Unravelling the chemical and transport characteristics of turbulent MILD combustion

Dimitris M. Manias; Efstathios-Al. Tingas; Yuki Minamoto; Hong G. Im

Abstract

Developing modern combustion engines needs to address stringent environmental regulations such as efficiency, pollutants and noise. As a promising approach to achieve high efficiency and reduced emissions, moderate or intense low-oxygen dilution (MILD) combustion [1] has been investigated. In MILD conditions, a reactant mixture is preheated and highly diluted by using exhaust gas or flue gas to achieve stable combustion and relatively low flame
temperature. This leads to lower thermal NOx formation and noise, as well as high combustion efficiency. Previous studies addressed key issues for MILD combustion, such as dominant reaction pathways depending on different diluent gases at varying dilution levels, and the morphology of MILD reaction zones exhibiting multimode combustion [2]. However, proper characterization of the structure of turbulent flames at MILD conditions may require a significantly different approach compared to conventional flames depending on the thermochemical conditions of the reactant mixture.

Originalsprache	English
Publikationsstatus	Published - Juni 2019
Veranstaltung	7th International Workshop on Model Reduction in Reactive Flow (IWMRRF) - Norwegian University of Science and Technology (NTNU), Trondheim, Norway Dauer: 18 Juni 2019 → 21 Juni 2019 Konferenznummer: 7 http://modelreduction.net/workshops/7th-international-workshop/

Conference

Conference	7th International Workshop on Model Reduction in Reactive Flow (IWMRRF)
Kurztitel	IWMRRF 2019
Land/Gebiet	Norway
Ort	Trondheim
Zeitraum	18/06/19 → 21/06/19
Internetadresse	http://modelreduction.net/workshops/7th-international-workshop/

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IWMRRF_2019Manias_Tingas_Minamoto_ImFinal published version, 3,9 MBLizenz: Unspecified

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http://modelreduction.net/workshops/7th-international-workshop/

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title = "Unravelling the chemical and transport characteristics of turbulent MILD combustion",

abstract = "Developing modern combustion engines needs to address stringent environmental regulations such as efficiency, pollutants and noise. As a promising approach to achieve high efficiency and reduced emissions, moderate or intense low-oxygen dilution (MILD) combustion [1] has been investigated. In MILD conditions, a reactant mixture is preheated and highly diluted by using exhaust gas or flue gas to achieve stable combustion and relatively low flame temperature. This leads to lower thermal NOx formation and noise, as well as high combustion efficiency. Previous studies addressed key issues for MILD combustion, such as dominant reaction pathways depending on different diluent gases at varying dilution levels, and the morphology of MILD reaction zones exhibiting multimode combustion [2]. However, proper characterization of the structure of turbulent flames at MILD conditions may require a significantly different approach compared to conventional flames depending on the thermochemical conditions of the reactant mixture.",

author = "Manias, \{Dimitris M.\} and Efstathios-Al. Tingas and Yuki Minamoto and Im, \{Hong G.\}",

note = "This work was sponsored by competitive research funding from King Abdullah University of Science and Technology (KAUST); 7th International Workshop on Model Reduction in Reactive Flow (IWMRRF), IWMRRF 2019 ; Conference date: 18-06-2019 Through 21-06-2019",

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T1 - Unravelling the chemical and transport characteristics of turbulent MILD combustion

AU - Manias, Dimitris M.

AU - Tingas, Efstathios-Al.

AU - Minamoto, Yuki

AU - Im, Hong G.

N1 - Conference code: 7

PY - 2019/6

Y1 - 2019/6

N2 - Developing modern combustion engines needs to address stringent environmental regulations such as efficiency, pollutants and noise. As a promising approach to achieve high efficiency and reduced emissions, moderate or intense low-oxygen dilution (MILD) combustion [1] has been investigated. In MILD conditions, a reactant mixture is preheated and highly diluted by using exhaust gas or flue gas to achieve stable combustion and relatively low flame temperature. This leads to lower thermal NOx formation and noise, as well as high combustion efficiency. Previous studies addressed key issues for MILD combustion, such as dominant reaction pathways depending on different diluent gases at varying dilution levels, and the morphology of MILD reaction zones exhibiting multimode combustion [2]. However, proper characterization of the structure of turbulent flames at MILD conditions may require a significantly different approach compared to conventional flames depending on the thermochemical conditions of the reactant mixture.

AB - Developing modern combustion engines needs to address stringent environmental regulations such as efficiency, pollutants and noise. As a promising approach to achieve high efficiency and reduced emissions, moderate or intense low-oxygen dilution (MILD) combustion [1] has been investigated. In MILD conditions, a reactant mixture is preheated and highly diluted by using exhaust gas or flue gas to achieve stable combustion and relatively low flame temperature. This leads to lower thermal NOx formation and noise, as well as high combustion efficiency. Previous studies addressed key issues for MILD combustion, such as dominant reaction pathways depending on different diluent gases at varying dilution levels, and the morphology of MILD reaction zones exhibiting multimode combustion [2]. However, proper characterization of the structure of turbulent flames at MILD conditions may require a significantly different approach compared to conventional flames depending on the thermochemical conditions of the reactant mixture.

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M3 - Abstract

T2 - 7th International Workshop on Model Reduction in Reactive Flow (IWMRRF)

Y2 - 18 June 2019 through 21 June 2019

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