Enhancing efficiency and reducing CO2 emission of a geothermal-driven polygeneration system: Environmental analysis and optimization

• Published in: Process Safety and Environmental Protection
• Main Author: Hai T.; Ali M.A.; Younus M.D.; Chauhan B.S.; Metwally A.S.M.; Ullah M.
• Format: Article
• Language: English
• Published: Institution of Chemical Engineers 2023
• Online Access: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85152669986&doi=10.1016%2fj.psep.2023.03.055&partnerID=40&md5=b4126b26a0d106abd1f27adba1a3a495

The limitations of the single-flash cycle (SFC) include low efficiency, limited power output, and the inability to produce multiple products simultaneously. Additionally, the SFC requires a large amount of water and can have negative environmental impacts. In this study, to improve performance and produce multiple products, subsystems such as a branched GAX cycle assisted by a thermoelectric generator, a domestic water heater, and a reverse osmosis unit are coupled with the SFC. Then, thermodynamic, environmental, sustainability, and net present value approaches are devoted to analyzing system performance. This study utilizes MATLAB software to achieve a two-objective optimization that uses both CO2 emission rate and exergetic efficiency as objectives. The CO2 emissions rate represents a downward inclination with an increase in temperature in the generator inlet. Net electricity, cooling load, and pure water rate have a downward inclination with an augmentation of the temperature in the generator inlet due to reducing mass flow rate in the branched GAX/TEG cycle. At the optimum point, the payback period of the designed system with increasing selling prices of the products is decreased. The polygeneration gain output ratio in the optimized conditions reduces compared to the base case, whereas the sustainability index increases. Compared to similar works, the designed system produces a higher output. © 2023 The Institution of Chemical Engineers