A study of fatigue damage mechanisms in Waspaloy from 25 to 800°C (original) (raw)

Fatigue Crack Initiation In WASPALOY at 20 °C

Robert Tryon

Metallurgical and Materials Transactions A, 2007

View PDFchevron_right

Machining conditions impact on the fatigue life of Waspaloy Impact of grain size

Nihad Bs

View PDFchevron_right

The effect of hold-time on fatigue crack growth behaviors of WASPALOY alloy at elevated temperature

Bruce Kang

Materials Science and Engineering: A, 2003

View PDFchevron_right

Effect of High Temperature Exposure on the Microstructure of Waspaloy

Rosario Gerhardt

Microscopy and Microanalysis, 2004

View PDFchevron_right

Investigation on hot deformation behavior of Waspaloy

amir amiri

Materials Science and Engineering: A, 2013

View PDFchevron_right

Fatigue Damage Initiation in Waspaloy Under Complex Cyclic Loading

AKRUM ABDUL-LATIF

Journal of Engineering Materials and Technology, 1999

View PDFchevron_right

High Temperature Fatigue Damage in Three Austenitic Alloys

A. Plumtree

Fatigue & Fracture of Engineering Materials and Structures, 1988

View PDFchevron_right

Impact of Thermomechanical Aging on Alloy 625 High Temperature Mechanical Properties

Johanne Laigo

Ott/8th International, 2014

View PDFchevron_right

Hardening mechanisms in a dynamic strain aging alloy, HASTELLOY X, during isothermal and thermomechanical cyclic deformation

Michael Castelli

Metallurgical Transactions A, 1992

View PDFchevron_right

Role of microstructural condition on fatigue damage development of AISI 316L at 20 and 300°C, Int. J. Fatigue, 2013

Minh Son Pham

International Journal of Fatigue

View PDFchevron_right

Deformation behavior of Waspaloy at hot-working temperatures

Dierk Raabe

2004

View PDFchevron_right

The thermal fatigue behavior of the combustor alloys In 617 and HAYNES 230 before and after welding

Farhad Rézaï-Aria

Metallurgical and Materials Transactions A, 1999

View PDFchevron_right

Damage mechanism related to localization of plastic deformation of Waspaloy™: effect of grain size

M. Risbet

Procedia Engineering, 2011

View PDFchevron_right

Modeling Grain Size and Strain Rate in Linear Friction Welded Waspaloy

P. Wanjara

Metallurgical and Materials Transactions A, 2013

View PDFchevron_right

High-Temperature Low-Cycle Fatigue Behavior in HAYNES 282: Influence of Initial Microstructure

Kaustav Barat

Metallurgical and Materials Transactions A, 2018

View PDFchevron_right

Role of the grain-boundary phase on the elevated-temperature strength, toughness, fatigue and creep resistance of silicon carbide sintered with Al, B and C

Robert O Ritchie

Acta Materialia, 2000

View PDFchevron_right

Ambient to high-temperature fracture toughness and cyclic fatigue behavior in Al-containing silicon carbide ceramics

Robert O Ritchie

Acta Materialia, 2003

View PDFchevron_right

Effects of grain size and precipitate size on the fatigue crack growth behavior of alloy 718 at 427 °C

Stephen Antolovich

Metallurgical Transactions A, 1987

View PDFchevron_right

Fatigue life and initiation mechanisms in wrought Inconel 718 DA for different microstructures

Jérôme Crépin

Icf13, 2013

View PDFchevron_right

Low-cycle thermal-mechanical fatigue as an accelerated creep test

Stan Mandziej

Procedia Engineering, 2010

View PDFchevron_right

Effect of Ageing on Microstructure, Mechanical Properties and Creep Behavior of Alloy 740H

R. L. Narayan

Metallurgical and Materials Transactions A, 2020

View PDFchevron_right

Fatigue Behavior of Ultrafine-Grained Medium Carbon Steel with Different Carbide Morphologies Processed by High Pressure Torsion

Yulia Ivanisenko

Metals, 2015

View PDFchevron_right

The Effect of Grain Size on the Susceptibility Towards Strain Age Cracking of Wrought Haynes® 282®

Gurdit Singh

Advances in Transdisciplinary Engineering, 2020

View PDFchevron_right

Author's Accepted Manuscript Effect of heat-treatment on microstructural evolution and mechanical behaviour of severely deformed Inconel 718

PRABHAT C H A N D YADAV

View PDFchevron_right

Fracture Behaviour of a New Submicron Grained Cemented Carbide

Cruz Fernandes

Ciencia e Tecnologia dos Materiais

View PDFchevron_right

Temperature Dependent Cyclic Deformation Mechanisms in Haynes 188 Superalloy

Michael Castelli

Computational Mechanics ’95, 1995

View PDFchevron_right

Characterization of microstructural fluctuations in Waspaloy exposed to 760°C for times up to 2500h

Rosario Gerhardt

Electrochimica Acta, 2006

View PDFchevron_right

Comparative Study of Microstructural Evolution and Mechanical Properties of Inconel® 718 and Waspaloy® Welds

Stavros Deligiannis

MATEC Web of Conferences

View PDFchevron_right

Effect of environment on the rupture behavior of alloys 909 and 718

James Earthman

Materials Science and Engineering: A, 1994

View PDFchevron_right

Tensile Properties, Microsctructure and Microhardness Analysis of Directly Deposited Waspaloy by Gas Tungsten Arc Welding

Ian Pashby

2020

View PDFchevron_right

Fatigue-crack growth and fracture properties of coarse and fine-grained Ti3SiC2

Robert O Ritchie

Scripta Materialia, 2000

View PDFchevron_right

Role of grain structure, grain boundaries, crystallographic texture, precipitates, and porosity on fatigue behavior of Inconel 718 at room and elevated temperatures

Marko Knezevic

Materials Characterization, 2019

View PDFchevron_right