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http://dx.doi.org/10.7746/jkros.2018.13.4.248

Vehicle Body Design of Armored Robot for Complex Disaster  

Park, Sang Hyun (KIRO)
Jin, Maolin (KIRO)
Kim, Young-Ryul (JINWOO SMC Co.,LTD.)
Kim, Doik (KIST)
Kim, Jun-Sik (KIST)
Shin, Dong Bin (KIRO)
Suh, Jinho (Dept. of Mechanical System Eng., Pukyong National University)
Publication Information
The Journal of Korea Robotics Society / v.13, no.4, 2018 , pp. 248-255 More about this Journal
Abstract
In this paper, a design for a vehicle body of an armored robot for complex disasters is described. The proposed design considers various requirements in complex disaster situations. Fire, explosion, and poisonous gas may occur simultaneously under those sites. Therefore, the armored robot needs a vehicle body that can protect people from falling objects, high temperature, and poisonous gas. In addition, it should provide intuitive control devices and realistic surrounding views to help the operator respond to emergent situations. To fulfill these requirements of the vehicle body, firstly, the frame was designed to withstand the impact of falling objects. Secondly, the positive pressure device and the cooling device were applied. Thirdly, a panoramic view was implemented that enables real-time observation of surroundings through a number of image sensors. Finally, the cockpit in the vehicle body was designed focused on the manipulability of the armored robot in disaster sites.
Keywords
Disaster Robot; Armored Robot System; Panoramic View; Cockpit;
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Times Cited By KSCI : 1  (Citation Analysis)
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1 D. Jeong, C. Kim, J. H. Kim, J. Suh, and M. Jin, "Mission Scenario-based Design of Hydraulic Manipulators for Armored Robot Systems," Journal of Drive and Control, vol.14, no.4, pp. 51-60, Dec., 2017.   DOI
2 P.-H. Chang, Y.-H. Kang, G. R. Cho, J. H. Kim, M. Jin, J. Lee, J. W. Jeong, D. K. Han, J. H. Jung, W.-J. Lee, and Y.-B. Kim, "Control architecture design for a fire searching robot using task oriented design methodology," 2006 SICE-ICASE International Joint Conference, Busan, Korea, pp. 3126-3131, 2006.
3 R. Szeliski, Computer Vision: algorithms and applications, Springer Science & Business Media, 2010.
4 R. Hartley and A. Zisserman, Multiple View Geometry in Computer Vision, 2nd ed. Cambridge University Press, 2003.
5 J.-S. Kim, M. Hwangbo, and T. Kanade, "Spherical approximation for multiple cameras in motion estimation: Its applicability and advantages," Computer Vision and Image Understanding, vol. 114, no. 10, pp. 1068-1083, Oct., 2010.   DOI
6 C. Zhu, Z. Zhou, Z. Xing, Y. Dong, Y. Ma, and J. Yu, "Robust plane-based calibration of multiple non-overlapping cameras," 2016 Fourth International Conference on 3D Vision (3DV), Stanford, CA, USA, pp. 658-666, 2016.
7 B. Triggs, P. F. McLauchlan, R. I. Hartley, and A. W. Fitzgibbon. "Bundle Adjustment - A Modern Synthesis," IWVA 1999: Vision Algorithms: Theory and Practice, Corfu, Greece, pp. 298-372, 1999.
8 H.-S. Kim, C.-H. Park, D.-I. Park, H.-M. Do, T.-Y. Choi, D.-H. Kim, and J.-H. Kyung, "Design of high payload dual arm robot with modifiable forearm module depending on mission," 2017 14th International Conference on Ubiquitous Robots and Ambient Intelligence (URAI), Jeju, Korea, pp. 83-84, 2017.
9 M. Jin, E.-J. Jung, O. Yu, D. Kim, J. Jang, D. Kim, S. Oh, and J. Suh, "Specification development on armored robot systems for accident response in composite disaster site," Korea Robotics Society Annual Conference, Gangwon-do, Korea, pp. 310-311, 2017.
10 Frank H. Hawkins, "Space and layout," Human Factors in Flight, 1st ed. Gower Technical Press, 1987, ch.12, pp. 256-270.
11 D. L. Baty and M. L. Watkins, "An Advanced Cockpit Instrumentation System: The Coordinated Cockpit Display," NASA Ames Research Center, Moffett Field, United States, Rep. NASA-TM-78559, A-7733, July, 1979.
12 J. Roskam, "Cockpit (or Flight deck) layout design," Airplane Design Part III: Layout Design of Cockpit, Fuselage, Wing and Empennage: Cutaways and Inboard Profiles, 1st ed. DAR Corporation, Kansas, USA, 2002, ch.2, pp. 3-29.
13 Aircrew Station Vision Requirements for Military Aircraft, AIR FORCE, USA, MIL-STD-850, June 8, 1967.
14 Korea Institute of Design Promotion, Size Korea, [Online], https://sizekorea.kr, Accessed: October 9, 2018.
15 Y.-R. Kim, O.-S. Yu, Y.-J. Choi, D.-J. Kim, J.-H. Lee, K. K. Ahn, M. Jin, and J. Suh, "An armored robot system for disaster circumstances," Korea Robotics Society Annual Conference, Gangwon-do, Korea, pp. 312-313, 2017.