Abstract
Scale formation that drastically increases thermal resistance and reduces freshwater production remains a critical challenge in thermal desalination. Novel designs of falling film evaporator and optimal operating condition hold great promise to mitigate scale formation, and increase heat transfer performance and fresh water production. In this work, CFD simulation based machine learning and multi-objective optimization are performed to identify optimal conditions and tube arrangement for evaporator. Non-dominated sorting genetic algorithm is adopted to determine and analyze the optimal pareto front for multiple objectives in desalination criteria. The errors of training, validation, and testing set are computed to identify an optimal hyperparameter set. For performance ratio, fouling resistance, and water production rate, the average relative error is 2.26%, 3.67%, and 3.24%. At pareto front, both performance ratio and water production rate increase at high temperature with fouling resistance (thermal resistance of the fouling layer) increasing as well. Tradeoffs between mitigating scale formation and enhancing desalination performance are evaluated in optimizations for different objectives. Potential optima are identified and can be applied as guidelines to determine evaporator design and system operating conditions.
Original language | English |
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Article number | 123223 |
Journal | International Journal of Heat and Mass Transfer |
Volume | 196 |
DOIs | |
State | Published - Nov 1 2022 |
Funding
This material is based upon work supported by the U.S. Department of Energy ’s Office of Energy Efficiency and Renewable Energy ( EERE ) under the Solar Energy Technology Office Award Number DE-EE0008392 . The authors are grateful to project manager Rajgopal Vijaykumar for guidance.
Keywords
- Deep neural network
- Multi-objective optimization
- Performance evaluation
- Scaling/fouling
- Thermal desalination