An enhanced productivity prediction model of active solar still using artificial neural network and Harris Hawks optimizer

An enhanced productivity prediction model of active solar still using artificial neural network and Harris Hawks optimizer

[Display omitted] •Performance of passive still, active still, and condenser is studied.•Distilling systems are modeled by different artificial intelligence-based models.•Accumulated productivity of active still is improved by 53.21%.•Artificial neural network unified with Harris Hawks optimizer is...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 170; p. 115020
Main Authors: Essa, F.A., Abd Elaziz, Mohamed, Elsheikh, Ammar H.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-04-2020
Elsevier BV
Subjects:
Artificial intelligence
Artificial neural network
Artificial neural networks
Computer simulation
Desalination
Distillation
Mean square errors
Neural networks
Prediction models
Predictions
Productivity
Productivity optimization
Solar energy
Solar still
Solar still condenser
Support vector machines
R2
ANN
MRE
FFNNs
COV
RMSE
SVM
HHO
MAE
MLP
Productivity optimization
Solar still
R
Desalination
OI
Artificial neural network
Solar still condenser
EC
CRM
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Summary:[Display omitted] •Performance of passive still, active still, and condenser is studied.•Distilling systems are modeled by different artificial intelligence-based models.•Accumulated productivity of active still is improved by 53.21%.•Artificial neural network unified with Harris Hawks optimizer is the best model.•In the best model, R2 is 0.97 and 0.98 for active and passive stills, respectively. In this paper, a new productivity prediction model of active solar still was developed depending on improving the performance of the traditional artificial neural networks using Harris Hawks Optimizer. This optimizer simulates the behavior of Harris Hawks to catch their prey, and this method is used to determine the optimal parameters of artificial neural networks. The proposed model, called Harris Hawks Optimizer – artificial neural network, is compared with two other models named support vector machine and traditional artificial neural network, in addition to the experimental-based behavior of the solar still. The models were applied to predict the yield of three different distillation systems, namely, passive solar still, active solar still, and active solar still integrated with a condenser. Experimentally, the productivity of the active distiller integrated with the condenser was increased by 53.21% at a fan speed of 1350 rpm. The performance of the models was assessed using different statistical criteria such as root mean square error, coefficient of determination, and others. Among the three models, Harris Hawks Optimizer – artificial neural network had the best accuracy in predicting the solar still yield compared with the real experimental results.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2020.115020