This work details investigation of two-phase aqueous foam flow, which is applicable for developing energy-efficient heat exchangers. In such heat exchangers, heat transfer rates are enhanced due to the structure and properties of aqueous foam, namely gas bubbles separated by a thin liquid film. Aqueous foam is noted to have an especially large inter-phase contact surface and reduced surface tension when compared to pure liquids. However, the foam flow in a channel provided with a heated surface (representing a typical heat exchanger element) invokes rearrangement and collision of foam bubbles. This in turn induces changes in local foam velocity, redistribution of volumetric void fraction and temperature. To study this phenomenon, the finite volume method was applied, which was implemented in FLUENT software (version 6.2). The computation domain consists of a rectangular channel with heat pipe located in a middle of a channel. The influence of different velocities and values of volumetric void fraction was examined. The relationship trend obtained by numerical modelling was compared with data obtained from experimental investigations.