This research purposes to study the physical phenomenon and fluid dynamics of microfluid having encapsulated air bubbles at advancing meniscus in the microchannel with Y type. The varying physical parameters include inlet mass flow rate, wetting conditions of microchannel walls, aspect ratio of microchannels, and angle formed by microchannels. The numerical simulation tool used in this study is the CFD-ACE+ commercial software produced by CFD Research Corporation. A VOF-PLIC interface tracking method is adapted to represent the fluid domain and to track the evolution of its free boundaries while CSF mode is choosed to model interfacial physics. According to the research result, the main parameters that affect the formation of encapsulated air bubble include inlet angle of micro-channels and wetting condation. The increase in the inlet angle will produce encapsulated air bubble with lager volume. The lager contact angle will easily come out with encapsulated air bubble with having lager volume. The lager aspect ratio will result in the change angle of meniscus normal line, faster the speed, and increase volume of air bubble for hydrophilic cases. Faster speed will step up dynamic wetting angle of meniscus slightly and volume of air bubble for hydrophilic cases. lower speed can make meniscus attain to steady state and eliminate the small air bubble on wall corner due to fast speed.