For preventing corrosion and promoting the service life of offshore steel structures, the cathodic protection method is generally applied. However, it had been shown that the higher the steel strength, the more likely the hydrogen brittle phenomenon will be induced under the cathodic protection, leading to a higher risk of structural failure. In order to assist the development of high-strength steels and their application to offshore structures, these steels under simulated cathodic protection was evaluated to investigate the effect of the applied cathodic potential on hydrogen embrittlement sensitivity. With ASTM G129 as the main test reference standard, this study carried out by slow strain rate tensile method and used the base metal and weld metal of S690Q as the test samples. For evaluating their hydrogen embrittlement tendency, data analysis, fracture surface observations and measurement were performed after the test. The results showed that the more negative the cathodic protection potential, the embrittlement index such as reduction of area ratios and plastic elongation ratios had a more decreasing tendency, it showed that the cathodic protection potential had an effect on S690Q hydrogen embrittlement. As cathodic protection potential was higher than -0.95 V, S690Q had a lower hydrogen embrittlement tendency, but as potential was lower than -1.05 V, the risk of hydrogen embrittlement would be higher. Compared with the base metal specimens, the weld metal showed a higher hydrogen embrittlement tendency and fractures occurred at the heat-affected zones. This phenomena might resulted from hydrogen embrittlement sensitive microstructure and the residual stress of the heat-affected zones generated when welding. The weld metal and HAZ might have a more probability of cracking than base metal under cathodic protection.