This research, evaluates the Effect of Heterogeneity of Hydraulic Conductivity on Health Risk at DNAPL Contaminated Sites by simulating groundwater contaminant transport. Using RT3D and Health Risk Assessment to simulate the migration of plume and evaluate the effect of the contamintant of concern on DNAPL contaminated sites. RT3D, which simulates the degradation of Tetrachloroethylene (PCE) and its degradation products, Trichloroethylene (TCE), Dichloroethylene (DCE), Vinyl Chloride(VC), concerns about the absorption of plume causing different velocity of transport. On the simulation site, the site for study was assumed to establish a vertical heterogeneity of hydraulic conductivity. The other DNAPL site in Taiwan was chosen as the case study. The results of the research show that, the assumption that the site point source exists in the upper aquifer pollution, if the low hydraulic conductivity were located on an upper aquifer, plume migration speeds down, making the concentration near the source was high, and the concentration far away the source was low. If high hydraulic conductivity were located on the upper aquifer, plume migration speeds up, and the concentration near the source was low, while the concentration far away the source was high. The results of the simulation show that the rate of transport of Vinyl Chloride is fast, leading to severe pollution beyond the site boundary within a time of 24 years. On the other hand, Results of the Taiwan DNAPL site simulation show that, when assuming low hydraulic conductivity on the upper layer, makes concentration increasing inside the site, the risk shows a big difference with the homogeneous aquifer, and in the outer site the risk difference is low. All the results of health risk assessment show main hazards exposure pathways by mainly inhalation, and followed by ingestion. The risk within the site boundary is primarily caused by both Trichloroethylene (TCE) and Vinyl Chloride (VC).