As stated in ACI 318-08, the steel fiber is allowed to be used as minimum shear reinforcement in RC structures. However, the climate in Taiwan is toride and humid with high saltinity in the air and the working load usually induce the cracks in the service life of concrete structure. For these reasons, the chloride ion may penetrate into the concrete easier, and therefore reduce the durability of the structures. Further, the steel fibers corrode and weaken the concrete sturctures. This study investigates the water-cemnt ratio and the addition of the steel fibers which influence the durability of the normal and high strength concrete with working stress cracks. The experiment was divided into three parts, including pre-cracking test, salt spray test, and flexural test. Pre-cracking test is to simulate the formation of flexureal cracks which are caused by working stress. Salt spray test is to simulate the corrosion situation of cracked beam under the salt environment for many years. Flexural test is to evaluate the residual mechanical behaviors and toughness of corroded beam. After these tests, the concrete around the cracks will be removed from beam and starts the chloride penetration test. According to the results of pre-cracking test, the crack width of the high strength concrete without steel fiber is larger than normal strength concrete. With the addition of the steel fiber, the cracks width reduced apparently. According to the results of salt spray test, the corrosion current denstity (Icorr) of normal strength concrete is the highest. The second highest Icorr is high strength concrete without steel fiber and the lowest Icorr is the concrete with steel fiber. However, the beam specimems was deisgned following the guideline of ACI 318-14; thus, it takes more time for reinforcement to corrod severely. In this study, the flexural test isn’t conducted, but the evalution index used in the flexural test was provided for future study in verifying the durability and residual mechanical behavior of steel fiber high strength concrete with working stress cracks.