بررسي عددي انتقال حرارت در ميكروكانال مارپيچي با نانو سيالات آب- اكسيد آلومينيوم و آب- اكسيد مس

Numerical Investigation of Heat Transfer in Serpentine Microchannel with Al2O3/Water and CuO/Water Nanofluids

در اين تحقيق ميكروكانال هاي گرماگير مورد بررسي قرار گرفته است. براي بهبود كارايي انتقال حرارت بايد هدايت حرارتي سيال، افزايش يابد. در اين پژوهش، به مطالعه عددي انتقال حرارت جابجايي اجباري، در ميكروكانال گرماگير مارپيچي، با استفاده از نانو سيال آب- اكسيد آلومينيوم و آب- اكسيد مس و به تاثير پارامتر هايي نظير قطر هيدروليكي، عدد رينولدز و كسر حجمي نانو ذرات بر روي عدد ناسلت پرداخته شده است؛ كه نتايج حاصل از اين پژوهش نشان مي دهد كه با افزايش رينولدز ، افت فشار براي نانوسيال اكسيد مس افزايش داشته است.

Nanofluids, a new class of thermo-fluids engineered by the stable suspension of Nano-sized metallic and nonmetallic entities (particles, fibers, tubes, droplets) in base fluids with optimized thermal conductivity, demonstrate the advantages of efficient thermal management with miniaturization .Micro-channel heat exchanger is very small and efficient by integrating some features such as high heat transfer coefficient, low fluid volume requirements, weight and small size, is a very efficient tool in the field of heat transfer purposes. In this research, heat sink microchannel will be investigated. in order to improve the efficiency of heat transfer should be increased the fluid thermal conductivity.in this study, Numerical Investigation of the forced convection heat transfer in Serpentine heat sink microchannel with water-AL2O3 and Water-CuO has been studied, and the effect of hydraulic diameter, the Reynolds number and volume fraction of nanoparticles on heat transfer is discussed. The results of this study showed by spiraling the microchannel, both the pressure drop and the thermal conductivity are increased and with the increase of Reynolds the pressure drop for nanoparticles of CuO is increased and it also the hydraulic diameter decreasing, the pressure drop and the thermal conductivity are increased over the microchannel.