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Zastosowanie bezzałogowych statków powietrznych w budownictwie

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
EN
Application of unmanned aerial vehicles in construction industry
Języki publikacji
PL
Abstrakty
PL
Bezzałogowe statki powietrzne, potocznie nazywane dronami, są szeroko stosowane w wielu sektorach gospodarki, m.in. w: górnictwie, rolnictwie, medycynie, ekologii, transporcie. Na podstawie wykonanego systematycznego przeglądu literatury wynika, że drony mają również szerokie zastosowanie w budownictwie, m.in. w: inspekcjach budowlanych, ocenie zniszczeń (szkód, uszkodzeń), pomiarach terenu (inwentaryzacje, mapowanie terenu), inspekcjach stanu bezpieczeństwa, monitorowaniu postępów prac, konserwacji budynków, a także badaniach termowizyjnych.
EN
Unmanned aerial vehicles, commonly known as drones, are widely used in many sectors of the economy, including in: mining, agriculture, medicine, ecology, transport. The systematic literature review shows that drones are also widely used in construction, including: construction inspections, damage assessment, area measurements (inventory, area mapping), safety inspections, monitoring of the work progress, maintenance buildings, as well as thermographic researches.
Rocznik
Strony
26--31
Opis fizyczny
Bibliogr. 45 poz.
Twórcy
  • Katedra Budownictwa Ogólnego, Wydział Budownictwa Lądowego i Wodnego, Politechnika Wrocławska
  • Katedra Inżynierii Materiałów i Procesów Budowlanych, Wydział Budownictwa Lądowego i Wodnego, Politechnika Wrocławska
Bibliografia
  • [1] T. Nowobilski, M. Sawicki. M. Szóstak. Drony w ocenie stanu rusztowań, Builder, 2020, 24(1), 40-41
  • [2] T. Nowobilski, M. Sawicki, M. Szóstak. Analiza rusztowań budowlanych z wykorzystaniem nowych technologii, Builder, 2020, 24(7), 32-34
  • [3] I. Rybka, T. Nowobilski, M. Stolarz. Nowoczesne technologie monitorowania robót ziemnych: praktyczne wdrożenie na przykładzie budowy Kwatery Południowej OUOW Żelazny Most, Builder, 2020, 24(5), 44-47
  • [4] P. Noszczyk. Zastosowania dronów w działaniach PSP, W Akcji, 2018, 6, 42-48
  • [5] T. Nowobilski. Bezzałogowe statki powietrzne w kontroli obiektów budowlanych, Builder, 2020, 24(2), 18-20
  • [6] M. Herrmann. Unmanned Aerial Vehicles in Construction: An Ove- rview of Current and Proposed Rules, in: Construction Research Congress 2016: Old and New Construction Technologies Converge in Historic San Juan – Proceedings of the 2016 Construction Research Congress, 2016, 588–596. doi:10.1061/9780784479827.060
  • [7] J. Łukasiewicz. Unmanned aerial vehicle as a device supporting the physical protection system of critical infrastructure facilities: Nuclear power plant as a case in point, Scientific Journal of Silesian University of Technology. Series Transport, 2020,108, 121–131. doi:10.20858/ SJSUTST.2020.108.11
  • [8] S. Zhou, M. Gheisari. Unmanned aerial system applications in construction: a systematic review, Construction Innovation, 2018, 18(4), 453–468. doi:10.1108/CI-02-2018-0010
  • [9] C. Rao, K. Krishna, K. Rachananjali, V. Sravani. Unmanned flying vehicles for various applications and their future scope in India, Journal of Mechanics of Continua and Mathematical Sciences, 2019, 14(6), 747–760. doi:10.26782/JMCMS.2019.12.00055
  • [10] J. Irizarry, D. Costa. Exploratory Study of Potential Applications of Unmanned Aerial Systems for Construction Management Tasks, Journal of Management in Engineering, 2016, 32(3), 05016001.doi:10.1061/(ASCE)ME.1943- 5479.0000422
  • [11] M. Freeman, M. Kashani, P. Vardanega, “Aerial robotic technologies for civil engineering: established and emerging practice,” Journal Of Unmanned Vehicle Systems, 2021, 9(2), 75–91.
  • [12] D. Han, S. Lee, M. Song, J. Cho. Change Detection in Unmanned Aerial Vehicle Images for Progress Monitoring of Road Construction, Buildings, 2021,11(4), doi:10.3390/BUILDINGS11040150
  • [13] M. Tatum, J. Liu. Unmanned Aircraft System Applications in Construction, Procedia Engineering, 2017, 196, 167–175. doi:10.1016/J.PROENG.2017.07.187
  • [14] K. Julge, A. Ellmann, R. Köök. Unmanned aerial vehicle surveying for monitoring road construction earthworks, Baltic Journal of Road and Bridge Engineering, 2019, 14(1), 1–17. doi:10.7250/BJRBE.2019-14.430
  • [15] F. Elghaish, S. Matarneh, S. Talebi, M. Kagioglou, M. R. Hosseini, S. Abrishami. Toward digitalization in the construction industry with immersive and drones technologies: a critical literature review, Smart and Sustainable Built Environment, 2020, doi:10.1108/SASBE-06-2020-0077
  • [16] A. Entrop, A. Vasenev. Infrared drones in the construction industry: Designing a protocol for building thermography procedures, Energy Procedia, 2017, 132, 63–68. doi:10.1016/J.EGYPRO.2017.09.636
  • [17] R. Eiris, G. Albeaino, M. Gheisari, W. Benda, R. Faris. InDrone: a 2D-based drone flight behavior visualization platform for indor building inspection, Smart and Sustainable Built Environment, 2021, doi:10.1108/SASBE-03-2021-0036
  • [18] H. Yang, Y. Lee, S. Jeon, D. Lee. Multi-rotor drone tutorial: systems, mechanics, control and state estimation, Intelligent Service Robotics, 2017, 10(2), 79–93. doi:10.1007/S11370-017-0224-Y
  • [19] Y. Li, C. Liu. Applications of multirotor drone technologies in construction management, International Journal of Construction Management, 2018. 19(5), 401–412. doi:10.1080/15623599.2018.1 452101
  • [20] S. Kim, S. Kim. Opportunities for site monitoring by adopting first personal view (FPV) of a drone, Smart Structures and Systems, 2018, 21(2), 139–149. doi:10.12989/SSS.2018.21.2.139
  • [21] G. Albeaino, M. Gheisari. Trends, benefits, and barriers of unmanned aerial systems in the construction industry: A survey study in the united states, Journal of Information Technology in Construction, 2021, 26, 84–111. doi:10.36680/J.ITCON.2021.006
  • [22] D. Höche, W. Weber, E. Gazenbiller, S. Gavras, N. Hort, H. Dieringa. Novel Magnesium Based Materials: Are They Reliable Drone Construction Materials? A Mini Review, Frontiers in Materials, 2021, 8. doi:10.3389/FMATS.2021.575530
  • [23] M. Sagrera, V. Tuyare, G. Compa-gnone, R. Sotelo. Design, construction and manually or autonomously control of an unmanned aerial vehicle, Memoria-Investigaciones en Ingenieria, 2015, 14
  • [24] J. Hu, A. Lanzon. An innovative tri-rotor drone and associated di- stributed aerial drone swarm control, Robotics and Autonomous Systems, 2018, 103, 162–174. doi:10.1016/J.ROBOT.2018.02.019
  • [25] P. Szywalski, A. Waindok. Practical Aspects of Design and Testing Unmanned Aerial Vehicles, Acta Mechanica et Automatica, 2020, 14(1), 50–58. doi:10.2478/AMA-2020-0008
  • [26] A. Keyvanfar, A. Shafaghat, M. Awanghamat. Optimization and Trajectory Analysis of Drone’s Flying and Environmental Variables for 3D Modelling the Construction Progress Monitoring, International Journal of Civil Engineering, 2021, doi:10.1007/S40999-021-00665-1
  • [27] A. Bahabry, X. Wan, H. Ghazzai, H. Menouar, G. Vesonder, Y. Massoud. Low-Altitude Navigation for Multi-Rotor Drones in Urban Areas,” IEEE Access, 2019, 7, 87716–87731. doi:10.1109/AC-CESS.2019.2925531
  • [28] W. Yi, M. Sutrisna. Drone scheduling for construction site surveillance, Computer-Aided Civil and Infrastructure Engineering, 2021, 36(1), 3–13. doi:10.1111/MICE.12593
  • [29] J. Siwiec. Comparison of Airborne Laser Scanning of Low and High Above Ground Level for Selected Infrastructure Objects, Journal of Applied Engineering Sciences, 2018, 8(2), 89–96. doi:10.2478/ JAES-2018-0023
  • [30] I. Jeelani, M. Gheisari. Safety challenges of UAV integration in construction: Conceptual analysis and future research roadmap, Safety Science, 2021, 144, 105473. doi:10.1016/J.SSCI.2021.105473
  • [31] H. Izadi Moud, I. Flood, X. Zhang, B. Abbasnejad, P. Rahgozar, M. McIntyre. Quantitative Assessment of Proximity Risks Associated with Unmanned Aerial Vehicles in Construction, Journal of Management in Engineering, 2021, 37(1), 04020095. doi:10.1061/(ASCE)ME.1943-5479.0000852
  • [32] M. Gheisari, B. Esmaeili. Unmanned Aerial Systems (UAS) for Construction Safety Applications, in: Construction Research Congress 2016: Old and New Construction Technologies Converge in Historic San Juan - Proceedings of the 2016 Construction Research Con gress, CRC 2016, 2016, 2642–2650. doi:10.1061/9780784479827.263
  • [33] J. Howard, V. Murashov, C. Branche. Unmanned aerial vehicles in construction and worker safety, American Journal of Industrial Medicine, 2018, 61(1), 3–10. doi:10.1002/AJIM.22782
  • [34] V. Nguyen, K. Jung, T. Dang. DroneVR: A web virtual reality simulator for drone operator, in: Proceedings - 2019 IEEE International Conference on Artificial Intelligence and Virtual Reality, AIVR 2019, 2019, 257–262. doi:10.1109/AIVR46125.2019.00060
  • [35] K. Kas, G. Johnson. Using unmanned aerial vehicles and robotics in hazardous locations safely, Process Safety Progress, 200, 39(1). doi: 10.1002/PRS.12066
  • [36] M. Namian, M. Khalid, G. Wang, and Y. Turkan, “Revealing Safety Risks of Unmanned Aerial Vehicles in Construction” Transportation Research Record, 2021, 2675(11), 334-347. doi 10.1177/03611981211017134
  • [37] M. N. Sakib, T. Chaspari, A. Behzadan. A feedforward neural network for drone accident prediction from physiological signals, Smart and Sustainable Built Environment, 2021, doi:10.1108/SAS-BE-12-2020-0181
  • [38] J. Liu, M. Jennesse, P. Holley. Utilizing Light Unmanned Aerial Vehicles for the Inspection of Curtain Walls: A Case Study, in: Construction Research Congress 2016: Old and New Construction Technologies Converge in Historic San Juan - Proceedings of the 2016 Construction Research Congress, CRC 2016, 2016, 2651–2659. doi:10.1061/9780784479827.264
  • [39] S. Lee, M. Song, S. Kim, J. Won. Change monitoring at expressway infrastructure construction sites using drone, Sensors and Materials, 2020, 32(11), 3923–3933. doi:10.18494/SAM.2020.2971
  • [40] W. Li, H. Li, Q. Wu, X. Chen, K. Ngan. Simultaneously detecting and counting dense vehicles from drone images, in: IEEE Transactions on Industrial Electronics, 2019, 66(12), 9651–9662. doi:10.1109/TIE.2019.2899548
  • [41] K. Pawlak, D. Serek. High Voltage Transmission Line Stringing Operation. Usage of Unmanned Aerial Vehicles for Installation of Con ductor and Grounding Wires with Optical Fibers, in: 15th International Conference On Electrical Machines, Drives And Power Systems (ELMA), 2017, 32–37
  • [42] H. Yusof, M. Ahmad, A. Abdullah. Historical building inspection using the unmanned aerial vehicle (UAV), International Journal of Sustainable Construction Engineering and Technology, 2020, 11(3), 12–20. doi:10.30880/IJSCET.2020.11.03.002
  • [43] H. Jung, J.Lee, I.Kim. Challenging issues and solutions of bridge inspection technology using unmanned aerial vehicles, in: Proceedings. Sensors and Smart Structures Technologies for Civil, Mechanical, and Aerospace Systems 2018, 2018, 1. doi:10.1117/12.2300957
  • [44] J. Seo, L. Duque, J. Wacker. Drone-enabled bridge inspection methodology and application, Automation in Construction, 2018, 94, 112–126. doi:10.1016/J.AUTCON.2018.06.006
  • [45] Y. Ayele, M. Aliyari, D. Griffths, E. Droguett. Automatic crack segmentation for uav-assisted bridge inspection, Energies, 2020, 13(23). doi:10.3390/EN13236250
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-919f7111-735e-47a4-b48f-912625e08407
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