Electrical power output estimation model for a conical diffuser augmented wind turbine

Masukume, Peace-Maker

Title: Electrical power output estimation model for a conical diffuser augmented wind turbine
Creator: Masukume, Peace-Maker
Subject: Wind power
Subject: Wind turbines
Subject: Renewable energy sources
Date Issued: 2016
Date: 2016
Type: Thesis
Type: Doctoral
Type: DPhil
Identifier: http://hdl.handle.net/10353/1517
Identifier: vital:27404
Description: Energy is integral to the quality of life of any society. However, meeting the demand for energy sustainably is the main challenge facing humanity. In general, non-renewable energy resources are used to supply the ever increasing energy demand. However, the extraction and processing of these resources is accompanied by the production of wastes which are a health hazard and impact negatively on climate change. Considering the finite nature of non-renewable sources, the environmental concerns which are associated with their usage and ensuring energy security, renewable energy sources have been brought in the energy supply chain. Wind energy is one of the renewable energy sources which has been supplying electrical energy to the ever increasing energy demand of humanity. Wind energy technology is a mature technology which over and above the bare (conventional) wind turbine technology has seen the development of duct augmented wind turbines. Ducts are used to encase wind turbine rotors to augment the power output of wind turbines especially in low wind speed areas. Though the technology has been under study for decades now, research indicates that there is no known model to estimate the power output of a diffuser augmented wind turbine. This thesis presents the development of the conical Diffuser Augmented Wind Turbine (DAWT) power output estimation model and its validation.
Format: 151 leaves
Format: pdf
Publisher: University of Fort Hare
Publisher: Faculty of Science & Agriculture
Language: English
Rights: University of Fort Hare

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