Predictive Soave-Redlich-Kwong (PSRK): Difference between revisions
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:<math> P = { { R T } \over { V - b } } - { { a(T) } \over { ( V + \epsilon b ) ( V + \sigma b ) } } </math> | :<math> P = { { R T } \over { V - b } } - { { a(T) } \over { ( V + \epsilon b ) ( V + \sigma b ) } } </math> | ||
Parameters for Soave-Redlich-Kwong equation are <ref>Perry's Chemical Engineers' Handbook | Parameters for Soave-Redlich-Kwong equation are <ref>DW Green and RH Perry, 2007. ''Perry's Chemical Engineers' Handbook'' 8th Edition, section 4-11. ISBN 9780071422949</ref>: | ||
:<math> \epsilon = 0</math> and <math> \sigma = 1</math> | :<math> \epsilon = 0</math> and <math> \sigma = 1</math> | ||
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=== PSRK mixing rule for calculating a(T) and b === | === PSRK mixing rule for calculating a(T) and b === | ||
Cohesion pressure (attractive parameter) <ref>Horstmann, | Cohesion pressure (attractive parameter) <ref>S Horstmann, A Jabłoniec, J Krafczyk, K Fischer and J Gmehling, 2005. PSRK group contribution equation of state: comprehensive revision and extension IV, including critical constants and α-function parameters for 1000 components. ''Fluid Phase Equilibria'' '''227''' 157-164 {{doi|10.1016/j.fluid.2004.11.002}}</ref>: | ||
:<math>a(T) = b RT \left( \sum x_i { {a_{ii}(T)} \over {b_i R T} } + { \frac{ { \frac{g_0^E}{R T} } + \sum x_i \ln \left( \frac{b}{b_i} \right) }{ \ln \left( \frac{u}{u + 1} \right)} } \right)</math> | :<math>a(T) = b RT \left( \sum x_i { {a_{ii}(T)} \over {b_i R T} } + { \frac{ { \frac{g_0^E}{R T} } + \sum x_i \ln \left( \frac{b}{b_i} \right) }{ \ln \left( \frac{u}{u + 1} \right)} } \right)</math> | ||
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Molecular volume parameter for component i <ref>Larsen, Rasmussen, Fredenslund; A Modified UNIFAC Group-Contribution Model for Prediction of Phase Equilibria and Heats of Mixing; Ind. Eng. Chem. Res. 1987, 26 2274-2286</ref>: | Molecular volume parameter for component i <ref>Larsen, Rasmussen, Fredenslund; A Modified UNIFAC Group-Contribution Model for Prediction of Phase Equilibria and Heats of Mixing; Ind. Eng. Chem. Res. 1987, 26 2274-2286 {{doi|10.1021/ie00071a018}}</ref>: | ||
<math> r_i = \sum_k \nu_k^{(i)} * R_k </math> | <math> r_i = \sum_k \nu_k^{(i)} * R_k </math> | ||
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<math> \omega_i = {{x_i * r_i^{2/3}} \over {\sum_j x_j * r_j^{2/3}}} </math> | <math> \omega_i = {{x_i * r_i^{2/3}} \over {\sum_j x_j * r_j^{2/3}}} </math> | ||
Group mole fraction <ref>Stephan, Schaber, Stephan, Mayinger: Thermodynamik. Grundlagen und technische Anwendungen: Band 2: Mehrstoffsysteme und chemische Reaktionen; Springer Verlag</ref>: | Group mole fraction <ref>Stephan, Schaber, Stephan, Mayinger: Thermodynamik. Grundlagen und technische Anwendungen: Band 2: Mehrstoffsysteme und chemische Reaktionen; Springer Verlag ISBN 9783642241611</ref>: | ||
<math> X_k = {{\sum_i \nu_k^{(i)} * x_i} \over {\sum_i \sum_l \nu_l^{(i)} * x_i}} </math> | <math> X_k = {{\sum_i \nu_k^{(i)} * x_i} \over {\sum_i \sum_l \nu_l^{(i)} * x_i}} </math> | ||
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=== Procedure for calculating vapor-liquid equilibria (VLE) (phi-phi approach) === | === Procedure for calculating vapor-liquid equilibria (VLE) (phi-phi approach) === | ||
Equilibrium condition <ref>Gmehling, Kolbe, Kleiber, Rarey; Chemical Thermodynamics for Process Simulation; February 2012; Wiley | Equilibrium condition <ref>Gmehling, Kolbe, Kleiber, Rarey; Chemical Thermodynamics for Process Simulation; February 2012; Wiley ISBN 9783527312771 | ||
</ref>: | |||
<math> x_i * \varphi_i^L = y_i * \varphi_i^V </math> | <math> x_i * \varphi_i^L = y_i * \varphi_i^V </math> | ||
Revision as of 10:46, 7 January 2016
Generic cubic equation of state
- <math> P = { { R T } \over { V - b } } - { { a(T) } \over { ( V + \epsilon b ) ( V + \sigma b ) } } </math>
Parameters for Soave-Redlich-Kwong equation are [1]:
- <math> \epsilon = 0</math> and <math> \sigma = 1</math>
Thus:
- <math> P = { { R T } \over { V - b } } - { { a(T) } \over { V ( V + b ) } } </math>
PSRK mixing rule for calculating a(T) and b
Cohesion pressure (attractive parameter) [2]:
- <math>a(T) = b RT \left( \sum x_i { {a_{ii}(T)} \over {b_i R T} } + { \frac{ { \frac{g_0^E}{R T} } + \sum x_i \ln \left( \frac{b}{b_i} \right) }{ \ln \left( \frac{u}{u + 1} \right)} } \right)</math>
with
- <math> u = 1.1 </math>,
- <math> a_{ii}(T) = \Psi \frac{ \alpha_i (T_{r,i}) R^2 T_{C,i}^2 }{ P_{C,i} } </math>, and
- <math> \Psi = 0.42748 </math>.
Excluded volume or "co-volume" (repulsive parameter):
<math> b = \sum x_i b_i </math>
where
- <math> b_i = \Omega { \frac{ RT_{C,i} }{ P_{C,i} } } </math>, and
- <math> \Omega = 0.08664 </math>
Different mixing rules can be applied and a list will be compiled here:
...
Mathias-Copeman equation
Fitting experimental data with Mathias-Copeman parameters <math> c_{1,i} </math>, <math> c_{2,i} </math> and <math> c_{3,i} </math>:
- <math> \alpha_i (T_{r,i}) = \left[ 1 + c_{1,i} \left(1 - \sqrt{T_{r,i}} \right) + c_{2,i} \left(1 - \sqrt{T_{r,i}} \right)^2 + c_{3,i} \left(1 - \sqrt{T_{r,i}} \right)^3 \right]^2 </math>
General form if no experimental data available:
- <math> c_{1,i} = 0.48 + 1.574 \omega_i - 0.176 \omega_i^2 </math>
- <math> c_{2,i} = 0 </math>
- <math> c_{3,i} = 0 </math>
Gibbs-Excess energy
<math> g^E = g_{c}^E + g_{r}^E</math>
<math> g_{c}^E = RT \sum x_i ln( {{\omega_i} \over {x_i}} ) </math>
<math> g_{r}^E = RT \sum x_i \frac{z}{2} q_i \ln \frac{\theta_{ii}}{\theta_i} </math>
<math> \Rightarrow g_{0}^E = R T_0 \sum x_i \left( \ln \frac{\omega_i}{x_i} + \frac{z}{2} + q_i \ln \frac{\theta_{ii}}{\theta_i} \right) </math>
modified UNIFAC
Molecular volume parameter for component i [3]:
<math> r_i = \sum_k \nu_k^{(i)} * R_k </math>
Molecular surface area parameter for component i:
<math> q_i = \sum_k \nu_k^{(i)} * Q_k </math>
where <math>\nu</math> is the number of the particular subgroups which a component i can be divided into. <math>R_k</math> is the volume parameter and <math>Q_k</math> the surface area parameter for subgroup k. <math>R_k</math> and <math>Q_k</math> are tabulated parameters and provided by the UNIFAC Consortium (http://unifac.ddbst.de/). Each subgroup can be assigned to a main group.
Modified volume fraction [Kikic et al.; 1980]:
<math> \omega_i = {{x_i * r_i^{2/3}} \over {\sum_j x_j * r_j^{2/3}}} </math>
Group mole fraction [4]:
<math> X_k = {{\sum_i \nu_k^{(i)} * x_i} \over {\sum_i \sum_l \nu_l^{(i)} * x_i}} </math>
Surface area fraction for component i in mixture:
<math> \theta_i = { {X_i * Q_i} \over {\sum_k X_k * Q_k} } </math>
Local surface area fraction for j around i:
<math> \theta_{ji} = { {\theta_j * \tau_{ji}} \over {\sum_m \theta_m * \tau_{mi}} } </math>
where
<math> \tau_{mi} = \Psi_{nm} </math>
and <math>\tau_{mi}</math> is the Boltzmann factor and can be calculated by transposing the main group interaction parameter matrix:
<math> \Psi_{nm} = exp(- { {a_{nm} + b_{nm}*T + c_{nm}*T^2} \over {T} }) </math>
<math>a_{nm}</math>, <math>b_{nm}</math> and <math>c_{nm}</math> are the binary interaction parameters representing the interaction between the main groups where the following applies:
<math> a_{nm} \ne a_{mn} </math>; <math> b_{nm} \ne b_{mn} </math>; <math> c_{nm} \ne c_{mn} </math>
The binary interaction parameters are also tabulated parameters and provided by the UNIFAC Consortium (http://unifac.ddbst.de/). The original UNIFAC model uses only <math> a_{nm} \ne a_{mn} </math> as interactions parameters. Modified UNIFAC and PSRK include <math> b_{nm} \ne b_{mn} </math> and <math> c_{nm} \ne c_{mn} </math> for describing main group interactions. Very important: PSRK relies on the modified UNIFAC equations but the parameters are different and therefore a different parameter dataset is provided for PSRK calculations.
A Excel file written by Carl Lira (http://www.egr.msu.edu/~lira/) can help to understand UNIFAC calculations. Take a look at the ACTCOEFF.XLS file under http://www.egr.msu.edu/~lira/computer/EXCEL/. Beware of that not the modified UNIFAC method is applied in Lira's Excel sheet but the original UNIFAC method. PSRK relies on the modified UNIFAC method and uses PSRK specific parameters.
The UNIFAC consortium has published all parameters for the original UNIFAC model: http://www.ddbst.com/published-parameters-unifac.html
For obtaining the parameters for applying the modified UNIFAC model or the PSRK model one has to become a member of the UNIFAC consortium.
These pages can also help to understand this topic:
http://www.pvv.org/~randhol/xlunifac/html/node9.html
http://www.aim.env.uea.ac.uk/aim/info/UNIFACgroups.html
Procedure for calculating vapor-liquid equilibria (VLE) (phi-phi approach)
Equilibrium condition [5]:
<math> x_i * \varphi_i^L = y_i * \varphi_i^V </math>
Fugacity coefficient for component i in a mixture:
<math> ln \varphi_i = \frac{1}{R*T} \int_{\infty}^V [ \frac{RT}{V} - ( \frac{\partial P}{\partial n_i} )_{T, V, n_{j \ne i}} ] dV - ln z </math>
Fugacity coefficient for the liquid phase:
...
Fugacity coefficient for the vapor phase:
...
K-factor:
<math> K_i = { {y_i} \over {x_i} } = { {\varphi_i^L} \over {\varphi_i^V} } </math>
Sum of mole fractions:
<math> S = \sum y_i = \sum K_i * x_i </math>
Flow diagram for calculating isothermal VLE using PSRK:
References
- ↑ DW Green and RH Perry, 2007. Perry's Chemical Engineers' Handbook 8th Edition, section 4-11. ISBN 9780071422949
- ↑ S Horstmann, A Jabłoniec, J Krafczyk, K Fischer and J Gmehling, 2005. PSRK group contribution equation of state: comprehensive revision and extension IV, including critical constants and α-function parameters for 1000 components. Fluid Phase Equilibria 227 157-164 doi:10.1016/j.fluid.2004.11.002
- ↑ Larsen, Rasmussen, Fredenslund; A Modified UNIFAC Group-Contribution Model for Prediction of Phase Equilibria and Heats of Mixing; Ind. Eng. Chem. Res. 1987, 26 2274-2286 doi:10.1021/ie00071a018
- ↑ Stephan, Schaber, Stephan, Mayinger: Thermodynamik. Grundlagen und technische Anwendungen: Band 2: Mehrstoffsysteme und chemische Reaktionen; Springer Verlag ISBN 9783642241611
- ↑ Gmehling, Kolbe, Kleiber, Rarey; Chemical Thermodynamics for Process Simulation; February 2012; Wiley ISBN 9783527312771
See also
Other cubic equations of state (EOS):