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Exergy assessment of infrared assisted air impingement dryer using response surface methodology, Back Propagation-Artificial Neural Network, and multi-objective genetic algorithm

Chinmayee Parida, P. Sahoo, Rabiya Nasir, Liaqat Ali Waseem, Aqil Tariq, Muhammad Aslam, Wesam Atef Hatamleh

2023Case Studies in Thermal Engineering23 citationsDOIOpen Access PDF

Abstract

This study deals with the exergy analysis of the thin-layer drying process of apple fruit via an infrared-assisted air impingement dryer. In the study, process conditions, namely, drying temperature (50–70 °C), slice thickness (2–6 mm), and recirculation ratio (10–90 %) were considered as independent parameters. The impacts of process parameters were studied over the responses, namely, exergy efficiency, exergy loss, improvement potential, and sustainability index. A comparative study was conducted between a Back-Propagation Artificial Neural Network (BP-ANN) coupled with a multi-objective genetic algorithm (MOGA) and Response Surface Methodology (RSM). It was found that both BP-ANN and RSM had good prediction ability, but BP-ANN performed slightly better with higher R2, lower RMSE, and MAE values. The optimized conditions for BP-ANN-MOGA were found to be a temperature of 50 °C, slice thickness of 3.9 mm, and recirculation ratio of 76.38 %, which yielded a response of exergy efficiency of 62.23 %, exergy loss of 221 kJ, an improvement potential of 105 kJ, and a sustainability index of 2.65. This study showed a better exergy assessment of the developed hybrid dryer from a thermodynamic point of view.

Topics & Concepts

ExergyResponse surface methodologyArtificial neural networkExergy efficiencyMean squared errorBackpropagationGenetic algorithmMaterials scienceEnvironmental scienceMathematicsComputer scienceProcess engineeringBiological systemArtificial intelligenceMachine learningStatisticsEngineeringBiologyFood Drying and ModelingPostharvest Quality and Shelf Life ManagementGreenhouse Technology and Climate Control