Organic Rankine cycle model for well-described and not-so-well-described working fluids

摘要

This paper presents an ORC (organic Rankine cycle) model consisting of turbine, condenser, pump, and boiler, with an optional IHX (internal heat exchanger). The model includes well-described (considerable experimental data) working fluids using the high accuracy EoS (equations of state) contained in REFPROP. Moreover, and more importantly, the model allows one to quickly and easily create from a few to many thousands of P-R (Peng-Robinson) EoS for not-so-well-described (little or no experimental data) working fluids. The latter is realized by parametrically varying critical temperature (T-C), critical pressure (P-C), acentric factor (omega), and ideal gas specific heat (c(p,c)(o)). Simulation results for a low-temperature ORC application show that efficiency (eta) increases with increasing heat source temperature (T-max), and does so more strongly when an IHX is included; whereas, volumetric work output (V) decreases with increasing T-max. The results further show that both eta and V strongly decrease with increasing heat sink temperature (T-cond). Parametrically varying TC, PC, omega, and c(p,c)(o) showed that: (1) Increasing T-C generally leads to higher eta and lower V. (2) Increasing P-C monotonically increases V. (3) Variations in omega do not significantly impact eta or V. (4) eta and V both generally decrease with increasing values of c(p,c)(o). (C) 2015 Elsevier Ltd. All rights reserved.