@Article{YuMinuMaas:2020:REReCh,
author = "Yu, Chunkan and Minuzzi, Felipe and Maas, Ulrich",
affiliation = "{Karlsruhe Institute of Technology} and {Instituto Nacional de
Pesquisas Espaciais (INPE)} and {Karlsruhe Institute of
Technology}",
title = "REDIM reduced chemistry for the simulation of counterflow
diffusion flames with oscillating strain rates",
journal = "Combustion Theory and Modelling",
year = "2020",
volume = "24",
number = "4",
pages = "682--704",
keywords = "reduced model, REDIM, diffusion flame, oscillation strain rate.",
abstract = "The dynamic behaviour and structures of laminar counterflow
diffusion methane flames under oscillatory strain rates are
investigated based on both detailed and reduced chemistry. It is
known both from experiment and numerical studies that flame can
deviate from its quasi-steady manner for high frequencies, which
makes the well-known steady laminar flamelet model questionable.
In this work, the Reaction-diffusion manifolds (REDIM) concept for
simplified chemistry is applied to study the laminar counterflow
diffusion flames with oscillating strain rates. In the
construction of REDIM, one needs little knowledge of the studied
system, and the REDIM reduced chemistry can cover both stable and
unstable (extinction) regimes of the studied system. It is shown
that the REDIM can capture both the steady and unsteady behaviours
of the flame structures even for high frequencies, where the
standard laminar steady flamelet approach is not appropriate.",
doi = "10.1080/13647830.2020.1739336",
url = "http://dx.doi.org/10.1080/13647830.2020.1739336",
issn = "1364-7830 and 1741-3559",
language = "en",
targetfile = "yu_redim.pdf",
urlaccessdate = "28 abr. 2024"
}