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Enhancing Photovoltaic Panel Performance through Hybrid Nanoparticle Cooling: A Study on Zinc Oxide and Aluminum Oxide Nanofluids

Alkhalil Shahnaz, Altork Yousef, Sukkariyh Mustafa, Abdelhafez Eman

Advances in Science and Technology. Research Journal

2024

Vol. 18, no 4

329--335

High operating temperatures, particularly under conditions of high solar irradiation have adverse effects on the performance of the photovoltaic (PV) panels. The efficiency of electricity generation decreases with an increase in operating temperature, and therefore, minimizing the operating temperature is essential. Thus, efficient cooling systems are of significant importance, particularly in areas with scorching heat during the day. Hybrid nanoparticles have been identified as one of the most effective methods in utilizing the concept of PV cooling because of their special characteristics that can help improve the efficiency of solar panels in the long run. These nanoparticles offer the best heat dissipation and convective heat transfer alongside better light trapping and stability and are relatively cheaper to produce, thus playing a central role in enhancing the cooling effectiveness in photovoltaic systems. In our view, depending on these combined forces, hybrid nanoparticles can enhance the general effectiveness, dependability, and efficacy of solar panels as a high-potential instrument for solar power extraction. This study sought to determine the most effective ZnO and Al₂O₃ Nanofluids concentrations in improving the performance of PV modules. Five PV modules were placed side by side. One of them was a reference sample; the other four were coated on the backside with a range of hybrid nanofluid concentrations. K-type thermocouples were used to monitor the hourly backside thermal profile of each module to ensure thermal integrity. Moreover, a data logger monitored the current and the voltage of each PV during the experiment. In general, the coated modules had significantly better results compared to the control. The best improvement in the generated output power was obtained when 0. 4% Al₂O₃ and 0.2% ZnO reached 28.4% and increased efficiency to 29.6%.

Hybrid nano improved phase change material for latent thermal energy storage system: Numerical study

Benlekkam Mohamed Lamine, Nehari Driss

Archive of Mechanical Engineering

2022

LXIX, nr 1

77--98

The phase change materials (PCM) are widely used in several applications, especiallyi n the latent heat thermal energy storage system (LHTESS). Due to the very low thermal conductivity of PCMs. A small mass fraction of hybrid nanoparticles TiO 2–CuO (50%–50%) is dispersed in PCM with five mass concentrations of 0%, 0.25%, 0.5%, 0.75% and 1 mass % to improve its thermal conductivity. This article is focused on thermal performance of the hybrid nano-PCM (HNPCM) used for the LHTESS. A numerical model based on the enthalpy-porosity technique is developed to solve the Navier-Stocks and energy equations. The computations were conducted for the melting and solidification processes of the HNPCM in a shell and tube latent heat storage (LHS). The developed numerical model was validated successfully with experimental data from the literature. The results showed that the dispersed hybrid nanoparticles improved the effective thermal conductivity and density of the HNPCM. Accordingly, when the mass fraction of a HNPCM increases by 0.25%, 0.5%, 0.75% and 1 mass %, the average charging time improves by 12.04 %, 19.9 %, 23.55%, and 27.33 %, respectively. Besides, the stored energy is reduced by 0.83%, 1.67%, 2.83% and 3.88%, respectively. Moreover, the discharging time was shortened by 18.47%, 26.91%, 27.71%, and 30.52%, respectively.