Title :
Harnessing High-Altitude Solar Power
Author :
Aglietti, Guglielmo S. ; Redi, Stefano ; Tatnall, Adrian R. ; Markvart, Thomas
Author_Institution :
Sch. of Eng. Sci., Univ. of Southampton, Southampton
fDate :
6/1/2009 12:00:00 AM
Abstract :
As an intermediate solution between Glaser´s satellite solar power (SSP) and ground-based photovoltaic (PV) panels, this paper examines the collection of solar energy using a high-altitude aerostatic platform. A procedure to calculate the irradiance in the medium/high troposphere, based on experimental data, is described. The results show that here a PV system could collect about four to six times the energy collected by a typical U.K.-based ground installation, and between one-third and half of the total energy the same system would collect if supported by a geostationary satellite (SSP). The concept of the aerostat for solar power generation is then briefly described together with the equations that link its main engineering parameters/variables. A preliminary sizing of a facility stationed at 6 km altitude and its costing, based on realistic values of the input engineering parameters, is then presented.
Keywords :
high altitude stratospheric platforms; photovoltaic power systems; solar power satellites; solar power stations; Glaser satellite solar power; aerostat; altitude 6 km; ground-based photovoltaic panels; high-altitude solar power; solar power generation; Conducting materials; Conductors; Photovoltaic systems; Power engineering and energy; Satellites; Solar energy; Solar power generation; Solar radiation; Space power stations; Terrestrial atmosphere; Energy conversion; PV space power systems; photovoltaic (PV) power systems; power conversion; solar energy; solar power satellites; solar radiation; terrestrial atmosphere;
Journal_Title :
Energy Conversion, IEEE Transactions on
DOI :
10.1109/TEC.2009.2016026
