To address the friction and wear issues of high-precision magnetic sensing encoder gear systems in aerospace applications under severe vibration and alternating high-low temperature conditions, this study proposes a surface modification method combining anodic oxidation with grease lubrication. By establishing an equivalent pin-on-disc model of gear meshing, the tribological behaviors of 7055 aluminum alloy substrates and 10-20 μm anodized films under dry friction/grease-lubricated conditions were systematically investigated. Experiments were conducted using an MFT-5000 tribometer to simulate extreme working conditions with an equivalent contact load of 100 N and a rotational speed of 59 rpm, complemented by white light interferometry three-dimensional topography analysis and quantitative characterization of mass loss. Results demonstrate that under dry friction, the 20 μm anodized specimen exhibited a 96% reduction in mass loss compared to the untreated substrate. In grease-lubricated conditions, its wear depth decreased by 56%. Microscopic morphology analysis revealed that increased oxide film thickness effectively inhibits the transition from abrasive to adhesive wear mechanisms. The experimental results have validated that the synergistic effect of oxide film thickness and lubrication significantly enhances the tribological performance of aluminum alloy gears, providing a theoretical basis for surface modification of aerospace precision transmission systems.