PSI - Issue 24

Fabio Giudice et al. / Procedia Structural Integrity 24 (2019) 706–711 F. Giudice, G. La Rosa, G. Fargione, R. Barbagallo / Structural Integrity Procedia 00 (2019) 000 – 000

710

5

• the comparison between thermographic analysis and acoustic emission, in order to verify the compatibility of the results obtained in terms of fatigue limit. Acknowledgements This work has been partially financed by the University of Catania within the project "Piano della Ricerca Dipartimentale 2016-2018" of the Department of Civil Engineering and Architecture. References Bodner, S.R., Davidson, D.L., Lankford, J., 1983. A Description of Fatigue Crack Growth in Terms of Plastic Work. Engineering Fracture Mechanics 17, 189-191. Boulanger, T., Chrysochoos, A., Mabru, C., Galtier, A., 2004. Calorimetric Analysis of Dissipative and Thermoelastic Effects Associated with the Fatigue Behavior of Steels. International Journal of Fatigue 26, 221-229. Caglioti, G., 1982. Mechanical and Thermal Behaviour of Metallic Materials. In: Caglioti G., Ferro, A. (Eds). North Holland, Amsterdam. Charkaluk, E., Constantinescu, A., 2009. Dissipative Aspects in High Cycle Fatigue. Mechanics of Materials 41, 483-494. Clienti, C., Fargione, G., La Rosa, G., Risitano, A., Risitano, G., 2010. A First Approach to the Analysis of Fatigue Parameters by Thermal Variations in Static Tests on Plastics. Engineering Fracture Mechanics 77, 2158-2167. Crupi, V., Chiofalo, G., Guglielmino, E., 2011. Infrared Investigations for the Analysis of Low Cycle Fatigue Processes in Carbon Steels. Proceedings of the Institution of Mechanical Engineers Part C: Journal of Mechanical Engineering Science 225, 833-842. Fargione, G., Geraci, A., La Rosa, G., Risitano, A., 2002. Rapid Determination of the Fatigue Curve by Thermographic Method. International Journal of Fatigue 24, 11-19. Fargione, G., Giudice, F., Risitano, A., 2017. The Influence of the Load Frequency on the High Cycle Fatigue Behavior. Theoretical and Applied Fracture Mechanics 88, 97-106. Felter, C.E., Morrow, J.D., 1961. Microplastic Strain Hysteresis Energy as a Criterion for Fatigue Fracture. Transactions of ASME D: Journal of Basic Engineering 83 15-22. Giudice, F., La Rosa, G., Lo Savio, F., Clienti, C., 2019. Comparison between Thermal Energy and Acoustic Emission for the Fatigue Behavior of Steels. Structural Integrity Procedia 18, 886-890. Hunady, R., Hagara, M., Schrötter, M., 2012. Using High-Speed Digital Image Correlation to Determine the Damping Ratio. Procedia Engineering 48, 242-249. Kaleta, J., Blotny, R., Harig, H., 1990. Energy Stored in a Specimen under Fatigue Limit Loading Conditions. Journal of Testing and Evaluation 19, 326-333. Kanchanomai, C., Yamamoto, S., Miyashita, Y., Mutoh, Y., McEvily, A.J., 2002. Low Cycle Fatigue Test for Solders using Non-Contact Digital Image Measurement System. International Journal of Fatigue 24, 57-67. Klingbeil, N.W., 2003. A Total Dissipated Energy Theory of Fatigue Crack Growth in Ductile Solids. International Journal of Fatigue 25, 117-128. Kordatos, E.Z., Aggelis, D.G., Matikas, T.E., 2012. Monitoring Mechanical Damage in Structural Materials using Complimentary NDE Techniques based on Thermography and Acoustic Emission. Composites Part B: Engineering 43, 2676 – 2686. Kordatos, E.Z., Dassios, K.G., Aggelis, D.G., Matikas, T.E. 2013. Rapid Evaluation of the Fatigue Limit in Composites using Infrared Lock-In Thermography and Acoustic Emission. Mechanics Research Communications 54, 14-20. La Rosa, G., Risitano, A., 2000. Thermographic Methodology for Rapid Determination of the Fatigue Limit of Materials and Mechanical Components. International Journal of Fatigue 22, 65-73. La Rosa, G., Risitano, A., 2014. Evaluation of the Fatigue Limit of Materials in Static Test using Thermal Analysis: Effect of the Cross-Head Speed. Key Engineering Materials 577/578, 69-72. La Rosa, G., Clienti, C., Lo Savio, F., 2014. Fatigue Analysis by Acoustic Emission and Thermographic Techniques. Procedia Engineering 74, 261-268. La Rosa, G., Clienti, C., Marino Cugno Garrano, A., 2016. The Use of Digital Image Correlation to Correct the Thermoelastic Curves in Static Tests. Structural Integrity Procedia 2, 2140-2147. La Rosa, G., Clienti, C., Marino Cugno Garrano, A., Lo Savio, F., 2017. A Novel Procedure for Tracking the Measuring Point in Thermoelastic Curves using D.I.C. Engineering Fracture Mechanics 183, 53-65. La Rosa, G., Clienti, C., Marino Cugno Garrano, A., Lo Savio, F., 2018. Low-Cycle Fatigue Hysteresis by Thermographic and Digital Image Correlation Methodologies: A First Approach. Structural Integrity Procedia 13, 1583-1588. Li, L., Muracciole, J.M., Waltz, L., Sabatier, L., Barou, F., Wattrisse, B., 2016. Local Experimental Investigations of the Thermomechanical Behavior of a Coarse-Grained Aluminum Multicrystal using Combined DIC and IRT Methods. Optics and Lasers in Engineering 8, 1-10. Luong, M.P., 1988. Fatigue Limit Evaluation of Metals using an Infrared Thermographic Technique. Mechanics of Materials 28, 155-163. Maquin, F., Pierron, F., 2009. Heat Dissipation Measurements in Low Stress Cyclic Loading of Metallic Materials: From Internal Friction to Micro Plasticity. Mechanics of Materials 41, 928-942. Maurel, V., Rémy, L., Dahmen, F., Haddar, N., 2009. An Engineering Model for Low Cycle Fatigue Life based on a Partition of Energy and Micro Crack Growth. International Journal of Fatigue 31, 952-961.