参考文献:1. PJ Shull (ed) (2002) Nondestructive evaluation, theory, techniques and applications. Taylor & Francis, New York 2. Grosse, CU, Ohtsu, M (2008) Acoustic emission testing. Springer, Heidelberg 540-69972-9" target="_blank" title="It opens in new window">CrossRef 3. Verstrynge, E, Schueremans, L, Gemert, D, Wevers, M (2009) Monitoring and predicting masonry鈥檚 creep failure with the acoustic emission technique. NDT&E Int 42: pp. 518-523 CrossRef 4. Carpinteri, A, Lacidogna, G, Niccolini, G, Puzzi, S (2008) Critical defect size distributions in concrete structures detected by the acoustic emission technique. Meccanica 43: pp. 349-363 CrossRef 5. Karihaloo, BL, Ramachandra Murthy, A, Iyer, NR (2013) Determination of size-independent specific fracture energy of concrete mixes by the tri-linear model. Cem Concr Res 49: pp. 82-88 CrossRef 6. Saliba, J, Loukili, A, Grondin, F, Regoin, JP (2013) Identification of damage mechanisms in concrete under high level creep by the acoustic emission technique. Mater Struct. 7. Calabrese, L, Campanella, G, Proverbio, E (2013) Identification of corrosion mechanisms by univariate and multivariate statistical analysis during long term acoustic emission monitoring on a pre-stressed concrete beam. Corros Sci 73: pp. 161-171 CrossRef 8. Vidya Sagar, R, Raghu Prasad, BK (2012) A review of recent developments in parametric based acoustic emission techniques applied to concrete structures. Nondestruct Test Eval 27: pp. 47-68 589759.2011.589029" target="_blank" title="It opens in new window">CrossRef 9. Invernizzi, S, Lacidogna, G, Carpinteri, A (2013) Particle-based numerical modeling of AE statistics in disordered materials. Meccanica 48: pp. 211-220 595-5" target="_blank" title="It opens in new window">CrossRef 10. Tittelboom, K, Belie, N, Lehmann, F, Grosse, CU (2012) Acoustic emission analysis for the quantification of autonomous crack healing in concrete. Constr Build Mater 28: pp. 333-341 CrossRef 11. Uddin, FAKM, Shigeishi, M, Ohtsu, M (2006) Fracture mechanics of corrosion cracking in concrete by acoustic emission. Meccanica 41: pp. 425-442 CrossRef 12. Carpinteri, A, Xu, J, Lacidogna, G, Manuello, A (2012) Reliable onset time determination and source location of acoustic emissions in concrete structures. Cem Concr Compos 34: pp. 529-537 CrossRef 13. Luo, X, Haya, H, Inaba, T, Shiotani, T (2006) Seismic diagnosis of railway substructures by using secondary acoustic emission. Soil Dyn Earthq Eng 26: pp. 1101-1110 CrossRef 14. Ohtsu, M (2010) Recommendation of RILEM TC 212-ACD: acoustic emission and related NDE techniques for crack detection and damage evaluation in concrete: test method for damage qualification of reinforced concrete beams by acoustic emission. Mater Struct 43: pp. 1183-1186 527-010-9639-z" target="_blank" title="It opens in new window">CrossRef 15. Ohtsu, M (2010) Recommendation of RILEM TC 212-ACD: acoustic emission and related NDE techniques for crack detection and damage evaluation in concrete: test method for classification of active cracks in concrete structures by acoustic emission. Mater Struct 43: pp. 1187-1189 527-010-9640-6" target="_blank" title="It opens in new window">CrossRef 16. Shahidan, S, Pulin, R, Muhamad Bunnori, N, Holford, KM (2013) Damage classification in reinforced concrete beam by acoustic emission signal analysis. Constr Build Mater 45: pp. 78-86 5" target="_blank" title="It opens in new window">CrossRef 17. Farhidzadeh, A, Dehghan-Niri, E, Salamone, S, Luna, B, Whittaker, A (2013) Monitoring crack propagation in reinforced concrete shear walls by acoustic emission. J Struct Eng. 18. Aggelis, DG (2011) Classification of cracking mode in concrete by acoustic emission parameters. Mech Res Commun 38: pp. 153-157 CrossRef 19. Haneef, TK, Kumari, K, Mukhopadhyay, CK, Venkatachalapathy, CK, Purnachandra Rao, B, Jayakumar, T (2013) Influence of fly ash and curing on cracking behavior of concrete by acoustic emission technique. Constr Build Mater 44: pp. 342-350 CrossRef 20. Carpinteri, A, Corrado, M, Lacidogna, G (2013) Heterogeneous materials in compression: correlations between absorbed, released and acoustic emission energies. Eng Fail Anal 33: pp. 236-250 5.016" target="_blank" title="It opens in new window">CrossRef 21. Scholey, JJ, Wilcox, PD, Wisnom, MR, Friswell, MI (2010) Quantitative experimental measurements of matrix cracking and delamination using acoustic emission. Composites A 41: pp. 612-623 CrossRef 22. Farhidzadeh, A, Salamone, S, Singla, P (2013) A probabilistic approach for damage identification and crack mode classification in reinforced concrete structures. J Intell Mater Syst Struct 24: pp. 1722-1735 5389X13484101" target="_blank" title="It opens in new window">CrossRef 23. Aggelis, DG, Mpalaskas, AC, Matikas, TE (2013) Investigation of different fracture modes in cement-based materials by acoustic emission. Cem Concr Res 48: pp. 1-8 CrossRef 24. Aggelis, DG, Verbruggen, S, Tsangouri, E, Tysmans, T, Hemelrijck, D (2013) Characterization of mechanical performance of concrete beams with external reinforcement by acoustic emission and digital image correlation. Constr Build Mater 47: pp. 1037-1045 5" target="_blank" title="It opens in new window">CrossRef 25. Aggelis, DG, Shiotani, T, Papacharalampopoulos, A, Polyzos, D (2012) The influence of propagation path on acoustic emission monitoring of concrete. Struct Health Monit 11: pp. 359-366 5921711419992" target="_blank" title="It opens in new window">CrossRef 26. Charalambopoulos, A, Gergidis, LN, Kartalos, G (2012) On the gradient elastic wave propagation in cylindrical waveguides with microstructure. Composites B 43: pp. 2613-2627 CrossRef 27. Tsinopoulos, SV, Verbis, JT, Polyzos, D (2010) An iterative effective medium approximation for wave dispersion and attenuation predictions in particulate composites. Adv Compos Lett 9: pp. 193-200 28. Aggelis, DG, Mpalaskas, AC, Matikas, TE (2013) Acoustic signature of different fracture modes in marble and cementitious materials under flexural load. Mech Res Commun 47: pp. 39-43 CrossRef 29. Aggelis, DG, Mpalaskas, AC, Ntalakas, D, Matikas, TE (2012) Effect of wave distortion on acoustic emission characterization of cementitious materials. Constr Build Mater 35: pp. 183-190 CrossRef 30. Polyzos, D, Papacharalampopoulos, A, Shiotani, T, Aggelis, DG (2011) Dependence of AE parameters on the propagation distance. J Acoust Emiss 29: pp. 57-67
刊物类别:Physics and Astronomy
刊物主题:Physics Mechanics Civil Engineering Automotive and Aerospace Engineering and Traffic Mechanical Engineering
出版者:Springer Netherlands
ISSN:1572-9648
文摘
Acoustic emission (AE) data from bending of externally reinforced large scale concrete beams are presented. Emissions from concrete cracking and debonding of carbon fiber reinforced polymer strip are identified in conjunction with other nondestructive testing measurements. It is shown that although the nature of AE signals differs much depending on the actual source, any discrimination between them will not be feasible if the data are not adequately treated as to their propagation path. The reason is that frequency and other waveform characteristics of cracking AE signals start to resemble debonding ones from the external reinforcement as they propagate for additional distance. The phenomenon is verified and strategies to overcome are discussed in order to enable application of simple parameter-based criteria developed in laboratory for the crack mode characterization in large structures.