IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID
The decrease in the efficiency of photovoltaic modules due to high temperatures has become a major problem affecting system performance. This study aims to optimize the solar photovoltaic system through a passive cooling method using adjustable water flow on the surface of the photovoltaic module...
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id-itb.:869212025-01-07T07:55:11ZIMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID Virgin Supit, Marshall Indonesia Theses Efficiency, Photovoltaic modules, Active cooling, Computational Fluid Dynamics, ANSYS 2024 R1, Inlet temperature, Power saving. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/86921 The decrease in the efficiency of photovoltaic modules due to high temperatures has become a major problem affecting system performance. This study aims to optimize the solar photovoltaic system through a passive cooling method using adjustable water flow on the surface of the photovoltaic modules to reduce the panel temperature, improve the energy conversion efficiency, and measure the energy savings achieved. By analyzing key parameters such as temperature and irradiance, this study models the effect of temperature on the performance of photovoltaic cells. It investigates how temperature control can affect the overall system efficiency by simulation using Computational Fluid Dynamics (CFD) ANSYS 2024 R1. The results show that increasing the coolant's mass flow rate significantly improves the cooling system's efficiency on the photovoltaic module. The cooling system's relative efficiency increases with the mass flow rate increase. At irradiance of 1,200 W/m2, the relative efficiency at a flow rate of 0.05 kg/s is 1.03%, rising to 6.04% at a flow rate of 0.25 kg/s, indicating a positive effect of the cooling system on the temperature of the photovoltaic module. The water inlet temperature also plays an important role in the cooling system's efficiency. A lower inlet temperature (21°C) was more effective in maintaining low panel temperature than a higher inlet temperature (23°C or 25.12°C), especially under high irradiance conditions. The power saving analysis showed that the efficiency of the cooling system is highly dependent on a combination of variables such as irradiance, head pump, and water flow rate. Significant power saving was recorded at high irradiance (1,100 - 1,200 W/m2) and low head (2.5 - 5 meters). The cooling system remained effective in generating positive power savings despite the decrease in the temperature coefficient of the photovoltaic module. Conversely, increasing the temperature coefficient improved the performance of the cooling system. This study indicates that the cooling system can significantly increase the efficiency of photovoltaic modules by minimizing excess temperature on the panels, and generating energy savings, especially under the combination of high irradiance, iv low water inlet temperature, and high flow rate conditions. Therefore, this research provides important insights into optimizing photovoltaic systems, by offering a cooling solution that not only increases efficiency but also reduces energy consumption for the cooling process itself. text |
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The decrease in the efficiency of photovoltaic modules due to high temperatures
has become a major problem affecting system performance. This study aims to
optimize the solar photovoltaic system through a passive cooling method using
adjustable water flow on the surface of the photovoltaic modules to reduce the panel
temperature, improve the energy conversion efficiency, and measure the energy
savings achieved. By analyzing key parameters such as temperature and
irradiance, this study models the effect of temperature on the performance of
photovoltaic cells. It investigates how temperature control can affect the overall
system efficiency by simulation using Computational Fluid Dynamics (CFD)
ANSYS 2024 R1.
The results show that increasing the coolant's mass flow rate significantly improves
the cooling system's efficiency on the photovoltaic module. The cooling system's
relative efficiency increases with the mass flow rate increase. At irradiance of 1,200
W/m2, the relative efficiency at a flow rate of 0.05 kg/s is 1.03%, rising to 6.04% at
a flow rate of 0.25 kg/s, indicating a positive effect of the cooling system on the
temperature of the photovoltaic module. The water inlet temperature also plays an
important role in the cooling system's efficiency. A lower inlet temperature (21°C)
was more effective in maintaining low panel temperature than a higher inlet
temperature (23°C or 25.12°C), especially under high irradiance conditions. The
power saving analysis showed that the efficiency of the cooling system is highly
dependent on a combination of variables such as irradiance, head pump, and water
flow rate. Significant power saving was recorded at high irradiance (1,100 - 1,200
W/m2) and low head (2.5 - 5 meters). The cooling system remained effective in
generating positive power savings despite the decrease in the temperature
coefficient of the photovoltaic module. Conversely, increasing the temperature
coefficient improved the performance of the cooling system.
This study indicates that the cooling system can significantly increase the efficiency
of photovoltaic modules by minimizing excess temperature on the panels, and
generating energy savings, especially under the combination of high irradiance,
iv
low water inlet temperature, and high flow rate conditions. Therefore, this research
provides important insights into optimizing photovoltaic systems, by offering a
cooling solution that not only increases efficiency but also reduces energy
consumption for the cooling process itself. |
| format |
Theses |
| author |
Virgin Supit, Marshall |
| spellingShingle |
Virgin Supit, Marshall IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID |
| author_facet |
Virgin Supit, Marshall |
| author_sort |
Virgin Supit, Marshall |
| title |
IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID |
| title_short |
IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID |
| title_full |
IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID |
| title_fullStr |
IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID |
| title_full_unstemmed |
IMPROVING PHOTOVOLTAIC MODULE PERFORMANCE WITH PASSIVE COOLING USING WATER FLUID |
| title_sort |
improving photovoltaic module performance with passive cooling using water fluid |
| url |
https://digilib.itb.ac.id/gdl/view/86921 |
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