On the use of spires for generating inflow conditions with energetic coherent structures in large eddy simulation |
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| Authors: | Daniel Foti Xiaolei Yang Filippo Campagnolo David Maniaci |
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| Institution: | 1. St. Anthony Falls Laboratory, Department of Mechanical Engineering, University of Minnesota, Minneapolis, MN, USA;2. Department of Civil Engineering, College of Engineering and Applied Science, Stony Brook University, Stony Brook, NY, USA;3. Wind Energy Institute, Technische Universit?t München, Garching bei München, Germany;4. Sandia National Laboratories, Albuquerque, NM, USA |
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| Abstract: | While it has long been a practice to place spires near the inlet of a wind tunnel to quickly develop a turbulent boundary layer with similarities to an atmospheric boundary layer, this has not been the case for creating turbulent boundary layer inflow in large eddy simulations (LESs) of turbulent flows. We carry out LES with the curvilinear immersed boundary method to simulate the flow in a wind tunnel with a series of spires in order to investigate the feasibility of numerically developing inflow conditions from a precursory spire LES and assessing the similarities of the turbulence statistics to those of an atmospheric boundary layer. The simulated mean velocity field demonstrates that a turbulent boundary layer with height equal to the spire height develops very quickly, within five spire heights downstream. The major attribute of using spires for precursory simulations is the spatially evolving coherent structures that form downstream of the spires offering a range of length scales at both the vertical and streamwise directions allowing multiple turbulent inflow conditions to be extracted from a single simulation. While the distribution of length scales far from the spires resembles an atmospheric boundary layer, some turbulence statistics have some significant differences. |
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| Keywords: | Inlet spires immersed boundary method wind tunnel large eddy simulations |
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