Thermoeconomic Optimization of a Polygeneration System Based on a Solar-Assisted Desiccant Cooling

This paper presents a thermoeconomic analysis of a polygeneration system based on solar-assisted desiccant cooling. The overall plant layout supplies electricity, space heating and cooling, domestic hot water, and freshwater for a residential building. The system combines photovoltaic/thermal collectors, photovoltaic panels, and a biomass boiler coupled with reverse osmosis and desiccant air conditioning. The plant was modeled in TRNSYS and simulated for 1 year. A parametric study defined the system's setup. A thermoeconomic optimization determined the set of parameters that minimize the simple payback period. The optimal structure showed a total energy efficiency of 0.49 for the solar collectors and 0.16 for the solar panels. The coefficient of performance of the desiccant air conditioning was 0.37. Finally, a sensitivity analysis analyzed the influence of purchase electricity and natural gas costs and the electricity sell-back price on the system. The optimum simple payback was 20.68 years; however, the increase in the energy cost can reduce it by up to 85%.

Automated summary

This paper presents a thermoeconomic analysis of a polygeneration system that combines solar-assisted desiccant cooling with other energy production and supply functions for a residential building. The system's optimal design and performance were determined through modeling and simulation, followed by a sensitivity analysis of the impact of energy costs on the system's payback period. The results showed promising energy efficiency and cost-effectiveness, with potential for significant reductions in payback period depending on variations in energy costs.