Abstract
In Peru, there are many monuments of high cultural and historical value, and with this, a rising need to ensure their conservation and optimal preservation over the years. Future structural damage situations can be avoided, and better restoration plans can be proposed by using non-invasive diagnostic techniques. This requires a constant process of monitoring to evaluate their structural state over time. For this purpose, a remote monitoring visualizing tool was proposed by using simple and reliable off the shelf applications. By establishing this system, it is now possible to visualize real time data from different projects, enabling the access to this data from any electronic device with internet connection through the web platform. The paper shows a detail description of the developed tool based on the following stages: (i) Acquisition and centralization of acceleration data, (ii) Wireless transfer/reception and processing of acquired data in a base station; and (iii) Dynamic visualization of processed data through a web platform. Accelerometers, data acquisition system, data processing software (LabVIEW), file transferring software (Bitvise and OneDrive), as well as web server services (Amazon Web Server) were used to acquire, transmit, process and visualize the changes in acceleration. The developed tool is use to monitor the “Church of San Juan Bautista de Huaro”. In this case study, the tool presents real time information about modal frequencies, damping, maximum accelerations, and maximum RMS, which are relevant to understand the current “health” of the structure.
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Zhou G, Yi T (2004) A summary review of correlations between temperature and vibration properties of Long-Span bridges. https://www.hindawi.com/journals/mpe/2014/638209/
Crespo S, Hernandez J, Carrion F, et al (2014) Plataforma para el análisis y visualización de señales para el monitoreo remoto de estructuras
Hoon S, Charles F, Francois H, et al (2004) A review of structural health review of structural health monitoring literature, pp 1996–2001
Chang P, Flatau A, Liu SC (2003) Health monitoring of civil infrastructure. Sage Publications 2(3):257–267. https://doi.org/10.1177/1475921703036169
Bhuiyan MZA, Wang G, Wu J et al (2015) Dependable structural health monitoring using wireless sensor networks. IEEE Trans Dependable Secure Comput 14(4):363–376. https://doi.org/10.1109/TDSC.2015.2469655
Al-Radaideh A, Al-Ali AR, Bheiry S, Alawnah S (2015) A wireless sensor network monitoring system for highway bridges. https://doi.org/10.1109/eitech.2015.7162953
Montero L, Aquila C, Santalucía J et al (2015) Red de Sensores Inalámbricos para Monitoreo Sísmico con Acceso a Internet. In: 2015 CHILEAN conference on electrical, electronics engineering, information and communication technologies (CHILECON). https://doi.org/10.1109/chilecon.2015.7400348
Phanish D, Garver P, Matalkah G et al (2015) A wireless sensor network for monitoring the structural health of a football stadium. In: IEEE 2nd World Forum on Internet of Things (WF-IoT), pp 471–477. https://doi.org/10.1109/wf-iot.2015.7389100
Valenzuela M (2015) Políticas culturales y estado-nación: las declaraciones del patrimonio histórico inmueble en el Perú entre 1821 y 2014. Devenir 2(3):8–21
Bernal I, Tavera H, Antayhua Y (2017) Zona Sismo génicas en Perú: Volúmenes de Deformación Gráficos Polares y Zonificación Preliminar. Boletín de la Sociedad Geológica del Perú 93:31–44
Córima. Revista de Investigación en Gestión Cultural (2017) La gestión de monumentos arqueológicos en Lima, Perú: panorama, diagnóstico y propuesta 2(2):1–32
Zonno G, Aguilar R, Castañeda B et al (2017) Laboratory evaluation of a fully automatic modal identification algorithm using automatic hierarchical clustering approach. Procedia Eng 199:882–887. https://doi.org/10.1016/j.proeng.2017.09.219
Acknowledgments
This work was developed thanks to the initiative of the research group “Engineering and Heritage PUCP” under the financing of FONDECYT (PROYECTO ID 349/316 DGI PUCP) with the aim of innovating in methodologies to conserve the national patrimony of Peru. The third author also acknowledges ELARCH program for the scholarship in support of his PhD studies (Project Reference number: 552129-EM-1-2014-1-IT-ERA MUNDUS-EMA21).
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Fosca, D., Pórcel, P., Zonno, G., Castañeda, B., Aguilar, R. (2019). Implementation of a Web Platform to Present Real Time Dynamic Monitoring Data from Heritage Structures. In: Aguilar, R., Torrealva, D., Moreira, S., Pando, M.A., Ramos, L.F. (eds) Structural Analysis of Historical Constructions. RILEM Bookseries, vol 18. Springer, Cham. https://doi.org/10.1007/978-3-319-99441-3_241
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DOI: https://doi.org/10.1007/978-3-319-99441-3_241
Publisher Name: Springer, Cham
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