|
|
|
SEDL / STP / STP801-EB
 |
STP801
Corrosion Fatigue: Mechanics, Metallurgy, Electrochemistry, and Engineering
Crooker TW, Leis BN
Pages: 534
Published: 1983
|
|
This publication presents research data covering corrosion and fracture mechanics of metals, primarily steel, aluminum, and titanium. The papers presented are primarily research in nature although several papers deal with application technology. The papers address: mechanics and basic metal characteristics, the effects of the environments of metals and crack initiation and propagation, engineering design considerations, and electrochemical considerations.
Table of Contents
Introduction
Crooker T., Leis B.
Summary
Crooker T., Leis B.
Fracture Mechanics and Corrosion Fatigue
Wei R., Shim G.
Corrosion-Fatigue Crack Initiation Behavior of Four Structural Steels
Novak S.
Anomalous Fatigue Crack Growth Retardation in Steels for Offshore Applications
Van Der Velden R., Ewalds H., Schultze W., Punter A.
Crack Growth by Stress-Assisted Dissolution and Threshold Characteristics in Corrosion Fatigue of a Steel
Endo K., Komai K., Shikida T.
Experimental Observations of Environmental Contributions to Fatigue Crack Growth
Bowles Quinton C., Schijve J.
Influence of Environment and Specimen Thickness on Fatigue Crack Growth Data Correlation by Means of Elber-Type Equations
Ewalds H., van Doorn F., Sloof W.
Corrosion-Fatigue Behavior of Ti-6Al-4V in a Sodium Chloride Aqueous Solution
Ebara R., Yamada Y., Goto A.
An Analysis of Random Pits in Corrosion Fatigue: A Statistical Three-Dimensional Evaluation of an Irregularly Corroded Surface
Kitagawa H., Tsuji K., Hisada T., Hashimoto Y.
Effects of Microstructure and Frequency on Corrosion-Fatigue Crack Growth in Ti-8Al-1Mo-1V and Ti-6Al-4V
Yoder G., Cooley L., Crooker T.
Corrosion-Fatigue Crack Growth Characteristics of Several HY-100 Steel Weldments with Cathodic Protection
Davis D., Czyryca E.
Corrosion-Fatigue Crack Initiation in an Iron-Caustic System
Leis B., Rungta R., Mayfield M., Beavers J.
Corrosion-Fatigue Crack Propagation Rates in Commercial 7075 and P/M X7091 Aluminum Alloys
Santner J., Kumar M.
Effect of Microstructure and Strength of Low-Alloy Steels on Cyclic Crack Growth in High-Temperature Water
Shoji T., Nakajima H., Tsuji H., Takahashi H., Kondo T.
Fractography and Mechanisms of Environmentally Enhanced Fatigue Crack Propagation of a Reactor Pressure Vessel Steel
Törrönen K., Kemppainen M.
Chemistry Effects in Corrosion Fatigue
Scott P.
A Theoretical Evaluation of the Oxygen Concentration in a Corrosion-Fatigue Crack
Turnbull A.
Some Electrochemical and Microstructural Aspects of Corrosion Fatigue
Congleton J., Craig I., Olieh R., Parkins R.
Environmental Influences on the Aqueous Fatigue Crack Growth Rates of HY-130 Steel
Fujii C., Smith J.
Implementing Corrosion-Fatigue Crack Growth Rate Data for Engineering Applications
Bamford W.
The Use of Notched Compact-Type Specimens for Crack Initiation Design Rules in High-Temperature Water Environments
Prater T., Coffin L.
Fatigue Design Stresses for Weathering Steel Structures
Albrecht P.
Corrosion Fatigue of Welded Steel Joints under Narrow-Band Random Loading
Booth G.
Influence of Weld Profile on Fatigue of Welded Structural Steel in Seawater
Nerolich S., Martin P., Hartt W.
Effects of Cathodic Protection on Corrosion Fatigue
Floyd Brown B.
Index
Committee: E08
Paper ID: STP801-EB
DOI: 10.1520/STP801-EB
ISBN-EB: 978-0-8031-4867-3
 ASTM International is a member of CrossRef.
0-8031-0245-3
978-0-8031-0245-3
STP801-EB
STP 801
|
