Design of floating photovoltaic structures using multiscale modelling approach

Global warming and the increasing emissions of greenhouse gases have for decades now, taken a toll on Earth’s environment. With the continual development of countries, the problem looks set to remain for the foreseeable future as energy demand continues to rise. In a bid to catalyse a paradigm shift...

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Main Author: To, Gavan Lap Fung
Other Authors: Law Wing-Keung, Adrian
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2022
Subjects:
Online Access:https://hdl.handle.net/10356/158938
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1589382022-06-08T04:11:38Z Design of floating photovoltaic structures using multiscale modelling approach To, Gavan Lap Fung Law Wing-Keung, Adrian School of Civil and Environmental Engineering Nanyang Environment and Water Research Institute CWKLAW@ntu.edu.sg Engineering::Civil engineering::Structures and design Engineering::Civil engineering::Water resources Global warming and the increasing emissions of greenhouse gases have for decades now, taken a toll on Earth’s environment. With the continual development of countries, the problem looks set to remain for the foreseeable future as energy demand continues to rise. In a bid to catalyse a paradigm shift, governments across the world have set goals to reduce greenhouse gas emissions of respective countries with the gradual uptake of green energy sources such as harnessing solar energy. Singapore is no exception, in recent years, the small island nation has seen the construction of numerous Floating Solar Farms (FSFs) deployed over both inland and coastal waters. As the nation progresses, FSFs will have to be constructed in increasingly rough water conditions. Therefore, it is paramount that FSF are designed thoroughly to ensure safety and longevity yet remain economically viable to ensure competitiveness against conventional fossil fuel energy sources. This report explores the design of FSF structure using a multiscale modelling approach developed by Sree et al (2022). The multiscale modelling approach is applied to optimised floater designs derived through modifications of an existing FSF structure. In applying the multiscale approach, the FSF is broken down into models with simpler representative geometries to allow for efficient analysis. The models are then analysed in both static and dynamic conditions using Finite Element Analysis to evaluate the safety of a given optimised floater design. In completing the project, this report will demonstrate how the multiscale modelling approach can be applied as a tool in the design of FSFs. Bachelor of Engineering (Civil) 2022-06-08T04:11:38Z 2022-06-08T04:11:38Z 2022 Final Year Project (FYP) To, G. L. F. (2022). Design of floating photovoltaic structures using multiscale modelling approach. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/158938 https://hdl.handle.net/10356/158938 en EN-20 application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Civil engineering::Structures and design
Engineering::Civil engineering::Water resources
spellingShingle Engineering::Civil engineering::Structures and design
Engineering::Civil engineering::Water resources
To, Gavan Lap Fung
Design of floating photovoltaic structures using multiscale modelling approach
description Global warming and the increasing emissions of greenhouse gases have for decades now, taken a toll on Earth’s environment. With the continual development of countries, the problem looks set to remain for the foreseeable future as energy demand continues to rise. In a bid to catalyse a paradigm shift, governments across the world have set goals to reduce greenhouse gas emissions of respective countries with the gradual uptake of green energy sources such as harnessing solar energy. Singapore is no exception, in recent years, the small island nation has seen the construction of numerous Floating Solar Farms (FSFs) deployed over both inland and coastal waters. As the nation progresses, FSFs will have to be constructed in increasingly rough water conditions. Therefore, it is paramount that FSF are designed thoroughly to ensure safety and longevity yet remain economically viable to ensure competitiveness against conventional fossil fuel energy sources. This report explores the design of FSF structure using a multiscale modelling approach developed by Sree et al (2022). The multiscale modelling approach is applied to optimised floater designs derived through modifications of an existing FSF structure. In applying the multiscale approach, the FSF is broken down into models with simpler representative geometries to allow for efficient analysis. The models are then analysed in both static and dynamic conditions using Finite Element Analysis to evaluate the safety of a given optimised floater design. In completing the project, this report will demonstrate how the multiscale modelling approach can be applied as a tool in the design of FSFs.
author2 Law Wing-Keung, Adrian
author_facet Law Wing-Keung, Adrian
To, Gavan Lap Fung
format Final Year Project
author To, Gavan Lap Fung
author_sort To, Gavan Lap Fung
title Design of floating photovoltaic structures using multiscale modelling approach
title_short Design of floating photovoltaic structures using multiscale modelling approach
title_full Design of floating photovoltaic structures using multiscale modelling approach
title_fullStr Design of floating photovoltaic structures using multiscale modelling approach
title_full_unstemmed Design of floating photovoltaic structures using multiscale modelling approach
title_sort design of floating photovoltaic structures using multiscale modelling approach
publisher Nanyang Technological University
publishDate 2022
url https://hdl.handle.net/10356/158938
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