In recent years, plastic film has become a very important product in the polymer industry, with a particular trend toward the development of multifunctional composite films. The major difficulty in co-extrusion of composite films is sharkskin and non-uniformity in layer thickness. The actual extrusion process or rheological behavior within the mold is difficult to observe directly, due to the high temperature and the high pressure. In this study, we employed Finite Element Method to simulate the isothermal and non-isothermal co-extrusion process, to explore defects such as sharkskin and propose practical solutions. In this study, we showed how the flow behavior during extrusion and the defects were a result of the relationship between angle of convergence, viscosity of the material, extrusion velocity and layer thickness. When the angle of convergence increased, the shear stress increased at the die wall in the sub-channel, resulting in the occurrence of sharkskin, with the phenomenon of encapsulation becoming critical the interface of the die exit. The greater the viscosity, the more the interfacial position between the polymer layers shifted toward the main-channel. The interfacial shear stress was discontinuous, resulting in distortion at the interface. Encapsulation increased with an increase in viscosity. A higher extrusion velocity in the sub-channel was able to reduce the viscosity ratio to remedy the encapsulation phenomenon, but it produced sharkskin and interfacial instability. During the extrusion process, certain aspects of the film thickness were under tremendous shear stress, leading to irregular distribution at the interface, as the thickness within the high-viscosity sub-channel became thinner. In the non-isothermal system, viscous heating was greater in the high-viscosity sub-channel, which led to a significant rise in temperature, with a greater decrease in viscosity than in the main-channel. This resulted in a diminished degree of encapsulation compared with the isothermal system.