114

Humphries SR, Yeung WY, Callaghan MD (2011) The effect of stress relaxation loading cycles on the creep behaviour of 2.25Cr–1Mo pressure vessel steel. Mater Sci Eng A 528(3):1216–1220CrossRef

British Energy Generation (2003) R5: Assessment procedure for the high temperature response of structures, Issue 3. British Energy Generation, United Kingdom

Callaghan MD, Humphries SR, Law M, Ho M, Yan K, Yeung WY (2011) Specimen-size dependency and modelling of energy evolution during high-temperature low-cycle fatigue of pressure vessel steel. Scr Mater 65(4):308–311CrossRef

Day MF, Harrison GF (1982) Design and calibration of extensometers and transducers. In: Loveday MS, Day MF, Dyson BF (eds) Measurement of high temperature mechanical properties of materials, United Kingdom. Her Majesty’s Stationery Office. p 225–240

Ellison EG, Lohr RD (1985) The extensometer-specimen interface. In: Sumner G, Livesey VB (eds) Techniques for high temperature fatigue testing. Elsevier Applied Science, London, pp 1–28

10.

Gostelow CR (1985) Strain measurements in high strength anisotropic materials. In: Sumner G, Livesey VB (eds) Techniques for high temperature fatigue testing. Elsevier Applied Science, London, pp 57–70

11.

Penny RK, Ellison EG, Webster GA (1966) Specimen alignment and strain measurement in axial creep tests. ASTM Mater Res Stand 6:76–84

12.

Thomas GB (1985) Axial extensometry for ridged specimens. In: Sumner G, Livesey VB (eds) Techniques for high temperature fatigue testing. Elsevier Applied Science, London, pp 45–56

13.

Walters DJ, Hales R (1981) An extensometer for creep-fatigue testing at elevated temperatures and low strain ranges (±0.2 per cent < δ∊ < 1.0 per cent). J Strain Anal Eng Des 16(2):145–147CrossRef

14.

Wells CH (1969) Elevated temperature testing methods. In: Manual on low cycle fatigue testing American Society for Testing and Materials, United States, p 87–99

15.

Olmi G (2012) A novel method for strain controlled tests. Exp Mech 52(4):379–393CrossRef

16.

Pang JHL, Xiong BS, Low TH (2004) Low cycle fatigue study of lead free 99.3Sn-0.7Cu solder alloy. Int J Fatigue 26(8):865–872CrossRef

17.

Tartaglia GP, de Vries MI, Horsten MG, Schmitt R (1994) Irradiation devices and testing facilities for small specimens of low-activation steels. J Nucl Mater 212–215(PART B):1655–1660CrossRef

18.

Grossbeck ML, Liu KC (1982) Fatigue behavior of type 316 stainless steel irradiated in a mixed spectrum fission reactor forming helium. Nucl Technol 58(3):538–547

19.

Vandermeulen W, Hendriks W, Massaut V, Van de Velde J (1988) Influence of neutron irradiation at 430 °C on the fatigue properties of SA 316L steel. J Nucl Mater 155–157:953–956CrossRef

20.

Ullmaier H, Shakib JI, Schmitz W, Faulkner RG, Little EA, Wienhold P (1990) Deterioration of fatigue life of 316L stainless steel due to TEXTOR exposure. J Nucl Mater 175(1–2):20–28CrossRef

21.

Furuya K, Nagata N, Watanabe R (1980) Low cycle fatigue properties of type 316 stainless steel in vacuum. J Nucl Mater 89(2–3):372–382CrossRef

22.

Gooch DJ (1988) Remanent life assessment of high temperature components. CEGB Research - Structural Integrity, vol 21. United Kingdom

23.

Ripley MI, Clare TE, Humphries SR (1990) Sampling and testing methods for remaining creep life assessment. In: Remaining life assessment of high temperature plant, Sydney, Australia

24.

Humphries SR (2009) High temperature stress relaxation properties of ferritic pressure vessel stee. Master, University of Technology Sydney, Australia

25.

ASTM International (1998) ASTM E 606 - 98 standard practice for strain-controlled fatigue testing. ASTM International United States

26.

Klueh RL, Nelson AT (2007) Ferritic/martensitic steels for next-generation reactors. J Nucl Mater 371(1–3):37–52CrossRef

27.

Lord DC, Coffin LF (1969) High temperature materials behaviour. In: Manual on low cycle fatigue testing American Society for Testing and Materials, United States, p 129–148

28.

Slot T, Stentz RH, Berling JT (1969) Controlled-strain testing procedures. In: Manual on low cycle fatigue testing American Society for Testing and Materials, United States, p 100–128

29.

Sumner G (1985) Heating methods and grips. In: Sumner G, Livesey VB (eds) Techniques for high temperature fatigue testing. Elsevier Applied Science, London, pp 71–97

30.

Humphries SR, Snowden KU, Yeung WY (2007) Assessment of the high temperature stress relaxation properties of ferritic pressure vessel steel. In: Proceedings of the 6th International Conference on Durability and Fatigue. 2007. Engineering Integrity Society, p 1-10

31.

Wynn J, Wood DS (1985) Side contact axial extensometry. In: Sumner G, Livesey VB (eds) Techniques for high temperature fatigue testing. Elsevier Applied Science, London, pp 29–43

32.

Yun GJ, Abdullah ABM, Binienda W (2011) Development of a closed-loop high-cycle resonant fatigue testing system. Exp Mech 52(3):275–288CrossRef

33.

Callaghan MD, Humphries SR, Law M, Ho M, Bendeich P, Li H, Yeung WY (2010) Energy-based approach for the evaluation of low cycle fatigue behaviour of 2.25Cr–1Mo steel at elevated temperature. Mater Sci Eng A 527(21–22):5619–5623CrossRef

34.

Raske DT, Morrow J (1969) Mechanics of materials in low cycle fatigue testing. In: Manual on low cycle fatigue testing American Society for Testing and Materials, United States, p 1-26

35.

National Research Institute for Metals (1989) Data sheets on elevated-temperature, time-dependent Low-cycle fatigue properties of SCMV 4 (2.25Cr-1Mo) steel plate for pressure vessels (No.62). National Research Institute for Metals, Tokyo

36.

Skelton RP (1994) Bauschinger and yield effects during cyclic loading of high temperature alloys at 550°C. Mater Sci Technol 10(7):627–639CrossRef

37.

Skelton RP, Challenger KD (1984) Fatigue crack growth in 2 1 4Cr-1Mo steel at 525°C I: Effects of environment and dwell. Mater Sci Eng 65(2):271–281CrossRef

38.

Wittke H, Olfe J, Rie KT (1997) Description of stress-strain hysteresis loops with a simple approach. Int J Fatigue 19(2):141–149CrossRef

39.

Ramberg W, Osgood WR (1943) Description of stress–strain curves by three parameters. National Advisory Committee For Aeronautics, Washington DC

40.

Bannantine JA, Comer JJ, Handrock JL (1990) Fundamentals of metal fatigue analysis. Prentice Hall, USA

41.

Dieter GE (1988) Mechanical metallurgy. McGraw-Hill Book Co. Materials Science and Metallurgy, Singapore

42.

Ellyin F (1997) Fatigue damage, crack growth, and life prediction. Chapman & Hall, London

43.

Landgraf RW, Morrow J, Endo T (1969) Determination of the cyclic stress-strain curve. J Mater Civ Eng 4:176–188

44.

National Research Institute for Metals (1978) Data sheets on elevated-tempearture, low-cycle fatigue properties of SCMV 4 (2.25Cr-1Mo) steel plate for pressure vessels (No7). National Research Institute for Metals, Tokyo

45.

Inoue T, Igari T, Okazaki M, Sakane M, Tokimasa K (1989) Fatigue-creep life prediction of 2 1 4Cr-1Mo steel by inelastic analysis. Nucl Eng Des 114(3):311–321CrossRef

46.

Coffin LF (1954) A study of the effects of cyclic thermal stresses on a ductile metal. Trans ASME 76:931–950

47.

Manson SS (1953) Behavior of materials under conditions of thermal stress. In: Heat transfer symposium, University of Michigan. Engineering Research Institute, p 9-75

48.

Basquin OH (1910) The exponential law of endurance tests. Proc ASTM 10:625–630

49.

Ainsworth RA (2006) R5 procedures for assessing structural integrity of components under creep and creep–fatigue conditions. Int Mater Rev 51(2):107–126MathSciNetCrossRef

Titel: Special Testing Equipment and Validation of Measurement Methodologies for High Temperature Low Cycle Fatigue Testing of Miniature Metallic Specimens
verfasst von: M. D. Callaghan
S. R. Humphries
M. Law
P. Bendeich
W. Y. Yeung
Publikationsdatum: 25.02.2016
Verlag: Springer US
Erschienen in: Experimental Mechanics / Ausgabe 6/2016
Print ISSN: 0014-4851
Elektronische ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-016-0145-2

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