PSI - Issue 52

Feifei Ren et al. / Procedia Structural Integrity 52 (2024) 730–739 Author name / Structural Integrity Procedia 00 (2023) 000–000

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De Luca, A., Perfetto, D., De Fenza, A., Petrone, G., Caputo, F., 2020. Guided wave shm system for damage detection in complex composite structure. Theoretical and Applied Fracture Mechanics 105, 102408. Kessler, S.S., Spearing, S.M., Soutis, C., 2002. Damage detection in composite materials using lamb wave methods. Smart materials and structures 11, 269. Mallet, L., Lee, B., Staszewski, W., Scarpa, F., 2004. Structural health monitoring using scanning laser vibrometry: Ii. lamb waves for damage detection. Smart Materials and Structures 13, 261. Qing, X., Li, W., Wang, Y., Sun, H., 2019. Piezoelectric transducer-based structural health monitoring for aircraft applications. Sensors 19, 545. Mitra, M., Gopalakrishnan, S., 2016. Guided wave based structural health monitoring: A review. Smart Materials and Structures 25, 053001. Ihn, J.B., Chang, F.K., 2008. Pitch-catch active sensing methods in structural health monitoring for aircraft structures. Structural Health Monitoring 7, 5–19. Lanza di Scalea, F., Salamone, S., 2008. Temperature e ff ects in ultrasonic lamb wave structural health monitoring systems. The Journal of the Acoustical Society of America 124, 161–174. Raghavan, A., Cesnik, C.E., 2008. E ff ects of elevated temperature on guided-wave structural health monitoring. Journal of Intelligent Material Systems and Structures 19, 1383–1398. Konstantinidis, G., Drinkwater, B.W., Wilcox, P.D., 2006. The temperature stability of guided wave structural health monitoring systems. Smart Materials and Structures 15, 967. Gorgin, R., Luo, Y., Wu, Z., 2020. Environmental and operational conditions e ff ects on lamb wave based structural health monitoring systems: A review. Ultrasonics 105, 106114. Yue, N., 2020. Stochastic analysis of guided wave structural health monitoring for aeronautical composites. Ph.D. thesis. Imperial College London. Rose, J.L., 2000. Ultrasonic waves in solid media. Giurgiutiu, V., Faisal Haider, M., 2019. Propagating, evanescent, and complex wavenumber guided waves in high-performance composites. Mate rials 12, 269. Huber, A., 2021. Numerical modeling of guided waves in anisotropic composites with application to air-coupled ultrasonic inspection . Giannakeas, I.N., Sharif-Khodaei, Z., Aliabadi, M., 2020. On the estimation of material properties using guided wave measurements for the calibration of finite element models, in: AIP Conference Proceedings, AIP Publishing LLC. p. 020008. Giannakeas, I.N., Sharif Khodaei, Z., Aliabadi, M., 2023. An up-scaling temperature compensation framework for guided wave–based structural health monitoring in large composite structures. Structural Health Monitoring 22, 777–798. Le Bourdais, F., Mesnil, O., d’Almeida, O., 2019. Machine-learning based temperature compensation for guided wave imaging in structural health monitoring, in: Proceedings of the 11th International Symposium on NDT in Aerospace, Paris-Saclay, Nov, pp. 13–15. ASTM, 2018. D3518 / d3518m standard test method for in-plane shear response of polymer matrix composite materials by tensile test of a ± 45° laminate. ASTM, 2017. D3039 / d3039m standard test method for tensile properties of polymer matrix composite materials. Saad, M.T., Miller, S.G., Marunda, T., 2014. Thermal characterization of im7 / 8552-1 carbon-epoxy composites, in: ASME International mechanical engineering congress and exposition, American Society of Mechanical Engineers. p. V08BT10A091. Yule, L., Zaghari, B., Harris, N., Hill, M., 2021. Modelling and validation of a guided acoustic wave temperature monitoring system. Sensors 21, 7390. Pinto, R., Catalanotti, G., Camanho, P., 2016. Measuring the intralaminar crack resistance curve of fibre reinforced composites at extreme temper atures. Composites Part A: Applied Science and Manufacturing 91, 145–155. Yule, L., Zaghari, B., Harris, N., Hill, M., 2021. Modelling and validation of a guided acoustic wave temperature monitoring system. Sensors 21, 7390. Yue, N., Aliabadi, M., 2020. A scalable data-driven approach to temperature baseline reconstruction for guided wave structural health monitoring of anisotropic carbon-fibre-reinforced polymer structures. Structural Health Monitoring 19, 1487–1506. Aliabadi, M.F., Khodaei, Z.S., 2017. Structural health monitoring for advanced composite structures. volume 8. World Scientific. Salmanpour, M.S., Sharif Khodaei, Z., Aliabadi, M.F., 2017. Impact damage localisation with piezoelectric sensors under operational and environ mental conditions. Sensors 17, 1178. Peddeti, K., Santhanam, S., 2018. Dispersion curves for lamb wave propagation in prestressed plates using a semi-analytical finite element analysis. The Journal of the Acoustical Society of America 143, 829–840. Sharif Khodaei, Z., Ferri Aliabadi, M., 2018. Impact detection and identification with piezoceramic sensors: passive sensing, in: Structural Health Monitoring for Advanced Composite Structures. World Scientific, pp. 215–265. Ren, F., Giannakeas, I.N., Khodaei, Z.S., Aliabadi, M.F., 2023. Theoretical and experimental investigation of guided wave temperature compen sation for composite structures with di ff erent thicknesses. Mechanical Systems and Signal Processing 200, 110594. URL: https://www. sciencedirect.com/science/article/pii/S0888327023005022 , doi: https://doi.org/10.1016/j.ymssp.2023.110594 .