Effect of γ-Al2O3/Water Nanofluid on Heat Transfer and Pressure Drop Characteristics of Shell and Coil Heat Exchanger With Different Coil Curvatures

This study presents an experimental investigation of the characteristics of convective heat transfer in horizontal shell and coil heat exchangers in addition to the friction factor for fully developed flow through their helically coiled tube (HCT). Five heat exchangers of counterflow configuration were constructed with different HCT-curvature ratios (delta) and tested at different mass flow rates and inlet temperatures of gamma-Al2O3/water nanofluid in the HCT. The tests were performed for gamma-Al2O3 with average size of 40 nm and particles volume concentration (phi) from 0% to 2% for 0: 0392 <= delta <= 0: 1194. Totally, 750 test runs were performed from which the HCT-average Nusselt number ((Nu(t)) over bar) and fanning friction factor (f(c)) were calculated. Results illustrated that (Nu(t)) over bar and fc of nanofluids are higher than those of the pure water at same flow condition, and this increase goes up with the increase in phi. When phi increases from 0% to 2%, the average increase in (Nu(t)) over bar is of 59.4-81% at lower and higher HCT-Reynolds number, respectively, and the average increase in fc is of 25.7% and 27.4% at lower and higher HCT-Reynolds number, respectively, when phi increases from 0% to 2% for delta = 0: 1194. In addition, results showed that (Nu(t)) over bar and fc increase by increasing coil curvature ratio. When d increases from 0.0392 to 0.1194 for phi = 2%, the average increase in (Nu(t)) over bar is of 130.2% and 87.2% at lower and higher HCT-Reynolds number, respectively, and a significant increase of 18.2-7.5% is obtained in the HCT-fanning friction factor at lower and higher HCT-Reynolds number, respectively. Correlations for (Nu(t)) over bar and fc as a function of the investigated parameters are obtained.