Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel
The Photovoltaic (PV) panel operating temperature affects the efficiency of the panel. The average afternoon temperature in Singapore can rise above 25 °c, which is approximately the optimal testing temperature for most PV panels. Therefore, to be able to utilise the panel efficiently, it is importa...
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sg-ntu-dr.10356-778752023-03-04T19:04:28Z Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel Tan, Wei Ming Ng Yin Kwee, Eddie School of Mechanical and Aerospace Engineering DRNTU::Engineering::Mechanical engineering The Photovoltaic (PV) panel operating temperature affects the efficiency of the panel. The average afternoon temperature in Singapore can rise above 25 °c, which is approximately the optimal testing temperature for most PV panels. Therefore, to be able to utilise the panel efficiently, it is important to constantly monitor the panel operating temperature. The water-cooling method is proposed by many researchers to maintain a uniform power output from the panel. In this report, an experimental setup is developed to observe how the ambient temperature, surface temperature, irradiance and flowrate of water would affect the power generation of the panel. A threshold temperature of 44 °c is used. For continuous cooling, the flow rate of 26.3 ml/s is used, and the total energy generated by the cooling panel is approximately 14.5% higher as compared to the non-cooling panel. For intermittent cooling, three different flowrates 26.3 ml/s, 21.6 ml/s and 16.6 ml/s were used. It is observed that the water flowrates do not make a big difference to the power generation efficiency %. Also, power generation efficiency of continuous water cooling that yields 14.5% which is higher as compared to intermittent water-cooling that yields 10.5-12.3%. From the experiments, it is observed that by using a water-cooling measure coupled with a flow control valve on the PV panel, its power generation efficiency improves. The panel efficiency refers to its power generation efficiency. It is define based on the comparison of power generation from the panel over a time period. Bachelor of Engineering (Mechanical Engineering) 2019-06-07T05:54:37Z 2019-06-07T05:54:37Z 2019 Final Year Project (FYP) http://hdl.handle.net/10356/77875 en Nanyang Technological University 76 p. application/pdf |
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DRNTU::Engineering::Mechanical engineering Tan, Wei Ming Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
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The Photovoltaic (PV) panel operating temperature affects the efficiency of the panel. The average afternoon temperature in Singapore can rise above 25 °c, which is approximately the optimal testing temperature for most PV panels. Therefore, to be able to utilise the panel efficiently, it is important to constantly monitor the panel operating temperature. The water-cooling method is proposed by many researchers to maintain a uniform power output from the panel. In this report, an experimental setup is developed to observe how the ambient temperature, surface temperature, irradiance and flowrate of water would affect the power generation of the panel. A threshold temperature of 44 °c is used. For continuous cooling, the flow rate of 26.3 ml/s is used, and the total energy generated by the cooling panel is approximately 14.5% higher as compared to the non-cooling panel. For intermittent cooling, three different flowrates 26.3 ml/s, 21.6 ml/s and 16.6 ml/s were used. It is observed that the water flowrates do not make a big difference to the power generation efficiency %. Also, power generation efficiency of continuous water cooling that yields 14.5% which is higher as compared to intermittent water-cooling that yields 10.5-12.3%. From the experiments, it is observed that by using a water-cooling measure coupled with a flow control valve on the PV panel, its power generation efficiency improves. The panel efficiency refers to its power generation efficiency. It is define based on the comparison of power generation from the panel over a time period. |
| author2 |
Ng Yin Kwee, Eddie |
| author_facet |
Ng Yin Kwee, Eddie Tan, Wei Ming |
| format |
Final Year Project |
| author |
Tan, Wei Ming |
| author_sort |
Tan, Wei Ming |
| title |
Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
| title_short |
Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
| title_full |
Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
| title_fullStr |
Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
| title_full_unstemmed |
Study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
| title_sort |
study the temperature feedback-based flow control valve on cooling a photovoltaic solar panel |
| publishDate |
2019 |
| url |
http://hdl.handle.net/10356/77875 |
| _version_ |
1759858081258274816 |