THERMODYNAMIC SYNERGY ASSESSMENT OF A DOUBLE-FLASH GEOTHERMAL–LiBr/H₂O ABSORPTION TRIGENERATION CONFIGURATION

1. Tesha. (2009). Absorption Refrigeration System as an Integrated Condenser Cooling Unit in a Geothermal Power Plant. United Nations University, Geothermal Training Programme.

2. Lech, P. (2009). A New Geothermal Cooling–Heating System for Buildings (Doctoral dissertation, Master’s Thesis. University of Iceland and the University of Akureyri).

3. ‏ Kanoglu, M., Yilmaz, C., & Abusoglu, A. (2016). Geothermal energy use in absorption precooling for Claude hydrogen liquefaction cycle. International Journal of Hydrogen Energy, 41(26), 11185-11200.‏

4. Uwera, J., Itoi, R., Jalilinasrabady, S., Jóhannesson, T., & Benediktsson, D. Ö. Design of a Cooling System Using Geothermal Energy for Storage of Agricultural Products with Emphasis on Irish Potatoes in Rwanda, Africa.‏

5. Kairouani, L., & Nehdi, E. (2006). Cooling performance and energy saving of a compression–absorption refrigeration system assisted by geothermal energy. Applied thermal engineering, 26(2), 288-294.‏

6. Best, R., Heard, C. L., Fernandez, H., & Siqueiros, J. (1986). Developments in geothermal energy in Mexico—Part five: The commissioning of an ammonia/water absorption cooler operating on low enthalpy geothermal energy. Journal of heat recovery systems, 6(3), 209-216.‏

7. Ishida, T., Kawano, S., Kohtaka, I., Yamada, K., Kaku, H., & Narita, T. (1991). U.S. Patent No. 5,007,240. Washington, DC: U.S. Patent and Trademark Office.‏

8. Ishida, T., Kawano, S., Kohtaka, I., Yamada, K., Kaku, H., & Narita, T. (1989). Hybrid Rankine cycle system U.S. Patent No. 5,007,240. Washington, DC: U.S. Patent and Trademark Office.‏

9. Shokati, N., Ranjbar, F., & Yari, M. (2014). A comparative analysis of rankine and absorption power cycles from exergoeconomic viewpoint. Energy Conversion and management, 88, 657-668.‏

10. Novotny, V., & Kolovratnik, M. (2016). Absorption power cycles for low‐temperature heat sources using aqueous salt solutions as working fluids. International Journal of Energy Research.‏

11. Wu, C. (1992). Cooling capacity optimization of a geothermal absorption refrigeration cycle. International journal of ambient energy, 13(3), 133-138.‏

12. Nowak, W., Stachel, A. A., & Borsukiewicz-Gozdur, A. (2008). Possibilities of implementation of absorption heat pump in realization of the Clausius–Rankine cycle in geothermal power station. Applied Thermal Engineering, 28(4), 335-340.‏

13. Lund, J. W. (1996). Lectures on direct utilization of geothermal energy. United Nations University Geothermal Training Programme.‏

14. Hultén, M., & Berntsson, T. (2002). The compression/absorption heat pump cycle—conceptual design improvements and comparisons with the compression cycle. international Journal of Refrigeration, 25(4), 487-497.‏

15. Ratlamwala, T. A. H., Dincer, I., & Gadalla, M. A. (2012). Thermodynamic analysis of a novel integrated geothermal based power generation-quadruple effect absorption cooling-hydrogen liquefaction system. international journal of hydrogen energy, 37(7), 5840-5849.‏

16. Rafferty, K. (1984). Absorption refrigeration: cooling with hot water. Geotherm. Energy Mag.;(United States), 12(3).‏

17. Klein, S. A. (2009). Engineering Equation Solver for Microsoft Windows Operating Systems: Commercial and Professional Versions. F-Chart Software, Madison, WI, available at: http://www. fchart. com/assets/downloads/ees_manual. pdf.‏

18. Cengel, Y. A., & Boles, M. A. (2002). Thermodynamics: an engineering approach. Sea, 1000, 8862.‏

19. Ozturk M, Dincer I (2013). Thermodynamic analysis of a solar-based multi-generation system with hydrogen production. Appl Therm Eng 51(1-2);1235-1244

20. Ozturk M, Dincer I (2013). Thermodynamic assessment of an integrated solar power tower and coal gasification system for multi-generation purposes. Energy Conversion Manage 76;1061-1072