In situ monitoring of fiber-reinforced composites : theory, basic concepts, methods, and applications

"...a comprehensive and well written book, which...will be useful reading for both researchers entering the field and experienced specialists looking for new ideas....a valuable and long-lasting contribution to experimental mechanics." - Stepan Lomov, KU Leuven This expert volume, an enhanced Habilitation thesis by the head of the Materials Testing Research Group at the University of Augsburg, provides detailed coverage of a range of inspection methods for insitu characterization of fiber-reinforced composites. The failure behavior of fiber reinforced composites is a complex evolution of microscopic damage phenomena. Beyond the use of classical testing methods, the ability to monitor the progression of damage insitu offers new ways to interpret the materials failure modes. Methods covered include digital image correlation, acoustic emission, electromagnetic emission, computed tomography, thermography, shearography, and promising method combinations. For each method, the discussion includes operational principles and practical applications for quality control as well as thoughtful assessment of the method's strengths and weakness so that the reader is equipped to decide which method or methods are most appropriate in a given situation. The book includes extensive appendices covering common experimental parameters influencing comparability of acoustic emission measurements; materials properties for modeling; and an overview of terms and abbreviations.

Preface.- Acknowledgements.- 1. Introduction.- 2. Failure of fiber reinforced composites. 2.1 Classification of failure mechanisms.- 2.2 Failure theories for fiber reinforced composites. 2.3 Challenges in mechanical testing of fiber reinforced materials.- 3. Digital image correlation. 3.1 Principle of operation. 3.2 System accuracy. 3.3 Strain concentration. 3.4 Application to composites.- 4. Acoustic emission. 4.1 Principle of operation. 4.2 Source mechanics. 4.3 Wave propagation. 4.4 Detection of acoustic emission signals.- 5. Electromagnetic Emission. 5.1 Principle of operation. 5.2 Source mechanism. 5.3 Signal propagation.- 6. Computed tomography. 6.1 Principle of operation. 6.2 Detail visibility. 6.3 Volumetric inspection of materials.- 7. Combination of methods. 7.1 Comparison of insitu methods. 7.2 Established method combinations. 7.3 Future developments.- Appendix A. Acoustic emission: Parameters of influence.- Appendix B. Material Properties.- Appendix C. Acoustic emission signal parameters.- Appendix D. Definitions and abbreviations.