VEÍCULO AÉREO NÃO TRIPULADO E APLICAÇÕES NA CONSTRUÇÃO CIVIL NA ÁREA DE TRANSPORTES – UM ESTUDO DE CASO NA CIDADE DE SALVADOR
DOI:
https://doi.org/10.46421/entac.v18i.1020Keywords:
Unmannede aerial vehicle (UAV), Bridges, Routine InspectionsAbstract
Unmanned aerial vehicles (UAVs) can be used for different purposes and it is a tool already studied for civil construction in the area of transport. This article aims to present some applications of UAVs in the area of transport found in the literature and to verify its possible use as a tool for routine inspection of bridges, based on ABNT NBR 9452: 2016 and its forms. As a case study, the use of UAV as a tool for the identification of pathologies in a viaduct in the city of Salvador was tested. The results showed that the UAV is a promising tool to aid in the routine inspection of bridges and can help in the analysis of pathologies in places with difficult access. To speed up the fieldwork, an app proposal is presented. This article is a part from an ongoing doctorate degree thesis.
References
AL-KAFF, A.; MARTÍN, D.; GARCÍA, F. LA ESCALERA, A. de; ARMINGOL, J. M. Survey of computer vision algorithms and applications for unmanned aerial vehicles. Expert Systems with Applications, v. 92, p. 447–463, 2018.
ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 9452: Inspeção de pontes, viadutos e passarelas de concreto - Procedimento. Rio de Janeiro, 2016.
HASSANALIAN, M.; ABDELKEFI, A. Classifications, applications, and design challenges of VANTs: A review. Progress in Aerospace Sciences, v. 91, p. 99–131, 2017.
HASSANALIAN, M.; RICE, D.; ABDELKEFI, A. Evolution of space VANTs for planetary exploration: A review. Progress in Aerospace Sciences, v. 97, p. 61–105, 2018.
JURIĆ-KAĆUNIĆ, D.; LIBRIĆ, L.; CAR, M. Application of unmanned aerial vehicles on transport infrastructure network. Građevinar, v. 68, n. 4, p. 287-300, 2016.
KARAN, E. P. et al. A Comprehensive Matrix of Unmanned Aerial Systems Requirements for Potential Applications within a Department of Transportation. Construction Research Congress: ASCE 2014.
LI, M.; ZHEN, L.; WANG, S. LV, W.; QU, X. Unmanned aerial vehicle scheduling problem for traffic monitoring. Computers & Industrial Engineering, v. 122, p. 15–23, 2018.
LIU, P. et al. A review of rotorcraft unmanned aerial vehicle (UAV) developments and applications in civil engineering. Smart structures and systems, v. 13, n. 6, p. 1065–1094, 2014.
LYGOURAS, E.; GASTERATOS, A.; TARCHANIDIS, K.; MITROPOULOS, A. ROLFER: A fully autonomous aerial rescue support system. Microprocessors and Microsystems, v. 61, p.32–42, 2018.
MELO, R. R. S. D. DIRETRIZES PARA INSPEÇÃO DE SEGURANÇA EM CANTEIROS DE OBRA POR MEIO DE IMAGEAMENTO COM VEÍCULO AÉREO NÃO TRIPULADO (VANT). 2016..
(Mestre em Engenharia Civil). PROGRAMA DE PÓS-GRADUAÇÃO EM ENGENHARIA CIVIL, UNIVERSIDADE FEDERAL DA BAHIA, Salvador.
MOGILI, R.; DEEPAK, B. B. V. L. Review on Application of VANT Systems in Precision Agriculture. In: INTERNATIONAL CONFERENCE ON ROBOTICS AND SMART MANUFACTURING. 2018, Chennai, India. Anais… Chenai: RoSMa2018, p. 502–509, 2018.
O’DRISCOLL, J. Landscape applications of photogrammetry using unmanned aerial vehicles. Journal of Archaeological Science: Reports, v. 22, p. 32–44, 2018.
OMAR, T.; NEHDI, M. L. Remote sensing of concrete bridge decks using unmanned aerial vehicle infrared thermography. Automation in Construction, v. 83, p. 360–371, 2017.
PURI, A. A survey of unmanned aerial vehicles (UAV) for traffic surveillance. University of South Florida. 2005RAKHA, T.; GORODETSKY, A. Review of Unmanned Aerial System (UAS) applications in the built environment: Towards automated building inspection procedures using VANTs.
Automation in Construction, v. 93, p. 252–264, 2018.
RENZO, A. B. D. et al. PDI para o Monitoramento de Rodovias com Imagens Aéreas Obtidas por VANT. XXXV SIMPÓSIO BRASILEIRO DE TELECOMUNICAÇÕES E PROCESSAMENTO DE SINAIS. São Pedro, SP 2017.
ROYER, J. P.; NAWAF, M. M.; MERAD, D.; SACCONE, M.; BIANCHIMANI, O. GARRABOU, J.; LEDOUX, J. B.; LOPEZ-SANZ, A.; DRAP, P. Photogrammetric Surveys and Geometric Processes to Analyse and Monitor Red Coral Colonies. Journal of Marine Science and Engineering, v. 6, n. 42, 2018.
STEFANO, G. di; ROMEO, G.; MAZZINI, A.; IAROCCI, A.; HADI, S.; PELPHREY, S. The LusiVANT: A multidisciplinary tool to access extreme environments. Marine and Petroleum Geology, v. 90, p. 26-37, 2018.
YUAN, H.; XIAO, C.; ZHAN, W.; WANG, Y.; SHI, C.; YE, H.; JIANG, K.; YE,·Z.; ZHOU, C.; WEN, Y.; LI, Q. Target Detection, Positioning and Tracking Using New UAV Gas Sensor Systems: Simulation and Analysis. Journal of Intelligent & Robotic Systems, 2018.
