The aim of this study is to characterize the mechanical properties and thermal conductivities of graphene/epoxy nanocomposites. The elastic constants and thermal conductivity were investigated for the pristine graphene and functionalized graphene through molecular dynamics (MD) simulations. The results indicated that implanting functional groups would reduce the in-plane Young’s modulus and thermal conductivity. Subsequently, the influences of functional groups grafted on the graphene surface on the properties of nanocomposites were explored by examining the interfacial thermal conductance (ITC), phonon mismatch, and normalized interaction energy. It was shown that functional groups could increase the interactions and decrease the phonon mismatch at the interface so that the ITC and thermal transport in the interfacial epoxy could be enhanced significantly. Afterward, the atomistic simulation together with micromechanical analysis was employed to characterize the Young’s modulus and thermal conductivity of graphene/epoxy nanocomposites. The atomistic interaction between graphene and the surrounding epoxy was considered in the molecular dynamic simulation and then used to derive the effective properties of graphene. Subsequently, the Young’s moduli and thermal conductivities of nanocomposites with randomly oriented graphene were modeled from the Mori–Tanaka micromechanical model. The nanocomposites containing pristine graphene, carboxyl (COOH)-functionalized graphene, and COOH- and amine (NH2)-functionalized graphene were considered in the simulation. The results indicated that the COOH- and NH2-functionalized graphene nanocomposite exhibited superior mechanical and thermal properties to those of the other two material systems. Moreover, the model predictions were in good agreement with the experimental data.