Exergy, economic, and optimization of a clean hydrogen production system using waste heat of a steel production factory.

In this present research study a multi-generation energy system which is coupled with CO 2 capture unit which is based on Rankine cycle, organic Rankine cycle, ejector cooling system and absorption chiller has been analyzed via energy, exergy, exergy-economic aspects by developing MATLAB, also to achieve the optimum operating condition genetic algorithm has been applied for system optimization. The objective of this study is to propose an optimized efficient integrated energy system to recycle the energy waste of a typical industrial factory. The optimization has been illustrated on a Pareto frontier to achieve the optimum scheme of the multi-generation system regarding technical and economic viewpoints. Results indicate the optimal condition of this system has occurred at 0.37 exergy efficiency with 0.03 $/s. Furthermore, by surging the mass flow rate of waste gases up to 70 kg/s, net power output augmented up to 7500 kW. Besides, hydrogen production and produced desalinated water rise up to 8.5 g/s and 16 kg/s, respectively. • Design a waste heat recovery system for a steel production factory. • Perform exergy, exergo-economic and optimization of suggested system. • The produced hydrogen can be reach 8.5 gr/s. • Optimization results indicate that the exergy efficiency can improve up to 37%. [ABSTRACT FROM AUTHOR]