China Fusion Engineering Test Reactor (CFETR) is an ITER-like superconducting tokamak reactor. Its major radius is 5.7m, minor radius is 1.6m and elongation ratio is 1.8. Its mission is to achieve 50–200MW of fusion power, 30–50% of duty time factor, and tritium breeding ratio not less than 1.2 to ensure the self-sufficiency. As one of the breeding blanket candidates for CFETR, a water cooled breeder blanket with superheated steam is proposed and its conceptual design is being carried out. In this design, sub-cooling water at 265°C under the pressure of 7MPa is fed into cooling plates in breeding zone and is heated up to 285°C with saturated steam generated, and then this steam is pre-superheated up to 310°C in first wall (FW), final, the pre-superheated steam coming from several blankets is fed into the other one blanket to superheat again up to 517°C. Due to low density of superheated steam, it has negligible impact on neutron absorption by coolant in FW so that the high energy neutrons entering into breeder zone moderated by water in cooling plate help enhance tritium breeding by 6 Li(n,α)T reaction. Li 2 TiO 3 pebbles and Be 12 Ti pebbles are chosen as tritium breeder and neutron multiplier respectively, because Li 2 TiO 3 and Be 12 Ti are expected to have better chemical stability and compatibility with water in high temperature. However, Be 12 Ti may lead to a reduction in tritium breeding ratio (TBR). Furthermore, a spot of sintered Be plate is used to improve neutron multiplying capacity in a multi-layer structure. As one alternative option, in spite of lower TBR, Pb is taken into account to replace Be plate in viewpoint of safety. In this contribution, study on neutronics and thermal design for a water cooled breeder blanket with superheated steam is reported.