The performance of solar-wind energy towers using a Lagrangian-Eulerian multiphase model -

Abstract

State of the art computational fluid dynamics (CFD) techniques have become indispensable for understanding physical phenomena, and for modeling and optimizing the performance of engineering devices involving fluid flow and heat and mass transfer mechanisms. Solar wind energy towers have been recently regarded as a bold new approach to the United States and other nations for their ability to provide clean and sustainable energy, overcoming the burdens of alternative energy sources. An energy tower is a tall tower, at least 400 m high, located in a hot and dry region whereby cool water sprayed at top will evaporate and create a downdraft. The produced high velocity airflow will drive turbines at the bottom of the tower and generate electricity. A 2D numerical model of a prospected tower is constructed to study the impact of different operating parameters including spray droplet diameter, spray flow rate, and ambient conditions on the performance of the tower. A Lagrangian-Eulerian multiphase technique is adopted for simulating droplet transport and evaporation. The model is first validated with published measured data extracted from a small scale PDEC experimental test facility at the Conphoebus Institute in Sicily. Results show that the model is able to accurately predict the evaporation phenomena and that an exit velocity of 33.2m-s can be achieved over a 1000m height tower.