source: branches/new_gui/my_folders/fogler/chap2/series_reactors.mso @ 931

#*-------------------------------------------------------------------
* EMSO Model Library (EML) Copyright (C) 2004 - 2007 ALSOC.
*
* This LIBRARY is free software; you can distribute it and/or modify
* it under the therms of the ALSOC FREE LICENSE as available at
* http://www.enq.ufrgs.br/alsoc.
*
* EMSO Copyright (C) 2004 - 2007 ALSOC, original code
* from http://www.rps.eng.br Copyright (C) 2002-2004.
* All rights reserved.
*
* EMSO is distributed under the therms of the ALSOC LICENSE as
* available at http://www.enq.ufrgs.br/alsoc.
*
*---------------------------------------------------------------------
* Series of CSTR and PFR
*----------------------------------------------------------------------
* Solved problem from Fogler (1999)
* Problem number: 2-2 at 2-7
* Page: 38-49 (Brazilian edition, 2002)
*----------------------------------------------------------------------
*
*   Description:
*      Sample to comparative between volumes to specific outlet molar 
*       conversion of CSTR and PFR by means of several different 
*       configurations
*
*   Assumptions:
*       * steady-state
*       * isotermic and isobaric system
*       * gaseous phase
*
*       Specify:
*               * the inlet stream (F,X)
*               * the expression of rate of reaction
*       * the initial volume
*               * the outlet conversion
*
*   Configurations:
*       * only one CSTR
*       * only one PFR
*       * 2 CSTRs in series
*       * 2 PFRs in series
*       * one PFR followed for one CSTR
*       * one CSTR followed for one PFR
*
*----------------------------------------------------------------------
* Author: Rodolfo Rodrigues and Argimiro R. Secchi
* $Id: series_reactors.mso 574 2008-07-25 14:18:50Z rafael $
*--------------------------------------------------------------------*#

using "types";


#*---------------------------------------------------------------------
* Estimation of rate of reaction
*--------------------------------------------------------------------*#

FlowSheet rate
        PARAMETERS
        a1              as Real                 (Brief="Parameter to estimate", Default=0.01);
        a2              as Real                 (Brief="Parameter to estimate", Default=0.01);
        a3              as Real                 (Brief="Parameter to estimate", Default=0.01);
        a4              as Real                 (Brief="Parameter to estimate", Default=0.01);

        VARIABLES
        r               as reaction_mol (Brief="Rate of reaction", DisplayUnit='mol/m^3/s');
        X               as fraction             (Brief="Molar conversion", Unit='mol/mol');
        
        EQUATIONS
        "Rate of reaction" # Attributed expression
        (-r) = (a4*X^3 + a3*X^2 + a2*X + a1)*'mol/l/s';
        
        SPECIFY
        X = 0.5;

        OPTIONS
        Dynamic = false;
end

Estimation rate_of_reaction as rate
        ESTIMATE
        # PAR   START   LOWER  UPPER
        a1              0.01    -1              1;
        a2              0.01    -1              1;
        a3              -0.01   -1              1;
        a4              0.01    -1              1;

        EXPERIMENTS
        # FILE                WEIGTH
        "raw_data.dat"          1; # Table 2-1 (Fogler,1999)

        OPTIONS
        Dynamic = false;
        NLPSolver(File = "ipopt_emso", 
                ObjTol = 1e-8
        );
end


#*---------------------------------------------------------------------
* Model of a simple stream
*--------------------------------------------------------------------*#

Model simple_stream
        VARIABLES
        F as flow_mol   (Brief="Molar flow", DisplayUnit='mol/s');
        X as fraction   (Brief="Molar conversion");
end

Model reactor_source
        ATTRIBUTES
        Pallete = true;
        Brief   = "Simple inlet stream";
        Icon    = "icon/inlet";
        
        VARIABLES
out Outlet      as simple_stream        (Brief="Outlet stream", PosX=1, PosY=0.5);
end

Model reactor_sink
        ATTRIBUTES
        Pallete = true;
        Brief   = "Simple outlet stream";
        Icon    = "icon/outlet";
        
        VARIABLES
in      Inlet   as simple_stream        (Brief="Inlet stream", PosX=0, PosY=0.5);
end


#*---------------------------------------------------------------------
* Model of a steady-state, isotermic, and isobaric CSTR
*--------------------------------------------------------------------*#

Model simple_cstr
        ATTRIBUTES
        Pallete = true;
        Brief   = "Simple model of a steady-state CSTR";
        Icon    = "icon/simple_cstr";
        
        PARAMETERS
        NT              as Integer              (Brief="Number of terms of reaction rate expression", Default=4);
        a(NT)   as reaction_mol (Brief="Parameter of reaction rate expression", DisplayUnit='mol/l/s');
        
        VARIABLES
in      Inlet   as simple_stream(Brief="Inlet stream", Symbol="_{in}", PosX=0, PosY=0);
out     Outlet  as simple_stream(Brief="Outlet stream", Symbol="_{out}", PosX=1, PosY=1);
        r               as reaction_mol (Brief="Rate of reaction", DisplayUnit='mol/l/s');
        V       as volume               (Brief="Volume", DisplayUnit='l', Upper=2e3);
        
        SET
        a = [0.00526629, 0.00133545, -0.0153342, 0.00921664]*'mol/l/s'; # Estimated
        
        EQUATIONS
        "Component molar balance"
        Inlet.F*(Outlet.X - Inlet.X) = (-r)*V;
        
        "Molar flow"
        Outlet.F = Inlet.F;

        "Rate of reaction"
        (-r) = sum(a*Outlet.X^[0:(NT-1)]);
end


#*---------------------------------------------------------------------
* Model of a steady-state, isotermic, and isobaric PFR
*--------------------------------------------------------------------*#

Model simple_pfr        
        PARAMETERS
        NT              as Integer              (Brief="Number of terms of reaction rate expression", Default=4);
        a(NT)   as reaction_mol (Brief="Parameter of reaction rate expression", DisplayUnit='mol/l/s');
        
        VARIABLES
in      Inlet   as simple_stream(Brief="Inlet stream", Symbol="_{in}");
out     Outlet  as simple_stream(Brief="Outlet stream", Symbol="_{out}");
        V       as volume               (Brief="Volume", DisplayUnit='l', Upper=2e3);
        r               as reaction_mol (Brief="Rate of reaction", DisplayUnit='mol/l/s');
        
        SET
        a = [0.00526629, 0.00133545, -0.0153342, 0.00921664]*'mol/l/s'; # Estimated
        
        EQUATIONS
        "Molar balance"
        diff(V) = Inlet.F/(-r)/'s';

        "Change time in X"
        Outlet.X = time/'s';
        
        "Molar flow"
        Outlet.F = Inlet.F;

        "Rate of reaction"
        (-r) = sum(a*Outlet.X^[0:(NT-1)]);

        INITIAL
        "Reactor volume"
        V = 0.0*'l';
end


#*---------------------------------------------------------------------
* Model of a discreted steady-state, isotermic, and isobaric PFR
*--------------------------------------------------------------------*#

Model simple_pfr_d
        ATTRIBUTES
        Pallete = true;
        Brief   = "Simple model of a steady-state PFR";
        Icon    = "icon/simple_pfr";
        
        PARAMETERS
        N       as Integer              (Brief="Number of discrete points", Lower=2, Default=150);
        NT              as Integer              (Brief="Number of terms of reaction rate expression", Default=4);
        a(NT)   as reaction_mol (Brief="Parameter of reaction rate expression",DisplayUnit='mol/l/s');
        
        VARIABLES
in      Inlet   as simple_stream(Brief="Inlet stream", Symbol="_{in}", PosX=0, PosY=0.5);
out     Outlet  as simple_stream(Brief="Outlet stream", Symbol="_{out}", PosX=1, PosY=0.5);
        V(N)    as volume           (Brief="Volume", DisplayUnit='l', Upper=2e3);
        r(N)    as reaction_mol (Brief="Rate of reaction", DisplayUnit='mol/l/s');
        X(N)    as fraction             (Brief="Molar conversion");
        dx      as fraction     (Brief="Conversion increment");
        
        SET
        a = [0.00526629, 0.00133545, -0.0153342, 0.00921664]*'mol/l/s'; # Estimated
        
        EQUATIONS
        
        "Outlet molar conversion"
        Outlet.X = X(N);
        
        "Discrete interval"
        dx = (Outlet.X - Inlet.X)/(N-1);

        "Initial reactor volume"
        V(1) = 0.0*'l';

        for i in [2:N] do
        "Molar balance"
           V(i) - V(i-1) = -0.5*Inlet.F*dx*(1/r(i-1) + 1/r(i)); # second order
#          V(i) - V(i-1) = Inlet.F*dx/(-r(i));                                  # first order
        "Discrete molar conversion"
           X(i-1) = X(i) - dx;
    end
        
        "Molar flow"
        Outlet.F = Inlet.F;
        
        for i in [1:N] do
        "Rate of reaction"
                (-r(i)) = sum(a*X(i)^[0:(NT-1)]);
        end
end


#*---------------------------------------------------------------------
* Example 2-2: Scale-up an isotermic CSTR in gaseous phase
*--------------------------------------------------------------------*#

FlowSheet cstr_sample
        PARAMETERS
        R       as Real                 (Brief="Universal gas constant", Unit='atm*l/mol/K', Default=0.082);
        T       as temperature  (Brief="Temperatura in the reactor");
        P       as pressure             (Brief="Pressure in the reactor");
        zin     as fraction             (Brief="Inlet molar fraction");
        v0  as flow_vol         (Brief="Volumetric flow");
        
        VARIABLES
        Vt      as volume               (Brief="Total reactor volume", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_cstr;

        CONNECTIONS
        Inlet   to R1.Inlet;
        
        EQUATIONS
        "Inlet molar flow"
        Inlet.F = (zin*P/(R*T))*v0;
        
        "Total reactor volume"
        Vt = R1.V;
        
        SET
        v0  = 6.0*'l/s';
        T       = 422.2*'K';
        P       = 10*'atm';
        zin     = 0.5;
        
        SPECIFY
        Inlet.X = 0.0;
        R1.Outlet.X = 0.8;
        
        OPTIONS
        Dynamic = false;
end


#*---------------------------------------------------------------------
* Example 2-3: Scale-up an isotermic PFR in gaseous phase
*--------------------------------------------------------------------*#

FlowSheet pfr_sample
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_pfr;
        
        CONNECTIONS
        Inlet   to R1.Inlet;
        
        SPECIFY
        Inlet.F = 0.866541*'mol/s';
        Inlet.X = 0.0;
        
        OPTIONS
        TimeStep = 0.008;
        TimeEnd = 0.8;
end


#*---------------------------------------------------------------------
* Example 2-3: (discreted)
*--------------------------------------------------------------------*#

FlowSheet pfr_d_sample
        VARIABLES
        Vt              as volume       (Brief="Total reactor volume", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_pfr_d;

        CONNECTIONS
        Inlet   to R1.Inlet;
        
        EQUATIONS
        "Total reactor volume"
        Vt = R1.V(R1.N);

        SET
        R1.N = 150;

        SPECIFY
        Inlet.F = 0.866541*'mol/s';
        Inlet.X = 0.0;

        R1.Outlet.X     = 0.8;
        
        OPTIONS
        Dynamic = false;
end


#*---------------------------------------------------------------------
* Example 2-4: Comparing volumes between one CSTR and one PFR
*--------------------------------------------------------------------*#

FlowSheet comparative
        VARIABLES
        V_cstr  as volume       (Brief="CSTR volume", DisplayUnit='l');
        V_pfr   as volume       (Brief="PFR volume", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        CSTR    as simple_cstr;
        PFR             as simple_pfr_d;

        CONNECTIONS
        Inlet   to CSTR.Inlet;
        Inlet   to PFR.Inlet;
        
        EQUATIONS
        "CSTR volume"
        V_cstr = CSTR.V;
        
        "PFR volume"
        V_pfr = PFR.V(PFR.N);
        
        SET
        PFR.N = 100;

        SPECIFY
        Inlet.F = 5.0*'mol/s';
        Inlet.X = 0.0;

        CSTR.Outlet.X = 0.6;
        PFR.Outlet.X = 0.6;
        
        OPTIONS
        Dynamic = false;
end


#*---------------------------------------------------------------------
* Example 2-5: two CSTRs in serie
*--------------------------------------------------------------------*#

FlowSheet cstr_cstr
        VARIABLES
        V1              as volume       (Brief="1st reactor volume", DisplayUnit='l');
        V2              as volume       (Brief="2nd reactor volume", DisplayUnit='l');
        Vt              as volume       (Brief="Total reactor volumes", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_cstr;
        R2              as simple_cstr;

        CONNECTIONS
        Inlet           to R1.Inlet;
        R1.Outlet       to R2.Inlet;
        
        EQUATIONS
        "1st volume reactor"
        V1 = R1.V;
        "1st volume reactor"
        V2 = R2.V;
        "Total volume of reactors"
        Vt = V1 + V2;
        
        SPECIFY
        Inlet.F = 0.866541*'mol/s';
        Inlet.X = 0.0;
        
        R1.Outlet.X = 0.4;
        R2.Outlet.X = 0.8;
        
        OPTIONS
        Dynamic = false;
end


#*---------------------------------------------------------------------
* Example 2-6: two PFRs in series (discreted)
*--------------------------------------------------------------------*#

FlowSheet pfr_pfr
        VARIABLES
        V1              as volume       (Brief="1st reactor volume", DisplayUnit='l');
        V2              as volume       (Brief="2nd reactor volume", DisplayUnit='l');
        Vt              as volume       (Brief="Total reactor volumes", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_pfr_d;
        R2              as simple_pfr_d;

        CONNECTIONS
        Inlet           to      R1.Inlet;
        R1.Outlet       to      R2.Inlet;
        
        EQUATIONS
        "1st reactor volume"
        V1 = R1.V(R1.N);
        "1st reactor volume"
        V2 = R2.V(R2.N);
        "Total reactor volumes"
        Vt = V1 + V2;
        
        SPECIFY
        Inlet.F = 0.866541*'mol/s';
        Inlet.X = 0.0;
        
        R1.Outlet.X = 0.4;
        R2.Outlet.X = 0.8;
        
        OPTIONS
        Dynamic = false;
end


#*---------------------------------------------------------------------
* Example 2-7a: one PFR and one CSTR in series
*--------------------------------------------------------------------*#

FlowSheet pfr_cstr
        VARIABLES
        V1              as volume       (Brief="1st reactor volume", DisplayUnit='l');
        V2              as volume       (Brief="2nd reactor volume", DisplayUnit='l');
        Vt              as volume       (Brief="Total reactor volumes", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_pfr_d;
        R2              as simple_cstr;

        CONNECTIONS
        Inlet           to      R1.Inlet;
        R1.Outlet       to      R2.Inlet;
        
        EQUATIONS
        "1st reactor volume"
        V1 = R1.V(R1.N);
        "1st reactor volume"
        V2 = R2.V;
        "Total reactor volumes"
        Vt = V1 + V2;
        
        SET
        R1.N = 100;
        
        SPECIFY
        Inlet.F = 0.866541*'mol/s';
        Inlet.X = 0.0;
        
        R1.Outlet.X = 0.5;
        R2.Outlet.X = 0.8;
        
        OPTIONS
        Dynamic = false;
end


#*---------------------------------------------------------------------
* Example 2-7b: one CSTR and one PFR in series
*--------------------------------------------------------------------*#

FlowSheet cstr_pfr
        VARIABLES
        V1              as volume       (Brief="1st reactor volume", DisplayUnit='l');
        V2              as volume       (Brief="2nd reactor volume", DisplayUnit='l');
        Vt              as volume       (Brief="Total reactor volumes", DisplayUnit='l');
        
        DEVICES
        Inlet   as simple_stream;
        R1              as simple_cstr;
        R2              as simple_pfr_d;

        CONNECTIONS
        Inlet           to      R1.Inlet;
        R1.Outlet       to      R2.Inlet;
        
        EQUATIONS
        "1st reactor volume"
        V1 = R1.V;
        "1st reactor volume"
        V2 = R2.V(R2.N);
        "Total reactor volumes"
        Vt = V1 + V2;
        
        SET
        R2.N = 100;
        
        SPECIFY
        Inlet.F = 0.866541*'mol/s';
        Inlet.X = 0.0;
        
        R1.Outlet.X = 0.5;
        R2.Outlet.X = 0.8;
        
        OPTIONS
        Dynamic = false;
end