Structural Health Monitoring of Large-Scale Bridges: A Synopsis of the Padma Bridge
Abstract
In the recent decade, the concept of "structural health monitoring," or SHM, has gained prominence due to its promise of reflecting the condition of structures and facilitating the monitoring of their behavior. Bangladesh is a country with a long coastline, thus it is unfortunate that the SHM system has not been more widely deployed on the country's many highway bridges across rivers. Saving money on manpower, remote monitoring allows for accurate, up-to-date assessments of a bridge's structural soundness. Recent developments in sensor, communication, and storage technologies have made a worldwide SHM system for infrastructures possible. The primary goal of this investigation is to assess the performance of the structural health monitoring system on the Padma Multipurpose Bridge. Recent developments in SHM's integration with ITS show the usefulness of ITS devices (such as traffic cameras and traffic detectors) in analyzing bridge responses to multimodal traffic with varying loads or during critical events that cause excessive vibration beyond the normal limit, which can be of great assistance in tackling the Padma bridge's serviceability challenge. Integrating information from an ITS device with SHM may increase the reliability and precision of the SHM system. As a consequence of this integration, the SHM system would be less likely to misdiagnose damages (i.e., vibrations caused by big cars on a bridge may be perceived by a SHM sensor as a structural health concern of the bridge), resulting in decreased maintenance costs. This investigative study provided a summary of the SHM systems now in place for major bridges in Bangladesh, such as the spectacular Padma Bridge, and discussed their use and appropriateness in the near and far future.
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H.-N. Li, T.-H. Yi, L. Ren, D.-S. Li, L.-S. J. S. M. Huo, and Maintenance, "Reviews on innovations and applications in structural health monitoring for infrastructures," vol. 1, pp. 1-45, 2014.
F. N. Catbas, M. Susoy, and D. M. J. E. s. Frangopol, "Structural health monitoring and reliability estimation: Long span truss bridge application with environmental monitoring data," vol. 30, pp. 2347-2359, 2008.
J. Ko and Y. Q. J. E. s. Ni, "Technology developments in structural health monitoring of large-scale bridges," vol. 27, pp. 1715-1725, 2005.
T. Mustafy, A. Pal, M. Islam, and R. Ahsan, "Development of plastic hinge length expression for fiber reinforced polymer strengthened concrete bridge pier."
T. Mustafy and R. Ahsan, "FE modeling and experimental verification of a CFRP strengthened steel section subjected to transverse end bearing force."
M. Abe, Y. Fujino, M. Yanagihara, and M. Sato, "Monitoring of hakucho suspension bridge by ambient vibration measurement," in Nondestructive Evaluation of Highways, Utilities, and Pipelines IV, 2000, pp. 237-244.
M. Celebi, R. Purvis, B. Hartnagel, S. Gupta, P. Clogston, P. Yen, et al., "Seismic instrumentation of the Bill Emerson Memorial Mississippi River Bridge at Cape Girardeau (MO): A cooperative effort," in Proceedings of the 4th International Seismic Highway Conference, 2004.
S.-H. Sim, J. Li, H. Jo, J.-W. Park, S. Cho, B. F. Spencer Jr, et al., "A wireless smart sensor network for automated monitoring of cable tension," vol. 23, p. 025006, 2013.
K. Y. J. S. c. Wong and h. monitoring, "Instrumentation and health monitoring of cable‐supported bridges," vol. 11, pp. 91-124, 2004.
J. Ma and D. J. Pines, "Concept of dereverbation and its application to damage detection in civil structures," in Smart Structures and Materials 2000: Smart Systems for Bridges, Structures, and Highways, 2000, pp. 127-134.
F. Chang, "Built-in diagnostic for structural health monitoring," in Proceedings of the Grantees Meeting, USJapan Urban Earthquake Disaster Mitigation Research Initiative, 1999.
M. W. Lin, A. O. Abatan, and Y. Zhou, "Transverse shear response monitoring of concrete cylinder using embedded high-sensitivity ETDR sensor," in Smart Structures and Materials 2000: Smart Systems for Bridges, Structures, and Highways, 2000, pp. 319-328.
S. S. Kessler, S. M. J. D. o. A. Spearing, and M. I. o. T. Astronautics, "Constantinos Soutis' Structural Health Monitoring in Composite Materials Using Lamb Wave Methods' Technology Laboratory for Advanced Composites," 2001.
H. Van der Auweraer and B. J. S. H. M. Peeters, "International research projects on structural health monitoring: an overview," vol. 2, pp. 341-358, 2003.
V. Giurgiutiu, Structural health monitoring: with piezoelectric wafer active sensors: Elsevier, 2007.
D. Balageas, C.-P. Fritzen, and A. Güemes, Structural health monitoring vol. 90: John Wiley & Sons, 2010.
F. Chowdhury, M. Raihan, and G. Islam, "Application of different structural health monitoring system on bridges: An overview," in IABSE-JSCE Joint Conference on Advances in Bridge Engineering-III, 2015, p. 10.
V. A. Kottapalli, A. S. Kiremidjian, J. P. Lynch, E. Carryer, T. W. Kenny, K. H. Law, et al., "Two-tiered wireless sensor network architecture for structural health monitoring," in Smart structures and materials 2003: Smart systems and nondestructive evaluation for civil infrastructures, 2003, pp. 8-19.
S. Thirumalini, M. J. S. H. M. o. B. Manikandan, Fibre-Reinforced Composites, and H. Composites, "Shukla Alokita1, Verma Rahul1, Kandasamy Jayakrishna1, VR Kar3, M. Rajesh1," p. 53, 2018.
M. Furinghetti, A. Pavese, F. Lunghi, and D. J. J. o. C. S. H. M. Silvestri, "Strategies of structural health monitoring for bridges based on cloud computing," vol. 9, pp. 607-616, 2019.
M. I. Reza, M. M. Mia, and A. Tamjeed, "Structural Health Monitoring of Japan Bangladesh Friendship Bridge."
S. Jang, H. Jo, S. Cho, K. Mechitov, J. A. Rice, S.-H. Sim, et al., "Structural health monitoring of a cable-stayed bridge using smart sensor technology: deployment and evaluation," vol. 6, pp. 439-459, 2010.
J. A. Rice, K. Mechitov, S.-H. Sim, T. Nagayama, S. Jang, R. Kim, et al., "Flexible smart sensor framework for autonomous structural health monitoring," vol. 6, pp. 423-438, 2010.
K. yuen Wong, K. I. Man, and W. yee Chan, "Monitoring Hong Kong’s bridges. Real time kinematic spans the gap," GPS World. July, 2001.
K.-Y. Koo, J. Brownjohn, D. List, and R. Cole, "Structural health monitoring of the Tamar suspension bridge," Structural Control and Health Monitoring, vol. 20, pp. 609-625, 2013.
S. Lovejoy, "Applications of Structural Health Monitoring to Highway Bridge. Presentation at the Western Bridge Engineers," ed: State Of Oregon Department Of Transportation, 2007.
M. Wang and J. Yim, "Monitoring of the I-39 Kishwaukee Bridge," 0197-9191, 2010.
A. Amin and Y. Okui, "Design, construction and maintenance of bridges in Bangladesh: In the past, present and future," in Proc. of IABSE–JSCE conf. on Advances in Bridge Engineering (Amin AFMS, Okui Y, Bhuiyan AR and Ueda T (eds)), Dhaka, Bangladesh, 2015, pp. 57-76.
M. Sobhan and A. S. Amin, "Recent trend and futuristic vision of bridge development in Bangladesh," in Proceedings of IABSE–JSCE Conference on Advances in Bridge Engineering (Amin AFMS, Okui Y and Bhuiyan AR (eds)), Dhaka, Bangladesh, 2010, pp. 1-11.
S. Noor, A. Amin, and A. Khan, "Numerical investigation of a counter measure to control local scour around a bridge pier: A new source of bridge vibration," in Proceedings of IABSE–JSCE Conference on Advances in Bridge Engineering (Amin AFMS, Okui Y, Bhuiyan AR, Ueda T (eds)), Dhaka, Bangladesh, 2015.
W. Wheeler, R. Aves, C. Tolley, M. Zaman, and M. R. Islam, "Detailed design of the Padma Multipurpose Bridge, Bangladesh–An overview," in IABSE-JSCE Joint Conference on Advances in Bridge Engineering-II, 2010.
N. Kravchuk, R. Colquhoun, and A. Porbaha, "Development of a friction pendulum bearing base isolation system for earthquake engineering education," in Proceedings of the 2008 American Society for Engineering Education Pacific Southwest Annual Conference, 2008, pp. 22-25.
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