.AixLib.Media.Refrigerants.R410A_HEoS.R410a_IIR_P1_48_T233_473_Formula

Information

This package provides a refrigerant model for R410a using a hybrid approach developed by Sangi et al.. The hybrid approach is implemented in AixLib.Media.Refrigerants.Interfaces.PartialHybridTwoPhaseMedium and the refrigerant model is implemented by complete the template AixLib.Media.Refrigerants.Interfaces.TemplateHybridTwoPhaseMediumRecord . The fitting coefficients required in the template are saved in the package AixLib.DataBase.Media.Refrigerants.R410a .

Assumptions and limitations

The implemented coefficients are fitted to external data by Engelpracht and are valid within the following range:

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Parameter

Minimum Value

Maximum Value

Pressure (p) in bar

1

48

Temperature (T) in K

233.15

473.15

The reference point is defined as 200 kJ/kg and 1 kJ/kg/K, respectively, for enthalpy and entropy for the saturated liquid at 273.15 K.

Assumptions and limitations

R410a is calculated as pseudo-pure fluid and, hence, only roughly valid within the two-phase region.

Validation

The model is validated by comparing results obtained from the example model AixLib.Media.Refrigerants.Examples.RefrigerantProperties to external data (e.g. obtained from measurements or external media libraries).

References

Lemmon, E. W. (2003): Pseudo-Pure Fluid Equations of State for the Refrigerant Blends R-410A, R-404A, R-507A, and R-407C. In: International Journal of Thermophysics 24 (4), S. 991–1006. DOI: 10.1023/A:1025048800563.

Geller, V. Z.; Bivens, D.; Yokozeki, A. (2000): Viscosity of Mixed Refrigerants, R404A, R407C, R410A, and R507C. In: International refrigeration and air conditioning conference. USA, S. 399–406. Online available at http://docs.lib.purdue.edu/iracc/508.

Nabizadeh, H.; Mayinger, F. (1999): Viscosity of Gaseous R404A, R407C, R410A, and R507. In: International Journal of Thermophysics 20 (3), S. 777–790. DOI: 10.1007/978-1-4615-4777-8_1.

Geller, V. Z.; Nemzer, B. V.; Cheremnykh, U. V. (2001): Thermal Conductivity of the Refrigerant Mixtures R404A, R407C, R410A, and R507A. In: International Journal of Thermophysics 22 (4), 1035–1043. DOI: 10.1023/A:1010691504352.

Fröba, A. P.; Leipertz, A. (2003): Thermophysical Properties of the Refrigerant Mixtures R410A and R407C from Dynamic Light Scattering (DLS). In: International Journal ofThermophysics 24 (5), S. 1185–1206. DOI: 10.1023/A:1026152331710.

Engelpracht, Mirko (2017): Development of modular and scalable simulation models for heat pumps and chillers considering various refrigerants. Master Thesis

Contents

NameDescription
 SmoothTransitionRecord that contains ranges to calculate a smooth transition between different regions
 f_IdgDimensionless Helmholtz energy (Ideal gas contribution alpha_0)
 f_ResDimensionless Helmholtz energy (Residual part alpha_r)
 t_fIdg_tShort form for tau*(dalpha_0/dtau)_delta=const
 tt_fIdg_ttShort form for tau*tau*(ddalpha_0/(dtau*dtau))_delta=const
 t_fRes_tShort form for tau*(dalpha_r/dtau)_delta=const
 tt_fRes_ttShort form for tau*tau*(ddalpha_r/(dtau*dtau))_delta=const
 d_fRes_dShort form for delta*(dalpha_r/(ddelta))_tau=const
 dd_fRes_ddShort form for delta*delta(ddalpha_r/(ddelta*delta))_tau=const
 td_fRes_tdShort form for tau*delta*(ddalpha_r/(dtau*ddelta))
 ttt_fIdg_tttShort form for tau*tau*tau*(dddalpha_0/(dtau*dtau*dtau))_delta=const
 ttt_fRes_tttShort form for tau*tau*tau*(dddalpha_r/(dtau*dtau*dtau))_delta=const
 ddd_fRes_dddShort form for delta*delta*delta* (dddalpha_r/(ddelta*ddelta*ddelta))_tau=const
 tdd_fRes_tddShort form for tau*delta*delta*(dddalpha_r/(dtau*ddelta*ddelta))
 ttd_fRes_ttdShort form for tau*tau*delta*(dddalpha_r/(dtau*dtau*ddelta))
 saturationPressureSaturation pressure of refrigerant (Ancillary equation)
 saturationTemperatureSaturation temperature of refrigerant (Ancillary equation)
 bubbleDensityBoiling curve specific density of refrigerant (Ancillary equation)
 dewDensityDew curve specific density of refrigerant (Ancillary equation)
 bubbleEnthalpyBoiling curve specific enthalpy of refrigerant (Ancillary equation)
 dewEnthalpyDew curve specific enthalpy of refrigerant (Ancillary equation)
 bubbleEntropyBoiling curve specific entropy of refrigerant (Ancillary equation)
 dewEntropyDew curve specific entropy of propane (Ancillary equation)
 temperature_phCalculates temperature as function of pressure and specific enthalpy
 temperature_psCalculates temperature as function of pressure and specific entroy
 density_pTComputes density as a function of pressure and temperature
 dynamicViscosityCalculates dynamic viscosity of refrigerant
 thermalConductivityCalculates thermal conductivity of refrigerant
 surfaceTensionSurface tension in two phase region of refrigerant

Revisions


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