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Abstract

In this article, different techniques to test notched small punch test samples in fracture conditions in aggressive environments are studied, based on the comparison of the micromechanisms at different rates. Pre-embrittled samples subsequently tested in air at rates conventionally employed (0.01 and 0.002 mm/s) are compared to embrittled ones tested in environment at the same rates (0.01 and 0.002 mm/s) and at a very slow rate (5E–5 mm/s). A set of samples tested in environment under a set of constant loads that produce very slow rates completes the experimental results. As a conclusion, it is recommended to test small punch test notched specimens in environment at very slow rates, of around E–6 mm/s, when characterizing in hydrogen embrittlement scenarios, in order to allow the material–environment interaction to govern the process.

Keywords

Small punch test hydrogen embrittlement punch rate fracture toughness

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References

Hamilton

JM.

The challenges of deep-water Artic development. Int J Offshore Polar Eng 2011; 21(4): 241–247.

Rehrl

Mraczek

Pichler

, et al. Mechanical properties and fracture behavior of hydrogen charged AHSS/UHSS grades at high- and low strain rate tests. Mater Sci Eng A 2014; 590: 360–367.

ISO 7539:2011. Parts 1 to 9: corrosion of metals and alloys.

Martínez-Pañeda

García

Rodrígez

Fracture toughness characterization through notched Small Punch test specimens. Mater Sci Eng A 2016; 657: 422–430.

Arroyo

Álvarez

Lacalle

Study of the energy for embrittlement damage initiation by SPT means. Estimation of KEAC in aggressive environments and rate considerations. Theor Appl Fract Mech 2016; 86: 61–68.

García

Arroyo

Rodríguez

, et al. Small Punch test methodologies for the analysis of the hydrogen embrittlement of structural steels. Theor Appl Fract Mech 2016; 86: 89–100.

Arroyo

Álvarez

Lacalle

, et al. Analysis of key factors of hydrogen environmental assisted cracking evaluation by Small Punch test on medium and high strength steels. Mater Sci Eng A 2017; 691: 180–194.

Manahan

Argon

Harling

OK.

The development of a miniaturized disk bend test for the determination of post irradiation mechanical properties. J Nucl Mater 1981; 104: 1545–1550.

CWA 15627:2007. Small Punch test method for metallic materials.

10.

ECISS/TC101/WG1. Metallic materials—Small Punch test method.

11.

Eskner

Sandstrom

Mechanical property using the Small Punch test. J Test Evaluat 1995; 32(4): 282–289.

12.

Lacalle

Álvarez

Arroyo

, et al. Methodology for fracture toughness estimation based on the use of Small Punch notched specimens and the CTOD concept. In: Proceedings of the 2nd international conference (SSTT) (ed Matocha

, et al), Ostrava, 2–4 October 2012.

13.

Finarelly

Roedig

Carsughi

Small Punch tests on austenitic and martensitic steels irradiated in a spallation environment with 530 MeV protons. J Nucl Mater 2004; 328: 146–150.

14.

Kim

Lee

BS.

Evaluation of ductile-brittle transition temperature before and after neutron irradiation for RPV steels using Small Punch tests. Nucl Eng Des 2005; 235: 1799–1805.

15.

Pressouyre

Bernstein

IM.

An example of the effect of hydrogen trapping on hydrogen embrittlement. Metal Trans A 1981; 12: 835–844.

16.

ASTM E1820-01. Standard test method for measurement of fracture toughness.

17.

ASTM E8/E8M-11. Standard test methods for testing of metallic materials.

18.

ASTM E399-12. Standard test method for linear-elastic plane-strain fracture toughness KIc of metallic materials.

19.

Gutiérrez-Solana

Álvarez

González

, et al. Stress corrosion cracking on weldable micro-alloyed steels. Contract no 7210-KB/327 final report, EUR 17249 EN, 1992-1995. Brussels: European Commission.

20.

Álvarez

Gutiérrez-Solana

Hydrogen induced cracking processes in structural microalloyed steels. Characterization and modelling. Mate Sci Forum 1998; 284–286: 303–310.

21.

Álvarez

Gutiérrez-Solana

An elastic-plastic fracture mechanics-based methodology to characterize cracking behavior and its applications to environmental assisted processes. Nucl Eng Des 1998; 188: 185–202.

22.

Kumar

German

Shih

CF.

An engineering approach to elastic-plastic solid (Research project EPRI NP-1931). New York: General Electric Company, 1981.

Rate effects on the estimation of fracture toughness by small punch tests in hydrogen embrittlement

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