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Enhancement of solar PV/T systems through cellulose nanocrystal -based cooling

Ahmad Abdul Kareem Ahmad Aqeel, Sami Salama Hussen Hajjaj, Mohamed R. Gomaa, Faten S. Obeidat, Hassan Mohamed, Chithirai Pon Selvan, V E Sathishkumar

2025Results in Engineering5 citationsDOIOpen Access PDF

Abstract

• The study demonstrates that cellulose nanocrystal (CNC) nanofluids substantially improve cooling efficiency in photovoltaic-thermal (PV/T) systems. • The optimal coolant flow rate of 0.9 L/min enhances electrical power output by up to 15.4 % and thermal energy recovery to 401 W. • CNC nanofluid reduces PV module surface temperature by 26 %, ensuring stable operation and prolonged lifespan. • The eco-friendly, biodegradable CNC-based coolant supports sustainable solar energy technologies aligned with global SDG objectives. The integration of efficient cooling strategies in photovoltaic-thermal (PV/T) systems is essential for improving energy conversion efficiency and operational stability. This study investigates the use of cellulose nanocrystal (CNC) nanofluids, prepared in a (40:60) ethylene glycol-water (EGW) base, as a sustainable and high-performance cooling medium. Both theoretical modeling and experimental analysis were conducted to assess electrical and thermal performance under varying coolant flow rates, ranging from 0.1 to 1.3 L/min. Results demonstrate that CNC nanofluids significantly reduce PV surface temperature and enhance system efficiency. The optimum performance was achieved at a flow rate of 0.9 L/min, resulting in notable improvements in electrical output and thermal dissipation. Maximum thermal energy reached 448 W, while electrical power output increased from 32 W (at 200 W/m²) to 155 W (at 1000 W/m²). Additionally, CNC nanofluids offer excellent thermal conductivity, stability, and eco-friendly characteristics. This research contributes to the advancement of green energy technologies and supports Sustainable Development Goals (SDGs) by promoting efficient, cost-effective, and environmentally sustainable solar energy solutions. The work's graphical abstracts are shown in Figure 1.

Topics & Concepts

NanofluidCoolantMaterials scienceThermalRenewable energySolar energyThermal energyProcess engineeringWater coolingNanocrystalVolumetric flow rateElectric potential energyEnergy conversion efficiencyMechanical engineeringThermal efficiencyNanotechnologyEnergy transformationCooling capacityEfficient energy useElectric powerSolar thermal collectorElectrical efficiencyPhotovoltaic systemElectricity generationSolar powerThermal power stationNanofluids in solar collectorsNuclear engineeringWater flowConcentrated solar powerCelluloseWorking fluidOperating temperatureMaximum power principleSolar Thermal and Photovoltaic SystemsPower Transformer Diagnostics and InsulationPhotovoltaic System Optimization Techniques
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