Experimental and numerical analysis of vaned wind turbine performance and flow phenomena

One feature in the ongoing energy transition is that the energy is more often produced close to its final utilizer. The operated device should be reliable to use and it should not annoy the people. Also, the size of the power production module may have limits that are not to be exceeded. One of the...

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Veröffentlicht in:	Energy (Oxford) 2018-09, Vol.159, p.827-841
Hauptverfasser:	Grönman, Aki, Backman, Jari, Hansen-Haug, Markus, Laaksonen, Mikko, Alkki, Markku, Aura, Pekka
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Consumer goods Energy transition Internal flow Mathematical models Numerical analysis Performance evaluation Renewable energy Savonius rotor Static pressure Stators Turbines Vane Wind power Wind turbine Wind turbines
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creator	Grönman, Aki Backman, Jari Hansen-Haug, Markus Laaksonen, Mikko Alkki, Markku Aura, Pekka
description	One feature in the ongoing energy transition is that the energy is more often produced close to its final utilizer. The operated device should be reliable to use and it should not annoy the people. Also, the size of the power production module may have limits that are not to be exceeded. One of the solutions is to use vaned Savonius turbines with a low-solidity vane design. It provides a relatively small physical size with low flickering and noise emissions, in addition to its improved starting behaviour in low winds. However, the performance of such a turbine is not well documented in the relevant literature and its internal flow physics are not well known. From this background the current study presents an experimental test case, coupled with validated numerical simulations, for a vaned Savonius turbine and performs what is so far the most complete fluid dynamic analysis of its performance and flow phenomena. The key novelties are that separate experimental and numerical results are presented with and without the stator in order to study the stator-rotor interaction, including accurate static pressure measurements inside the turbine. In addition, a general flow model is presented. •The influence of stator-rotor interaction is examined.•Experiments are conducted including separate results with and without a rotor.•A generic flow model for a vaned Savonius turbine is presented.
doi_str_mv	10.1016/j.energy.2018.06.204
format	Article
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The key novelties are that separate experimental and numerical results are presented with and without the stator in order to study the stator-rotor interaction, including accurate static pressure measurements inside the turbine. 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source	Elsevier ScienceDirect Journals
subjects	Computer simulation Consumer goods Energy transition Internal flow Mathematical models Numerical analysis Performance evaluation Renewable energy Savonius rotor Static pressure Stators Turbines Vane Wind power Wind turbine Wind turbines
title	Experimental and numerical analysis of vaned wind turbine performance and flow phenomena
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