Fiber-reinforced composite has gradually replaced the traditional material, such as metallic material, to be used in aircraft structure, interior and nacelle due to its excellent mechanical properties and light-weight. Nowadays, the percentage of fiber-reinforced composite used in airliner has over 50%. In other words, fiber-reinforced composite has become the main material for manufacturing modern aircraft parts. In the aerospace industry, autoclave forming process is commonly adopted for the manufacture of composite parts. This process can stably produce high quality and complex shape parts. Although autoclave forming process can reach the standard of aerospace, it spends a lot of time for trial and error to search for a steady way to produce parts. Therefore, in this thesis efforts were endeavored to reduce the lead time and save the production cost for the autoclave forming process with the use of the finite element analysis. This thesis first establishes the finite element model which can simulate both the air flow and the heat transfer presented in the autoclave forming process. The air flow speeds at different locations around the circumference of the autoclave inlet were measured and used as the initial air flow speeds for the simulation model. A measured temperature at the autoclave inlet was also used as an input data. The finite element simulations were then performed for a simplified model in which the composite layers were not considered. The heating efficiency is represented by the temperature evolution of the die surface at various locations during the heating process and a fast heating rate was anticipated. The temperature evolution of the die surface at various locations obtained from the finite element simulations and measured from the actual autoclave forming process was compared. The comparison reveals that the heating paths resulted from the simulation results and the measured data agree with each other in trend and the quantitative difference is within an acceptable range. It confirms that established finite element model with the specified initial and boundary conditions is capable of predicting the heat transfer during the autoclave process. In addition, this thesis also builds an equivalent material model for the composite in order to decrease the computation time that strongly depends on the complex geometry and the various thicknesses of the composite layers. The equivalent material model considers the composite layers having an equal thickness with the honey-cone structure built in. The equivalent thermal properties such as the thermal conductivity, specific heat and density were also determined by experiments performed and the theoretical derivations. With the equivalent material properties of the composite layers applied to the simulation model aforementioned, the temperature evolution of the die surface at various locations obtained from the finite element simulations differs from that measured from the actual autoclave forming process only within a range of 10%.