Simulation-optimization is applied to determine nearly optimal process designs in column sequencing and stacking problems using a simulated annealing algorithm (SAA) in the client (MATLAB) and a single distillation column in the server (Aspen Plus). Each column in every sequence is optimized separately and the total cost of each sequence is calculated. This method benefits both from the rigor of column modeling in a process simulator and the flexibility of implementing sequential procedures and derivative-free optimization in a procedural programming language. Using this method, a single column can be optimized within six minutes of computer time. Furthermore, when stacking rules and available utilities are specified, a nearly optimal heat-integrated distillation column sequence can be designed automatically. Results are illustrated using two case studies of column sequencing problems. Finally, two plantwide processes combined with column sequencing and stacking were proposed. The outputs of reaction section will determine the inputs of separation section. Some specifications are defined to govern the inputs and outputs between two sections. The results demonstrate that optimization from numerous design variables (13 and 11 variables) in plantwide process is feasible.