TY - GEN
T1 - Numerical investigation of the aerodynamic performance for a wells-type turbine in a wave energy converter
AU - Stipcich, G.
AU - Ramezani, A.
AU - Nava, V.
AU - Touzon, I.
AU - Sanchez-Lara, M.
AU - Remaki, L.
PY - 2015
Y1 - 2015
N2 - Ocean waves constitute an extensive energy resource, whose extraction has been the subject of intense research activity in the last three decades. Among the different variants of Wave Energy Converters, the principle of the Oscillating Water Column (OWC) is one of the most promising ones. An OWC comprises two key elements: A collector chamber, which transfers the wave oscillations' energy to the air within the chamber by back and forth displacement, and a power take off system, which converts the pneumatic power into electricity or some other usable form. The Wells turbine is a self-rectifying air turbine, a suitable solution for energy extraction from reciprocating air flow in an OWC. In the present work, the steady state, inviscid flow in the Wells turbine is investigated by numerical simulations. The relatively novel Virtual Multiple Reference Frame (VMRF) technique is used to account for the rotary motion of the turbine, and the overall performance is compared with results in the literature.
AB - Ocean waves constitute an extensive energy resource, whose extraction has been the subject of intense research activity in the last three decades. Among the different variants of Wave Energy Converters, the principle of the Oscillating Water Column (OWC) is one of the most promising ones. An OWC comprises two key elements: A collector chamber, which transfers the wave oscillations' energy to the air within the chamber by back and forth displacement, and a power take off system, which converts the pneumatic power into electricity or some other usable form. The Wells turbine is a self-rectifying air turbine, a suitable solution for energy extraction from reciprocating air flow in an OWC. In the present work, the steady state, inviscid flow in the Wells turbine is investigated by numerical simulations. The relatively novel Virtual Multiple Reference Frame (VMRF) technique is used to account for the rotary motion of the turbine, and the overall performance is compared with results in the literature.
KW - Computational fluid dynamics
KW - Marine energy
KW - Oscillating water column
KW - Virtual multiple reference frame
KW - Wells turbine
UR - http://www.scopus.com/inward/record.url?scp=84938863276&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84938863276
T3 - MARINE 2015 - Computational Methods in Marine Engineering VI
SP - 802
EP - 813
BT - MARINE 2015 - Computational Methods in Marine Engineering VI
A2 - Muscari, Roberto
A2 - Broglia, Riccardo
A2 - Salvatore, Francesco
PB - International Center for Numerical Methods in Engineering
T2 - 6th International Conference on Computational Methods in Marine Engineering, MARINE 2015
Y2 - 15 June 2015 through 17 June 2015
ER -