Special Report                                                                   Special Report



 Making profi ts fl ow: Demystifying fl ow reactors  depends on more factors than just the   Scaling-up a reaction in Batch Reactor
       kinetic rate constant (k)  and  concen-
                                                                             When scaling up  a batch reaction,
       tration. Some reactions are limited by                             the reaction time often increases  due
 Reactions performed in fl ow reac-  DARSHAN CHHEDA  mass-transfer  and heat-transfer consi-  to limitations  in heat and mass trans-
 tors are always faster  compared   Tonight’s Show:  Process Engineer – R&D Flow Chemistry  derations: mass-transfer controlled,   fer, rather than changes in intrinsic
 “to batch reactors!” This statement   Magic of Flow Reactors  Amar Equipment Pvt. Ltd.  heat-transfer controlled, reaction   kinetics.  The  intrinsic kinetics should
 astounds  every rational chemist and   Email: darshan.chheda@amarequip.com  controlled,  or more commonly, by   remain constant if conditions are main-
 chemical engineer.  a combination of these factors.                      tained (same temperature and pres-
 DR. VISHWANATH H. DALVI                                                  sure). While the reaction rate constant
 It  is particularly astonishing  when   Advisor – Flow Technology  When we describe a reaction as   remains constant (ideally),  changes
 people make such claims. The design   Amar Equipment Pvt. Ltd.  kinetically  controlled, it means the   occur due to reactor geometry and
 Faculty, Institute of Chemical Technology
 equation for a batch reactor is identical   Mumbai  reaction  rate depends on the intrinsic   volume increases, particularly  in the
 to that of a plug fl ow reactor. In theory,   Email: vishwanath.dalvi@amarequip.com  reaction kinetics-the molecular reaction   decrease of heat transfer area per unit
 if a reaction achieves a certain conver-  pathway, activation  energy, tempera-  volume and mixing effi ciency.
 sion after ‘X’ minutes of reaction time,   DR. CHANDRAKANTH GADIPELLY  ture, and    pressure.  The reaction rate  then to the solid catalyst phase limits the
 it should achieve the same conversion   Principal  Research Scientist – R&D   is sensitive to the reaction temperature  reaction rate).  Heat transfer limitations
 Flow Chemistry
 after  ‘X’ minutes of residence time,   Amar Equipment Pvt. Ltd.  (and pressure to some extent in highly   Larger reactors suffer from lower
 provided the temperature and pressure   Email: chandrakanth.gadipelly@amarequip.com  compressible fl uids like gases).  In heat-transfer limited  reactions,  surface area-to-volume ratios. This cre-
 of the reaction remain constant, i.e., k,   This raises several questions: Why   the rate is constrained by how quickly  ates  heat transfer limitations  because
 the reaction rate constant, remains the  make  such a claim?  Do reactions   pared to batch reactors? If the tempera-  A mass-transfer controlled reaction  heat can be removed from or added to  less surface area is available to remove
 same. (Fig.1)  actually run faster in fl ow reactors com-  ture and  pressure  remain unchanged,   means the reaction rate is limited by how  the reaction system. (Note:  This is a  or add heat  relative  to the reaction
 what causes this acceleration?  What   quickly the reactants/reagents/products  user-imposed limitation;  the reaction  volume.  The resulting temperature
 dC  drives  the  transition  to  fl ow  reactors?
 Design Equation for a batch reactor:   A  = –kC A Design Equation for a Plug-fl ow reactor:   dC A  n  can be transported to or from the reaction  is  deliberately throttled, for  example,  gradients can cause certain parts to be at
 n
 dt  =  –kC A  Do reactions inherently perform better
 dT    site. This typically occurs at phase bounda-  by restricting the fl ow of one or more  non-optimal temperatures for the reac-
 Assuming fi rst-order kinetics: n = 1  Assuming fi rst-order kinetics: n = 1  in fl ow reactors than in batch reactors?  ries, such as gas-liquid, liquid-liquid, or  reactants). This typically occurs in highly  tion. This can slow reactions in cooler
       solid-liquid interfaces. While the reaction  exothermic or  endothermic reactions.  regions and lead to inconsistent product
 Concentration profi le for A (wrt time):  Concentration profi le for A (wrt residence time/length):  The answers to these questions are   proceeds rapidly when reactants reach the  Insuffi cient heat transfer rates can lead  quality, such as charring at hot spots.
 C (t) = C e  –k(T)t  –  more complex than one might expect.   reaction site, the rate-determining factor is  to thermal runaways in exothermic
 A  A,O  C (T) = C e  k(T)T  The determining factor is the regime
 A
 A,O
 Rearranging for time:  Rearranging for residence time:  under which a reaction operates (Fig. 2).   the speed at which they arrive there. This  reactions  or inadequate  conversion in
       behaviour is common in heterogeneous  endothermic reactions (e.g., nitrations or
 t = –1  In  C (t)  –1  C (T)  Without delving into excessive detail,   reactions (e.g.,  hydrogenation, where  oxidations where localized overheating
 A
 A
 k(T)  C A,O  T =  k(T) In  C
 A, O  it is important  to understand that  not   the transfer of hydrogen gas into the  could accelerate the reaction uncontrol-
 all  reactions are limited  by the  rate   liquid phase containing the substrate and  lably).
 Fig. 1: Design equations for Batch and Plug Flow reactors  of  intrinsic reaction.  The conversion
                                                         Hand holes for
 Kinetically Controlled Regime  Mass Transfer Controlled Regime  Heat Transfer Controlled Regime  charging reactor
 UA∆T  LMTD
 r =         m  r = k a (C ,    - C    )  r =   ∆UH  Rxn
 k C A
 A, Surface
 A Bulk
 L
 Where,  Where,                                              Connection for
 k is the kinetic rate constant;   k  is the mass transfer coeffi cient;  Where,  heating or
 L
 m is order of the reaction  a is the interfacial area per unit volume;  U is the overall heat transfer coeffi cient;  cooling jacket  “See! Scale-up is so easy”
 A is the heat transfer area;
 C A, Bulk  is the concentration of reactant A in the  ∆T  is the log mean temperature difference;  Mass transfer limitations
 bulk phase;  ∆H LMTD  is the enthalpy of the reaction                       Larger reactors typically  cannot
 C A, Surface  is the concentration of reactant A on    Rxn   Agitator    achieve the same level of mixing as a
 the reaction site  The reaction is deliberately throttled (slowed   (Lab-scale : Round Bottom Flask)
 down) to allow enough time for heat transfer                             round-bottom  fl ask,  where  mixing  is
 surfaces to remove heat                                                  faster and more thorough. Poor mixing
                                      (Pilot-scale: Stirred-Tank Reactor)  in large-scale reactors leads to concen-
                                                                          tration gradients,  resulting in slower
 Fig. 2: Rate equations for different regimes                             reaction rates in regions where reactants/

 178  Chemical Weekly  February 4, 2025  Chemical Weekly  February 4, 2025                             179


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