Abstract:The thermal glider’s changeable volume produces propelling force to power the glider’s descending and ascending through the thermocline. The different depth, thickness, and intensity of the thermocline at different seasons and locations affect the working processes of the glider’s power system. Based on the enthalpy method, a mathematical model of the underwater glider’s power system was established and the time efficiency of operation was introduced, so that the effects of different thermoclines on the underwater glider’s power system were analyzed theoretically. The simulation result shows that the thermocline affects the transition time of the phase change processes of working fluids within the thermal engine tubes. There exist the threshold values of the thermocline’s depth and upper thickness for the power system’s operation. A depth or upper thickness of the thermocline less than the corresponding threshold leads the power system to work abnormally. To keep the power system working efficiently, a glider must be kept in warm surface water for a certain period before it moves through cold water, so that the time efficiency of operation is reduced. A less time efficiency of operation is unfavorable to the thermal glider to penetrate through the ocean currents.
出版日期: 2009-12-05
引用本文:
. Effects of thermocline on performance of underwater
glider’s power system propelled by ocean thermal energy[J]. Front. Energy, 2009, 3(4): 472-479.
Hai YANG, Jie MA, . Effects of thermocline on performance of underwater
glider’s power system propelled by ocean thermal energy. Front. Energy, 2009, 3(4): 472-479.
Davis R E, Eriksen C C, Jones C P. Autonomous buoyancy-driven underwater gliders. In: Griffiths G ed. The Technology and Applications of Autonomous Underwater Vehicles. London: Taylorand Francis, 2002, 37–58
Eriksen C C, Osse T J, Light R D, Wen T, Lehman T W, Sabin P L, Ballard J W, Chiodi A M. Seaglider: a long-range autonomous underwater vehicle for oceanographicresearch. IEEE Journal of Oceanic Engineering, 2001, 26(4): 424–436 doi: 10.1109/48.972073
Sherman J, Davis R E, Owens W B. The autonomous underwater glider “Spray”. IEEE Journal of Oceanic Engineering, 2001, 26(4): 437–446 doi: 10.1109/48.972076
Webb D C, Simonetti P J, Jones C P. SLOCUM: an underwater glider propelled by environmentalenergy. IEEE Journal of Oceanic Engineering, 2001, 26(4): 447–452 doi: 10.1109/48.972077
Wang Shuxin, Wang Yanhui, Zhang Datao, He Manli, Zhu Guangwen, Renwei. Design and trial on anunderwater glider propelled by thermal engine. Ocean Technology, 2006, 25(1): 1–5 (in Chinese)
Wang Yanhui, Wang Shuxin, Xie Chungang. Dynamic analysis and system design on an underwater gliderpropelled by temperature difference energy. Journal of Tianjin University, 2007, 40(2): 133–138 (in Chinese)
Qiu Zhang, Cai Shuqun, Zhu Liangsheng. Distribution characteristics of mean seawater temperaturerelated to the thermocline in the deep-water area of Nansha. Marine Science Bulletin, 2001, 3(2): 1–5
Voller V R. Fast implicit finite-difference method for the analysis of phasechange problems. Numerical Heat Transfer,Part B, 1990, 17(2): 155–169 doi: 10.1080/10407799008961737
Costa M, Buddhi D, Oliva A. Numerical simulation of a latent heat thermal energystorage system with enhanced heat conduction. Energy Conversion and Management, 1998, 39(3,4): 319–330
Isachenko V P, Osipova V A, Sukomel A S. Heat Transfer, 3rd ed. Moscow:MIR Publisher, 1977, 251–253
State Oceanic Administration of the People’sRepublic of China. The Treatment of OceanInvestigation Information. Beijing: Ocean Press, 1992 (in Chinese)
