4.7 Article

Performance optimization of heat-exchanger with delta-wing tape inserts using machine learning

Journal

APPLIED THERMAL ENGINEERING
Volume 216, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.applthermaleng.2022.119135

Keywords

Delta-wing vortex generator; Artificial neural network; Heat transfer optimization; Accurate prediction

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This study proposes and develops a machine learning-based approach for predicting the heat transfer performance of a heat exchanger that employs delta-wing tape inserts. By building an artificial neural network (ANN) model and training it with a large dataset, the parameters Nu, f, and eta are successfully predicted. The results show that the proposed method can accurately predict the heat transfer characteristics and provide valuable guidance for practical applications.
Nusselt number (Nu), friction factor (f), and thermal performance factor (eta) are effective thermal parameters in determining the robustness of thermal management systems. However, a precise prediction of these parameters is a challenge due to complicated fluid and thermal behaviors of thermal systems, such as heat exchangers. In this study, we propose and develop a machine learning-based approach for predicting the heat transfer performance of a heat exchanger that employs delta-wing tape inserts. An aggregated database, containing 300 data points, is obtained from seven sources that include two working fluids. The wing-width ratio (w/W), pitch ratio (p/W), attack angle (alpha), Reynolds number (Re), and tube length (L) are in the ranges of 0.31 to 0.83, 0.95 to 1.65, 30 degrees to 70 degrees, 4,000 to 22,000, and 1,200 to 2,500 mm, respectively. Nu, f, and eta are predicted using an artificial neural network (ANN) model based on a universal aggregated database divided into training and test datasets. Optimization is performed, and an ANN model architecture is selected, consisting of input parameters (w/W, Re, alpha, p/ W, and L) and hidden layers (10,10,10) that predict the test data with a mean absolute error (MAE) of 0.002393 for f, 1.821792 for Nu, and 0.00507 for eta. The robustness of the developed ANN model is analyzed by precluding the databases from the training datasets together and is utilized to predict these excluded datasets. Furthermore, multiple linear regression analysis is adopted to measure and validate the efficiency of the proposed model. From the study results, it is evident that the proposed ANN method can provide valuable guidance to accurately predict the heat transfer characteristics with the lowest variance. Here, the 5-10-10-10-1 configuration is verified as the optimal configuration for the proposed model as it has the lowest MAE of 0.002393.

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