Experimental Investigation of Heat Transfer Enhancement in Double-Pipe Heat Exchangers Using Al2O3/Water Nanofluid and Segmental or Flower Baffles | ||||
Engineering Research Journal (Shoubra) | ||||
Volume 54, Issue 2, April 2025, Page 149-160 PDF (1.58 MB) | ||||
Document Type: Research articles | ||||
DOI: 10.21608/erjsh.2025.358561.1395 | ||||
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Authors | ||||
Ashraf Elsayed Abdelaleem Elmohlawy ![]() ![]() ![]() ![]() ![]() | ||||
Mechanical Engineering Department, Faculty of Engineering at Shoubra, Benha University, Cairo, Egypt | ||||
Abstract | ||||
This study investigates the hydrothermal performance of a horizontal double-pipe heat exchanger with a counter-flow arrangement. The system incorporates flower baffles at a relative angle of γ = 90° and segmental baffles, while Al2O3/water nanofluid is used in the annular side. The experiments evaluate the effects of nanoparticle concentration (0–1.5% by volume), annulus Reynolds number (2620 ≤ Reₐₙ ≤ 13110), and Prandtl number (3.91 ≤ Prₐₙ ≤ 7.48) under steady operating conditions. Hot water at 70°C is maintained at a constant flow rate in the inner tube, while cold water circulates in the annular region. Key findings demonstrate significant enhancements in the Nusselt number (¯Nu_an) and friction factor (f_an) with the addition of baffles and Al2O3 nanoparticles. Flower baffles outperformed segmental baffles, achieving increases in ¯Nu_an and f_an by 343.1% and 190.3%, respectively, at a nanoparticle concentration of 1.5%. The Heat Transfer Performance Index (HTPI) consistently exceeded unity across all test parameters, with the highest HTPI of 3.24 observed for flower baffles with δ = 16.7% and λ = 8.3%. Furthermore, empirical correlations for ¯Nu_an, f_an, and HTPI are proposed. The results highlight the combined potential of nanoparticle-enhanced fluids and innovative baffle geometries to improve heat exchanger performance, offering valuable insights for industrial applications. | ||||
Keywords | ||||
Double-pipe heat exchanger; Flower baffles; Al2O3 nanofluid; Heat Transfer Performance Index; Compound heat transfer enhancement | ||||
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