Research Article
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Year 2024, Volume: 27 Issue: 4, 23 - 29, 01.12.2024

Abstract

References

  • H. Averfalk, P. Ingvarsson, U. Persson, M. Gong, and S. Werner, "Large heat pumps in Swedish district heating systems," Renew. Sustain. Energy Rev., 79, 1275-1284, 2017
  • B. Ziegler and C. Trepp, "Equation of state for ammonia-water mixtures," Int. J. Refrig., 7, 101-106, 1984.
  • Y.M. El-Sayed and M. Tribus, “Thermodynamic properties of water-ammonia mixtures: theoretical implementation for use in power cycle analysis”, ASME Pub. ,1, 89–95.,1985.
  • K.E. Herold, K. Han and M.J. Moran., “AMMWAT: a computer program for calculating the thermodynamic properties of ammonia and water mixtures using a Gibbs free energy formulation”. ASME Pub., 4, 65–75, 1988.
  • Y.M. Park and R.E. Sonntag, "Thermodynamic properties of ammonia-water mixtures: a generalized equation-of-state approach," ASHRAE Trans., 96, 150-159, 1990.
  • M. Pfaff, R. Saravanan, M. Prakash Maiya, and S. Srinivasa Murthy, "Studies on bubble pump for a water–lithium bromide vapor absorption refrigerator," Int. J. Refrig., 21, 452-462, 1998.
  • L.A. McNeely, "Thermodynamic properties of aqueous solutions of lithium bromide," ASHRAE Trans., 85, 413-434, 1979.
  • R.J. Lee, R.M. DiGuilio, S.M. Jeter, and A.S. Teja, "Properties of lithium bromide-water solutions at high temperatures and concentrations-part II: density and viscosity," ASHRAE Trans., 96, 709-714, 1990.
  • M. Jeter, J.P. Moran, and A.S. Teja, "Properties of lithium bromide-water solutions at high temperatures and concentrations-part III: specific heat," ASHRAE Trans., 98, 137-149, 1992.
  • J.L.Y. Lenard, S.M. Jeter, and A.S. Teja, "Properties of lithium bromide-water solutions at high temperatures and concentrations-part IV: vapor pressure," ASHRAE Trans., 98, 167-172, 1992.
  • J. Patek and J. Klomfar, "Simple function for fast calculations of selected thermodynamic properties of ammonia-water system," Int. J. Refrig., 18, 228-234, 1995.
  • M. Fatouh and S. Srinivasa Murthy, "Comparison of R22-absorbent pairs for absorption cooling based on P–T–X data," Renew. Energy, 3, 31-37, 1993.
  • M.O. McLinden, E.W. Lemmon, and R.T. Jacobsen, "Thermodynamic properties for alternatives refrigerants," Int. J. Refrig., 21, 322-338, 1998.
  • R.S. Agarwal and S.L. Bapat, "Solubility characteristics of R22-DMF refrigerant-absorbent combination," Int. J. Refrig., 12, 70-74, 1985.
  • S. Dorairaj and R.S. Agarwal, "Prediction of transport properties of R22-DMF refrigerant-absorbent combinations”, Int. J. Refrig., 10, 224-228, 1986.
  • N.N. Smirnova, L.Ya Tsvetkova, T.A. Bykova, and Y. Marcus, "Thermodynamic properties of N,N-dimethylformamide and N,N-dimethylacetamide," J. Chem. Thermodyn., 39, 1508-1513, 2007.
  • L.J. He, L.M. Tang, J.M. Chen, "Performance prediction of refrigerant-DMF solutions in a single-stage solar-powered absorption refrigeration system at low generating temperatures”, Solar Energy, 83, 2029-2038, 2009.
  • A. Koyfman, M. Jelinek, A. Levy, I. Borde, "An experimental investigation of bubble pump performance for diffusion absorption refrigeration system with organic working fluids,” Appl. Therm. Eng., 23, 1181-1194, 2003.
  • A. Zohar, M. Jelinek, A. Levy, I. Borde, "Performance of diffusion absorption refrigeration cycle with organic working fluids,” Int. J. Refrig.,32, 1241-1246., 2009.
  • N. Ben Ezzine, R. Garma, and A. Bellagi, "A numerical investigation of a diffusion-absorption refrigeration cycle based on R124-DMAC mixture for solar cooling," Energy, 35, 1874-1883, 2010.
  • N. Ben Ezzine, R. Garma, M. Bourouis, and A. Bellagi, "Experimental studies on bubble pump operated diffusion absorption machine based on light hydrocarbons for solar cooling,” Renew. Energy, 35, 464-470, 2010.
  • E. Granryd, "Hydrocarbons as refrigerants - an overview," Int. J. Refrig., 24, 1, 15-24, 2001.
  • B. Palm, "Hydrocarbons as refrigerants in small heat pump and refrigeration systems – A review," Int. J. Refrig., 31, 4, 552-563, 2008.
  • N. Chekir, Kh. Mejbri, A. Bellagi, "Simulation d’une machine frigorifique à absorption fonctionnant avec des mélanges d’alcanes,” Int. J. Refrig., 29, 3, 469-475, 2006.
  • H. Dardour, P. Cézac, J.-M. Reneaume, M. Bourouis, and A. Bellagi, "Numerical Investigation of an Absorption-Diffusion Cooling Machine Using C3H8/C9H20 as Binary Working Fluid," Oil Gas Sci. Technol., 68, 249-254, 2013.
  • M. Mehyo, E. Özbaş, and H. Özcan, "Performance investigation of utilizing nanoferrofluid as a working solution in a diffusion absorption refrigeration system under an external magnetic field effect," Heat Mass Transfer, 58, 2107-2128, 2022.
  • I. Borde, M., Jelinek, N.C Daltrophe,” Working fluids for an absorption system based on R124 (2-chloro-1,1,1,2,-tetrafluoroethane) and organic absorbents,” Int. J. Refrig., 20, 4, 256-266, 1997.
  • N. Dvoskin, “Thermodynamic equilibrium of new organic mixtures for absorption heat pumps,” M.S. Thesis, Dept. Mech. Eng., Ben Gurion Univ., Beer Sheva, Israel, 2004.

Thermodynamic Properties of R1234yf and DMAC Binary Solution

Year 2024, Volume: 27 Issue: 4, 23 - 29, 01.12.2024

Abstract

To assess the performance of potential refrigerant-absorbent pairs, it is essential to have thermodynamic properties of both the pure components and their mixtures. Since these mixtures do not behave ideally, the properties of the solutions can only be obtained through experimental means. This paper’s proposed candidate pair is the environmentally friendly refrigerant 2,3,3,3-Tetrafluoropropene (R1234yf) and the organic solvent Dimethylacetamide (DMAC). For this purpose, an experimental setup was designed to obtain data at the equilibrium point between the gas and liquid phases. The collected data was analyzed using models based on the vapor-liquid equilibrium of mixtures. Correlations were established for pressure-temperature and refrigerant concentration in the liquid phase and the solution's enthalpy. These results can facilitate further investigations into the solution’s compatibility as an alternative working pair.

Supporting Institution

Ministry of Enrgy

References

  • H. Averfalk, P. Ingvarsson, U. Persson, M. Gong, and S. Werner, "Large heat pumps in Swedish district heating systems," Renew. Sustain. Energy Rev., 79, 1275-1284, 2017
  • B. Ziegler and C. Trepp, "Equation of state for ammonia-water mixtures," Int. J. Refrig., 7, 101-106, 1984.
  • Y.M. El-Sayed and M. Tribus, “Thermodynamic properties of water-ammonia mixtures: theoretical implementation for use in power cycle analysis”, ASME Pub. ,1, 89–95.,1985.
  • K.E. Herold, K. Han and M.J. Moran., “AMMWAT: a computer program for calculating the thermodynamic properties of ammonia and water mixtures using a Gibbs free energy formulation”. ASME Pub., 4, 65–75, 1988.
  • Y.M. Park and R.E. Sonntag, "Thermodynamic properties of ammonia-water mixtures: a generalized equation-of-state approach," ASHRAE Trans., 96, 150-159, 1990.
  • M. Pfaff, R. Saravanan, M. Prakash Maiya, and S. Srinivasa Murthy, "Studies on bubble pump for a water–lithium bromide vapor absorption refrigerator," Int. J. Refrig., 21, 452-462, 1998.
  • L.A. McNeely, "Thermodynamic properties of aqueous solutions of lithium bromide," ASHRAE Trans., 85, 413-434, 1979.
  • R.J. Lee, R.M. DiGuilio, S.M. Jeter, and A.S. Teja, "Properties of lithium bromide-water solutions at high temperatures and concentrations-part II: density and viscosity," ASHRAE Trans., 96, 709-714, 1990.
  • M. Jeter, J.P. Moran, and A.S. Teja, "Properties of lithium bromide-water solutions at high temperatures and concentrations-part III: specific heat," ASHRAE Trans., 98, 137-149, 1992.
  • J.L.Y. Lenard, S.M. Jeter, and A.S. Teja, "Properties of lithium bromide-water solutions at high temperatures and concentrations-part IV: vapor pressure," ASHRAE Trans., 98, 167-172, 1992.
  • J. Patek and J. Klomfar, "Simple function for fast calculations of selected thermodynamic properties of ammonia-water system," Int. J. Refrig., 18, 228-234, 1995.
  • M. Fatouh and S. Srinivasa Murthy, "Comparison of R22-absorbent pairs for absorption cooling based on P–T–X data," Renew. Energy, 3, 31-37, 1993.
  • M.O. McLinden, E.W. Lemmon, and R.T. Jacobsen, "Thermodynamic properties for alternatives refrigerants," Int. J. Refrig., 21, 322-338, 1998.
  • R.S. Agarwal and S.L. Bapat, "Solubility characteristics of R22-DMF refrigerant-absorbent combination," Int. J. Refrig., 12, 70-74, 1985.
  • S. Dorairaj and R.S. Agarwal, "Prediction of transport properties of R22-DMF refrigerant-absorbent combinations”, Int. J. Refrig., 10, 224-228, 1986.
  • N.N. Smirnova, L.Ya Tsvetkova, T.A. Bykova, and Y. Marcus, "Thermodynamic properties of N,N-dimethylformamide and N,N-dimethylacetamide," J. Chem. Thermodyn., 39, 1508-1513, 2007.
  • L.J. He, L.M. Tang, J.M. Chen, "Performance prediction of refrigerant-DMF solutions in a single-stage solar-powered absorption refrigeration system at low generating temperatures”, Solar Energy, 83, 2029-2038, 2009.
  • A. Koyfman, M. Jelinek, A. Levy, I. Borde, "An experimental investigation of bubble pump performance for diffusion absorption refrigeration system with organic working fluids,” Appl. Therm. Eng., 23, 1181-1194, 2003.
  • A. Zohar, M. Jelinek, A. Levy, I. Borde, "Performance of diffusion absorption refrigeration cycle with organic working fluids,” Int. J. Refrig.,32, 1241-1246., 2009.
  • N. Ben Ezzine, R. Garma, and A. Bellagi, "A numerical investigation of a diffusion-absorption refrigeration cycle based on R124-DMAC mixture for solar cooling," Energy, 35, 1874-1883, 2010.
  • N. Ben Ezzine, R. Garma, M. Bourouis, and A. Bellagi, "Experimental studies on bubble pump operated diffusion absorption machine based on light hydrocarbons for solar cooling,” Renew. Energy, 35, 464-470, 2010.
  • E. Granryd, "Hydrocarbons as refrigerants - an overview," Int. J. Refrig., 24, 1, 15-24, 2001.
  • B. Palm, "Hydrocarbons as refrigerants in small heat pump and refrigeration systems – A review," Int. J. Refrig., 31, 4, 552-563, 2008.
  • N. Chekir, Kh. Mejbri, A. Bellagi, "Simulation d’une machine frigorifique à absorption fonctionnant avec des mélanges d’alcanes,” Int. J. Refrig., 29, 3, 469-475, 2006.
  • H. Dardour, P. Cézac, J.-M. Reneaume, M. Bourouis, and A. Bellagi, "Numerical Investigation of an Absorption-Diffusion Cooling Machine Using C3H8/C9H20 as Binary Working Fluid," Oil Gas Sci. Technol., 68, 249-254, 2013.
  • M. Mehyo, E. Özbaş, and H. Özcan, "Performance investigation of utilizing nanoferrofluid as a working solution in a diffusion absorption refrigeration system under an external magnetic field effect," Heat Mass Transfer, 58, 2107-2128, 2022.
  • I. Borde, M., Jelinek, N.C Daltrophe,” Working fluids for an absorption system based on R124 (2-chloro-1,1,1,2,-tetrafluoroethane) and organic absorbents,” Int. J. Refrig., 20, 4, 256-266, 1997.
  • N. Dvoskin, “Thermodynamic equilibrium of new organic mixtures for absorption heat pumps,” M.S. Thesis, Dept. Mech. Eng., Ben Gurion Univ., Beer Sheva, Israel, 2004.
There are 28 citations in total.

Details

Primary Language English
Subjects Energy Systems Engineering (Other)
Journal Section Research Articles
Authors

Bella Gurevich 0000-0001-5967-4323

Early Pub Date September 6, 2024
Publication Date December 1, 2024
Submission Date June 6, 2024
Acceptance Date August 23, 2024
Published in Issue Year 2024 Volume: 27 Issue: 4

Cite

APA Gurevich, B. (2024). Thermodynamic Properties of R1234yf and DMAC Binary Solution. International Journal of Thermodynamics, 27(4), 23-29. https://doi.org/10.5541/ijot.1496861
AMA Gurevich B. Thermodynamic Properties of R1234yf and DMAC Binary Solution. International Journal of Thermodynamics. December 2024;27(4):23-29. doi:10.5541/ijot.1496861
Chicago Gurevich, Bella. “Thermodynamic Properties of R1234yf and DMAC Binary Solution”. International Journal of Thermodynamics 27, no. 4 (December 2024): 23-29. https://doi.org/10.5541/ijot.1496861.
EndNote Gurevich B (December 1, 2024) Thermodynamic Properties of R1234yf and DMAC Binary Solution. International Journal of Thermodynamics 27 4 23–29.
IEEE B. Gurevich, “Thermodynamic Properties of R1234yf and DMAC Binary Solution”, International Journal of Thermodynamics, vol. 27, no. 4, pp. 23–29, 2024, doi: 10.5541/ijot.1496861.
ISNAD Gurevich, Bella. “Thermodynamic Properties of R1234yf and DMAC Binary Solution”. International Journal of Thermodynamics 27/4 (December 2024), 23-29. https://doi.org/10.5541/ijot.1496861.
JAMA Gurevich B. Thermodynamic Properties of R1234yf and DMAC Binary Solution. International Journal of Thermodynamics. 2024;27:23–29.
MLA Gurevich, Bella. “Thermodynamic Properties of R1234yf and DMAC Binary Solution”. International Journal of Thermodynamics, vol. 27, no. 4, 2024, pp. 23-29, doi:10.5541/ijot.1496861.
Vancouver Gurevich B. Thermodynamic Properties of R1234yf and DMAC Binary Solution. International Journal of Thermodynamics. 2024;27(4):23-9.