Comprehensive modelling of rotary desiccant wheel with different multiple regression and machine learning methods for balanced flow

•Regression and machine learning approaches can be used for modeling desiccant wheel.•Multiple linear regression model is the most practical model to use.•The best model is random forest model.•Comparison of the models with the data presented in literature is acceptable. In this paper, several alter...

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Published in:Applied thermal engineering 2021-11, Vol.199, p.117544, Article 117544
Main Authors: Güzelel, Yunus Emre, Olmuş, Umutcan, Çerçi, Kamil Neyfel, Büyükalaca, Orhan
Format: Article
Language:English
Subjects:
Algorithms
Datasets
Decision Tree
Decision trees
Desiccant wheel
Desiccants
Heat transfer
Humidity
Machine learning
Modelling
Multilayer Perceptron
Multilayer perceptrons
Multiple linear regression
Preliminary designs
Regression
Regression analysis
Silica gel
Silicon dioxide
Simulation
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creator Güzelel, Yunus Emre
Olmuş, Umutcan
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Büyükalaca, Orhan
description •Regression and machine learning approaches can be used for modeling desiccant wheel.•Multiple linear regression model is the most practical model to use.•The best model is random forest model.•Comparison of the models with the data presented in literature is acceptable. In this paper, several alternative models were developed with multiple linear regression and machine learning algorithms to determine the output states of silica gel desiccant wheels for balanced flow. The decision tree method was used for this purpose for the first time in open literature. All the models developed include six input parameters and a wider range than those available in the literature. Predictions from the models were compared with the master dataset used to derive the models, each of the five sub-datasets that make up the master dataset and with data available in the literature. It was determined that the most suitable models are those coded as multiple linear regression-IV (MLR-IV), multilayer perceptron regressor-III (MLPR-III) and decision tree-VII (DT-VII), and DT-VII is the best among them. The determination coefficient and root mean square error for temperature were found to be 0.9894 and 0.8743 °C for MLR-IV, 0.9817 and 1.1526 °C for MLPR-III, 0.9986 and 0.3295 °C for DT-VII, respectively. The corresponding values for humidity ratio were 0.9912 and 0.3701 g kg−1 for MLR-IV, 0.9885 and 0.4227 g kg−1 for MLPR-III, 0.9994 and 0.0995 g kg−1 for DT-VII, respectively. The results obtained revealed that the proposed models can be used safely in preliminary design, simulation and dynamic energy analysis of systems with desiccant wheels.
doi_str_mv 10.1016/j.applthermaleng.2021.117544
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The determination coefficient and root mean square error for temperature were found to be 0.9894 and 0.8743 °C for MLR-IV, 0.9817 and 1.1526 °C for MLPR-III, 0.9986 and 0.3295 °C for DT-VII, respectively. The corresponding values for humidity ratio were 0.9912 and 0.3701 g kg−1 for MLR-IV, 0.9885 and 0.4227 g kg−1 for MLPR-III, 0.9994 and 0.0995 g kg−1 for DT-VII, respectively. 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In this paper, several alternative models were developed with multiple linear regression and machine learning algorithms to determine the output states of silica gel desiccant wheels for balanced flow. The decision tree method was used for this purpose for the first time in open literature. All the models developed include six input parameters and a wider range than those available in the literature. Predictions from the models were compared with the master dataset used to derive the models, each of the five sub-datasets that make up the master dataset and with data available in the literature. It was determined that the most suitable models are those coded as multiple linear regression-IV (MLR-IV), multilayer perceptron regressor-III (MLPR-III) and decision tree-VII (DT-VII), and DT-VII is the best among them. The determination coefficient and root mean square error for temperature were found to be 0.9894 and 0.8743 °C for MLR-IV, 0.9817 and 1.1526 °C for MLPR-III, 0.9986 and 0.3295 °C for DT-VII, respectively. The corresponding values for humidity ratio were 0.9912 and 0.3701 g kg−1 for MLR-IV, 0.9885 and 0.4227 g kg−1 for MLPR-III, 0.9994 and 0.0995 g kg−1 for DT-VII, respectively. 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In this paper, several alternative models were developed with multiple linear regression and machine learning algorithms to determine the output states of silica gel desiccant wheels for balanced flow. The decision tree method was used for this purpose for the first time in open literature. All the models developed include six input parameters and a wider range than those available in the literature. Predictions from the models were compared with the master dataset used to derive the models, each of the five sub-datasets that make up the master dataset and with data available in the literature. It was determined that the most suitable models are those coded as multiple linear regression-IV (MLR-IV), multilayer perceptron regressor-III (MLPR-III) and decision tree-VII (DT-VII), and DT-VII is the best among them. The determination coefficient and root mean square error for temperature were found to be 0.9894 and 0.8743 °C for MLR-IV, 0.9817 and 1.1526 °C for MLPR-III, 0.9986 and 0.3295 °C for DT-VII, respectively. The corresponding values for humidity ratio were 0.9912 and 0.3701 g kg−1 for MLR-IV, 0.9885 and 0.4227 g kg−1 for MLPR-III, 0.9994 and 0.0995 g kg−1 for DT-VII, respectively. The results obtained revealed that the proposed models can be used safely in preliminary design, simulation and dynamic energy analysis of systems with desiccant wheels.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.applthermaleng.2021.117544</doi></addata></record>
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source ScienceDirect Freedom Collection 2022-2024
subjects Algorithms
Datasets
Decision Tree
Decision trees
Desiccant wheel
Desiccants
Heat transfer
Humidity
Machine learning
Modelling
Multilayer Perceptron
Multilayer perceptrons
Multiple linear regression
Preliminary designs
Regression
Regression analysis
Silica gel
Silicon dioxide
Simulation
title Comprehensive modelling of rotary desiccant wheel with different multiple regression and machine learning methods for balanced flow
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