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ABSTRACT
Present-day civilization is likely to face an acute shortage of potable water across the world. The instances of insufficiency of potable water are predominant in coastal areas where power availability is also a challenge. As an option, the desalination of seawater through the freezing and washing route can be integrated with power plants on seashores. This study aims to integrate a solid oxide fuel cell (SOFC)-based direct energy conversion system with a gas turbine (GT) run on the Brayton cycle and Kalina cycle for power generation and utilization of the exhaust heat available from it to run a vapor absorption refrigeration system (VARS) to accomplish the freezing of seawater for its desalination. Thus, the novel power and desalination system, namely, SOFC-GT-Kalina cycle-VARS combined system, is seen to offer the cumulative work output of 1594.34 kW at an efficiency of 60.73%, a cycle pressure ratio (CPR) of 12, and a turbine inlet temperature (TIT) of 1700 while desalinating water. The maximum potable water is obtained at the rate of 10.38 m3/min, a CPR of 6, and a TIT of 1700 K with the power output of 1535.41 kW and efficiency of 58.46%. In view of serious potable water crisis at seashores, the arrangement for power generation and desalination simultaneously is a quite attractive proposition.
KEYWORDS:
Disclosure statement
No potential conflict of interest was reported by the author(s).
Highlights
1. Utilization of waste energy from SOFC
2. Thermodynamic analysis of combined power and desalination
3. Power availability from the combined SOFC-GT-Kalina cycle
4. Refrigeration using waste energy to run the vapour absorption cycle