Premixed hydrogen-air flames interacting with a hydrogen porous wall

被引：4

作者：

Salimath, Prashant S. ^{[1
]}

Ertesvag, Ivar S. ^{[1
]}

Gruber, Andrea ^{[2
]}

机构：

[1] NTNU Norwegian Univ Sci & Technol, Dept Energy & Proc Engn, Kolbjorn Hejes Vei 1b, NO-7491 Trondheim, Norway

[2] SINTEF Energy Res, Trondheim, Norway

来源：

INTERNATIONAL JOURNAL OF HYDROGEN ENERGY | 2018年 / 43卷 / 07期

关键词：

Permeable wall; S3D; Head on quenching; Flame-wall interaction; Wall heat flux; Detailed chemical mechanism; DIRECT NUMERICAL-SIMULATION; CHARACTERISTIC BOUNDARY-CONDITIONS; LAMINAR FLAME; JET FLAMES; TEMPERATURE; COMBUSTION; MEMBRANES; PRESSURE; FLOW;

D O I：

10.1016/j.ijhydene.2017.12.166

中图分类号：

O64 [物理化学（理论化学）、化学物理学];

学科分类号：

070304 ; 081704 ;

摘要：

A laminar one-dimensional hydrogen-air flame travelling and quenching towards a chemically inert permeable wall (PW) is studied. Hydrogen flows through the wall into the premixed H-2-air. The S3D numerical code with detailed chemistry is used. PW results are compared against results of an impermeable wall (IW), including effects of varying wall mass flux, stoichiometry, inert dilution and unburned-gas and wall temperatures. The maximum reaction heat release rate occurs at the wall in all cases. For rich and stoichiometric mixtures, PW with fuel influx gave a moderate reduction of the quenching (i.e. maximum) wall heat flux compared to IW, whereas for a lean mixture, the increase is considerable. Effects of the fuel influx on the importance of individual elementary reactions and radicals and intermediate species are investigated. The lean PW cases have similarities to much richer IW cases. Both a lower wall temperature and dilution reduce the burned-mixture temperature and, consequently, the wall heat flux. (C) 2018 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

引用

页码：3822 / 3836

页数：15

共 50 条

[1] DYNAMICS OF PREMIXED HYDROGEN-AIR FLAMES IN MICROCHANNELS WITH A WALL TEMPERATURE GRADIENT
Nair, Aswathy
Kishore, V. Ratna
Kumar, Sudarshan
[J]. COMBUSTION SCIENCE AND TECHNOLOGY, 2015, 187 (10) : 1620 - 1637
[2] DNS of swirling hydrogen-air premixed flames
Minamoto, Yuki
Aoki, Kozo
Tanahashi, Mamoru
Swaminathan, Nedunchezhian
[J]. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2015, 40 (39) : 13604 - 13620
[3] Morphology and structure of hydrogen-air turbulent premixed flames
Minamoto, Yuki
Yenerdag, Basmil
Tanahashi, Mamoru
[J]. COMBUSTION AND FLAME, 2018, 192 : 369 - 383
[4] APPLICATION OF SENSITIVITY ANALYSIS TO PREMIXED HYDROGEN-AIR FLAMES
SMOOKE, MD
RABITZ, H
REUVEN, Y
DRYER, FL
[J]. COMBUSTION SCIENCE AND TECHNOLOGY, 1988, 59 (4-6) : 295 - 319
[5] Structure of turbulent rich hydrogen-air premixed flames
Sun, Zuo-Yu
[J]. INTERNATIONAL JOURNAL OF ENERGY RESEARCH, 2018, 42 (08) : 2845 - 2858
[6] MECHANISM OF COMBUSTION REACTIONS IN HYDROGEN-AIR PREMIXED FLAMES
FUKUTANI, S
KUNIOSHI, N
JINNO, H
[J]. BULLETIN OF THE CHEMICAL SOCIETY OF JAPAN, 1990, 63 (08) : 2191 - 2198
[7] The effect of pressure on lean premixed hydrogen-air flames
Rieth, Martin
Gruber, Andrea
Chen, Jacqueline H.
[J]. COMBUSTION AND FLAME, 2023, 250
[8] Preferential diffusion effects on the burning rate of interacting turbulent premixed hydrogen-air flames
Im, HG
Chen, JH
[J]. COMBUSTION AND FLAME, 2002, 131 (03) : 246 - 258
[9] Dynamics and stability of premixed hydrogen-air flames in square microchannels with wall temperature gradients
Lee, Sangyoon
Lee, Bok Jik
[J]. PROCEEDINGS OF THE COMBUSTION INSTITUTE, 2021, 38 (02) : 1933 - 1943
[10] Diffusive effects of hydrogen on pressurized lean turbulent hydrogen-air premixed flames
Song, Wonsik
Hernandez-Perez, Francisco E.
Im, Hong G.
[J]. COMBUSTION AND FLAME, 2022, 246

← 1 2 3 4 5 →