Owing to the rising awareness of environment protection, automotive industry aims at cutting carbon dioxide emissions under the premise of the vehicle safety standards by utilizing the ultra high strength steels. However, the forming of the ultra high strength steels in room temperature will induce some problems such as the tendency to springback and fracture. In order to overcome these disadvantages, the hot stamping process has been developed. The tensile strength of hot stamped steels can exceed 1500MPa by transforming the ferritic-pearlitic microstructure to the high strength martensitic microstructure. With the development of high-strength steels, each country establishes higher and higher vehicle safety standards. The design of vehicle parts pursues not only high strength but also the ability to absorb impact energy. Thus, the tailored blanks are applied to meet the demands of the two key properties. The research uses the finite element analysis software LS-DYNA to establish the impact model for the B-pillar and the hat-shape part which has B-pillar’s characteristics. Applying the method of tailor welded blank (TWB), the tailored part possesses two materials in a single sheet. The part in the local regions with softer mechanical strength is made of alloy steel JSC 440W to improve the energy absorption characteristics while other regions are made of the quenchable boron steel 15B22 to achieve high strength. The analysis of the distribution of JSC 440W and 15B22 would compare with the traditional steels to quantify the benefits of tailor properties. As the result of the research, compared to the traditional steels with tensile strength 780 MPa and 980 MPa, the design of tailor welded blanks can save 13.80 % and 7.45 % in weight.