The differences of tension-tension fatigue and tensile creep characters of 2D-C/SiC and 3D-C/SiC composites have been scrutinized to meet the engineering needs. Experiments of tension-tension fatigue and tensile creep are carried out under vacuum high temperature condition. All of the high temperature fatigue curves are flat; the fatigue curves of the 2D-C/SiC are flatter and even parallel to the horizontal axis. While the tension-tension fatigue limit of the 3D-C/SiC is higher than that of the 2D-C/SiC, the fiber pullout length of the fatigue fracture surface of the 3D-C/SiC is longer than that of the 2D-C/SiC, and fracture morphology of the 3D-C/SiC is rougher, and pullout length of the fiber tows is longer. At the same time the 3D-C/SiC has higher tensile creep resistance. The tensile curve and the tensile creep curve of both materials consist of a series of flat step. These phenomena can be explained by the non-continuity of the damage. The differences of tension-tension fatigue and tensile creep characters of 2D-C / SiC and 3D-C / SiC composites have been scrutinized to meet the engineering needs. Experiments of tension-tension fatigue and tensile creep are carried out under vacuum high temperature conditions All of the high temperature fatigue curves are flat; the fatigue curves of the 2D-C / SiC are flatter and even parallel to the horizontal axis. While the tension-tension fatigue limit of the 3D-C / SiC is higher than that of the 2D-C / SiC, the fiber pullout length of the fatigue fracture surface of the 3D-C / SiC is longer than that of the 2D-C / SiC, and fracture morphology of the 3D-C / SiC is rougher, and pullout length of the fiber tows is longer. At the same time the 3D-C / SiC has higher tensile creep resistance. The phenomena can be explained by the non-continuity of the damage.