Experimental and numerical studies of multi-effect desalination plants without thermal vapor compression

This paper presents a mathematical model that deals with multi-effect desalination plants without thermal vapor compression. It was extensively investigated using data obtained from Zuara desalination plant. It is located 70 km west of Tripoli the capital city of Libya. The developed mathematical mo...

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Bibliographic Details
Published in:Journal of the Brazilian Society of Mechanical Sciences and Engineering 2022-08, Vol.44 (8), Article 363
Main Authors: Muftah, Ali K., Zili-Ghedira, Leila, Dhahri, Hacen, Abugderah, Mabruk M.
Format: Article
Language:English
Subjects:
Desalination
Efficiency
Engineering
Heat loss
Loading rate
Mathematical analysis
Mathematical models
Mechanical Engineering
Obsolescence
Productivity
Seawater
Technical Paper
Thermodynamic efficiency
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Summary:This paper presents a mathematical model that deals with multi-effect desalination plants without thermal vapor compression. It was extensively investigated using data obtained from Zuara desalination plant. It is located 70 km west of Tripoli the capital city of Libya. The developed mathematical model was authenticated by the simulation of the first stage of the mentioned plant, which consists of three units with a capacity of 40,000 m 3 /d. An extensive comparison between theoretical and real data was carried out. The theoretical results have the same trend as the experimental ones, especially in the early plant operating period. The obtained results show that the plant’s water production and thermal efficiency are sensitive to seawater temperature. According to the theoretical results, high performance is obtained during the winter season due to the possibility of increasing the loading rate without reaching the top brine temperature. The experimental data are obtained during the spring and autumn seasons because the heat loss is not high, and there is no need for additional seawater cooling medium. Both productivity and efficiency are directly proportional to the unit operating load rates. The plant obsolescence resulted in a decrease in the productivity and efficiency by 50 t/h and 8%, respectively. The study concluded that the specific heat area SHTA is directly proportional to the plant load and inversely proportional to the seawater temperature.
ISSN:1678-5878
1806-3691
DOI:10.1007/s40430-022-03672-y