Numerical simulation for impact of implement of reflector and turbulator within the solar system in existence of nanomaterial

Turbulent flow of oil based hybrid nanofluid within an absorber tube of concentrated solar system has been evaluated in this article. To concentrate the solar irradiation, the parabolic plate has been located below the tube and variable heat flux was considered as the boundary condition of the tube. The presence of a turbulator within the circular tube causes secondary flow to increase. Both thermal (S(gen,th)) and frictional (S(gen,f)) components of irreversibility were reported in outputs. As Re increases, the residence time decreases and lower outlet temperature has been achieved. S(gen,th) decreases about 57.36% with growth of Re while S(gen,f) increases about 17.44 times. As the number of rows of tapes increases, the value of S(gen,f) enhances about 69.23% while the value of S(gen,th) decreases around 3.67%. Increase of pitch ratio causes S(gen,th) to decrease about 11.25% while frictional component increases around 76.7%.