Innovative solar distillation system with prismatic absorber basin: experimental analysis and LSTM machine learning modeling coupled with great wall construction algorithm
Innovative solar distillation system with prismatic absorber basin: experimental analysis and LSTM machine learning modeling coupled with great wall construction algorithm
Enhancing the vaporization surface area of the solar distillers through the implementation of a novel configurations based solar distiller represents a cost-efficient strategy for maximizing the distilled water output of conventional solar stills. The study introduces a pioneering wicked prismatic-shaped solar distiller equipped with wick materials and feed spaying nozzles, aimed at augmenting vaporization rates inside the still trough and, consequently, increasing the yield of freshwater. Two solar distillers with double slope covers are constructed and tested include a modified solar still with a prismatic basin, two incline covers, and spraying nozzles (MSS) and a reference double slope solar still (RSS). Furthermore, we have constructed a hybrid artificial intelligence framework, integrating a long short-term memory (LSTM) neural network fine-tuned through the utilization of great wall construction algorithm (GWCA). This model has been designed for the purpose of forecasting both the saltwater temperature and the associated freshwater product within the two examined solar distillers, whereas, the time, solar flux, wind velocity, and ambient temperature are considered as inputs. GWCA is effectively employed to optimize the LSTM model by determining the optimal parameter values to enhance its performance. The experimental results revealed that the daily freshwater production for the MSS reached 7.94 kg/m²/day, while the RSS achieved 5.31 kg/m²/day. This represents a substantial 49.53 % improvement when compared to the RSS. Additionally, the daily energy efficiency of the MSS and RSS was assessed at 57.40 % and 39.80 %, respectively, whereas the daily exergy efficiency was 3.80 % and 2.20 %, respectively, signifying a notable 44.23 % and 72.74 % increase the energetic and exergetic efficiencies over RSS. Furthermore, the prediction findings demonstrated that during the testing phase, the coefficient of determination for saltwater temperature prediction of the MSS was calculated at 0.996 for LSTM-GWCA and 0.963 for LSTM. In the case of freshwater product prediction, these values were 0.983 for LSTM-GWCA and 0.922 for LSTM, respectively.
Comparative experimental analysis, Great wall construction algorithm, Hybrid machine learning framework, Long short-term memory, Prismatic-shaped double slope solar distiller, Wick materials and spraying nozzles
1120-1133
Elsheikh, Ammar
e95d74f4-05af-4d46-9313-4da313769ffd
Zayed, Mohamed
9013d050-943a-4284-b1f6-a81cb02126b0
Aboghazala, Ali
e26f2dc2-bfb5-40e8-8c00-f373c1d6a097
Essa, Fadl A.
077bdb16-df22-42f2-a3c1-2a73e5589020
Rehman, Shafiqur
014bf0ed-d80d-49b6-bd7d-44cae1a7aa0f
L. Muskens, Otto
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Kamal, Abdallah
1971f7d1-c306-4a7c-bdd8-e6c2d128c90e
Elaziz, Mohamed Abd
cf67d73d-daee-4e6c-add1-94774d345a82
24 April 2024
Elsheikh, Ammar
e95d74f4-05af-4d46-9313-4da313769ffd
Zayed, Mohamed
9013d050-943a-4284-b1f6-a81cb02126b0
Aboghazala, Ali
e26f2dc2-bfb5-40e8-8c00-f373c1d6a097
Essa, Fadl A.
077bdb16-df22-42f2-a3c1-2a73e5589020
Rehman, Shafiqur
014bf0ed-d80d-49b6-bd7d-44cae1a7aa0f
L. Muskens, Otto
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Kamal, Abdallah
1971f7d1-c306-4a7c-bdd8-e6c2d128c90e
Elaziz, Mohamed Abd
cf67d73d-daee-4e6c-add1-94774d345a82
Elsheikh, Ammar, Zayed, Mohamed, Aboghazala, Ali, Essa, Fadl A., Rehman, Shafiqur, L. Muskens, Otto, Kamal, Abdallah and Elaziz, Mohamed Abd
(2024)
Innovative solar distillation system with prismatic absorber basin: experimental analysis and LSTM machine learning modeling coupled with great wall construction algorithm.
Process Safety and Environmental Protection, 186, .
(doi:10.1016/j.psep.2024.04.063).
Abstract
Enhancing the vaporization surface area of the solar distillers through the implementation of a novel configurations based solar distiller represents a cost-efficient strategy for maximizing the distilled water output of conventional solar stills. The study introduces a pioneering wicked prismatic-shaped solar distiller equipped with wick materials and feed spaying nozzles, aimed at augmenting vaporization rates inside the still trough and, consequently, increasing the yield of freshwater. Two solar distillers with double slope covers are constructed and tested include a modified solar still with a prismatic basin, two incline covers, and spraying nozzles (MSS) and a reference double slope solar still (RSS). Furthermore, we have constructed a hybrid artificial intelligence framework, integrating a long short-term memory (LSTM) neural network fine-tuned through the utilization of great wall construction algorithm (GWCA). This model has been designed for the purpose of forecasting both the saltwater temperature and the associated freshwater product within the two examined solar distillers, whereas, the time, solar flux, wind velocity, and ambient temperature are considered as inputs. GWCA is effectively employed to optimize the LSTM model by determining the optimal parameter values to enhance its performance. The experimental results revealed that the daily freshwater production for the MSS reached 7.94 kg/m²/day, while the RSS achieved 5.31 kg/m²/day. This represents a substantial 49.53 % improvement when compared to the RSS. Additionally, the daily energy efficiency of the MSS and RSS was assessed at 57.40 % and 39.80 %, respectively, whereas the daily exergy efficiency was 3.80 % and 2.20 %, respectively, signifying a notable 44.23 % and 72.74 % increase the energetic and exergetic efficiencies over RSS. Furthermore, the prediction findings demonstrated that during the testing phase, the coefficient of determination for saltwater temperature prediction of the MSS was calculated at 0.996 for LSTM-GWCA and 0.963 for LSTM. In the case of freshwater product prediction, these values were 0.983 for LSTM-GWCA and 0.922 for LSTM, respectively.
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More information
Accepted/In Press date: 14 April 2024
e-pub ahead of print date: 18 April 2024
Published date: 24 April 2024
Keywords:
Comparative experimental analysis, Great wall construction algorithm, Hybrid machine learning framework, Long short-term memory, Prismatic-shaped double slope solar distiller, Wick materials and spraying nozzles
Identifiers
Local EPrints ID: 501287
URI: http://eprints.soton.ac.uk/id/eprint/501287
ISSN: 0957-5820
PURE UUID: 94b908f5-75ca-4ed6-801b-0582d20475e0
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Date deposited: 28 May 2025 16:50
Last modified: 29 May 2025 01:44
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Contributors
Author:
Ammar Elsheikh
Author:
Mohamed Zayed
Author:
Ali Aboghazala
Author:
Fadl A. Essa
Author:
Shafiqur Rehman
Author:
Abdallah Kamal
Author:
Mohamed Abd Elaziz
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