The braces in Concentrically Braced Frame disspate energy by yielding in tension and buckling in compression. It is common that the braces rupture due to low cycle fatigue. To improve the energy dissipation capacity of braces, we reinforced the typical braces by reducing flange width and increasing web or flange areas to widen the energy dissipation zones in braces. The objectives of this approach are to increase the energy dissipation area and reduce the strain range which is critical to fatigue life. In this research, we use Finite Elements Analysis to compare different reinforcement options. The discussed parameters include the von Mises stress distribution and plastic equivalent strain (PEEQ). Two series of reinforcement options are CU series, where we cut the flanges and reinforce the web, and CP series where we reinforce the flanges. The results of FEM analysis show that in CU series buckling concentrates in middle length while tension yielding occurs outside the middle length. However, in some cases PEEQ is increased by 20% leading to large plastic strain. For CP series which is designed refering to design pholisphy of cover plate in FEMA-351, when the length of reinforcement is 43% of brace length, the tension strain can be dispersed to wider areas and PEEQ is decreased by10%. By selecting appropriate design details, both CU and CP series are able to improve the energy dissipation behavior of typical braces.