微小重力下での直線燃料液滴列に沿った火炎伝ぱ (第3報, 火炎伝ぱのモデル計算)

梅村, 章, UMEMURA, Akira, 内田, 正宏, UCHIDA, Masahiro

09 1900

No description available.

Numerical Calculation

Droplet Combustion

Flame Propagation

Diffusion Flame

Premixed Flame

対向流予混合火炎中のOH濃度と燃焼速度

YAMASHITA, Hiroshi, HAYASHI, Naoki, ISAYAMA, Tsutomu, YAMAMOTO, Kazuhiro, 山下, 博史, 林, 直樹, 伊佐山, 勉, 山本, 和弘

08 1900

No description available.

Stretch

Counterflow flame

OH

Burning velocity

Premixed flame

部分予混合雰囲気中における可燃性固体上の火炎の燃え拡がり解析

YAMASHITA, Hiroshi, YAMAMOTO, Kazuhiro, OGATA, Yoshinori, 山下, 博史, 山本, 和弘, 緒方, 佳典

02 1900

No description available.

Flame index

Partially premixed atmosphere

Thin solid fuel

Flame spread

三重管バーナに形成される浮き上がり火炎の挙動に関する研究

YAMASHITA, Hiroshi, HAYASHI, Naoki, ISOBE, Yusuke, YAMAMOTO, Kazuhiro, 山下, 博史, 林, 直樹, 磯部, 佑介, 山本, 和弘

11 1900

No description available.

Numerical Analysis

Leading-edge Flame

Lifted Flame

Non-premixed Flame

乱流燃焼場のPIV計測と乱れスケールの算出

山本, 和弘, YAMAMOTO, Kazuhiro, 井上, 聡, INOUE, Satoshi, 山下, 博史, YAMASHITA, Hiroshi, 下栗, 大右, SHIMOKURI, Daisuke, 石塚, 悟, ISHIZUKA, Satoru, 小沼, 義昭, ONUMA, Yoshiaki

11 1900

No description available.

Premixed Combustion

Flame

Turbulent Flow

Flow Measurements

PIV

旋回噴流燃焼器を用いた強乱流予混合火炎の研究 (第2報, 静電探針を用いた火炎の微細構造の検討)

山本, 和弘, YAMAMOTO, Kazuhiro, 阿知波, 朝士, ACHIHA, Tomoshi, 小沼, 義昭, ONUMA, Yoshiaki

25 February 2000

No description available.

Premixed Combustion

Turbulent Combustion

Flame

Turbulence

Electrostatic Probe

旋回噴流燃焼器を用いた強乱流予混合火炎の研究 (第3報, Slot-Correlation法による燃焼場の乱れスケールの計測)

山本, 和弘, YAMAMOTO, Kazuhiro, 西澤, 泰樹, NISHIZAWA, Yasuki, 小沼, 義昭, ONUMA, Yoshiaki

25 February 2002

No description available.

Premixed Combustion

Turbulence

LDV

Flow Measurements

Slot-Correlation Method

反応進行度とその勾配による非定常対向流予混合火炎の火炎構造の整理

林, 直樹, HAYASHI, Naoki, 山下, 博史, YAMASHITA, Hiroshi, 中村, 祐二, NAKAMURA, Yuji, 山本, 和弘, YAMAMOTO, Kazuhiro

25 January 2006

No description available.

Premixed Flame

Unsteady Behavior

Counterflow

Reaction Progress Variable

Numerical Analysis

メタン・空気予混合気の着火特性に関する詳細素反応機構を考慮した数値解析

松山, 竜佐, MATSUYAMA, Ryusuke, 山下, 博史, YAMASHITA, Hiroshi, 山本, 和弘, YAMAMOTO, Kazuhiro

25 October 2006

No description available.

Ignition

Premixed Combustion

Detailed Elementary Chemical Kinetics

Numerical Analysis

Leading points concepts in turbulent premixed combustion modeling

Amato, Alberto

27 August 2014

The propagation of premixed flames in turbulent flows is a problem of wide physical and technological interest, with a significant literature on their propagation speed and front topology. While certain scalings and parametric dependencies are well understood, a variety of problems remain. One major challenge, and focus of this thesis, is to model the influence of fuel/oxidizer composition on turbulent burning rates. Classical explanations for augmentation of turbulent burning rates by turbulent velocity fluctuations rely on global arguments - i.e., the turbulent burning velocity increase is directly proportional to the increase in flame surface area and mean local burning rate along the flame. However, the development of such global approaches is complicated by the abundance of phenomena influencing the propagation of turbulent premixed flames. Emphasizing key governing processes and cutting-off interesting but marginal phenomena appears to be necessary to make further progress in understanding the subject. An alternative approach to understand turbulent augmentation of burning rates is based upon so-called "leading points", which are intrinsically local properties of the turbulent flame. Leading points concepts suggest that the key physical mechanism controlling turbulent burning velocities of premixed flames is the velocity of the points on the flame that propagate farthest out into the reactants. It is postulated that modifications in the overall turbulent combustion speed depend solely on modifications of the burning rate at the leading points since an increase (decrease) in the average propagation speed of these points causes more (less) flame area to be produced behind them. In this framework, modeling of turbulent burning rates can be thought as consisting of two sub-problems: the modeling of (1) burning rates at the leading points and of (2) the dynamics/statistics of the leading points in the turbulent flame. The main objective of this thesis is to critically address both aspects, providing validation and development of the physical description put forward by leading point concepts. To address the first sub-problem, a comparison between numerical simulations of one-dimensional laminar flames in different geometrical configurations and statistics from a database of direct numerical simulations (DNS) is detailed. In this thesis, it is shown that the leading portions of the turbulent flame front display a structure that on average can be reproduced reasonably well by results obtained from model geometries with the same curvature. However, the comparison between model laminar flame computations and highly curved flamelets is complicated by the presence of negative (i.e., compressive) strain rates, due to gas expansion. For the highest turbulent intensity investigated, local consumption speeds, curvatures, strain rates and flame thicknesses approach the maximum values obtained by the laminar model geometries, while other cases display substantially lower values. To address the second sub-problem, the dynamics of flame propagation in simplified flow geometries is studied theoretically. Utilizing results for Hamilton-Jacobi equations from the Aubry-Mather theory, it is shown how the overall flame front progation under certain conditions is controlled only by discrete points on the flame. Based on these results, definitions of leading points are proposed and their dynamics is studied. These results validate some basic ideas from leading points arguments, but also modify them appreciably. For the simple case of a front propagating in a one-dimensional shear flow, these results clearly show that the front displacement speed is controlled by velocity field characteristics at discrete points on the flame only when the amplitude of the shear flow is sufficiently large and does not vary too rapidly in time. However, these points do not generally lie on the farthest forward point of the front. On the contrary, for sufficiently weak or unsteady flow perturbations, the front displacement speed is not controlled by discrete points, but rather by the entire spatial distribution of the velocity field. For these conditions, the leading points do not have any dynamical significance in controlling the front displacement speed. Finally, these results clearly show that the effects of flame curvature sensitivity in modifying the front displacement speed can be successfully interpreted in term of leading point concepts.

Premixed flames

Turbulent combustion

Leading points

Flame stretch

G-equation