3D stacking of integrated circuits (ICs) provides significant advantages in saving device footprints, improving power management, and continuing performance enhancement, particularly for many-core systems. However, the stacked structure makes the heat dissipation a challenging issue. While Thermal Through Silicon Via (TTSV) is a promising way of lowering the thermal resistance of dies, past research has either overestimated or underestimated the effects of TTSVs as a consequence of the lack of detailed 3D IC models or system-level simulations. Here, we propose a simulation flow to accurately simulate TTSV effects on 3D ICs. We adopt benchmarks from Splash-2 running on a full-system mode of the gem5 simulator, which generates all the system component activities. McPAT is used to generate the corresponding power consumption and the power traces are fed to HotSpot for thermal simulation. The temperature profiles of 2D and 3D Nehalem-like ×86 processors are compared. TTSVs are later placed close to hotspot regions to facilitate heat dissipation; the peak temperature of 3D Nehalem is reduced by 5--25% with a small area overhead of 6%. By using a detailed 3D thermal model, full-system simulation, and a validated thermal simulator, our results show accurate thermal analysis of 3D ICs.