The variations in the total effective thermal conductivity (k(eff,t)) of a tetrakaidecahedra unit cell structure as functions of porosity (phi), thermal conductivity of the solid phase (k(s)) and the average temperature of the medium (T-avg), in the presence of combined conduction and radiation heat transfer, are presented in this article. For this purpose, the governing energy conservation equation is numerically solved using the blocked-off region approach based on the finite volume method. In addition, the variations in the radiative properties of the structure as functions of surface reflectivity (rho(s)), pore density (PPC) and phi are investigated, for which, a pure radiation heat transfer based numerical model is developed and used. From the detailed numerical simulations, three different correlations for k(eff,t) are proposed. Correlation 1 is developed by fitting the raw simulated data, although its form does not respect some of the limiting conditions. Particularly for k(s) < 5 W/mK and in the absence of thermal radiation, it under-predicts the effective thermal conductivity due to pure heat conduction (k(eff,PC)). Correlation 2, on the other hand, satisfies all possible limiting conditions, although it requires one additional simulation or correlation for k(eff,PC). Finally, correlation 3 is obtained by superposing the effective thermal conductivities due to pure radiation (k(eff.R)) and k(eff,PC), while introducing an adjustable coefficient in order to account for the coupling between them. From the investigation on radiative properties, it is observed that the extinction coefficient increases with the decrease in phi and with the increase in PPC as well as rho(s) and hence k(eff,t) as well as k(eff,R) is expected to decrease for these conditions. (C) 2018 Elsevier Ltd. All rights reserved.