The offshore oil production is increasingly using pumping equipment at the seabed for production of wells at long distances from production units. Most of these devices have difficulty to operate in the presence of gas, especially in slug flow conditions, where the pump suction s void fraction can vary significantly. This problem limits the equipment s range of operation. One way to minimize the effects of slugging and thus enlarge the operation range of these devices is to use flow mixers at the pump s suction, which helps to ensure the operation even in the presence of large gas bubbles. Therefore, the design and prediction of the behavior of this type of equipment are essential for proper operation of subsea pumping systems. At the present work, the efficiency of a type of flow mixer to provide uniform void fractions at its outlet is numerically investigated, with the two fluid model. Different geometric configurations are analyzed and the influence of intake flow of both phases is discussed. The methodology is validated through comparison of the pressure drop through the flow mixer with available experimental data, where good agreement was observed. The numerical model also shows that a buffer of liquid is maintained inside the equipment and the gas is forced to disperse in the liquid stream to exit the mixer. The mixer s behavior in the presence of slugs is also investigated. Finally, a new geometry is proposed, which seems to be more efficient to avoid flow s intermittencies.