Abstract
With vast amounts of water consumed for electricity generation and water scarcity predicted to rise in the near future, the necessity to evaluate water consumption in power plants arises. Cooling systems are the main source of water consumption in thermoelectric power plants, since water is a cooling fluid with relatively low cost and high efficiency. This study evaluates the performance of two types of power plants: a natural gas combined-cycle and an integrated solar combined-cycle. Special focus is made on the cooling system used in the plants and its characteristics, such as water consumption, related costs, and fuel requirements. Wet, dry, and hybrid cooling systems are studied for each of the power plants. While water is used as the cooling fluid to condense the steam in wet cooling, dry cooling uses air circulated by a fan. Hybrid cooling presents an alternative that combines both methods. We find that hybrid cooling has the highest investment costs as it bears the sum of the costs of both wet and dry cooling systems. However, this system produces considerable fuel savings when compared to dry cooling, and a 50% reduction in water consumption when compared to wet cooling. As expected, the wet cooling system has the highest exergetic efficiency, of 1 and 5 percentage points above that of dry cooling in the conventional combined-cycle and integrated solar combined-cycle, respectively, thus representing the lowest investment cost and highest water consumption among the three alternatives. Hybrid and dry cooling systems may be considered viable alternatives under increasing water costs, requiring better enforcement of the measures for sustainable water consumption in the energy sector.
Highlights
Economic development leads to an increase in water and electricity demand
After generating power in the steam turbine, the steam is condensed through use of a cooling fluid, usually freshwater which is normally associated with lower costs and higher power plant efficiencies [6]
This paper presents the evaluation of two power plants, i.e., a natural gas combined-cycle (NGCC) plant and a concentrated solar power integrated combined-cycle (ISCC) power plant, with three different water cooling systems
Summary
Economic development leads to an increase in water and electricity demand. Water scarcity, is expected to create severe social problems in the near future [1,2]. The ISCC power plant is composed of a concentrated solar power (CSP) field, to generate additional steam to increase the power output of the steam turbine (ST) [15,16], and a conventional NGCC The combination of these technologies presents several advantages, including the reduction of fossil fuel consumption and CO2 emissions when compared to conventional combined-cycle [17], and cost reduction, when compared to a CSP power plant. The ISCCGT showed better environmental performance, since the lower fuel mass flow led to a reduction in greenhouse gas emissions [22] They evaluated the change in capital cost with increasing solar hybridization and decreasing natural gas. The exergy-based analyses presented here allow for a complete and accurate evaluation of the plants and the cooling systems
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