STP1425

    Fretting Fatigue: Advances in Basic Understanding and Applications

    Mutoh Y, Hoeppner DW, Kinyon SE
    Published: 2003


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    Gain an understanding of the fretting fatigue phenomenon and for developing fretting fatigue design. Fretting is well known to degrade fatigue strength significantly. Fretting fatigue failure has been increasingly disclosed in service components because those components have suffered more severe loading conditions than before due to the demands of save-energy and environment-preservation.

    Twenty-nine peer-reviewed papers cover:

    Fretting in Steel Ropes and Cable—reviews the topic.

    Fretting Wear and Crack Nucleation—covers the process of fretting crack nucleation under fretting wear through both detailed in-situ observations and mechanical models, which included not only fracture mechanics but also interface mechanics.

    Fretting Fatigue Crack and Damage—discusses fretting fatigue crack propagation under mixed mode, based on the fracture mechanics approach.

    Life Prediction—addresses fretting fatigue life estimations, based on various approaches including fracture mechanics, notch fatigue analysis and multiaxial fatigue parameters.

    Fretting Fatigue Parameter Effects—covers effects of parameters that influence fretting fatigue behavior and strength, including contact pressure, friction coefficient, contact pad geometry, and mating material.

    Loading Condition and Environment—addresses the effect of loading conditions including block loading, high frequency and service loading.

    Titanium Alloys—discusses titanium alloys, which have been typically used for structural components suffering fretting fatigue, such as turbine components and bio-joints, due to their lightweight as well as excellent corrosion resistance.

    Surface Treatment—deals with improvements of fretting fatigue strength by using coating techniques.

    Case Studies and Applications—introduces case studies on electrical cables, dovetail joints, pin joints and rollers.

    This volume is a valuable resource for engineers that need to develop an understanding of fretting fatigue and also serves the fretting fatigue community including both newcomers and those that have been involved for some time.


    Table of Contents

    Fretting in Steel Ropes and Cables — A Review
    Waterhouse R.

    A Global Methodology to Quantify Fretting Damages
    Fouvry S., Kapsa P., Vincent L.

    Observations and Analysis of Relative Slip in Fretting Fatigue
    Kondoh K., Mutoh Y., Nishida T., Xu J.

    Fretting Fatigue Initial Damage State to Cracking State: Observations and Analysis
    Clark P., Hoeppner D.

    Observations and Analysis of Fretting Fatigue Crack Initiation and Propagation
    Kondoh K., Mutoh Y., Xu J.

    Stress Intensity Factors KI and KII of Oblique Through Thickness Cracks in a Semi-Infinite Body Under Fretting Fatigue Conditions
    Kimura T., Sato K.

    Characterization of Fretting Fatigue Process Volume Using Finite Element Analysis
    Neu R., Swalla D.

    A Critical Assessment of Damage Parameters for Fretting Fatigue
    Ciavarella M., Demelio G., Dini D.

    An Estimation of Life in Fretting Fatigue Using an Initiation-Propagation Model
    Domínguez J., García M., Navarro C.

    Application of Multiaxial Fatigue Parameters to Fretting Contacts with High Stress Gradients
    Araújo J., Nowell D.

    A Theoretical and Experimental Procedure for Predicting the Fretting Fatigue Strength of Complete Contacts
    Hills D., Limmer L., Mugadu A.

    Improvement of Fretting Fatigue Strength by Using Stress-Release Slits
    Hattori T., Nakamura M., Watanabe T.

    Effect of Contact Pressure on Fretting Fatigue in Type 316L Stainless Steel
    Hanawa T., Maruyama N., Nakazawa K.

    Influence of Nonhomogeneous Material in Fretting Fatigue
    Goh C., McDowell D., Neu R.

    Local Fretting Regime Influences on Crack Initiation and Early Growth
    Dubourg M.

    Effect of Contact Pad Geometry on Fretting Fatigue Behavior of High Strength Steel
    Akiyama T., Kido Y., Matsumura T., Ochi Y.

    Fretting Fatigue Under Block Loading Conditions
    Hooper J., Irving P.

    High-Frequency Fretting Fatigue Experiments
    Farris T., Matlik J.

    Development of Test Methods for High Temperature Fretting of Turbine Materials Subjected to Engine-Type Loading
    Farris T., Murthy H., Okane M., Rajeev P.

    Fretting Fatigue Behavior of Titanium Alloys
    Chandrasekaran V., Hoeppner D., Taylor A.

    An Investigation of Fretting Fatigue Crack Nucleation Life of Ti-6Al-4V under Flat-on-Flat Contact
    Ashbaugh N., Hutson A., Nicholas T.

    Evaluation of Ti-48Al-2Cr-2Nb Under Fretting Conditions
    Draper S., Lerch B., Miyoshi K., Raj S.

    Fretting Fatigue Crack Initiation Behavior of Ti-6Al-4V
    Jain V., Lykins C., Mall S., Namjoshi S.

    Fretting Fatigue Characteristics of Titanium Alloy Ti-6Al-4V in Ultra High Cycle Regime
    Kumuthini K., Mutoh Y., Nagata K., Shirai S.

    Effect of Lubricating Anodic Film on Fretting Fatigue Strength of Aluminum Alloy
    Maejima M., Mizutani J., Mutoh Y., Nishida T.

    Fretting Fatigue Properties of WC-Co Thermal Sprayed NiCrMo Steel
    Hiki M., Okane M., Shiozawa K., Suzuki K.

    Fretting Wear and Fatigue in Overhead Electrical Conductor Cables
    Lindley T.

    Evaluating Fatigue Life of Compressor Dovetails by Using Stress Singularity Parameters at the Contact Edge
    Hattori T., Machida T., Yoshimura T.

    The Analysis of Fretting Fatigue Failure in Backup Roll and its Prevention
    Kondo Y., Kubota M., Odanaka H., Ohkomori Y., Sakae C.

    Author Index

    Subject Index


    Committee: E08

    Paper ID: STP1425-EB

    DOI: 10.1520/STP1425-EB

    ISBN-EB: 978-0-8031-5476-6

    ISBN-13: 978-0-8031-3456-0

    ASTM International is a member of CrossRef.

    0-8031-3456-8
    978-0-8031-3456-0
    STP1425-EB