Thermal performance comparison of aluminum and iron alloys in heat exchangers for solar water heating systems: Experimental study under Iraqi climate conditions

Thermal performance comparison of aluminum and iron alloys in heat exchangers for solar water heating systems: Experimental study under Iraqi climate conditions

Solar water heating systems (SWHS) represent a critical technology for achieving global renewable energy targets, with the International Energy Agency projecting solar thermal could meet 17 % of worldwide heating demand by 2030. However, optimal material selection for heat exchangers in extreme clim...

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Bibliographic Details
Main Authors: Emad Jaleel Mahdi, Hussein Fawzi Hussein, Farqad Rasheed Saeed
Format: Article
Language:English
Published: Elsevier 2025-07-01
Series:Next Materials
Subjects:
Solar water heating
Aluminum heat exchanger
Evacuated tube collector
Thermal efficiency
Material performance
Online Access:http://www.sciencedirect.com/science/article/pii/S2949822825004538
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Summary:Solar water heating systems (SWHS) represent a critical technology for achieving global renewable energy targets, with the International Energy Agency projecting solar thermal could meet 17 % of worldwide heating demand by 2030. However, optimal material selection for heat exchangers in extreme climates like Iraq (4.4–44.5°C) remains unresolved, particularly for evacuated-tube systems. This study experimentally compares aluminum (Al) and iron (Fe) radiators in a closed-cycle SWHS under Iraqi conditions, evaluating thermal dissipation rates, fan-assisted airflow effects, and cost-performance tradeoffs. Using a controlled setup with evacuated tube collectors (300 L capacity, 5 L/min flow rate), performance was assessed through steady-state measurements (ΔT activation threshold: 8°C) and metallurgical analysis.Results demonstrate Al’s superior thermal conductivity (205 W/m·K) enables 28 % faster heat dissipation than Fe (80 W/m·K), achieving ΔT = 10°C in 35 versus 48 min. Fan integration further improves Al’s efficiency by 15 %, reaching 82 % thermal efficiency despite a marginal 5–8 % energy penalty. Corrosion resistance and lightweight properties favor Al, while Fe’s cost-effectiveness suits budget-constrained applications. These findings provide actionable insights for SWHS design in arid regions, balancing rapid heat delivery Al + fan) with economic viability (Fe). The study bridges material science and applied engineering, offering a framework for climate-specific SWHS optimization.
ISSN:2949-8228

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