http://orcid.org/0000-0003-1490-9111
![Sample our Engineering & Technology journals, sign in here to start your access, latest two full volumes FREE to you for 14 days]({"type":"image" , "src" : "/sda/5933/TOC-Subject-Sample-2021-Engineering-Tech.jpg"})
ABSTRACT
The measurements on flame structure and burning velocities of C3H8/air, CH4/air and CO/H2/air turbulent premixed flames were conducted. Various experimental conditions for these mixtures were considered to understand the molecular and thermal diffusion process in turbulent flame, which was referred to the fuel effects. The fuel effects are interpreted as local burning velocity variation caused by molecular and thermal diffusivity with stretch effect. Leading points concept is a promising scaling approach to incorporate the fuel effects in turbulent flames recently. In this article, data across a variety of equivalence ratio and hydrogen fractions were obtained using Bunsen burner. Flame front was detected with OH-PLIF technique and turbulent burning velocity ST referred to leading edge was derived. A new leading points characteristic speed SL,LP was presented invoking both negative and positive Markstein number mixtures, revising the previous model in literature which is only suitable for negative Markstein number fuels. The turbulent burning velocity ST under relatively weak turbulence intensity in this study and data of high turbulence intensity, high pressure from literature were renormalized with SL,LP instead of SL,0 based on leading points concept, where SL,0 is the unstretched laminar flame speed. The results show that all the data sets were collapsed well which validated the significance of SL,LP in normalizing ST of different mixtures. An empirical formula for turbulent burning velocity correlation was obtained as . This formula is similar to that of Kobayashi; however, it shows superiority in incorporating the fuel effects.