PSI - Issue 64

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Author name / Structural Integrity Procedia 00 (2019) 000 – 000

M. Pedram et al. / Procedia Structural Integrity 64 (2024) 621–628

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Acknowledgements This publication has emanated from a PhD thesis in Civil Engineering funded in Queen’s University Belfast (QUB) in collaboration with a wider US- Ireland R&D partnership project ‘USI107: Mobile Automated Rovers Fly By (MARS-FLY) for Bridge Network Resiliency. ’ References ASTM-D4788- 03 2013. “Standard Test Method for Detecting Delaminations in Bridge Decks Using Infrared Thermography.” ASTM International, West Conshohocken, PA. Bergman, T. L., Lavine, A. S., Incropera, F. P. & Dewitt, D. P. 2011. Introduction to heat transfer , John Wiley & Sons. Doshvarpassand, S., Wu, C. & Wang, X. 2019. An overview of corrosion defect characterization using active infrared thermography. Infrared Physics & Technology, 96 , 366-389. Hiasa, S., Birgul, R. & Catbas, F. N. 2017. Investigation of effective utilization of infrared thermography (IRT) through advanced finite element modeling. Construction and Building Materials, 150 , 295-309. Ichi, E. & Dorafshan, S. 2022. Effectiveness of infrared thermography for delamination detection in reinforced concrete bridge decks. Automation in Construction, 142 , 104523. Kashif Ur Rehman, S., Ibrahim, Z., Memon, S. A. & Jameel, M. 2016. Nondestructive test methods for concrete bridges: A review. Construction and Building Materials, 107 , 58-86. Pedram, M., Taylor, S. & Hamill, G. 2022a. Effect of thermal excitation mechanism on detection of subsurface defects in concrete using infrared thermography. 11th International Conference on Structural Health Monitoring of intelligent Infrastructure. Concordia University, Montreal, Canada: International Conference on Structural Health Monitoring of Intelligent Infrastructure: Proceedings. Pedram, M., Taylor, S., Hamill, G. & Robinson, D. 2022b. Subsurface defect detection in concretes by active infrared thermography. IABSE Symposium: Challenges for Existing and Oncoming Structures. Prague, Czech Republic. Pedram, M., Taylor, S., Hamill, G., Robinson, D., Obrien, E. J. & Uddin, N. 2022c. Experimental evaluation of heat transition mechanism in concrete with subsurface defects using infrared thermography. Construction and Building Materials, 360 , 129531. Pedram, M., Taylor, S., Hamill, G., Robinson, D., Obrien, E. J. & Uddin, N. 2024. Objective characterisation of reinforced concrete with progressive corrosion defects through clustering and thresholding of infrared images. Measurement, 225 , 114017. Pedram, M., Taylor, S., Robinson, D. & Hamill, G. 2021. Subsurface defect detection in concrete using infrared thermography. In: CUNHA, Á. & CAETANO, E. (eds.) 10th International Conference on Structural Health Monitoring of Intelligent Infrastructure (SHMII-10). Porto, Portugal: International Society for Structural Health Monitoring of Intelligent Infrastructure, ISHMII. Pedram, M., Taylor, S., Robinson, D., Hamill, G., O’brien, E. & Uddin, N. 2022d. Experimental investigation of subsurface defect detection in concretes by infrared thermography and convection heat exchange. Journal of Civil Structural Health Monitoring . Reddy, J. N. & Gartling, D. K. 2010. The finite element method in heat transfer and fluid dynamics , CRC press. Washer, G., Fenwick, R. & Bolleni, N. 2010. Effects of solar loading on infrared imaging of subsurface features in concrete. Journal of Bridge Engineering, 15 , 384-390. Watase, A., Birgul, R., Hiasa, S., Matsumoto, M., Mitani, K. & Catbas, F. N. 2015. Practical identification of favorable time windows for infrared thermography for concrete bridge evaluation. Construction and Building Materials, 101 , 1016-1030.