부산대학교 도서관

A dual-scale flamelet/progress variable (DS-FPV) approach is developed to predict polycyclic aromatic hydrocarbon (PAH) formation in the environment of coal combustion. An additional progress variable CPAHsis newly defined in this approach to describe the evolution of PAHs, and the major species and temperature are still described by the traditional progress variable defined in the original FPV approach. Detailed chemistry simulations of a counterflow flame fueled with volatile matter and char off-gas are performed, and the solutions are regarded as references to evaluate the developed DS-FPV approach. It is found that the position of PAHs formation is located at the region that is close to the flame center in the fuel-rich side, and PAHs are mainly produced at the stage of volatile combustion. The original FPV approach can correctly predict the major species and temperature, but significant discrepancies appear for the species of PAHs that has a very weak correlation with the traditional progress variable. This issue is successfully addressed by the DS-FPV approach. Both the a prioriand a posteriorianalyses demonstrate that the developed DS-FPV approach can accurately and efficiently predict not only the distribution of major species and temperature but also the distribution of PAHs, although the peak values of mass fractions of PAHs are slightly underpredicted. The extension of this approach to turbulent pulverized coal combustion needs further efforts in the future.