In recent progress on geodynamics modeling, a coupled plate-mantle-core system can be addressed from geodynamo model incorporating the heat flow across the core-mantle boundary (CMB) computed from numerical mantle convection simulations with plate reconstruction in 200 Myrs [Olson et al., 2013]. However, computing the heat flow across the CMB, it is strongly dependent on material properties of lowermost mantle minerals such as post-perovskite phase as well as thermo-chemical piles [Nakagawa and Tackley, 2008; Dekura et al., 2013; Ammann et al., 2014]. In previous study [Nakagawa and Tackley, 2008], simple tests on a relationship between deep mantle heat flow and thermo-chemical heterogeneity have been pointed out that such a relationship is not very simple as a heterogeneous boundary condition incorporating with geodynamo simulations, which is a linear treatment [e.g. Olson et al., 2013]. Here new scaling relationship between deep mantle heat flow and thermo-chemical heterogeneity derived from numerical mantle convection simulations with plate reconstruction data. On the thermo-chemical heterogeneity, it forms by the segregation of oceanic crust in the deep mantle plus the post-perovskite phase transition. Preliminary result suggests that no simple scaling relationship can be found between deep mantle heat flow and thermo-chemical heterogeneity, which is consistent with simple tests [Nakagawa and Tackley, 2008]. This also suggests that a linear scaling relationship between heat flow and seismic anomalies seems to be an over-simplified heterogeneous boundary condition for geodynamo modeling. This can also imply for a formation mechanism on Large-Low-Shear-Velocity-Provinces (LLSVPs), which could be either thermal plus post-perovskite phase or thermo-chemical piles plus post-perovskite phase.