Power grids are unarguably the backbone of national infrastructures, providing vital support to economic growth. On the other hand, economic growth and the integration of plug-in hybrid electric vehicles have led to relentless power demand increase. Unfortunately, the update of power grids cannot always keep pace with power demand growth, which imposes potential threats on the reliable operation of power grids. When this occurs, the grids may still operate well under normal conditions, but when some loads change suddenly, they may fail much more easily. It is, therefore, imperative to establish a quantitative method to evaluate the robustness of power grids under load uncertainties, which can benefit grid planning, upgrade, and optimization. Unfortunately, despite the importance of this problem, it remains open in the literature. In this paper, we formally formulate the problem of power grid robustness and propose an efficient framework to measure it based on two sampling techniques: StopSign and Interval. The performance of the proposed framework has been evaluated on IEEE standard bus systems. To the best of the authors' knowledge, this is the first in-depth work on power grid robustness estimation under load uncertainties.