During the process of making metallic contacts for the electronics industry, they become stained with lubricating oil. Nowadays, the oil is removed by organic solvents. The aim of this work was to investigate their replacement by supercritical CO2, promoting a greener solution. The contacts stained with 3% lubricating oil were placed forming a fixed bed. The CO2 at different temperatures, pressures and mass flow rates was made to continuously flowing over this. The oil removal rates and yields were monitored and compared. As the pressure was increased between 120 and 300 bar, the oil extraction rate and consequently the yield also increased because of the CO2 density increment. But, the existence of a chemisorbed oil layer on the surface of the contact was demonstrated, probably formed by the paraffinic heavy fractions and some additives, and this was difficult to remove. The rise in temperature (37-110 degrees C) helped with the detachment of this layer, because of the endothermic character of the desorption. The viscosity of the oil also decreased. The increase in flow rate (1-7 g min(-1)) helped to sweep away the desorbed oil. However, within the explored variables and independently of the contact composition, it was impossible to achieve total lubricant elimination. Therefore, the addition of a cosolvent, ethanol, was explored. The lower the temperature was, the larger amounts of ethanol were needed. Thus, total lubricating oil elimination was achieved at 110 degrees C with the addition of 5% ethanol. These results were confirmed by electronic microscopy images. (C) 2012 Elsevier B.V. All rights reserved.