Recent research and development of combustion simulation

Hideyuki Aoki; Akira Suzuki; Yutaka Hisaeda; Yoshikazu Suwa; Tatsuji Nakagawa; Mitsuru Yaga; Masakazu Shoji; Takatoshi Miura

doi:10.1002/htj.10003

Recent research and development of combustion simulation

Hideyuki Aoki, Akira Suzuki, Yutaka Hisaeda, Yoshikazu Suwa, Tatsuji Nakagawa, Mitsuru Yaga, Masakazu Shoji, Takatoshi Miura

ENG - Chemical Engineering

Tohoku University

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

We present (1) Gas fuel combustion rate expressions using the full kinetic reaction mechanism and the reduced mechanism, (2) A comparison of calculated results by Lagrangian and Eulerian methods on spray and solid particles, (3) The wall boundary treatment such as a wall function and low Reynolds number model, (4) A devolatilization reaction model of pulverized coal such as the FLASHCHAIN model, (5) k-ε turbulence model and LES approach on combustion flow field, (6) Radiative heat transfer in combustion, (7) Soot formation in the flame, (8) NO_x formation mechanism, and (9) Treatment on unburned particle fragmentation. Considering this overview of the above-mentioned modeling, the future of combustion simulation is discussed.

Original language	English
Pages (from-to)	581-613
Number of pages	33
Journal	Heat Transfer - Asian Research
Volume	30
Issue number	7
DOIs	https://doi.org/10.1002/htj.10003
Publication status	Published - 2001 Nov

Keywords

Combustion
LES
Numerical simulation
Radiative heat transfer
Soot formation

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10.1002/htj.10003

Cite this

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title = "Recent research and development of combustion simulation",

abstract = "We present (1) Gas fuel combustion rate expressions using the full kinetic reaction mechanism and the reduced mechanism, (2) A comparison of calculated results by Lagrangian and Eulerian methods on spray and solid particles, (3) The wall boundary treatment such as a wall function and low Reynolds number model, (4) A devolatilization reaction model of pulverized coal such as the FLASHCHAIN model, (5) k-ε turbulence model and LES approach on combustion flow field, (6) Radiative heat transfer in combustion, (7) Soot formation in the flame, (8) NOx formation mechanism, and (9) Treatment on unburned particle fragmentation. Considering this overview of the above-mentioned modeling, the future of combustion simulation is discussed.",

keywords = "Combustion, LES, Numerical simulation, Radiative heat transfer, Soot formation",

author = "Hideyuki Aoki and Akira Suzuki and Yutaka Hisaeda and Yoshikazu Suwa and Tatsuji Nakagawa and Mitsuru Yaga and Masakazu Shoji and Takatoshi Miura",

year = "2001",

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doi = "10.1002/htj.10003",

language = "English",

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TY - JOUR

T1 - Recent research and development of combustion simulation

AU - Aoki, Hideyuki

AU - Suzuki, Akira

AU - Hisaeda, Yutaka

AU - Suwa, Yoshikazu

AU - Nakagawa, Tatsuji

AU - Yaga, Mitsuru

AU - Shoji, Masakazu

AU - Miura, Takatoshi

PY - 2001/11

Y1 - 2001/11

N2 - We present (1) Gas fuel combustion rate expressions using the full kinetic reaction mechanism and the reduced mechanism, (2) A comparison of calculated results by Lagrangian and Eulerian methods on spray and solid particles, (3) The wall boundary treatment such as a wall function and low Reynolds number model, (4) A devolatilization reaction model of pulverized coal such as the FLASHCHAIN model, (5) k-ε turbulence model and LES approach on combustion flow field, (6) Radiative heat transfer in combustion, (7) Soot formation in the flame, (8) NOx formation mechanism, and (9) Treatment on unburned particle fragmentation. Considering this overview of the above-mentioned modeling, the future of combustion simulation is discussed.

AB - We present (1) Gas fuel combustion rate expressions using the full kinetic reaction mechanism and the reduced mechanism, (2) A comparison of calculated results by Lagrangian and Eulerian methods on spray and solid particles, (3) The wall boundary treatment such as a wall function and low Reynolds number model, (4) A devolatilization reaction model of pulverized coal such as the FLASHCHAIN model, (5) k-ε turbulence model and LES approach on combustion flow field, (6) Radiative heat transfer in combustion, (7) Soot formation in the flame, (8) NOx formation mechanism, and (9) Treatment on unburned particle fragmentation. Considering this overview of the above-mentioned modeling, the future of combustion simulation is discussed.

KW - Combustion

KW - LES

KW - Numerical simulation

KW - Radiative heat transfer

KW - Soot formation

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U2 - 10.1002/htj.10003

DO - 10.1002/htj.10003

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SN - 1099-2871

VL - 30

SP - 581

EP - 613

JO - Heat Transfer - Asian Research

JF - Heat Transfer - Asian Research

IS - 7

ER -

Recent research and development of combustion simulation

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