Affiliation:
1. Applied Physics Laboratory, and School of Oceanography, University of Washington, Seattle, Washington
Abstract
Abstract
Advances in low-power instrumentation and communications now often make energy storage the limiting factor for long-term autonomous oceanographic measurements. Recent advances in photovoltaic cells, with efficiencies now close to 30%, make solar power potentially viable even for vehicles such as floats that only surface intermittently. A simple application, the development of a solar-powered Argos recovery beacon, is described here to illustrate the technology. The 65-cm2 solar array, submersible to at least 750 dbar, powers an Argos beacon. Tests indicate that with minor improvements the beacon will run indefinitely at any latitude equatorward of about 50°. Scaling up this design to current operational profiling floats, each profile could easily be powered by a few hours of solar charging, a shorter time than is currently being used for Argos data communications.
Publisher
American Meteorological Society
Subject
Atmospheric Science,Ocean Engineering
Reference8 articles.
1. Atmaram, G., G. G.Ventre, C. W.Maytrott, J. P.Dunlop, and R.Swamy, 1996: Long term performance and reliability of crystalline silicon photovoltaic modules. Proc. 25th IEEE Photovoltaic Specialists Conf., Washington, DC, IEEE, 1279–1282.
2. Solar-powered autonomous undersea vehicles.;Blidberg;Sea Technol.,1997
3. MBARI’s buoy based seafloor observatory design.;Chaffey;Oceans ’04, MTS/IEEE TECHNO-OCEAN ’04,2004
4. Performance of autonomous Lagrangian floats.;D’Asaro;J. Atmos. Oceanic Technol.,2003
5. Profiling ALACEs and other advances in autonomous subsurface floats.;Davis;J. Atmos. Oceanic Technol.,2001
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