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Journal of Applied Engineering Science
2016, vol. 14, br. 2, str. 314-327
jezik rada: engleski
vrsta rada: originalan članak
objavljeno: 27/10/2016
doi: 10.5937/jaes14-10918
Creative Commons License 4.0
An unmanned aerial vehicle for multi-purpose tasks in construction industry
(naslov ne postoji na srpskom)
aGic gradnje d.o.o.
bUniversity of Maribor, Faculty of Civil Engineering, Slovenia


(ne postoji na srpskom)
The aim of this paper is to present an unmanned aerial vehicle (UAV) developed for multipurpose usage in construction industry such as construction site monitoring, examination of constructions, infrared thermography, photogrammetry, transport applications and also for marketing activities. Initially, this article briefly introduces the possibilities of UAV applications in construction industry. Thereupon, the paper presents the structure, the hardware and the software system of a hexacopter, specially developed as the UAV for multipurpose use at construction sites and on locations of existing facilities. Due to the nature of the movement and vibrations created during the flight, it was necessary to develop a stabilizing system for capturing quality photos and videos. Therefore, this paper also exposes an applicable solution for such stabilization system which was installed in the UAV. Further- more, some actual practices and applications performed employing the developed UAV in the field are shown at the end of the paper. The possible uses of the developed UAV demonstrated that it is suitably operational for multipurpose tasks, particularly on the account of its flexibility, generated thrust and installed software system. Additionally, it is unlike the out of the box systems, which are usually intended for single use.

Ključne reči


*** (2014) SimpleBGC software user manual. Basecamelectronics, https://www.basecam-, retrieved on May 4th, 2016
Asbeck, A., Dastoor, S., Parness, A., i dr. (2009) Climbing rough vertical surfaces with hierarchical directional adhesion. u: IEEE International Conference on Robotics and Automation, 12-17 May 2009, Kobe, pp. 2675-2680
Åström, K.J., Hägglund, T. (2001) The future of PID control. Control Engineering Practice, 9(11): 1163-1175
Cajzek, R., ek Klan, U. (2014) Quality management of special purpose buildings: A case of National Forensic Laboratory in Ljubljana. International Journal of Industrial Engineering and Management, Vol. 5, No. 3, pp. 115-122
Cajzek, R., Klanšek, U. (2015) Applications of unmanned aerial vehicles in construction industry. u: 12th International Conference Organization, Technology and Management in Construction, 5-7 September 2015, Primošten, pp. 136-144
Draeyer, B., Strecha, C. (2014) Putting stock in your survey. GEO: Connexion, Vol.13, No. 2, pp. 32-34
Federal Aviation Administration Small UAS notice of proposed rulemaking (NPRM)., retrieved on May 4th, 2016
Haynes, G.C., Khripin, A., Lynch, G., i dr. (2009) Rapid pole climbing with a quadrupedal robot. u: IEEE International Conference on Robotics and Automation, 12-17 May 2009, Kobe, pp. 2767-2772
Heutger, M., Kückelhaus, M. (2014) Unmanned aerial vehicles in logistics. DHL Customer Solutions & Innovation,, retrieved on May 4th, 2016
Kharchenko, V., Prusov, D. (2012) Analysis of unmanned aircraft systems application in the civil field. Transport, 27(3): 335-343
Mavromatidis, L.E., Dauvergne, J.L., Saleri, R., i dr. (2014) First experiments for the diagnosis and thermophysical sampling using pulsed IR thermography from unmanned aerial vehicle (UAV). u: Quantitative InfraRed Thermography (QIRT) conference, 7-11 July 2014, Bordeaux, pp. 1-8
Mejias, L., Correa, J., Mondragon, I., i dr. (2007) COLIBRI: A vision-guided UAV for surveillance and visual inspection. u: IEEE International Conference on Robotics and Automation, 10-14 April 2007, Roma, pp. 2760-2761
Metni, N., Hamel, T. (2007) A UAV for bridge inspection: Visual servoing control law with orientation limits. Automation in Construction, 17(1): 3-10
Moranduzzo, T., Melgani, F. (2014) Monitoring structural damages in big industrial plants with UAV images. u: IEEE International Symposium on Geoscience and Remote Sensing IGARSS, 13-18 July 2014, Quebec City, pp. 4950-4953
Quater, P.B., Grimaccia, F., Leva, S., Mussetta, M., Aghaei, M. (2014) Light Unmanned Aerial Vehicles (UAVs) for Cooperative Inspection of PV Plants. IEEE Journal of Photovoltaics, 4(4): 1107-1113
Rikalovic, A.M., Cocić, I. (2014) GIS based multi-criteria decision analysis for industrial site selection: The state of the art. Journal of Applied Engineering Science, vol. 12, br. 3, str. 197-206
Roca, D., Lagüela, S., Díaz-Vilariño, L., Armesto, J., Arias, P. (2013) Low-cost aerial unit for outdoor inspection of building façades. Automation in Construction, 36: 128-135
Sa, I., Hrabar, S., Corke, P. (2014) Inspection of pole-like structures using a vision-controlled VTOL UAV and shared autonomy. u: IEEE International Conference on Intelligent Robots and Systems, 14-18 September 2014, Chicago, pp. 4819-4826
Schober, T. (2010) CLIBOT 8211; ein seilkletternder Roboter zur Bauwerksinspektion. Bautechnik, 87(2): 81-85
Siebert, S., Teizer, J. (2014) Mobile 3D mapping for surveying earthwork projects using an Unmanned Aerial Vehicle (UAV) system. Automation in Construction, 41: 1-14
Vetter, A., Fecher, F., Adams, J., Schaeffler, R., Theisen, J., Brabec, C.J., Buerhop, C. (2013) Lock-in thermography as a tool for quality control of photovoltaic modules. Energy Science & Engineering, 1(1): 12-17
Windau, J., Itti, L. (2011) Multilayer real-time video image stabilization. u: IEEE/RSJ International Conference on Intelligent Robots and Systems, 25-30 September 2011, San Francisco, pp. 2397-2402
Zajc, D., Bojc, I. (2014) Project documentation: Project execution plan. Ljubljana: SŽ projektivno podjetje Ljubljana d.d, 3639/OBJ_3/2