Abstract
As obtained geofluids from enhanced geothermal systems usually have lower temperatures and contain chemicals and impurities, a novel power cycle (NPC) with a unit capacity of several hundred kilowatts has been configured and developed in this study, with particular reference to the geofluid temperature (heat source) ranging from 110 °C to 170 °C. Using a suitable CO2-based mixture working fluid, a transcritical power cycle was developed. The novelty of the developed power cycle lies in the fact that an increasing-pressure endothermic process was realized in a few-hundred-meters-long downhole heat exchanger (DHE) by making use of gravitational potential energy, which increases the working fluid’s pressure and temperature at the turbine inlet and, hence, increases the cycle’s power output. The increasing-pressure endothermic process in the DHE has a better match with the temperature change of the heat source (geofluid), as does the exothermic process in the condenser with the temperature change of the sink (cooling water), which reduces the heat transfer irreversibility and improves the cycle efficiency. Power cycle performance has been analyzed in terms of the effects of mass fraction of the mixture working fluids, the working fluid’s flowrate and its DHE inlet pressure, geofluid flowrate, and the length of the DHE. Results show that, for a given geofluid’s temperature and mass flowrate, the cycle’s net power output is a strong function of the working-fluid’s flowrate, as well as of its DHE inlet pressure. Too high or too low of a DHE inlet pressure results in a lower power output. When geofluid temperature is 130 °C, the optimum DHE inlet pressure is found to be 11 MPa, corresponding to an optimum working-fluid flowrate of 6.5 kg/s. The longer the DHE, the greater the corresponding working-fluid flowrate and the higher the net power output. For geofluid temperature ranging from 110 °C to 170 °C, the developed NPC has a better thermodynamic performance than the conventional ORC. The advantage of using the developed NPC becomes obvious when geofluid temperature is low. The maximum net power output difference between the NPC and the ORC happens when the geofluid temperature is 130 °C and NPC’s working fluid mass fraction (R32/CO2) is 0.5/0.5.
Highlights
As most obtained geofluids from the enhanced geothermal system (EGS) geothermal resources usually have lower temperatures and contain chemicals and impurities, binary cycle geothermal power generation technologies associated with organic Rankine cycle (ORC) or TRC were usually proposed [1–3]
Compared with the subcritical ORC, TRC has an advantage in reducing the heat transfer irreversibility when the supercritical working fluid is gaining heat from the heat source, because the temperature of the working fluid is not constant during this heating process, which has a better match with the heat source temperature change [6]
The mixture working fluid’s downhole heat exchanger (DHE) inlet pressure, mixing ratio and flowrate are used as independent variables of pattern search algorithm (PSA)
Summary
As most obtained geofluids from the EGS geothermal resources usually have lower temperatures and contain chemicals and impurities, binary cycle geothermal power generation technologies associated with ORC (organic Rankine cycle) or TRC (transcritical Rankine cycle) were usually proposed [1–3]. Binary ORC is a relatively common technology using medium or low temperature geothermal resource for power generation [4,5]. Research on TRC with CO2 as working fluid was carried out by Zhang et al [7]; they studied a solar thermal power generation cycle using CO2 as working fluid and obtained the thermal efficiency of power generation cycles and COP (coefficients of performance) [8] during summer and winter in Japan through experiments
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