Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel

Accurate quantification of the current accumulated material damage in the steel wall of a reactor vessel is essential in assessing the safety and integrity of the structure. In this study, a framework for mechanism-based structural life monitoring and assessment procedure is proposed and examined. T...

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Main Author: Khattak, Muhammad Adil
Format: Thesis
Language:English
Published: 2009
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Online Access:http://eprints.utm.my/id/eprint/16941/1/MuhammadAdilKhattakPFKM2009.pdf
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spelling my-utm-ep.169412018-06-25T08:59:56Z Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel 2009 Khattak, Muhammad Adil TJ Mechanical engineering and machinery Accurate quantification of the current accumulated material damage in the steel wall of a reactor vessel is essential in assessing the safety and integrity of the structure. In this study, a framework for mechanism-based structural life monitoring and assessment procedure is proposed and examined. The methodology is based on the competition between damage evolution and continual strength degradation of the material throughout the design life of the component. In this respect, damage evolution characteristics of the welded vessel steel are established through controlled laboratory experiments. Two types of steels, type-316 austenitic stainless steel and A516 Gr70 pressure vessel steel are used in this research. The samples (SS316 austenitic stainless steel) were heat treated (HT) at 500°C, 800°C and 1000°C followed by furnace cooling. This work examines the effect of different microstructures of austenitic stainless steel on both static and fatigue responses of the alloy. Type A516 steels are commonly used in welded construction of pressure vessels and boilers. Prolonged exposure to high operating temperature and fluctuating pressure could induce undesirable microstructure evolution, particularly in the vicinity of the welded connection. This in turn, modifies the long-term mechanics response of the structure and affects structural reliability prediction. This research attempts to quantify the effects of absorbed hydrogen and thermal aging on crack-tip plastic zone, impact toughness and fatigue crack growth response of the Type A516 Gr70 steel plate and the associated heat affected zone (HAZ). Ductileto- brittle transition temperature (TDBTT) values of Base Metal (BM) and Weld Metal (WM) are -26°C and -20°C respectively, while TDBTT value of HAZ is -32°C. Results show that a crack continuously grows in the base metal or HAZ with increasing applied crack tip driving force, Ka. The threshold stress intensity factor range, Kth for HAZ (13.2 MPam) is lower than that for the base metal (15.3 MPam). Prolonged thermal exposure further lowers Kth of HAZ to 11.4 MPam. 2009 Thesis http://eprints.utm.my/id/eprint/16941/ http://eprints.utm.my/id/eprint/16941/1/MuhammadAdilKhattakPFKM2009.pdf application/pdf en public phd doctoral Universiti Teknologi Malaysia, Faculty of Mechanical Engineering Faculty of Mechanical Engineering
institution Universiti Teknologi Malaysia
collection UTM Institutional Repository
language English
topic TJ Mechanical engineering and machinery
spellingShingle TJ Mechanical engineering and machinery
Khattak, Muhammad Adil
Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
description Accurate quantification of the current accumulated material damage in the steel wall of a reactor vessel is essential in assessing the safety and integrity of the structure. In this study, a framework for mechanism-based structural life monitoring and assessment procedure is proposed and examined. The methodology is based on the competition between damage evolution and continual strength degradation of the material throughout the design life of the component. In this respect, damage evolution characteristics of the welded vessel steel are established through controlled laboratory experiments. Two types of steels, type-316 austenitic stainless steel and A516 Gr70 pressure vessel steel are used in this research. The samples (SS316 austenitic stainless steel) were heat treated (HT) at 500°C, 800°C and 1000°C followed by furnace cooling. This work examines the effect of different microstructures of austenitic stainless steel on both static and fatigue responses of the alloy. Type A516 steels are commonly used in welded construction of pressure vessels and boilers. Prolonged exposure to high operating temperature and fluctuating pressure could induce undesirable microstructure evolution, particularly in the vicinity of the welded connection. This in turn, modifies the long-term mechanics response of the structure and affects structural reliability prediction. This research attempts to quantify the effects of absorbed hydrogen and thermal aging on crack-tip plastic zone, impact toughness and fatigue crack growth response of the Type A516 Gr70 steel plate and the associated heat affected zone (HAZ). Ductileto- brittle transition temperature (TDBTT) values of Base Metal (BM) and Weld Metal (WM) are -26°C and -20°C respectively, while TDBTT value of HAZ is -32°C. Results show that a crack continuously grows in the base metal or HAZ with increasing applied crack tip driving force, Ka. The threshold stress intensity factor range, Kth for HAZ (13.2 MPam) is lower than that for the base metal (15.3 MPam). Prolonged thermal exposure further lowers Kth of HAZ to 11.4 MPam.
format Thesis
qualification_name Doctor of Philosophy (PhD.)
qualification_level Doctorate
author Khattak, Muhammad Adil
author_facet Khattak, Muhammad Adil
author_sort Khattak, Muhammad Adil
title Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
title_short Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
title_full Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
title_fullStr Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
title_full_unstemmed Effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
title_sort effects of absorbed hydrogen and thermal exposure on mechanical properties, crack opening and fatigue crack propagation of welded steel
granting_institution Universiti Teknologi Malaysia, Faculty of Mechanical Engineering
granting_department Faculty of Mechanical Engineering
publishDate 2009
url http://eprints.utm.my/id/eprint/16941/1/MuhammadAdilKhattakPFKM2009.pdf
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