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VOL. 39, 2014 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Peng Yen Liew, Jun Yow Yong  

Copyright © 2014, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-30-3; ISSN 2283-9216 DOI:10.3303/CET1439022 

 

Please cite this article as: Rom A., Gimeno D.E., Friedl A., 2014, A user-defined pervaporation unit operation in AspenPlus© 

on the basis of experimental results from three different organophilic membranes, Chemical Engineering Transactions, 39, 

127-132  DOI:10.3303/CET1439022 

127 

A User-Defined Pervaporation Unit Operation in 

AspenPlus
© 

on the Basis of Experimental Results from 

Three Different Organophilic Membranes 

Antonia Rom*, Diana Esteve Gimeno, Anton Friedl 

Vienna University of Technology, Institute of Chemical Engineering, Getreidemarkt 9/166, 1060 Vienna, 

Austriaantonia.rom@tuwien.ac.at 

Simulation is an important tool to balance, compare and investigate processes. Due to new investigations 

and the variety of processes not every process step is available as unit operation in simulation software. 

Absence of unit operations is evaded with help of simplifications, assumptions and usage of similar 

process steps. At best unit operations should calculate in and outlet streams based on sophisticated 

models according to the theory in literature. Therefor the aim of this work was to generate a pervaporation 

unit operation on the basis of experimental results working on AspenPlus
©
 platform. 

Per-vaporation as a thermal membrane process step is gaining more and more interest from researchers 

in the last decades. The possibility to separate close boiling point, heat sensitive and azeotropic mixtures 

opens a big field for industrial application (Shao et al., 2007). Additionally energy savings are possible 

when effective process combinations are implemented (Vane, 2005). The membrane, as the heart of the 

pervaporation process, is currently the limiting factor. Despite high membrane costs, membrane fouling is 

also one big disadvantage. Therefore investigation of different membranes is also in focus of research 

works. 

The potential energy savings offered when using pervaporation can be determined at its best, when the 

process step is investigated in simulation software. The aim of this work should enable this possibility to 

generate a pervaporation unit operation on the basis of experimental results. Therefore three different 

organophilic membranes were investigated on a laboratory setup. Influences like feed temperature, feed 

concentration, Reynolds number in the module and applied vacuum pressure were varied. 

The gained results offer a data set to regress membrane and component specific permeances depending 

on the investigated parameters. The same experiments with all three membranes were carried out in the 

laboratory. A sequence from the trials is used to regress permeance models for each membrane and 

component. These regression models were implemented in the user defined unit operation. In the unit 

operation mass transport and simple heat balance including evaporation are considered. 

As a result three unit operations with different membranes are available for simulation. Validation of the 

experimental results shows very good accordance with all three investigated membranes. The aim of a 

first estimation of the pervaporation step in the simulation software is reached. The results of this work 

enable the connection of the pervaporation unit operation in global process sheets and hybrid 

combinations. 

1. Introduction 

In pervaporation a liquid feed is in contact with a dense polymeric membrane or a porous zeolith 

membrane. By applying a vacuum on the permeate side liquid is diffusing in and transported through the 

membrane and evaporated on the permeate side. Depending on the use of the pervaporation step the 

membrane is either hydrophob or organophil for dehydration or volatile organic compounds removal 

respectively. In this work organophilic membranes were chosen, so the organic compound is enriched on 

the permeate side. The preferred transport from the feed to the permeate side of one component is the 

result of the selective membrane and the vapour liquid equilibrium of the components (Vane, 2005). 



 
128 

 
In the work of Wijmans and Baker (1995) the solution-diffusion model is used to describe transport 

mechanism in pervaporation. The model describes the molar component flow Ni in [kmol/m²h] as the 

product of the permeance Pi, which is not mandatory constant, and the driving force as chemical potential 

gradient between feed and permeate side. Transformation to partial pressures leads to Eq.(1), where pi,f is 

the partial pressure of component i in the feed and Pi,p in the permeate side. 

 (1) 

The permeance as membrane specific coefficient in [kmol/m²h] includes membrane specifications as 

membrane thickness, diffusivity and sorption coefficient. Since these parameters are not always available 

for the investigated membranes, permeance is often the preferred used term. 

Regarding simulation of PV a few modelling approaches for the transport mechanism in pervaporation are 

investigated in literature (Marriot et al., 2001). In the work of Schiffmann and Repke (2012) a stepwise 

development from a shortcut, over discrete to a rigorous model is presented. The developed model can be 

integrated in AspenPlus
©
 and offers the opportunity to connect and balance the pervaporation step to other 

processes. In the work of Veroef et al. (2008) the pervaporation step is calculated in visual basic and 

connected with AspenPlus
©
. However the system cannot be fully described yet. The challenge to accept 

pervaporation in industry is connected to the process understanding and process modelling. Depending on 

the application different components as well as the membrane itself has to be investigated and therefore 

further investigation in modelling has to be done. 

2. Material and Methods 

With the help of a design of experiment the influence of feed temperature, feed concentration, flow rate 

and vacuum pressure were investigated. A trial of twenty experiments was defined. In Table 1 set process 

parameters are listed. The experiments were carried out on a lab scale pervaporation setup. Further 

detailed informations can be found in the earlier work of Rom et al. (2013). 

Model solutions were prepared with 96 % Merck butanol and distilled water. Three different PDMS 

[Polydimethylsiloxan] membranes are investigated and with every membrane the defined trial of 20 

experiments was carried out. 

Transmembrane component flux Ji in [kg/m²h] was calculated and is described as the mass flow of 

component i as mi passing the membrane divided by the membrane area A and the experimental time t 

according to Eq(2) 

 (2) 

The selectivity of the process is described as the ratio of the separation facto of the single components, as 

ist is described in Eq(3) 

 (3) 

Combining Eq(1) and Eq(2) and transferring the transmembrane flux to a molar basis with Mi as molar 

mass gives the equation for the permeance of one component according to Eq(4) 

 (4) 

A set of 15 permeances, calculated from Eq(4) as a function of feed temperature T, feed concentration c, 

flow rate V and vacuum pressure p were regressed with multiple linear regression in the mathematical 

software programme R. The function used considers no interaction between investigated variables 

according to Eq.(5) using linear relations 

 (5) 



 
129 

Table 1: process parameters during pervaporation experiments 

experiment temperature 

(°C) 

pressure 

(mbar) 

initial 

butanol 

concentration 

(w%) 

flow 

rate 

(L/h) 

1 55 4 0.5 200 

2 35 7 1 150 

3 25 10 0.5 200 

4 55 10 0.5 200 

5 25 4 1.5 200 

6 25 10 1.5 200 

7 25 4 1.5 100 

8 35 7 1 150 

9 25 4 0.5 200 

10 55 4 1.5 200 

11 55 10 1.5 200 

12 25 10 1.5 100 

13 55 10 1.5 100 

14 35 7 1 150 

15 55 10 0.5 100 

16 55 4 0.5 100 

17 35 7 1 150 

18 55 4 1.5 100 

19 25 4 0.5 100 

20 25 10 0.5 100 

 

with A, B, C, D and E as regressed coefficients for each component and each investigated membrane. 

Since calculated permeances show no interaction between influences in the investigated range a 

univariate approach is tested. If special process conditions require multivariate data regression a more 

complex model has to be applied (Drljo et al., 2012). 

The regressed functions for the permeance of components i,j were implemented in the user-defined unit 

operation for pervaporation. The unit operation is based on simple mass transport and heat balances.  

Mass transport mechanism is calculated according to the solution diffusion model in Eq(1). The driving 

force as partial pressure difference is calculated on the basis of physical property models in AspenPlus
©
. 

Only the regressed function for the permeance describes the membrane and the diffusivity of the 

investigated components. As simplification heat transfer is calculated only considering heat of vaporization 

(Karlsson and Trägårdh, 1996). Since three different membranes were investigated three different unit-

operations were implemented in the simulation software. 

The importance of permeance, as intrinsic membrane coefficient, as well as molar based selectivities, is 

described in the work of Baker et al. (2010). Despite the fact that in this work the model is based on the 

membrane permeance, further investigations of the membranes are not discussed. Since in simulation 

flow sheets separation rate and stream properties are the focus, results will be discussed in terms of Ji and 

αji according to Eq(2) and Eq(3). 

3. Results 

First the validation of the regressed model is discussed. All six models show good significance. With this 

statement further simulation with all three membranes are performed. 

3.1 Validation of the model 

As it was described in section 1 and 2 the regressed model based on fifteen experiments should predict 

and calculate validation points. A common way to show the reliability of the regressed model is to compare 

experimental validation points with the calculated results of the model. To validate the significance of the 

model a test validation set of five additional experiments was used. Figure 1 compares the calculated 

permeances by the model (PMOD) with the experimental investigated permeances (Pexp) butanol and 



 
130 

 
water for each membrane. As it can be seen the points lie close to the y=x line, which means zero 

deviation. Squared correlation coefficient for the butanol permeance models lie between R²=0.743 and 

R²=0.939.  

The water permeance models show similar significance, with R² between 0.75 and 0.948.Validation of the 

models for PDMS membrane 1 with both R² over 0.9 shows the best significance, which yields in very 

good simulation results during latter calculation in AspenPlus©. The results show, that further improvement 

in the model and a wider value range should be aspired. However all six models show good significance 

based on a minimal amount of 15 experiments. 

Figure 2: Predicted permeances by the regression model PMOD, versus permeance calculated from 

experiments PEXP: a) PDMS 1, b) PDMS 2, c) PDMS 3; butanol (triangle) and water (rhombus) 

3.2 Flux and selectivity 

Implementation of the user-defined unit operation in the simulation software offers the opportunity to 

compare membrane process parameters like transmembrane component flux and selectivity. In Figure 2 

comparison of the experimental calculated values as well as the simulated values are plotted. As it can be 

seen all three unit operations simulate the membrane separation step with good significance, keeping in 

mind the aim as a first estimation in simulation. 

Special distribution of the validation set can be recognized in Figure 2. Since the DoE allows only a 

variation of special parameters, for the validation set experiments with corner points like high/ low 

concentration or high/low pressure were chosen. In the simulation run these corner points can be 

simulated and compared with the results in the experiments. 

According to the significance of the model membrane 3 with the lowest R² values shows highest deviations 

at high concentration and high temperature. All three membranes show higher deviations as the 

transmembrane butanol flux increases. This can be the reason due to measurement problems at higher 

transmembrane fluxes in the laboratory. A bigger modelling and validation set raises the significance of the 

regressed models. Additionally the regression model with only linear considerations might not fit perfectly. 

Nonlinear interactions at high temperature and high concentration could be considered in multivariate data 

a) 

 

 

 
b) 

 

 

 
c) 

 

 

 



 
131 

analysis. Another reason might be based in the developed unit-operation itself. Since the used unit 

operation is based on a discrete cross-flow model, further development to a rigorous state might be 

preferable. All three membranes show the same influence on transmembrane butanol flux as it increases 

with higher butanol concentration in feed as well as higher temperature. Highest selectivity was observed 

using PDMS 3 with the lowest transmembrane flux. 

Figure 2: Transmembrane butanol flux on the right and selectivity on the left a) PDMS 1, b) PDMS 2, c) 

PDMS 3; full rhombus: simulated data with process settings of the validation set, white rhombus: 

calculated data from experiments of the validation set 

4. Conclusion 

A user-defined unit operation on AspenPlus
©
 platform was investigated based on experimental results. 

Hybrid design of pervaporation and distillation offer great potential in energy savings and therefore 

simulation of this separation step is desirable. 

a) 

 

 

 
b) 

 

 

 
c) 

 

 

 



 
132 

 
With the help of design of experiment minimal amount of process parameters bring great output. By 

calculating the permeance at experimental conditions, a model for each component and each membrane 

was regressed. The applied user-defined unit operation is based on the sophisticated solution diffusion 

model for pervaporation processes from the work of Wijmans and Baker (1995). Validation of the 

regressed models shows good reliance and significance of the models is verified. Implementation of the 

user-defined unit operation in the simulation software and calculating membrane parameters like 

transmembrane flux and selectivity offer the opportunity to vary streams and connect the pervaporation 

step to other processes like distillation. Using simple mass and energy balances resulted in unit-operations 

generating acceptable data for the first approach. With a simple multiple linear regression different 

membranes can be simulated in the pervaporation step with good significance. In the next steps the 

discrete simulation model needs further development to a rigorous model. Also greater experimental data 

sets can offer better simulation results. 

References 

Baker R.W., Wijmans J., Huang Y., 2010, Permeability, permeance and selectivity: A preferred way of 

reporting pervaporation performance data, Journal of Membrane Science, 348, 346-352, DOI: 

10.1016/j.memsci.2009.11.022 

Drljo A., Liebmann B., Wukovits W., Friedl A., 2012, Predicting Minimum Energy Conditions for a 

Distillation Column by Design of Experiments and Process Simulation, Chemical Engineering 

Transactions, 29, 325 – 330, DOI: 10.3303/CET1229055 

Karlsson H.O., Trägårdh G., 1996, Heat transfer in pervaporation, Journal of Membrane Science, 119, 

295-306, DOI: 10.1016/0376-7388(96)00150-0 

Lipnizki F., Field R.W., Ten P.-K., 1999, Pervaporation-based hybrid process: a review of process design, 

applications and economics, Journal of Membrane Science, 153, 183-210, DOI: 10.1016/S0376-

7388(98)00253-1 

Marriott J.I., Sørensen E., Bogle I.D.L., Detailed mathematical modelling of membrane modules, 

Computers & Chemical Engineering, 2001, 25, 693-700, DOI: 10.1016/S0098-1354(01)00670-6 

Rom A., Esteve Gimeno D., Friedl A., 2013, Organophilic Pervaporation of Butanol from an Aqueous 

Solution with POMS, Chemical Engineering Transactions, 35, 1315 – 1320, DOI: 

10.3303/CET1335219 

Schiffmann P., Repke J.-U., 2012, Development of a Modeling Tool for the Systematic Design of 

Membrane Modules for Pervaporation, CIT, 84, 1997–2004. 

Shao P., Huang R., 2007, Polymeric membrane pervaporation, Journal of Membrane Science, 287, 162-

179, DOI: 10.1016/j.memsci.2006.10.043 

Wijmans J., Baker R., 1995, The solution-diffusion model: a review, Journal of Membrane Science, 107, 1-

21, DOI: 10.1016/0376-7388(95)00102-I 

Vane L. M., 2005, A review of pervaporation for product recovery from biomass fermentation processes, 

Journal of Chemical Technology and Biotechnology, 80, 603-629, DOI: 10.1002/jctb.1265 

Verhoef A., Degrève J., Huybrechs B., van Veen H., Pex P., Van der Bruggen B., 2008, Simulation of a 

hybrid pervaporation–distillation process, Computers & Chemical Engineering, 32, 1135-1146, DOI: 

10.1016/j.compchemeng.2007.04.014