CFD Analysis and Electrical Efficiency Improvement of a Hybrid PV/T Panel Cooled by Forced Air Circulation

Ömeroğlu, Gökhan

doi:10.1155/2018/9139683

Cited by 12 publications

(6 citation statements)

References 30 publications

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“…As a result, the average temperature of PV panels with heat sinks was lower than in PV panels without heat sinks. Research by Omeroglu [36] revealed a similar result where the heat sink configuration affected the air velocity and heat transfer rate from a PV panel to the surrounding environment. Popovici et al [23] demonstrated that the orientation and direction of the fin in the heat sink also affected the air temperature distribution.…”

mentioning

confidence: 78%

Numerical and Experimental Investigation of Air Cooling for Photovoltaic Panels Using Aluminum Heat Sinks

Arifin

Tjahjana

Hadi

et al. 2020

International Journal of Photoenergy

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An increase in the operating temperature of photovoltaic (PV) panels caused by high levels of solar irradiation can affect the efficiency and lifespan of PV panels. This study uses numerical and experimental analyses to investigate the reduction in the operating temperature of PV panels with an air-cooled heat sink. The proposed heat sink was designed as an aluminum plate with perforated fins that is attached to the back of the PV panel. A comprehensive computational fluid dynamics (CFD) simulation was conducted using the software ANSYS Fluent to ensure that the heat sink model worked properly. The influence of heat sinks on the heat transfer between a PV panel and the circulating ambient air was investigated. The results showed a substantial decrease in the operating temperature of the PV panel and an increase in its electrical performance. The CFD analysis in the heat sink model with an air flow velocity of 1.5 m/s and temperature of 35°C under a heat flux of 1000 W/m2 showed a decrease in the PV panel’s average temperature from 85.3°C to 72.8°C. As a consequence of decreasing its temperature, the heat sink increased the open-circuit photovoltage (VOC) and maximum power point (PMPP) of the PV panel by 10% and 18.67%, respectively. Therefore, the use of aluminum heat sinks could provide a potential solution to prevent PV panels from overheating and may indirectly lead to a reduction in CO2 emissions due to the increased electricity production from the PV system.

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mentioning

confidence: 78%

Numerical and Experimental Investigation of Air Cooling for Photovoltaic Panels Using Aluminum Heat Sinks

Arifin

Tjahjana

Hadi

et al. 2020

International Journal of Photoenergy

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“…Blasius equation for Turbulent Friction factor in smooth circular pipe is denoted by Eq. ( 11) and the same referred in Omeroglu [19] and Deng et al [25].…”

Section: Q Input = Vi: ð2þmentioning

confidence: 71%

“…Nusselt number ratio used by Omeroglu [19] and Deng et al [25] for evaluating the augmentation is represented in Nu Nu o : ð9Þ…”

Section: Q Input = Vi: ð2þmentioning

confidence: 99%

“…For constant pumping power, thermohydraulic performance is determined from Eq. (12) used by Omeroglu [19] and Deng et al [25].…”

Section: Q Input = Vi: ð2þmentioning

confidence: 99%

“…Aboghrara et al [18] reiterated the fact that heat transfer due to convection can be enhanced by incrementing the contact area and also by increasing the turbulent mixing by introducing roughness elements in the flow path. Omeroglu [19] evaluated the thermal enhancement inside a photovoltaic/thermal collector by using fin turbulators. The author established that with increase in Reynolds International Journal of Photoenergy number, heat transfer increased; however, thermal performance decreased.…”

Section: Introductionmentioning

confidence: 99%

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Influence of Narrow Rectangular Channel ( $AR = 1 : 4$ ) on Heat Transfer and Friction for V- and W-Shaped Ribs in Turbine Blade Applications

Krishnaswamy

Suresh

Ali

2021

International Journal of Photoenergy

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Effective cooling of blades with a nominal pressure drop is essential for performance augmentation and thermal management of gas turbines. Hence, present work is aimed at determining the heat transfer enhancement and friction for W- and V-shaped ribs inside a rectangular cooling channel having hydraulic diameter ( D h ) of 0.048 m and aspect ratio ( AR ) 1 : 4. Ribs are fixed facing downstream with angle of attack ( α ) 45° on opposite walls. Pitch ( P ) between two successive ribs is 25 mm for both cases. Continuous V- and W-shaped ribs with height to channel hydraulic diameter ratio ( e / D h ) 0.052 and 0.0416 and pitch to height ratio ( P / e ) 10 and 12.5, respectively, have been examined for Reynolds number ( Re ) range 20000-80000. Heat transfer augmentation achieved at Re 80000 is 1.94 and 1.8 times higher than Re 20000 for V- and W-shaped ribs, respectively. Streamwise and spanwise variations in local Nusselt number ratio are highest for V-shaped ribs, which are estimated to be 31% and 12%. For W-shaped ribs, variations are 17.5% and 3.5%. Nusselt number ( Nu ) is highest along span length 0.5 w for V-shaped ribs due to dominance of apex induced secondary flow. For W-shaped ribs, Nusselt number along the span lengths is found to be nearly same view uniformity in secondary flow. Maximum enhancement ( Nu / N u o ) estimated for both the rib shapes is 3.9 at Re 20000. Due to increased rib height, friction losses for V-shaped ribs are higher than W-shaped ribs. Maximum friction loss increment is estimated to be 85% for V-shaped ribs and 42% for W-shaped ribs between Re 20000 and 40000. For both rib shapes, impact of ribs is found to be greatest at Re 40000. Thermohydraulic performance ( THP ) for W-shaped ribs is superior to V-shaped ribs. Best THP achieved for W- and V-shaped ribs are 3.7 and 3.4 at Re 20000.

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PV/T Principles and Design

Al‐Waeli

Kazem

Chaichan

et al. 2019

Photovoltaic/Thermal (PV/T) Systems

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CFD Analysis and Electrical Efficiency Improvement of a Hybrid PV/T Panel Cooled by Forced Air Circulation

Cited by 12 publications

References 30 publications

Numerical and Experimental Investigation of Air Cooling for Photovoltaic Panels Using Aluminum Heat Sinks

Numerical and Experimental Investigation of Air Cooling for Photovoltaic Panels Using Aluminum Heat Sinks

Influence of Narrow Rectangular Channel ( $AR = 1 : 4$ ) on Heat Transfer and Friction for V- and W-Shaped Ribs in Turbine Blade Applications

PV/T Principles and Design

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CFD Analysis and Electrical Efficiency Improvement of a Hybrid PV/T Panel Cooled by Forced Air Circulation

Cited by 12 publications

References 30 publications

Numerical and Experimental Investigation of Air Cooling for Photovoltaic Panels Using Aluminum Heat Sinks

Numerical and Experimental Investigation of Air Cooling for Photovoltaic Panels Using Aluminum Heat Sinks

Influence of Narrow Rectangular Channel ( AR = 1 : 4 ) on Heat Transfer and Friction for V- and W-Shaped Ribs in Turbine Blade Applications

PV/T Principles and Design

Contact Info

Product

Resources

About

Influence of Narrow Rectangular Channel ( $AR = 1 : 4$ ) on Heat Transfer and Friction for V- and W-Shaped Ribs in Turbine Blade Applications