Abstract
A hybrid underwater glider Petrel-II has been developed and field tested. It is equipped with an active buoyancy unit and a compact propeller unit. Its working modes have been expanded to buoyancy driven gliding and propeller driven level-flight, which can make the glider work in strong currents, as well as many other complicated ocean environments. Its maximal gliding speed reaches 1 knot and the propelling speed is up to 3 knots. In this paper, a 3D dynamic model of Petrel-II is derived using linear momentum and angular momentum equations. According to the dynamic model, the spiral motion in the underwater space is simulated for the gliding mode. Similarly the cycle motion on water surface and the depth-keeping motion underwater are simulated for the level-flight mode. These simulations are important to the performance analysis and parameter optimization for the Petrel-II underwater glider. The simulation results show a good agreement with field trials.
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References
Ambler, C., 2010. Design of an Underwater Vertical Glider for Subsea Equipment Delivery, Master Thesis, Massachusetts Institute of Technology.
Bachmayer, R., Leonard, N.E., Graver, J., Fiorelli, E., Bhatta, P. and Paley, D., 2004. Underwater gliders: Recent developments and future applications, Proceedings of International Symposium on Underwater Technology, Taipei, 195–200.
Claus, B., Bachmayer, R. and Cooney, L., 2012. Analysis and development of a buoyancy-pitch based depth control algorithm for a hybrid underwater glider, Autonomous Underwater Vehicles (AUV), 2012 IEEE/OES, Southampton, UK, 1–6.
Claus, B., Bachmayer, R. and Williams, C.D., 2010. Experimental flight stability tests for the horizontal flight mode of a hybrid glider, Autonomous Underwater Vehicles (AUV), 2010 IEEE/OES, Monterey, USA, 1–6.
Eriksen, C.C., Osse, T.J., Light, R.D., Wen, T., Lehman, T.W., Sabin, P.L., Ballard, J.W. and Chiodi, A.M., 2001. Seaglider: A long-range autonomous underwater vehicle for oceanographic research, IEEE J. Oceanic Eng., 26(4), 424–436.
Fan, S.S. and Woolsey, C.A., 2014. Dynamics of underwater gliders in currents, Ocean Eng., 84, 249–258.
Graver, J.G., 2005. Underwater Glider: Dynamics, Control and Design, Ph. D. Thesis, Princeton University.
Leonard, N.E. and Graver, J.G., 2001. Model-based feedback control of autonomous underwater gliders, IEEE J. Oceanic. Eng., 26(4), 633–645.
Liu, F., Wang, Y.H. and Wang, S.X., 2014. Development of the hybrid underwater glider Petrel-II, Sea Technol., 55(4), 51–54.
Mahmoudian, N., 2009. Efficient Motion Planning and Control for Underwater Gliders, Ph.D. Thesis, Virginia Polytechnic Institute and State University.
Reed, B., Ambler, C., Guerrero, J. and Hover, F., 2011. Vertical glider robots for subsea equipment delivery, 2011 IEEE International Conference on Robotic and Automation (ICRA), Shanghai, China, 2356–2361.
Rong, J.D., 2008. Analysis and Design of Performace of Underwater Lanuched Capsules, National Defense Industry Press, Beijing. (in Chinese)
Wang, S.X., Liu, F., Shao, S., Wang, Y.H., Niu, W.D. and Wu, Z.L., 2014. Dynamic modeling of hybrid underwater glider based on the theory of differential geometry and sea trails, Journal of Mechanical Engineering, 50(2), 19–27. (in Chinese)
Wang, S.X., Zhang, H.W., Hou, W. and Liang, J., 2007. Control and navigation of the variable buoyancy AUV for underwater landing and takeoff, Int. J. Control, 80(7), 1018–1026.
Wang, Y.H. and Wang, S.X., 2009. Dynamic modeling and three-dimensional motion analysis of underwater gliders, China Ocean Eng., 23(3), 489–504.
Wang, S.X., Sun, X.J., Wang, Y.H., Wu, J.G. and Wang, X.M., 2011. Dynamic modeling and motion simulation for a winged hybrid-driven underwater glider, China Ocean Eng., 25(1), 97–112.
Wood, S., Rees, M. and Pfeiffer, Z., 2007. An autonomous self-mooring vehicle for littoral coastal observations, Proc. OCEANS-Eur., Aberdeen, Scotland, 1–6.
Wu, J.G., Chen, C.Y. and Wang, S.X., 2010. Hydrodynamic effects of a shroud design for a hybrid-driven underwater glider, Sea Technol., 51(6), 45–47.
Zhang, S.W., Yu, J.C., Zhang, A.Q. and Zhang, F.M., 2013. Spiraling motion of underwater gliders: Modeling, analysis, and experimental results, Ocean Eng., 60, 1–13.
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Foundation item: The research was financially supported by the National Natural Science Foundation of China (Grant No. 51475319), and the National Hi-Tech Research and Development Program of China (863 Program, Grant No. 2012AA091001).
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Liu, F., Wang, Yh., Wu, Zl. et al. Motion analysis and trials of the deep sea hybrid underwater glider Petrel-II. China Ocean Eng 31, 55–62 (2017). https://doi.org/10.1007/s13344-017-0007-4
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DOI: https://doi.org/10.1007/s13344-017-0007-4