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Comparative thermodynamic analyses of Rankine cycles using different working fluids for LNG cold energy recovery

Qiang Liu, Jian Song, Yuanyuan Duan

2025Case Studies in Thermal Engineering10 citationsDOIOpen Access PDF

Abstract

This study investigates the impact of condensation temperature on the thermodynamics of Rankine cycles for LNG cold energy recovery using seawater as heat source. The turbine power output is maximized when the LNG temperature at the condenser outlet approaches the pseudocritical temperature at the supercritical pressure, where specific heat peaks. Both evaporation and condensation temperatures are optimized to maximize the net power output considering the limitations of turbine exhaust vapor quality and condensation pressure. The results show that R32 outputs the highest net power, followed by R1270. Although the turbine with R170 generates comparable power to R32, the net power output is 8 % lower due to the highest parasitic power consumption. The cycle using a low critical temperature working fluid requires a more compact turbine with lower inlet volumetric flow rate and smaller evaporator area than that using a high critical temperature fluid. The turbine using R32 offers a moderate size with a higher expansion ratio. R744 requires the least evaporator area and total area for per unit net power, while R32 has the smallest condenser area but requires 78 % more evaporator area than R744.

Topics & Concepts

Degree RankineRankine cycleOrganic Rankine cycleWorking fluidThermodynamicsEnvironmental scienceElectricity generationPhysicsPower (physics)Thermodynamic and Exergetic Analyses of Power and Cooling SystemsAdvanced Thermodynamic Systems and EnginesSpacecraft and Cryogenic Technologies