Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency

M. Tech. (Engineering, Electrical, Department Electronic Engineering, Faculty of Engineering and Technology), Vaal University of Technology === In order to facilitate sustainable development, it is necessary to further improve and increase the energy efficiency and use of renewable energy and its r...

Full description

Bibliographic Details
Main Author: Ozemoya, Augustine
Other Authors: Swart, James
Format: Others
Language:en
Published: 2016
Subjects:
Online Access:http://hdl.handle.net/10352/301
id ndltd-netd.ac.za-oai-union.ndltd.org-vut-oai-digiresearch.vut.ac.za-10352-301
record_format oai_dc
spelling ndltd-netd.ac.za-oai-union.ndltd.org-vut-oai-digiresearch.vut.ac.za-10352-3012016-10-22T03:56:55Z Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency Ozemoya, Augustine Swart, James Pienaar, Christo Energy efficiency Renewable energy Photovoltaic modules Temperature sensors Electronic performance Cooling systems PIC microcontroller 621.381542 Photovoltaic power generation. Photovoltaic systems. Photovoltaic power systems. M. Tech. (Engineering, Electrical, Department Electronic Engineering, Faculty of Engineering and Technology), Vaal University of Technology In order to facilitate sustainable development, it is necessary to further improve and increase the energy efficiency and use of renewable energy and its related technologies. The main limiting factors to the extensive use of photovoltaic (PV) modules include the high initial investment cost and the relatively low conversion efficiency. However, other factors, such as an increase in ambient temperature, exert a considerable negative influence on PV modules, with cell efficiencies decreasing as the cell’s operating temperature increases. Higher PV module surface temperatures mean lower output voltages and subsequent lower output power. Therefore, this dissertation focuses on optimizing the available output power from a PV module by investigating and controlling the effect that the PV module’s surface temperature exerts on the amount of electrical energy produced. A pilot study was conducted by using a PV module set to three different tilt angles with an orientation angle and temperature sensors placed at different points. This was done to determine temperature distribution on the PV module surfaces as well as identify which tilt angle produces the highest PV module surface temperature. The main study was designed to investigate the electrical performance of a PV module with different cooling systems (water and forced air) as against a referenced measurement (no cooling). The cooling systems will be switched on and off at specific time intervals with the help of an electronic timer circuit incorporating a PIC microcontroller. The pilot study was conducted for a 50 week period where the results indicated a direct correlation between temperature rise and voltage decrease. The PV module’s temperature is highest at a tilt angle of 16° during the day and lowest at night time. It further reveals that the PV module’s front and back surface temperature can be distinctly different, with the highest recorded values occurring at the back of the PV module. The main study was conducted for a period of 15 weeks with results indicating that the water cooling system resulted in an average higher output power of 49.6% when compared to the reference system (no cooling system). Recommendations are made that sufficient space should be included between the module frames and mounting structure to reduce high operating temperatures owing to poor air circulation. 2016-08-25T06:06:43Z 2016-08-25T06:06:43Z 2015-06 Thesis http://hdl.handle.net/10352/301 en xii, 87 leaves : illustrations
collection NDLTD
language en
format Others
sources NDLTD
topic Energy efficiency
Renewable energy
Photovoltaic modules
Temperature sensors
Electronic performance
Cooling systems
PIC microcontroller
621.381542
Photovoltaic power generation.
Photovoltaic systems.
Photovoltaic power systems.
spellingShingle Energy efficiency
Renewable energy
Photovoltaic modules
Temperature sensors
Electronic performance
Cooling systems
PIC microcontroller
621.381542
Photovoltaic power generation.
Photovoltaic systems.
Photovoltaic power systems.
Ozemoya, Augustine
Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
description M. Tech. (Engineering, Electrical, Department Electronic Engineering, Faculty of Engineering and Technology), Vaal University of Technology === In order to facilitate sustainable development, it is necessary to further improve and increase the energy efficiency and use of renewable energy and its related technologies. The main limiting factors to the extensive use of photovoltaic (PV) modules include the high initial investment cost and the relatively low conversion efficiency. However, other factors, such as an increase in ambient temperature, exert a considerable negative influence on PV modules, with cell efficiencies decreasing as the cell’s operating temperature increases. Higher PV module surface temperatures mean lower output voltages and subsequent lower output power. Therefore, this dissertation focuses on optimizing the available output power from a PV module by investigating and controlling the effect that the PV module’s surface temperature exerts on the amount of electrical energy produced. A pilot study was conducted by using a PV module set to three different tilt angles with an orientation angle and temperature sensors placed at different points. This was done to determine temperature distribution on the PV module surfaces as well as identify which tilt angle produces the highest PV module surface temperature. The main study was designed to investigate the electrical performance of a PV module with different cooling systems (water and forced air) as against a referenced measurement (no cooling). The cooling systems will be switched on and off at specific time intervals with the help of an electronic timer circuit incorporating a PIC microcontroller. The pilot study was conducted for a 50 week period where the results indicated a direct correlation between temperature rise and voltage decrease. The PV module’s temperature is highest at a tilt angle of 16° during the day and lowest at night time. It further reveals that the PV module’s front and back surface temperature can be distinctly different, with the highest recorded values occurring at the back of the PV module. The main study was conducted for a period of 15 weeks with results indicating that the water cooling system resulted in an average higher output power of 49.6% when compared to the reference system (no cooling system). Recommendations are made that sufficient space should be included between the module frames and mounting structure to reduce high operating temperatures owing to poor air circulation.
author2 Swart, James
author_facet Swart, James
Ozemoya, Augustine
author Ozemoya, Augustine
author_sort Ozemoya, Augustine
title Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
title_short Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
title_full Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
title_fullStr Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
title_full_unstemmed Controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
title_sort controlling a photovoltaic module's surface temperature to ensure high conversion efficiency
publishDate 2016
url http://hdl.handle.net/10352/301
work_keys_str_mv AT ozemoyaaugustine controllingaphotovoltaicmodulessurfacetemperaturetoensurehighconversionefficiency
_version_ 1718388659528400896