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Fatigue of Materials at Very High Numbers of Loading Cycles

Experimental Techniques, Mechanisms, Modeling and Fatigue Life Assessment

  • Book
  • © 2018

Overview

Editors:
  1. Hans-Jürgen Christ

    1. Siegen, Germany

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  • Priority Program SPP 1466
  • Infinite Fatigue Life of Materials
  • Mechanistic Understanding of Very High Cycle Fatigue (VHCF)

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Table of contents (27 chapters)

  1. Front Matter

    Pages I-IX
    Download chapter PDF

  2. Fatigue of low alloyed carbon steels in the HCF/VHCF-regimes

    • J. Bach, M. Göken, Heinz-Werner Höppel
    Pages 1-23

  3. Atomic-scale modeling of elementary processes during the fatigue of metallic materials: from crack initiation to crack-microstructure interactions

    • J. Möller, Erik Bitzek
    Pages 25-48

  4. Fatigue behaviour of austenitic stainless steels in the VHCF regime

    • A. Grigorescu, P.-M. Hilgendorff, Martina Zimmermann, Claus-Peter Fritzen, Hans-Jürgen Christ
    Pages 49-71

  5. Simulation of the VHCF deformation of austenitic stainless steels and its effect on the resonant behaviour

    • P.-M. Hilgendorff, A. C. Grigorescu, Martina Zimmermann, Claus-Peter Fritzen, Hans-Jürgen Christ
    Pages 73-94

  6. Slip band formation and crack initiation during very high cycle fatigue of duplex stainless steel – Part 1: Mechanical testing and microstructural investigations

    • T. Waurischk, M. Söker, A. Giertler, N. Schönhoff, M. Galster, B. Dönges et al.
    Pages 95-110

  7. Fatigue mechanism and its modeling of an austenitic-ferritic duplex stainless steel under HCF and VHCF loading conditions

    • B. Dönges, Claus-Peter Fritzen, Hans-Jürgen Christ
    Pages 111-131

  8. Influence of different loading stresses on the peak shape of X-ray rocking curves of an austenitic-ferritic duplex stainless steel during VHCF

    • A. K. Hüsecken, B. Dönges, M. Söker, K. Istomin, Ulrich Krupp, Hans-Jürgen Christ et al.
    Pages 133-147

  9. Three-dimensional characterization of duplex stainless steel by means of synchrotron radiation X-ray diffraction imaging techniques

    • Wolfgang Ludwig, M. Syha, N. Vigano, B. Dönges, A. Giertler
    Pages 149-166

  10. Very high cycle fatigue crack initiation: investigation of fatigue mechanisms and threshold values for 100Cr6

    • D. Spriestersbach, P. Grad, A. Brodyanski, J. Lösch, M. Kopnarski, Eberhard Kerscher
    Pages 167-210

  11. Evaluation of multiple-flaw failure of bearing steel 52100 of different heats in the VHCF regime and mathematical determination of single-flaw behaviour

    • Klaus Burkart, B. Clausen, H.-W. Zoch
    Pages 211-231

  12. Influence of near-surface stress gradients and strength effect on the very high cycle fatigue behavior of 42CrMo4 Steel

    • M. Korn, T. Rohm, Karl-Heinz Lang
    Pages 233-252

  13. Fatigue behavior of X10CrNiMoV12-2-2 under the influence of mean loads and stress concentration factors in the very high cycle fatigue regime

    • F. Ritz, T. Beck, S. Kovacs
    Pages 253-272

  14. Experimental and numerical investigations on crack initiation and crack growth under constant and variable amplitude loadings in the VHCF regime

    • Manuela Sander, C. Stäcker, T. Müller
    Pages 273-293

  15. Influence of ceramic particles and fibre reinforcement in metal-matrix-composites on the VHCF behaviour. Part I: Experimental investigations of fatigue and damage behaviour

    • A. Illgen, M. Baaske, Felix Ballani, Anja Weidner, H. Biermann
    Pages 295-318

  16. Influence of ceramic particles and fibre reinforcement in metal matrix composites on the VHCF behaviour. Part II: Stochastic modelling and statistical inference

    • M. Baaske, A. Illgen, Anja Weidner, H. Biermann, Felix Ballani
    Pages 319-342

  17. Development of a fatigue life prediction concept in the very high cycle fatigue range based on covariate microstructural features

    • A. Kolyshkin, E. Kaufmann, M. Zimmermann, H.-J. Christ
    Pages 343-364

  18. Experimental investigation of damage detection and crack initiation up to the very high cycle fatigue regime

    • M. Buck, T. Straub, Christoph Eberl
    Pages 365-393

  19. Discrete dislocation dynamics study of dislocation microstructure during cyclic loading

    • T. El-Achkar, Daniel Weygand
    Pages 395-416

  20. Investigation of the infinite life of fibre-reinforced plastics using X-ray refraction topography for the in-situ, non-destructive evaluation of micro-structural degradation processes during cyclic fatigue loading

    • A. Müller, Volker Trappe, S. Hickmann, H.-P. Ortwein
    Pages 417-439
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Keywords

About this book

This book represents the final reports of the scientific projects funded within the DFG-SPP1466 and, hence, provides the reader with the possibility to familiarize with the leading edge of VHCF research. It draws a balance on the existing knowledge and its enhancement by the joint research action of the priority program. Three different material classes are dealt with: structural metallic materials, long-fiber-reinforced polymers and materials used in micro-electro-mechanical systems. The project topics address the development of suitable experimental techniques for high-frequency testing and damage monitoring, the characterization of damage mechanisms and damage evolution, the development of mechanism-based models and the transfer of the obtained knowledge and understanding into engineering regulations and applications.

Editors and Affiliations

  • Siegen, Germany

    Hans-Jürgen Christ

About the editor

Hans-Jürgen Christ is Full Professor of Materials Engineering at the University of Siegen, Germany. The main objective of his research is a detailed understanding of the behavior of metals and alloys under complex conditions representing those in technical service of engineering materials. The correlation of microscopic processes with the resulting macroscopic changes in properties is used to reveal the relevant mechanisms and damage processes, in order to develop a better prediction of the application limits and the expected lifetime of materials under service conditions.

Bibliographic Information

  • Book Title: Fatigue of Materials at Very High Numbers of Loading Cycles

  • Book Subtitle: Experimental Techniques, Mechanisms, Modeling and Fatigue Life Assessment

  • Editors: Hans-Jürgen Christ

  • DOI: https://doi.org/10.1007/978-3-658-24531-3

  • Publisher: Springer Spektrum Wiesbaden

  • eBook Packages: Chemistry and Materials Science, Chemistry and Material Science (R0)

  • Copyright Information: Springer Fachmedien Wiesbaden GmbH, part of Springer Nature 2018

  • Hardcover ISBN: 978-3-658-24530-6Published: 05 December 2018

  • eBook ISBN: 978-3-658-24531-3Published: 19 November 2018

  • Edition Number: 1

  • Number of Pages: IX, 628

  • Number of Illustrations: 1 b/w illustrations

  • Topics: Structural Materials, Metallic Materials, Energy Materials

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