Semibatch reactor

Sometimes a particular reactant can go through parallel paths that yield two different products, only one of which is desired. Consider the simple example below:

A→U (desired product)
A→W (undesired product)

The rate expressions, considering the variability of the volume of reaction, are:

${\displaystyle V{\frac {dC_{A}}{dt}}+C_{V}{\frac {dV}{dt}}}$ = ${\displaystyle F_{A}}$ - ${\displaystyle k_{1}}$ ${\displaystyle C_{A}^{\alpha }}$

${\displaystyle V{\frac {dC_{U}}{dt}}+C_{V}{\frac {dV}{dt}}}$ = ${\displaystyle k_{1}}$ ${\displaystyle C_{A}^{\alpha }}$ - ${\displaystyle F_{U}}$

${\displaystyle V{\frac {dC_{W}}{dt}}+C_{W}{\frac {dV}{dt}}}$ = ${\displaystyle k_{2}}$ ${\displaystyle C_{A}^{\beta }}$ - ${\displaystyle F_{W}}$

Where ${\displaystyle F_{A}}$ is the molar rate of addition of the reactant A. Note that the presence of these addition terms, which could be negative in case of products removal (e.g. by fractional distillation) are the ones marking the difference of the semi batch reactor cases from the simpler batch cases.

For standard batch reactors (no addition terms) the selectivity of the desired product is defined as:

S = ${\displaystyle {\frac {d(VC_{U})}{d(VC_{W})}}}$ = ${\displaystyle {\frac {k_{1}}{k_{2}}}C_{A}^{\alpha -\beta }}$

S = ${\displaystyle {\frac {dC_{U}}{dC_{W}}}}$ = ${\displaystyle {\frac {k_{1}}{k_{2}}}C_{A}^{\alpha -\beta }}$ for constant volume (i.e. batch) reactions.

If ${\displaystyle \beta >\alpha }$, the concentration of the reactant should be kept at a low level in order to maximize selectivity. This can be accomplished using a semibatch reactor.

Exothermic reactions release heat, and ones that are highly exothermic can cause safety concerns. Semibatch reactors allow for slow addition of reactants in order to control the heat released and thus, temperature, in the reactor.

In order to minimize the reversibility of a reaction one must minimize the concentration of the product. This can be done in a semibatch reactor by using a purge stream to remove products and increase the net reaction rate by favoring the forward reaction.