The United States Environmental Protection Agency （US EPA） ranked acenaphthylene （Acpy） as 16 among polycyclic aromatic hydrocarbons （PAHs） in terms of priority air pollutants. Despite the use of plasma technology in recent years to treat and decompose toxic compounds, power consumption costs during plasma operations are prohibitively high. Reducing plasma operational costs and validating the destructive efficiency of toxic compounds by using plasma are thus of priority concern. This study simulated an atmospheric plasma reactor by using a method based on computational fluid dynamics （CFD）. The commercial FLUENT code was then adopted to simulate the Acpy compound by using a three-dimensional atmospheric plasma reactor in order to treat cooking fume exhaust emitted from the restaurant kitchen. Next, parameters of the temperature, velocity mass fraction and efficiency of Acpy compound decompose in the code were examined to determine how they influence the atmospheric reactor. The numerical approach was based on refers to a specific finite volume method. The RNG κ-ε turbulence model, the SIMPLE algorithm and finite-rate eddy dissipation model were employed to solve in the combustion case. During simulation, the atmospheric plasma reactor size and operating parameters were taken from the self-designed atmospheric plasma reactor in our previous study （NSC95-2211-E020-020）. Additionally, CFD simulation results and measurement data were compared and discussed. According to results, CFD simulation can reduce operating costs associated with plasma reactor experiments. Results of this study provide a valuable reference for efforts to treat air carcinogenic compounds by using an atmospheric plasma reactor.