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Strength of Materials
Published in: Strength of Materials 3/2019

15-08-2019

Determination of the Mechanical Characteristics of the Metal of the Equipment of Nuclear Power Stations from Hardness Measurement and Indentation Data

Authors: R. V. Kravchuk, O. A. Katok, V. V. Kharchenko, A. A. Kotlyarenko, M. P. Rudnyts’kyi

Published in: Strength of Materials | Issue 3/2019

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Abstract

The main normative documents for the nuclear power industry of Ukraine, which regulate the determination of mechanical characteristics from hardness measurement data, are considered and analyzed. It has been shown that the use of these documents for monitoring the technical condition of the equipment of nuclear power stations, in particular of the metals of the bypass pipeline of the high-pressure pump SAOZ of the core emergency cooling system (08Kh18N10T steel), coil from the welded joint zone of the Du 600 inlet branch pipe of the IRA30S02 non-return valve (16GS steel), and the body shell of the dismounted PV2500-97-10A (09G2S steel) high-pressure heater calls for their more detailed justification. To determine the mechanical characteristics of metals and to increase the reliability of their evaluation in nondestructive monitoring, a standard developed by the Pisarenko Institute of Problems of Strength of the National Academy of Sciences of Ukraine is used. According to this standard, the evaluation is made not only on the basis of hardness measurement data, but also by the method of instrumented indentation. It has been shown that this method is more efficient for the determination of the strength characteristics of steels. The difference between the ultimate strength and yield strength values according to this standard and those obtained in tensile tests is not over 8.6% and not over 6.6%, respectively. When diagnosing the technical condition of the metal of pipelines, indentation tests allow one to determine strength characteristics not only in the axial and tangential directions, but also in the radial direction.
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Literature
1.
PNAÉ G-7-008-89. Rules for the Design and Safe Operation of the Equipment and Pipelines of Nuclear Power Plants [in Russian], Scientific-Technical Center for Nuclear and Radiation Safety of the Gosatomnadzor of Russia, Moscow (2003).
2.
SOU-N NAEK 133:2016. Engineering, Scientific and Technical Support. Procedure for Determining the Mechanical Properties of Metal from Hardness Test Data [in Ukrainian], National Nuclear Power Generating Company “Enerhoatom,” Kyiv (2016).
3.
TPKM-10-01. Model Program of the Periodic Control of the Mechanical Properties of the Metal of Pipelines of Nuclear Power Stations with WWER-1000 Reactors [in Russian], Kiev (2011).
4.
RD ÉO 0027-2005. Instructions for Determining the Mechanical Properties of the Metal of the Equipment of Power Stations by Specimen-Free Methods from Hardness Characteristics [in Russian], Rosénergoatom Concern, Moscow (2005).
5.
GOST R 57172-2016. Technical Diagnostics. Determination of Residual Surface Stresses by the Method of Instrumented Indentation. General Requirements [in Russian], Valid since October 10, 2016.
6.
GOST R 56232-2014. Determination of the Stress–Strain Diagram by the Method of Instrumented Indentation of a Ball. General Requirements [in Russian], Valid since November 11, 2014.
7.
M. B. Bakirov, V. V. Potapov, I. V. Frolov, and D. A. Nikolaev, “Development and introduction of a specimen-free method of kinetic indentation into the practice of the operational control of the equipment and pipelines of nuclear power stations with WWER. Development of a new standard for the kinetic indentation method,” in: Proc. of the IVth Int. Sci.-Tech. Conf. on Ensuring the Safety of Nuclear Power Stations with WWR (May 23–26, 2005, Podolsk), Federal State Unitary Enterprise Development Design Office “Gidropress” (2005).
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A. S. Hamada, F. M. Haggag, and D. A. Porter, “Non-destructive determination of the yield strength and flow properties of high-manganese twinning-induced plasticity steel,” Mater. Sci. Eng. A, 558, 766–770 (2012).CrossRef
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V. M. Matyunin and A. Yu. Marchenko, “Interrelation between the strains and hardening parameters of metal under tension and plastic indentation,” Zavod. Lab. Diagn. Mater., 82, No. 9, 51–57 (2016).
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P. S. Yukhymets’, O. P. Hopkalo, and O. E. Hopkalo, “Calulated and experimental fundamentals of a procedure for evaluating the residual life of typical pipeline elements with surface defects,” in: Collection of Scientific Papers on the Results Obtained in 2013–2015 [in Ukrainian], Paton Electric Welding Institute of the National Academy of Sciences of Ukraine, Kyiv (2015).
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O. A. Katok, N. P. Rudnitskii, V. V. Kharchenko, et al., “On the determination of the mechanical characteristics of steels from hardness test results,” Strength Mater., 46, No. 6, 773–776 (2014).CrossRef
12.
GOST 10006-80. Metal Pipes. Tensile Testing Method [in Russian], Valid since July 1, 1980.
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DSTU EN 10002-1:2006. Metallic Materials. Tensile Testing. Part 1: Room-Temperature Test Method [in Ukrainian], Valid since July 1, 2008.
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DSTU ISO 6506-1:2007. Metallic Materials. Determination of Brinell Hardness. Part 1: Room-Temperature Test Method [in Ukrainian], Valid since January 1, 2009.
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ISO 14577-1:2015. Metallic Materials – Instrumented Indentation Test for Hardness and Materials Parameters – Part 1: Test Method, International Organization for Standardization (2015).
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V. V. Kharchenko, N. P. Rudnitskii, O. A. Katok et al., “Installation for determining the mechanical characteristics of structural materials using instrumented indentation,” in: Reliability and Life of Machines and Structures [in Russian], Issue 27 (2007), pp. 140–147.
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SOU-56-28-2018. Metallic Materials. Determination of the Mechanical Characteristics of Structural Materials from Brinell Hardness Characteristics and by the Method of Instrumented Indentation. Testing Method [in Ukrainian], Pisarenko Institute of Problems of Strength of the National Academy of Sciences of Ukraine, Kyiv (2018).
Metadata
Title
Determination of the Mechanical Characteristics of the Metal of the Equipment of Nuclear Power Stations from Hardness Measurement and Indentation Data
Authors
R. V. Kravchuk
O. A. Katok
V. V. Kharchenko
A. A. Kotlyarenko
M. P. Rudnyts’kyi
Publication date
15-08-2019
Publisher
Springer US
Published in
Strength of Materials / Issue 3/2019
Print ISSN: 0039-2316
Electronic ISSN: 1573-9325
DOI
https://doi.org/10.1007/s11223-019-00084-7

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