In this study, air co-flow is applied to surround methane inverse diffusion flame on a stratified burner. To discuss the effects of the exit velocity of co-flow on the characteristics of a methane inverse diffusion flame, the structure of combustion flow field and distributions of free radicals were investigated by the methods of Particle Image Velocimetry (PIV) and chemiluminescence. The flame temperature was also measured. The results reveal that the stability of the inverse diffusion flame becomes less stable while accelerating the air co-flow speed, but air co-flow enhances the mixture of fuel and oxidizer, hence improves the efficiency of combustion. The basic flame pattern was classified into three various types, including double-layer inverse diffusion flame, transitional inverse diffusion flame, and single-layer inverse diffusion flame. While applying co-flow, the outer layer of inverse diffusion flame started to lift off. Through PIV, it was found that air co-flow could avoid fuel flow moving downstream due to the appearance of reverse vortex structure, which may increase the mixture between methane and air. The distributions of free radicals show that the intensity of OH* radicals with a suitable air co-flow velocity is significantly higher than those with excessive air co-flow or without air co-flow. This result implies that there is more fuel involved in the reaction. Though air co-flow would decrease the flame stability, an appropriate manipulated velocity could make the reaction of fuel mixture more complete. Also, the temperature corresponding to the OH* intensity of the outer flame rose with an increasing air co-flow velocity, meaning that the unburned gas reacted with co-flow more completely at the outer flame and improved the overall combustion efficiency. The results of this study are to expand the application of methane inverse diffusion flame, to enhance the combustion efficiency and to achieve low-level soot pollution by adjusting the exit velocity of air co-flow.