This study builds upon the research conducted by Tam (2022) and aims to investigate the seismic behavior of built-up box columns in a BRB frame using finite element analysis. Two different sizes of sandwiched buckling-restrained braces (SBRB) were initially modeled using two different methods in ABAQUS. Subsequently, a complete BRB frame model was developed based on the experiments conducted by Tam (2022), and a detailed comparison was made between the experimental and simulation results. Based on this foundation, a total of three sets of BRB frame models were established, consisting of six steel column cross sections, to explore the seismic behavior of both the columns and the frame concerning the width-to-thickness ratio (b/t) and initial axial load ratio (P/P_y). The study findings indicate that in specimens with larger aspect ratios, the bottom column buckling is more severe, occurring earlier and significantly affecting the overall behavior of the frame. In columns with higher initial axial loads, the severity of bottom column buckling increases, leading to larger axial shortening of the columns and causing asymmetric behavior in the frame. The results demonstrate that for box steel columns subjected to high axial forces, when the aspect ratio was set to the average value between the limits for highly ductile members and moderately ductile members, the maximum story drift angle capacity could achieve 0.04 rad. However, when the aspect ratio precisely falls within the limit for moderately ductile members, the maximum story drift angle capacity is only 0.015 rad. As for box steel columns subjected to intermediate axial forces, the maximum lateral displacement angle capacity reaches 0.03 rad. It can be observed that the overturning effect of the frame leads to asymmetric responses of the components. When the frame goes toward the direction which causes axial force smaller than the initial axial force, the behavior remains satisfactory, regardless of the aspect ratio being far below the limit for moderately ductile members.