This study explored the damage sequence of key components (pylon, support, foundation, and pier) of long-span three-pylon cable-stayed bridges with super-high piers in mountainous areas under earthquake action. The under-construction Pingtang major bridge in Guizhou province was taken as the case study. First, the spatial finite element model was established based on OPEENSEES software. Then, the seismic vulnerability model of cable-stayed bridges was established based on the probability theory. Finally, incremental dynamic analysis was carried out with concrete strain and relative displacement of support as vulnerability indicators. The vulnerability curves of components were obtained, and the failure order of components of this type of bridge was analyzed. The results showed that transverse earthquakes will cause more damage to the cable-stayed bridge than longitudinal earthquakes; the middle tower bearing and the side tower foundation in the bridge structure are most vulnerable to damage under longitudinal earthquakes; and the side tower bearing and the transition pier foundation in the bridge structure are most vulnerable to damage under transverse earthquakes.