TY - JOUR
T1 - Computational fluid dynamic simulation with experimental validation in turbine pipeline
AU - Oñate, William
AU - Maldonado, Santiago
AU - Taco, Sebastián
AU - Caiza, Gustavo
N1 - Publisher Copyright:
© BEIESP.
PY - 2019/5
Y1 - 2019/5
N2 - With the increase of carbon dioxide emissions and greenhouse gases generated by the consumption of fossil fuels, this research considers the use of alternative energy sources, like the tidal energy which stores and contains the water in a reservoir through a dam or levee. This energy is later released and is converted into electrical energy through the unidirectional flushing of the fluid by a turbine pipeline, emerging variables such as pressure, speed magnitude, and turbulent kinetic energy. These variables will be studied using a computer dynamic 2D model simulated by the ANSYS FLUENT software by setting boundary conditions obtained by digital methodology of classical mechanics of fluids. The results were compared with those obtained experimentally through a tidal module, which consists of elements that were selected after criterion arrays, finding that, during the fluid download process for the energy generation, there is a qualitative similarity in the four areas of the pipeline of turbine (entry, final part of the leeward side of the bulb, posterior and anterior to the propeller), as well as the quantitative values presented similarity in two inner points of the turbine pipeline, getting an error of 1.69% and 1.95% respectively, thus validating the prediction.
AB - With the increase of carbon dioxide emissions and greenhouse gases generated by the consumption of fossil fuels, this research considers the use of alternative energy sources, like the tidal energy which stores and contains the water in a reservoir through a dam or levee. This energy is later released and is converted into electrical energy through the unidirectional flushing of the fluid by a turbine pipeline, emerging variables such as pressure, speed magnitude, and turbulent kinetic energy. These variables will be studied using a computer dynamic 2D model simulated by the ANSYS FLUENT software by setting boundary conditions obtained by digital methodology of classical mechanics of fluids. The results were compared with those obtained experimentally through a tidal module, which consists of elements that were selected after criterion arrays, finding that, during the fluid download process for the energy generation, there is a qualitative similarity in the four areas of the pipeline of turbine (entry, final part of the leeward side of the bulb, posterior and anterior to the propeller), as well as the quantitative values presented similarity in two inner points of the turbine pipeline, getting an error of 1.69% and 1.95% respectively, thus validating the prediction.
KW - Alternative energy
KW - Bulb
KW - Dyke
KW - Tidal turbine
UR - http://www.scopus.com/inward/record.url?scp=85073790525&partnerID=8YFLogxK
M3 - Article
AN - SCOPUS:85073790525
SN - 2277-3878
VL - 8
SP - 927
EP - 931
JO - International Journal of Recent Technology and Engineering
JF - International Journal of Recent Technology and Engineering
IS - 1C2
ER -