The purpose of this study was to establish a monitoring system that is available for continuous in-situ monitoring on the cooling system of a boiler in a fossil power plant. Data bases such as the corrosion potential, polarization resistance, and zero-resistance current density, in combination with the SEM morphology of corrosion pits and potentiodynamic polarization analyses obtained from laboratory tests, were built together in the monitor system. In this work, the data of potentiodynamic polarization correlated to the SEM morphology of a pitting corrosion crack, initiated under a critical concentration of chloride, were built in the system. This system is useful for providing a warning of pitting risk on 304 stainless steels, a major material used in the cooling system where seawater was present. Abrupt changes simultaneously appearing in more titan two electrochemical measurements would lead to an alarm. This alarm would prompt the operators to take emergency actions for preventing the initiation of pitting corrosion. With our developed monitoring system, pitting corrosion could he detected when there are abrupt changes in corrosion potential and zero-resistance current density, resulted from a chloride concentration of higher than 400 ppm.