Batch reactive distillation (BRD) is an integrated process which combines the advantages of reactive distillation and the flexibility of batch processes. Semi-batch reactive extractive distillation (SBRED) is a design alternative for BRD in which one reactant is continuously fed into the column during the batch. Esterifications of low molecular weight alcohols (methanol-amyl alcohol) with acetic acid have been studied as model systems for the design and optimization of BRD and SBRED processes. For n-butyl acetate and amyl acetate system, the lowest-boiling point (unstable node) is a ternary heterogeneous azeotrope located in a two-liquid region. The phase split naturally provides high purity of water (99.5%) in aqueous phase. A BRD process is feasible in these two systems because water can be removed from the reflux drum (decanter) at the top of the column. For isopropyl acetate system, the lowest-boiling point (unstable node) is also a ternary heterogeneous azeotrope located in a two-liquid region. However, the aqueous phase only provides 95% of water. It showed that SBRED can improve the production efficiency. The concentration of isopropyl alcohol in the distillate can be efficiently reduced by feeding acetic acid as an entrainer into the column continuously so that the distillate composition is closer to the water-acetate edge. High purity of water can be collected in aqueous phase and binary mixture of water and acetate can be collected in organic phase. Then a non reactive inverted batch distillation column with a decanter is used to withdraw high purity of acetate from the organic phase. For ethyl acetate system, the lowest-boiling point (unstable node) is a ternary azeotrope which is not located in a two-liquid region. Therefore, unlike previous systems, BRD with a decanter is not feasible. In our work, we consider the application of SBRED similar to isopropyl acetate system. For methyl acetate system, the lowest-boiling point (unstable node) is a binary azeotrope (of methanol and methyl acetate) which is not located in a two-liquid region. The SBRED system is preferable because methanol is much more volatile than acetic acid. The concentration of methanol in the distillate can be efficiently reduced by using a side feed entrainer. Eventually high purity methanol (97.5%) can be achieved within a single column. In this thesis, the esterifications of acetic acid with three different alcohols (methanol, ethanol, isopropanol) using SBRED are studied. All three systems use acetic acid as a side feed entrainer to drag the alcohol down, thereby preventing the alcohol from going up as a distillate. For ethyl acetate and isopropyl acetate system, the organic phase product needs to be further purified by using a nonreactive inverted batch distillation column. For methyl acetate system, we study the preliminary optimization to show that how we adjust the parameters to improve the dynamic process while the parameters are highly interdependent with each other.