Numerical simulation of the combustion of preheated ultra-lean dimethyl ether/air mixture

Blejchař, T.; Nevrlý, V.; Dostál, Michal; Klečka, V.; Bitala, P.; Válek, V.; Vašinek, M.; Suchánek, Jan; Zelinger, Zdeněk; Wild, J.

doi:https://dx.doi.org/10.1063/5.0120818

Number of the records: 1

Numerical simulation of the combustion of preheated ultra-lean dimethyl ether/air mixture

1.

SYSNO ASEP	0569869
Document Type	C - Proceedings Paper (int. conf.)
R&D Document Type	Conference Paper
Title	Numerical simulation of the combustion of preheated ultra-lean dimethyl ether/air mixture
Author(s)	Blejchař, T. (CZ) Nevrlý, V. (CZ) Dostál, Michal (UFCH-W)_{RID, ORCID, SAI} Klečka, V. (CZ) Bitala, P. (CZ) Válek, V. (CZ) Vašinek, M. (CZ) Suchánek, Jan (UFCH-W)_{RID, ORCID} Zelinger, Zdeněk (UFCH-W)_{RID, ORCID} Wild, J. (CZ)
Article number	030002
Source Title	AIP Conference Proceedings, 2672. - Melville : AIP Publishing, 2023 - ISSN 0094-243X
Number of pages	6 s.
Publication form	Print - P
Action	Meeting of Departments of Fluid Mechanics and Thermodynamics /39./
Event date	13.10.2021 - 15.10.2021
VEvent location	Horní Bečva
Country	CZ - Czech Republic
Event type	WRD
Language	eng - English
Country	US - United States
Keywords	combustion ; organic compounds ; computational methods
Subject RIV	CF - Physical ; Theoretical Chemistry
OECD category	Physical chemistry
R&D Projects	LTC17071 GA MŠMT - Ministry of Education, Youth and Sports (MEYS)
	GA17-05167s GA ČR - Czech Science Foundation (CSF)
Institutional support	UFCH-W - RVO:61388955
EID SCOPUS	85149779687
DOI	10.1063/5.0120818
Annotation	The combustion of preheated ultra-lean dimethyl ether/air mixture was investigated numerically. A laminar burner stabilized flame of preheated ultra-lean dimethyl ether was stabilized by methane co-flow and combustion respectively. Steady burning of co-flow methane ensured ignition of dimethyl ether/air mixture at temperature ca 330 °C. A detailed reaction mechanism of dimethyl ether low-temperature combustion and methane combustion were applied in the two-dimension axisymmetric numerical simulation. The state-of-the-art low-temperature chemistry of dimethyl ether and methane was applied in numerical simulation. The thermal interaction of flame and solid boundaries was achieved by solid-fluid coupled boundary conditions in numerical simulation. 2D axisymmetric numerical simulation was performed based on the physical measurement and experimental setup. The axial temperature profile of the flame was obtained by experiments and numerical simulation relatively well agreed with the experiment. The chemical radicals, like OH, CH2O, and HO2, occurrence in lean dimethyl/air flame were also obtained by experiment. The computational simulation of flame showed that there was thermal interaction between flames and solid parts of the experimental burner. The dimethyl ether/air mixture was preheated upstream by the thermal conductivity of solid parts. High and Low-temperature combustion zones were identified on the base of results of numerical simulation and the presence of radicals specific for the appropriate type of combustion respectively.
Workplace	J. Heyrovsky Institute of Physical Chemistry
Contact	Michaela Knapová, michaela.knapova@jh-inst.cas.cz, Tel.: 266 053 196
Year of Publishing	2024

Number of the records: 1