Wind Energy Science (Jan 2021)

Computational analysis of high-lift-generating airfoils for diffuser-augmented wind turbines

  • A. D. Paranjape,
  • A. S. Bajaj,
  • S. T. Palanganda,
  • R. Parikh,
  • R. Nayak,
  • J. Radhakrishnan

DOI
https://doi.org/10.5194/wes-6-149-2021
Journal volume & issue
Vol. 6
pp. 149 – 157

Abstract

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The impetus towards sustainable energy production and energy access has led to considerable research and development on decentralized generators, in particular diffuser-augmented wind turbines. This paper aims to characterize the performance of diffuser-augmented wind turbines (DAWTs) using high-lift airfoils employing a three-step computational analysis. The study is based on computational fluid dynamics, and the analysis is carried out by solving the unsteady Reynolds-averaged Navier–Stokes (URANS) equations in two dimensions. The rotor blades are modeled as an actuator disk, across which a pressure drop is imposed analogous to a three-dimensional rotor. We study the change in performance of the enclosed turbine with varying diffuser cross-sectional geometry. In particular, this paper characterizes the effect of a flange on the flow augmentation provided by the diffuser. We conclude that at the end of the three-step analysis, Eppler 423 showed the maximum velocity augmentation.