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2016 | 48 | 119-132
Article title

The possibilities of using drones in the courier services

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EN
Abstracts
EN
The article analyzes the market for postal services on the example of Poland. Then there were presented the advantages of using drones in postal courier services. Next the assumption of conception of using unmanned aerial vehicles in courier services and a procedure of delivery of consignments were presented. Then for the real example of a drone there were conducted the calculation of real flight parameters and the forces effecting on a drone. At the end the economic aspect of using the drones in the courier services was calculated. Based on the results were discussed the usefulness of the use of of drones in courier services. In summary it was concluded that courier deliveries using the drones can be competitive in the future for the traditional methods of delivery. The cost of 1 parcel delivery can be even about 9% lower than so far. Consideration should be given that the prices used to estimate the cost of production machines are retail prices. The mass production of drones can bring savings in production costs in the range of 15-20%. The only element that does not allow to run the project of delivering items using the drones is the battery. The calculations show that at the proposed subassemblies the battery capacity allows only for a 7-minute flight. However, the works on the new sources of supply are conducted - lithium batteries, the anodes of pure lithium, the fuel cells.
Year
Volume
48
Pages
119-132
Physical description
Contributors
author
  • Cluster Research and Development Innovation Foundation for Development of Science and Business on Medical and Exact Science, Wroclaw, Poland, jacek.doskocz@plusuj.pl
author
  • International University of Logistics and Transport in Wroclaw, Wroclaw, Poland
  • International University of Logistics and Transport in Wroclaw, Wroclaw, Poland
  • Lower Silesia Accelerator Technology and Innovation Sp z o.o., Wroclaw, Poland
References
  • [1] Hejduk, M., Wykorzystanie bezzałogowych statków latających – dronów w dostawach kurierskich, Praca dyplomowa, Wrocław (2015).
  • [2] Ross, J.A., Computer vision and target localization algorithms for autonomous unmanned aerial vehicles, Pennsylvania State University (2008).
  • [3] Green, J.K., Lethal unmanned air vehicle feasibility study, Praca dyplomowa (1995).
  • [4] Raport o stanie rynku pocztowego za rok 2013. Urząd Komunikacji Elektronicznej (2014).
  • [5] Ustawa z dnia 23 listopada 2012 r. Prawo Pocztowe. Dz.U. 2012, poz. 1529.
  • [6] Yuichi, H., Obanawa, H., Gomez, C., 3D Modelling of Inaccessible Areas using UAV-based Aerial Photography and Structure from Motion, EGU General Assembly (2014).
  • [7] http://www.amur.pl/wp-content/uploads/2014/03/drony.pdf
  • [8] http://pulsinnowacji.pb.pl/3606377,41540,drony-jeszcze-nie-zastapia-kurierow
  • [9] http://whatnext.pl/pierwszy-komercyjny-lot-drona-pocztowego/
  • [10] Lapena-Rey, N., Mosquera, J., Bataller, E., Otri, F., Environmentally friendly power sources for aerospace applications. Journal of Power Sources, 181(2) (2008) 353-362.
  • [11] Lapena-Rey, N., Mosquera, J., Bataller, E., Orti, F., First fuel-cell manned aircraft, Journal of Aircraft, 47(6) (2010) 1825-1835.
  • [12] Moffitt, B. A., Bardley, T.H., Parekh, D., Mavirs D., Design and performance validation of a fuel cell unmanned aerial vehicle, American Institute of Aeronautics and Astronautics, 2006.
  • [13] Bardley, T. H., Moffitt, B. A., Fuller, T. F., Mavris, D., Parekh, D., Design studies for hydrogen fuel cell powered unmanned aerial vehicles, American Institute of Aeronautics and Astronautics.
  • [14] Rhoads, G. D., Wagner, N. A., Taylor, B., Keen, D., Design and flight test results for a 24 hour fuel cell unmanned aerial vehicle, 5thAnnual International Energy Conversion Engineering Conference, AIAA 2010-6690.
  • [15] Record flight UAV using Protonex fuel cell system. Fuel Cells Bulletin 4 (2009).
  • [16] Jadoo fuel cells powers Mako unmanned aerial vehicle. Fuel Cells Bulletin 4 (2009).
  • [17] Catterall C., The Hot Air Ballon Book, Chicago Review Press, 2013, 16.
  • [18] Unmanned Aerial Systems Circular. International Civil Aviation Organization (CAO) (2011).
  • [19] Scheding, S., Finn, A., Developments and Challenges for Autonomous Unmanned Vehicles, A compendium Springer Science & Business 9, 1 (2010).
  • [20] Zain, M., Hussin, A.K., Ganraj, D., An ultralight helicopter for rice farmers, University of Technology MARA (2001).
  • [21] Puttock, A.K., Cunliffe, A.M., Anderson, K., Brazier, R.E., Aerial photography collected with a multirotor drone reveals impact of Eurasian beaver reintroduction on ecosystem structure, Journal of Unmanned Vehicle Systems, 3(3) (2015) 123-130.
  • [22] Hsu, J., Cloudy with a Chance of Drones, Scientific American 313 (2015) 20.
  • [23] Ogden, L.A., Drone Ecology, BioScience 63(9) (2013) 776.
  • [24] Drones: The American Controversy. Journal of Strategic Security, 7, 4, Special Issue Winter (2014).
  • [25] Schlag, C., The New Privacy Battle: How to Expending Use of Drones Continuous to Erode Our Concept of Privacy and Privacy Rights, Journal of Technology Law & Policy, 13 (2013).
  • [26] Floreano, D., Wood, R.J., Science, technology and the future of small autonomous drones, Nature 521 (2015) 460-466.
  • [27] Koh, L.P., Wich, S.A., Dawn of drone ecology: low-cost autonomous aerial vehicles for conservation, Tropical Conservation Science, 5(2) (2015) 121-132.
  • [28] Myose, R.Y., Strohl, R.J., Uninhabited aerial vehicle (UAV), Engineering & Materials (2014).
  • [29] Alberstadt, R., Drones under International Law, Open Journal of Political Science, 4(4) (2014).
  • [30] Unmanned Aerial Vehicles in Logistics. A DHL perspective on implications and use cases for the logistics industry (2014).
  • [31] Civilian Use of Drones in the EU. European Union Committee7th Report of Session 2014-15.
  • [32] Loke, S.W., The Internet of Flying-Things: Opportunities and Challenges with Airborne Fog Computing and Mobile Cloud in the Clouds.
  • [33] Galvez, J.P., McCall, M.K, Napoletano, B.M., Sarge, A.W., Koh, L.P., Small drones for Community-Based Forest Monitoring: An Assessment of Their Feasibility and Potential in Tropical Areas, Forests, 5 (2015) 1481-1507.
  • [34] Martin, H.J., British American Security Information Council The UK and Armed Drones Key considerations for the future of the UK’s programme, January (2013).
  • [35] Murrow, H. N., Eckstrom, C. V., Drones for Aerodynamic and Structural Testing (DAST), A Status Report. 16(8) (1979) 521-526.
  • [36] Topalov, A.V., Unmanned Aerial Vehicles and Aircraft Systems, International Journal of Advanced Robotic Systems, 2013.
  • [37] Rango, A., Laliberte, A., Steele, C., Herrick, J.E., Bestelmeyer, B., Schmugge, T., Roanhorse, A., Jenkins, V., Using Unmanned Aerial vehicles for Rangelands: Current Applications and Future Potentials, Environmental Practice, 8 (2006) 159-168.
  • [38] Clothier, R., and Walker, R.: Determination and evaluation of UAV safety objectives. In Proceedings 21st International Unmanned Air Vehicle Systems Conference. Bristol, UK (2006).
  • [39] Lum, C.W., Gauksheim, K., Deseure, C. Vagners, J., and McGeer, T.: Assessing and estimating risk of operating unmanned aerial systems in populated areas. In Proceedings of the 11th AIAA Aviation Technology, Integration, and Operations (ATIO) Conference, Virginia Beach (2011).
  • [40] Dalamagkidis, K., Valavanis, K.P., and Piegl, L.A.: Evaluating the risk of unmanned aircraft ground impacts. In Proceedings of the 16th Mediterranean Conference on Control and Automation, Ajaccio, France, 25-27 June (2008).
Document Type
article
Publication order reference
Identifiers
YADDA identifier
bwmeta1.element.psjd-d681cbe3-29e6-42c4-898b-4132493a08ed
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