A parallelized 2D/2D-axisymmetric pressure-based, finite-volume gas flow model has been developed for simulating compressible, viscous, heat conductive and rarefied gas flows at all speeds with conjugate heat transfer. The governing equations are solved on the structured, collocated grid using a finite volume method. An extended SIMPLE algorithm for compressible flow simulation is proposed which is based on the SIMPLE scheme developed by Patankar and Spalidinf [1972]. The flow properties are solved by a prediction/correction algorithm. Applications with wide range of pressures, flow speeds, and various species concentrations are demonstrated by comparing with previous simulations wherever possible. Research in this thesis is divided into three major phases, which are briefly described in the following in turn. In the first phase, a parallelized 2D/2D-axisymmetric gas flow model was developed and verified. The discretized equations, including continuity equation, momentum equation, energy equation and species equation are solved by the parallel ASM (Additive Schwarz Method) and GMRES or BCGS schemes, which are used as the preconditioner and linear matrix equation solver, respectively. The developed code was validated by comparing with previous published simulations wherever available for both low- and high-speed gas flows. Parallel performance for a micro-scale supersonic flow problem (800,000 computational cells) is tested on the V’ger cluster system (Xeon 3GHz dual-core dual-CPU) at National Central University up to 64 processors. Parallel efficiency of the developed gas flow model using 64 processors is about 70%. In the second phase, (1) A chamber-scale gas discharge of plasma enhanced chemical vapor deposition (PECVD) with silane/hydrogen as the precursors, which was used for depositing hydrogenated amorphous silicon thin film, (2) A helium micro-cell plasma and (3) A two-dimensional helium DBD (Dielectric-barrier discharge) driven by 25 kHz distorted sinusoidal voltages were simulated using the developed gas flow model coupling with parallelized 2D fluid modeling codes developed by Hung [2010] and Lin [2012]. The simulation results show that there are significant differences between the cases with and without considering neutral flow and thermal field. In the third part, a parametric study was performed to determine the influences of the system configurations, and the flow conditions on the flow and heat transfer characteristics of a helium dielectric-barrier discharge atmospheric-pressure plasma jet. Recommendations of future research are also outlined at the end of this thesis.