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CapMachine/CapMachine.Wpf/PPCalculation/REFPROP/FLUIDS/EGLYCOL.FLD

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Ethylene glycol !Short name
107-21-1 !CAS number
1,2-Ethandiol !Full name
OH(CH2CH2)OH !Chemical formula {C2H6O2}
Glycol alcohol !Synonym
62.06784 !Molar mass [g/mol]
260.6 !Triple point temperature [K]
470.313 !Normal boiling point [K]
719.0 !Critical temperature [K]
10508.7 !Critical pressure [kPa]
5.88 !Critical density [mol/L]
0.619 !Acentric factor
2.41 !Dipole moment [Debye] McClellan, A.L., "Tables of Experimental Dipole Moments, " Rahara Enterprises, El Cerrito, CA, Vol. 3 (1989)
NBP !Default reference state
10.0 !Version number
3082 !UN Number :UN:
other !Family :Family:
???? !Heating value (upper) [kJ/mol] :Heat:
1S/C2H6O2/c3-1-2-4/h3-4H,1-2H2 !Standard InChI String :InChi:
LYCAIKOWRPUZTN-UHFFFAOYSA-N !Standard InChI Key :InChiKey:
???? !Alternative fluid for mixing rules :AltID:
7d1768e0 !Hash number from InChI Key :Hash:
!The fluid files contain general information about the fluid in the first 15 to 20 lines, followed by sections for the
! equations of state, transport equations, and auxiliary equations. Equations of state are listed first. The NIST recommended
! equations begin with a hash mark (#). The secondary equations begin with the @ symbol. These symbols can be swapped to
! select a secondary equation as primary and the primary as secondary. The equation of state section also contains auxiliary
! equations for the ideal gas heat capacity or ideal gas Helmholtz energy. Below the equations of state (both primary and
! secondary) are the transport equations, first viscosity and then thermal conductivity. These are then followed by the
! secondary equations if available. The transport section also contains auxiliary equations required to calculate either the
! dilute gas state or the critical enhancement. At the end of the file are additional but not necessary auxiliary equations,
! including simple equations for the vapor pressure, saturated liquid and vapor densities, melting line (for some fluids), and
! sublimation line (for even fewer fluids). This section also contains the equations for dielectric constant and surface
! tension if available. The sections are divided by different symbols (these being _-+=^*~) to aid the eye in locating a
! particular section. Secondary equations are indented 10 spaces to avoid confusion with the NIST recommended equations. The
! end of the fluid file is marked with @END. Anything below that is ignored.
! compiled by E.W. Lemmon, NIST Physical and Chemical Properties Division, Boulder, Colorado
! 11-27-06 EWL, Original version.
! 03-11-09 EWL, Add transport routines.
! 08-20-10 IDC, Add ancillary equations.
! 03-25-14 MLH, Add surface tension.
! 12-31-14 EWL, Refit equation of state.
! 05-04-17 MLH, Prelim vis and therm con ecs fits added with revised EOS, revised surft with revised Tc.
! 04-23-18 EWL, Add final equation of state of Zhou and Lemmon (2018).
! 04-24-18 MLH, Revised transport and surface tension with final EOS.
________________________________________________________________________________
#EOS !---Equation of state---
FEQ !Helmholtz equation of state for ethylene glycol of Zhou and Lemmon (2018).
:TRUECRITICALPOINT: 719.0 5.88 !True EOS critical point [K, mol/L] (where dP/dD=0 and d^2P/dD^2=0 at constant T)
:DOI:
?
?```````````````````````````````````````````````````````````````````````````````
?Zhou, Y. and Lemmon, E.W.,
? unpublished equation, 2018.
?
!```````````````````````````````````````````````````````````````````````````````
260.6 !Lower temperature limit [K]
750.0 !Upper temperature limit [K]
100000.0 !Upper pressure limit [kPa]
18.31 !Maximum density [mol/L]
CPP !Pointer to Cp0 model
62.06784 !Molar mass [g/mol]
260.6 !Triple point temperature [K] (NIST Chemistry Webbook)
0.0002366 !Pressure at triple point [kPa]
18.30 !Density at triple point [mol/L]
470.313 !Normal boiling point temperature [K]
0.619 !Acentric factor
719.0 10508.7 5.88 !Tc [K], pc [kPa], rhoc [mol/L]
719.0 5.88 !Reducing parameters [K, mol/L]
8.3144598 !Gas constant [J/mol-K]
14 4 7 12 0 0 0 0 0 0 0 0 !# terms and # coefs/term for normal terms, Gaussian terms, and Gao terms
0.019393376 1.0 5. 0. !a(i),t(i),d(i),l(i)
1.2215576 0.1 1. 0.
1.2751617 1.27 1. 0.
-3.6681302 1.244 1. 0.
-1.4660821 1.1 2. 0.
0.24628603 0.32 3. 0.
-0.063217756 1.0 4. 0.
1.4131488 0.89 2. 1.
3.5245547 1.2 3. 1.
-2.2658015 1.34 3. 1.
0.94972119 1.3 4. 1.
-0.13037392 1.49 5. 1.
0.19881857 1.23 6. 1.
-0.022141839 0.18 7. 1.
1.1273408 1.1 1. 2. 2. -0.9 -0.91 1.17 1.37 0. 0. 0.
-0.12188623 0.75 1. 2. 2. -1.35 -1.25 1.49 0.4 0. 0. 0.
-0.79487875 0.79 2. 2. 2. -0.8 -0.97 1.3 1. 0. 0. 0.
-0.024231918 0.77 3. 2. 2. -1.9 -0.5 1.5 2.45 0. 0. 0.
-0.00574040155 0.6 4. 2. 2. -2.0 -1.0 1.2 1.9 0. 0. 0.
0.0083087704 1.0 5. 2. 2. -1.3 -0.42 1.2 2. 0. 0. 0.
-0.041852456 1.0 3. 2. 2. -20.0 -1000.0 1.07 0.9 0. 0. 0.
#AUX !---Auxiliary function for Cp0
CPP !Ideal gas heat capacity function for ethylene glycol of Zhou and Lemmon (2018).
?
?```````````````````````````````````````````````````````````````````````````````
?Zhou, Y. and Lemmon, E.W., 2018.
?
!```````````````````````````````````````````````````````````````````````````````
0. !
10000. !
0. !
0. !
1.0 8.3144598 !Reducing parameters for T, Cp0
1 1 0 0 0 0 0 !Nterms: polynomial, exponential, cosh, sinh
4.0 0.0
20.86 1260.0
#AUX !---Auxiliary function for PX0
PX0 !Helmholtz energy ideal-gas function for ethylene glycol of Zhou and Lemmon (2018).
?
?```````````````````````````````````````````````````````````````````````````````
?Zhou, Y. and Lemmon, E.W., 2018.
?
!```````````````````````````````````````````````````````````````````````````````
1 2 1 0 0 0 0 0 !Nterms: ai*log(tau**ti); ai*tau**ti; ai*log(1-exp(bi*tau))
3.0 1.0 !ai, ti for [ai*log(tau**ti)] terms
-1.2230958209345886 0.0 !aj, ti for [ai*tau**ti] terms
3.8389800933704281 1.0 !aj, ti for [ai*tau**ti] terms
20.86 1260.0 !aj, ti for [ai*log(1-exp(-ti/T)] terms
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
#TRN !---ECS Transport---
ECS !Extended Corresponding States model (Propane reference)
:DOI: 10.6028/NIST.IR.8209
?
?```````````````````````````````````````````````````````````````````````````````
? *** ESTIMATION METHOD--- NOT STANDARD REFERENCE QUALITY---
?
?Based on comparisons to limited liquid-phase thermal conductivity data, uncertainty of the thermal conductivity
? is estimated to be 2% for the liquid phase at atmospheric pressure between 298 K and 452 K.
? Gas-phase thermal conductivity data are unavailable, and uncertainty is estimated to be 20%.
?
?Based on comparisons to limited liquid-phase viscosity data, uncertainty I estimated to
? be 4% for the liquid phase between 288 K and 373 K at atmospheric pressure.
? At pressures up to 10 MPa the uncertainty rises to 20%.
? Gas-phase viscosity data is unavailable, uncertainty is estimated to be 20%.
?
?Uses method described in the following reference:
? Huber, M.L., Laesecke, A., and Perkins, R.A.,
? "Model for the Viscosity and Thermal Conductivity of Refrigerants, Including
? a New Correlation for the Viscosity of R134a,"
? Ind. Eng. Chem. Res., 42(13):3163-3178, 2003. doi: 10.1021/ie0300880
?
?The Lennard-Jones parameters were estimated with the method of Chung.
?
!```````````````````````````````````````````````````````````````````````````````
260.0 !Lower temperature limit [K]
750.0 !Upper temperature limit [K]
10000.0 !Upper pressure limit [kPa]
18.31 !Maximum density [mol/L]
FEQ PROPANE.FLD
VS1 !Model for reference fluid viscosity
TC1 !Model for reference fluid thermal conductivity
NUL !Large molecule identifier
1 !Lennard-Jones flag (0 or 1) (0 => use estimates)
0.4482 !Lennard-Jones coefficient sigma [nm] for ECS method
570.95 !Lennard-Jones coefficient epsilon/kappa [K] for ECS method
1 0 0 !Number of terms in f_int term in Eucken correlation, spare1, spare2
1.32e-3 0. 0. 0. !Coefficient, power of T, spare1, spare2
4 0 0 !Number of terms in psi (visc shape factor): poly,spare1,spare2
0.864168 0. 0. 0. !Coefficient, power of Tr, power of Dr, spare
-2.30208e-3 0. 1. 0. !Coefficient, power of Tr, power of Dr, spare
-1.83225e-3 0. 2. 0. !Coefficient, power of Tr, power of Dr, spare
9.04878e-3 0. 3. 0. !Coefficient, power of Tr, power of Dr, spare
2 0 0 !Number of terms in chi (t.c. shape factor): poly,spare1,spare2
1.79177 0. 0. 0. !Coefficient, power of Tr, power of Dr, spare
-0.275354 0. 1. 0. !Coefficient, power of Tr, power of Dr, spare
TK3 !Pointer to critical enhancement auxiliary function
#AUX !---Auxiliary function for the thermal conductivity critical enhancement
TK3 !Simplified thermal conductivity critical enhancement for ethylene glycol of Perkins et al. (2013).
?
?```````````````````````````````````````````````````````````````````````````````
?Perkins, R.A., Sengers, J.V., Abdulagatov, I.M., and Huber, M.L.,
? "Simplified Model for the Critical Thermal-Conductivity Enhancement in Molecular Fluids,"
? Int. J. Thermophys., 34(2):191-212, 2013. doi: 10.1007/s10765-013-1409-z
?
!```````````````````````````````````````````````````````````````````````````````
0. !
10000. !
0. !
0. !
9 0 0 0 !# terms: CO2-terms, spare, spare, spare
1.0 1.0 1.0 !Reducing parameters for T, rho, tcx [mW/(m-K)]
0.63 !Nu (universal exponent)
1.239 !Gamma (universal exponent)
1.02 !R0 (universal amplitude)
0.063 !Z (universal exponent--not used for t.c., only viscosity)
1.0 !C (constant in viscosity eqn = 1/[2 - (alpha + gamma)/(2*nu)], but often set to 1)
0.166e-9 !Xi0 (amplitude) [m]
0.073 !Gam0 (amplitude) [-]
5.42e-10 !Qd_inverse (modified effective cutoff parameter) [m]; arbitrary guess
1078.5 !Tref (reference temperature)=1.5*Tc [K]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
#STN !---Surface tension---
ST1 !Surface tension model for ethylene glycol of Huber (2018).
:DOI: 10.6028/NIST.IR.8209
?
?```````````````````````````````````````````````````````````````````````````````
?Fit to the data of:
? Azizian, S. and Hemmati, M., "Surface Tension of Binary Mixtures of Ethanol + Ethylene Glycol from 20 to 50 °C," J. Chem. Eng. Data, 48:662-663, 2003. doi: 10.1021/je025639s
? Azizian, S. and Bashavard, N., "Surface Tensions of Dilute Solutions of Cycloheptanol in Ethylene Glycol," J. Chem. Eng. Data, 50:1091-1094, 2005. doi: 10.1021/je050055m
? Rafati, A.A., Bagheri, A., and Najafi, M., "Surface Tension of Non-Ideal Binary and Ternary Liquid Mixtures at Various Temperatures and p = 81.5 kPa," J. Chem. Thermodyn., 43:248-254, 2011. doi: 10.1016/j.jct.2010.09.003
? Estimated uncertainty for 283-323 K is 2%.
?
!```````````````````````````````````````````````````````````````````````````````
0. !
10000. !
0. !
0. !
1 !Number of terms in surface tension model
719.0 !Critical temperature used in fit (dummy)
0.0731084 0.776849 !sigma0 and n
#PS !---Vapor pressure---
PS5 !Vapor pressure equation for ethylene glycol of Zhou and Lemmon (2018).
?
?```````````````````````````````````````````````````````````````````````````````
?Zhou and Lemmon, 2018.
?
?Functional Form: P=Pc*EXP[SUM(Ni*Theta^ti)*Tc/T] where Theta=1-T/Tc, Tc and Pc
? are the reducing parameters below, which are followed by rows containing Ni and ti.
?
!```````````````````````````````````````````````````````````````````````````````
0. !
10000. !
0. !
0. !
719.0 10508.7 !Reducing parameters
5 0 0 0 0 0 !Number of terms in equation
-10.193 1.0
6.7548 1.5
-6.0404 1.9
-3.869 3.64
-8.4146 18.0
#DL !---Saturated liquid density---
DL1 !Saturated liquid density equation for ethylene glycol of Zhou and Lemmon (2018).
?
?```````````````````````````````````````````````````````````````````````````````
?Zhou and Lemmon, 2018.
?
?Functional Form: D=Dc*[1+SUM(Ni*Theta^ti)] where Theta=1-T/Tc, Tc and Dc are
? the reducing parameters below, which are followed by rows containing Ni and ti.
?
!```````````````````````````````````````````````````````````````````````````````
0. !
10000. !
0. !
0. !
719.0 5.88 !Reducing parameters
6 0 0 0 0 0 !Number of terms in equation
1.3902 0.29
-7.6323 1.25
3.5326 0.75
10.85 1.8
-8.7298 2.5
3.3638 3.4
#DV !---Saturated vapor density---
DV3 !Saturated vapor density equation for ethylene glycol of Zhou and Lemmon (2018).
?
?```````````````````````````````````````````````````````````````````````````````
?Zhou and Lemmon, 2018.
?
?Functional Form: D=Dc*EXP[SUM(Ni*Theta^ti)] where Theta=1-T/Tc, Tc and Dc are
? the reducing parameters below, which are followed by rows containing Ni and ti.
?
!```````````````````````````````````````````````````````````````````````````````
0. !
10000. !
0. !
0. !
719.0 5.88 !Reducing parameters
6 0 0 0 0 0 !Number of terms in equation
-0.47502 0.173
-5.5419 0.6
-16.175 2.08
-50.153 4.8
-86.316 10.0
-169.85 18.0
@END
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