Witte, F., Hofmann, M., Meier, J., Tuschy, I., & Tsatsaronis, G. (2022). Generic and Open-Source Exergy Analysis - Extending the Simulation Framework TESPy. Energies, 15. http://doi.org/10.3390/en15114087
Exergy-based methods support the identification of thermodynamic inefficiencies and the discovery of optimization potentials in thermal engineering applications. Although a large variety of simulation software is available in this field, most do not offer an integrated solution for exergy analysis. While there are commercial products on the market with such capabilities, their access for research and educational purposes is limited. The presented open-source software offers an integrated and fully automated exergy analysis tool for thermal conversion processes. In a first step, physical exergy is implemented, and the tool is then applied to three different example plants to highlight its capabilities and validate the implementation: A solar thermal power plant, a supercritical CO2 power cycle, and an air refrigeration cycle. The respective models and the results of the analyses are presented briefly. By providing the results in modern data structures, they are easily accessible and postprocessible. Future work will include chemical exergy to enable analyses of applications with conversion of matter. Additionally, the implementation of the exergoeconomic analysis and optimization is envisaged.
Tuschy, I., Althaus, R., Gerdes, R., & Keller-Sornig, P. (2002). The Future of Compressed Air Energy Storage: High Efficiency and Power Output with Reliable Turbine Technology. In G. Tsatsaronis (Hrsg.), ECOS 2002 15th International Conference on Efficiency, Costs, Optimization, Simulation and Environmental Impact of Energy Systems: Proceedings (Bd. 2). Berlin: Technische Universität Berlin, Institute for Energy Engineering.