✦ LIBER ✦

Modeling and calculation of turbulent lifted diffusion flames

✍ Scribed by J.P.H. Sanders; A.P.G.G. Lamers

Publisher: Elsevier Science
Year: 1994
Tongue: English
Weight: 903 KB
Volume: 96
Category: Article
ISSN: 0010-2180
DOI: 10.1016/0010-2180(94)90155-4

No coin nor oath required. For personal study only.

✦ Synopsis

Liftoff heights of turbulent diffusion flames have been modeled using the laminar diffusion flamelet concept of Peters and Williams [A/ AA J., 21:423-429 (1983)]. The strain rate of the smallest eddies is used as the stretch describing parameter, instead of the more common scalar dissipation rate. The h(U) curve, which is the mean liftoff height as a function of fuel exit velocity can be accurately predicted, while this was impossible with the scalar dissipation rate. Liftoff calculations performed in the flames as well as in the equivalent isothermal jets, using a standard k-~ turbulence model yield approximately the same correct slope for the h(U) curve while the offset has to be reproduced by chosing an appropriate coefficient in the strain rate model. For the flame calculations a model for the pdf of the fluctuating flame base is proposed. The results are insensitive to its width. The temperature field is qualitatively different from the field calculated by Bradley et al. (Twenty-Third Symposium on Combustion, 1990, pp. 685-692) who used a premixed ttamelet model for diffusion flames.

📜 SIMILAR VOLUMES

Similarity solutions in buoyancy-control

✍ M.A. Pivovarov; H. Zhang; D.E. Ramaker; P.A. Tatem; F.W. Williams 📂 Article 📅 1993 🏛 Elsevier Science 🌐 English ⚖ 838 KB

This work considers the applicability of different versions of the k-e hypothesis of turbulence for flame modeling. Utilizing similarity solutions, we find that the k-e hypothesis gives a finite radius for a weak axysimmetric plume above the heat source. The radius of this plume is defined as an eig

The calculation of mean radical concentr

The calculation of mean radical concentrations in turbulent diffusion flames

✍ J. Janicka; W. Kollmann 📂 Article 📅 1982 🏛 Elsevier Science 🌐 English ⚖ 793 KB

A prediction model for turbulent diffusion flames is presented and applied to H2-air-diffusion flames and in particular to the calculation of mean radical concentrations. The fast shuffle reactions in the H2-ah'reaction system are assumed to be in partial equilibrium, whereas the three-body recombin

CO/Air turbulent diffusion flame: Measur

CO/Air turbulent diffusion flame: Measurements and modeling

✍ M.K. Razdan; J.G. Stevens 📂 Article 📅 1985 🏛 Elsevier Science 🌐 English ⚖ 847 KB

Measurements are presented for a turbulent diffusion flame jet of carbon monoxide in coflowing air. Detailed profiles of average velocity, turbulence intensity, average temperature, and species concentrations were measured at a Reynolds number of 1.14 × 104. Several checks on the data indicated good

A flame-zone model for turbulent hydroca

A flame-zone model for turbulent hydrocarbon diffusion flames

✍ H.E. Eickhoff; K. Grethe 📂 Article 📅 1979 🏛 Elsevier Science 🌐 English ⚖ 428 KB

A flame-zone model for an assumed quasilaminar flame substructure of turbulent diffusion flames, combined with a probability density function (PDF) representation of fuel-atom concentration, was developed and tested for a free-jet natural gas flame. The turbulent mixing has been calculated from a se

On the numerical modeling of buoyancy-do

On the numerical modeling of buoyancy-dominated turbulent vertical diffusion flames

✍ M.O. Annarumma; J.M. Most; P. Joulain 📂 Article 📅 1991 🏛 Elsevier Science 🌐 English ⚖ 703 KB

Prediction of turbulent diffusion flames

Prediction of turbulent diffusion flames with a four-equation turbulence model

✍ W. Kolbe; W. Kollmann 📂 Article 📅 1980 🏛 Elsevier Science 🌐 English ⚖ 567 KB