Min Che scite author profile

Numerical methods are often used to obtain two-dimensional air-side heat transfer coefficients (HTCs) on heat exchanger fin surfaces. The model's accuracy is usually verified through averaged HTCs by comparing to published experimental results. However, substantial disagreement is not uncommon and can hardly be explained by averaged HTCs. This study focuses on comparing experimental, local air-side HTCs to numerical ANSYS Fluent results. A mass transfer experimental method was employed to obtain HTC distributions on the fin-and-tube heat exchanger (HX) fin surfaces. Therefore, disagreements between the experimental and numerical results can be explained in detail. There are several significant findings: inaccurate predictions of local HTCs are observed even though the averaged HTCs from the numerical method may agree with the averaged experimental results under some conditions. The models fail to capture horseshoe vortices, underestimate the HTCs in the wake region of the tubes, and overpredict row-by-row HTC degradation. Moreover, the accuracy of the numerical model decreases when the complexity of geometry increases. For the flat plate, numerically obtained HTCs agree with the experimental results within 10%. However, the error is more than 30% for the 8-row HX. Nonetheless, the model's accuracy becomes worse at higher airflow velocities. Oversized fin-and-tube HXs with multiple tube rows are often selected as a result of using the underpredicted averaged air-side HTCs from the numerical CFD simulations. Thence, the authors have proposed a corrective method to improve the accuracy of the numerical model.

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Experimental study of local air-side heat transfer coefficient on real-scale heat exchanger fins by employing an absorption-based mass transfer method

Che

Elbel

2021

Applied Thermal Engineering

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A Geometric-Factor-Revised Permittivity Model for Three-Phase Mixture with Arbitrary Inclusion Packing

Guo

Che

Ling

2021

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Min Che

An experimental method to quantify local air-side heat transfer coefficient through mass transfer measurements utilizing color change coatings

Experimental quantification of air-side row-by-row heat transfer coefficients on fin-and-tube heat exchangers

Comparison of Local and Averaged Air-Side Heat Transfer Coefficients on Fin-and-Tube Heat Exchangers Obtained With Experimental and Numerical Methods

Experimental study of local air-side heat transfer coefficient on real-scale heat exchanger fins by employing an absorption-based mass transfer method

A Geometric-Factor-Revised Permittivity Model for Three-Phase Mixture with Arbitrary Inclusion Packing

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