AME 513 Principles of Combustion Lecture 10 Premixed flames III: Turbulence effects.

Slides:



Advertisements
Similar presentations
Particle Fall through the atmosphere
Advertisements

Turbulent combustion (Lecture 1)
MAE 5310: COMBUSTION FUNDAMENTALS
Turbulent Combustion Jehad Yamin.
Lecture 15: Capillary motion
Wrinkled flame propagation in narrow channels: What Darrieus & Landau didn’t tell you M. Abid, J. A. Sharif, P. D. Ronney Dept.
MAE 5310: COMBUSTION FUNDAMENTALS
Laminar Flame Theory By Eng. Mohamad Okour UINVERSITY OF JORDAN MECHANICAL ENGINEERING DEPARTEMENT.
Laminar Premixed Flames and Diffusion Flames
A parametric study of the effect of fractal-grid generated turbulence on the structure of premixed flames Thomas Sponfeldner, S. Henkel, N. Soulopoulos,
Flame Stabilization.  In order to accomplish commercial combustion, the supply velocity of the reactant mixture is desired to be extremely high; it is.
AME 513 Principles of Combustion Lecture 8 Premixed flames I: Propagation rates.
SM(1) Sep nd International Conference on Hydrogen Safety, San Sebastian, Spain Molecular Transport Effects of Hydrocarbon Addition on Turbulent.
Toshio Mogi, Woo-Kyung Kim, Ritsu Dobashi The University of Tokyo
AME 513 Principles of Combustion
Lecture 9 - Kolmogorov’s Theory Applied Computational Fluid Dynamics
Laminar Premixed Flames A flame represents an interface separating the unburned gas from the combustion products. A flame can propagate as in an engine.
Performance of Ignition Process P M V Subbarao Professor Mechanical Engineering Department Effectiveness of Ignition for Efficient Combustion …..
LES Combustion Modeling for Diesel Engine Simulations Bing Hu Professor Christopher J. Rutland Sponsors: DOE, Caterpillar.
XIV A.I.VE.LA. National Meeting Experimental study of turbulence-flame front interactions by means of PIV-LIF technique. Troiani G., Marrocco M. ENEA C.R.
9 th HEDLA Conference, Tallahassee, Florida, May 3, 2012 Spontaneous Deflagration-to-Detonation Transition in Thermonuclear Supernovae Alexei Poludnenko.
Advanced fundamental topics (3 lectures)  Why study combustion? (0.1 lectures)  Quick review of AME 513 concepts (0.2 lectures)  Flammability & extinction.
AME 513 Principles of Combustion
Flow over an Obstruction MECH 523 Applied Computational Fluid Dynamics Presented by Srinivasan C Rasipuram.
Analysis of In-Cylinder Process in Diesel Engines P M V Subbarao Professor Mechanical Engineering Department Sudden Creation of Young Flame & Gradual.
AME 436 Energy and Propulsion Lecture 4 Basics of combustion.
An Experimental Study of Hydrogen Autoignition in a Turbulent Co-Flow of Heated Air C.N. Markides & E. Mastorakos Hopkinson Laboratory, Department of Engineering,
Sensible heat flux Latent heat flux Radiation Ground heat flux Surface Energy Budget The exchanges of heat, moisture and momentum between the air and the.
California State University, Chico
Convection Prepared by: Nimesh Gajjar. CONVECTIVE HEAT TRANSFER Convection heat transfer involves fluid motion heat conduction The fluid motion enhances.
Kinetic Theory. Microscopic Analysis  The behavior of a gas should be described by the molecules. 1) The gas consists of a large number of identical.
Centre for Fire and Explosion Studies Numerical Study of Spontaneous Ignition of Pressurized Hydrogen Release through a length of tube with local contraction.
AME 514 Applications of Combustion
AME 513 Principles of Combustion Lecture 7 Conservation equations.
Design & Thermo Chemistry of Turbo Combustor P M V Subbarao Professor Mechanical Engineering Department Design for performance, safety and Reliability…..
Nature of Heat Release Rate in an Engine
Faculty of Engineering, Kingston University London
Anharmonic Effects. Any real crystal resists compression to a smaller volume than its equilibrium value more strongly than expansion to a larger volume.
Design Analysis of Furnace Of A Steam Generator P M V Subbarao Professor Mechanical Engineering Department Perfection of Primary Cause for All that Continues…..
Copyright © 2009 Pearson Education, Inc. © 2009 Pearson Education, Inc. This work is protected by United States copyright laws and is provided solely for.
Design of Engine Cylinder for Creation of A Selected Turbulent Flow P M V Subbarao Professor Mechanical Engineering Department Geometry to create qualitatively.
Mathematical Equations of CFD
Properties of Gases Kinetic Molecular Theory. Kinetic-Molecular Theory  Based on idea that particles of matter are always in motion.  Provides reasoning.
TURBULENT PREMIXED FLAMES AT HIGH KARLOVITZ NUMBERS UNDER OXY-FUEL CONDITIONS Yang Chen 1, K.H. Luo 1,2 1 Center for Combustion Energy, Tsinghua University,
Funded by FCH JU (Grant agreement No ) 1 © HyFacts Project 2012/13 CONFIDENTIAL – NOT FOR PUBLIC USE 1.
Measurements in Fluid Mechanics 058:180:001 (ME:5180:0001) Time & Location: 2:30P - 3:20P MWF 218 MLH Office Hours: 4:00P – 5:00P MWF 223B-5 HL Instructor:
Auto Ignition, Premixed & Diffusive Combustion in CI Engines
Shaping the Future Emissions Formation and Control.
ME 101: Fluids Engineering Chapter 6 ME Two Areas for Mechanical Engineers Fluid Statics –Deals with stationary objects Ships, Tanks, Dams –Common.
Convection in Flat Plate Boundary Layers P M V Subbarao Associate Professor Mechanical Engineering Department IIT Delhi A Universal Similarity Law ……
The Boltzmann Distribution allows Calculation of Molecular Speeds Mathematically the Boltzmann Distribution says that the probability of being in a particular.
The Chemistry of Fuel Combustion in SI Engines P M V Subbarao Professor Mechanical Engineering Department Exploit the Chemical Characteristics of Combustion?!?!
Heat release modeling FPVA-based model V. Terrapon and H. Pitsch 1 Stanford PSAAP Center - Working draft.
High Fidelity Numerical Simulations of Turbulent Combustion
AME 436 Energy and Propulsion Lecture 4 Basics of combustion.
ASCI/Alliances Center for Astrophysical Thermonuclear Flashes An Interface Propagation Model for Reaction-Diffusion Advection Adam Oberman An Interface.
COMBUSTION FUNDAMENTALS Turbulent Premixed and Non-Premixed Flames
MAE 5310: COMBUSTION FUNDAMENTALS
ME 475/675 Introduction to Combustion
A.Teodorczyk, P.Drobniak, A.Dabkowski
Enhanced Activities due to In Cylinder Turbulence
Experiments on Strained Premixed Flames in the Distributed Reaction Regime Alessandro Gomez, Department of Mechanical Engineering, Yale University, USA.
Natural Convection New terms Volumetric thermal expansion coefficient
Estimation of Turbulent Flame Speeds in SI Engines
Experiments on Strained Premixed Flames in the Distributed Reaction Regime Alessandro Gomez, Department of Mechanical Engineering, Yale University, USA.
Generation and Control of Turbulent Flames in SI Engine
COMBUSTION TA : Donggi Lee PROF. SEUNG WOOK BAEK
Design rules to generate Turbulent Flame Speeds in SI Engines
Analysis of Turbulent Flame in SI Engine
Presentation transcript:

AME 513 Principles of Combustion Lecture 10 Premixed flames III: Turbulence effects

2 AME Fall Lecture 10 - Premixed flames III Motivation  Study of premixed turbulent combustion important because  Turbulence increases mean flame propagation rate (S T ) and thus mass burning rate (=  S T A projected )  If this trend increased ad infinitum, arbitrarily lean mixtures (low S L ) could be burned arbitrarily fast by using sufficiently high u’...but too high u' leads to extinction - nixes that idea  Even without forced turbulence, if the Grashof number gd 3 / 2 is larger than about 10 6 (g = 10 3 cm/s 2, ≈ 1 cm 2 /s  d > 10 cm), turbulent flow will exist due to buoyancy  Examples  Premixed turbulent flames »Gasoline-type (spark ignition, premixed-charge) internal combustion engines »Stationary gas turbines (used for power generation, not propulsion)  Nonpremixed flames »Diesel-type (compression ignition, nonpremixed-charge) internal combustion engines »Gas turbines »Most industrial boilers and furnaces

3 AME Fall Lecture 10 - Premixed flames III Turbulent burning velocity  Models of premixed turbulent combustion don’t agree with experiments nor each other!

4 AME Fall Lecture 10 - Premixed flames III Basics of turbulence  Good reference: Tennekes: “A First Course in Turbulence”  Job 1: need a measure of the strength of turbulence  Define turbulence intensity (u’) as rms fluctuation of instantaneous velocity u(t) about mean velocity ( )

5 AME Fall Lecture 10 - Premixed flames III Basics of turbulence  Job 2: need a measure of the length scale of turbulence  Define integral length scale (L I ) as  A measure of size of largest eddies  Largest scale over which velocities are correlated  Typically related to size of system (tube or jet diameter, grid spacing, …) Here the overbars denote spatial (not temporal) averages  A(r) is the autocorrelation function at some time t  Note A(0) = 1 (fluctuations around the mean are perfectly correlated at a point)  Note A(∞) = 0 (fluctuations around the mean are perfectly uncorrelated if the two points are very distant)  For truly random process, A(r) is an exponentially decaying function A(r) = exp(-r/L I )

6 AME Fall Lecture 10 - Premixed flames III Basics of turbulence  In real experiments, generally know u(t) not u(x) - can define time autocorrelation function A(x,  ) and integral time scale  I at a point x Here the overbars denote temporal (not spatial) averages  With suitable assumptions L I = (8/π) 1/2 u’  I  Define integral scale Reynolds number Re L  u’L I / (recall = kinematic viscosity)  Note generally Re L ≠ Re flow = Ud/ ; typically u’ ≈ 0.1U, L I ≈ 0.5d, thus Re L ≈ 0.05 Re flow  Turbulent viscosity T  Molecular gas dynamics: ~ (velocity of particles)(length particles travel before changing direction)  By analogy T ~ u’L I or T / = C Re L ; C ≈  Similarly, turbulent thermal diffusivity  T /  ≈ Re L

7 AME Fall Lecture 10 - Premixed flames III Turbulent burning velocity  Experimental results shown in Bradley et al. (1992) smoothed data from many sources, e.g. fan-stirred bomb

8 AME Fall Lecture 10 - Premixed flames III = S T /S L Bradley et al. (1992)  Compilation of data from many sources = u’/S L

9 AME Fall Lecture 10 - Premixed flames III Characteristics of turbulent flames  Most important property: turbulent flame speed (S T )  Most models based on physical models of Damköhler (1940)  Behavior depends on Karlovitz number (Ka)  Low Ka: “Huygens propagation,” thin fronts that are wrinkled by turbulence but internal structure is unchanged  High Ka: Distributed reaction zones, broad fronts Defined using cold- gas viscosity

10 AME Fall Lecture 10 - Premixed flames III Characteristics of turbulent flames

11 AME Fall Lecture 10 - Premixed flames III Turbulent combustion regimes  Comparison of flamelet and distributed combustion (Yoshida, 1988) Flamelet: temperature is either T ∞ or T ad, never between, and probability of product increases through the flame Distributed: significant probability of temperatures between T ∞ or T ad, probability of intermediate T peaks in middle of flame

12 AME Fall Lecture 10 - Premixed flames III Estimates of S T in flamelet regime  Damköhler (1940): in Huygens propagation regime, flame front is wrinkled by turbulence but internal structure and S L are unchanged  Propagation rate S T due only to area increase via wrinkling: S T /S L = A T /A L S T /S L = A T /A L

13 AME Fall Lecture 10 - Premixed flames III Estimates of S T in flamelet regime  Low u’/S L : weakly wrinkled flames  S T /S L = 1 + (u’/S L ) 2 (Clavin & Williams, 1979) - standard for many years  Actually Kerstein and Ashurst (1994) showed this is valid only for periodic flows - for random flows S T /S L - 1 ~ (u’/S L ) 4/3  Higher u’/S L : strongly wrinkled flames  Schelkin (1947) - A T /A L estimated from ratio of cone surface area to base area; height of cone ~ u’/S L ; result  Other models based on fractals, probability-density functions, etc., but mostly predict S T /S L ~ u’/S L at high u’/S L with the possibility of “bending” or quenching at sufficiently high Ka ~ (u’/S L ) 2, e.g. Yakhot (1988):

14 AME Fall Lecture 10 - Premixed flames III Effects of thermal expansion  Byckov (2000):  Same as Yakhot (1988) if no thermal expansion (  = 1)  Also says for any , if u’/S L = 0 then S T /S L = 1; probably not true

15 AME Fall Lecture 10 - Premixed flames III S T in distributed combustion regime  Much less studied than flamelet combustion  Damköhler (1940): A ≈ 0.25 (gas); A ≈ 6.5 (liquid)  Assumption  T ≈  L probably not valid for high  ; recall …but probably ok for small   Example: 2 equal volumes of combustible gas with E = 40 kcal/mole, 1 volume at 1900K, another at 2100K  (1900) ~ exp(-40000/(1.987*1900)) = 3.73 x 10 4  (2100) ~ exp(-40000/(1.987*2100)) = 1.34 x 10 4 Average = 2.55 x 10 4, whereas  (2000) = 2.2 x 10 4 (16% difference)!  Averaging over ±5% T range gives 16% error!