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soot abatement using fuel additives PDF

265 Pages·2004·2.44 MB·English
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The Pennsylvania State University The Graduate School College of Engineering SOOT ABATEMENT USING FUEL ADDITIVES A Thesis in Mechanical Engineering by Juntao Wu © 2004 Juntao Wu Submitted in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy December 2004 The thesis of Juntao Wu has been reviewed and approved* by the following: Thomas A. Litzinger Professor of Mechanical Engineering Thesis Advisor Chair of Committee Robert J. Santoro George L. Guillet Professor of Mechanical Engineering Richard A. Yetter Professor of Mechanical Engineering Harold H. Schobert Professor of Fuel Science Richard C. Benson Professor of Mechanical Engineering Head of Department of Mechanical and Nuclear Engineering *Signatures are on file in the Graduate School iii ABSTRACT A study of the mechanism of soot abatement by oxygen-containing additives was conducted by both experimental and modeling methods. The overall technical objective is to develop a fundamental understanding of the complex roles of oxygen-containing additives in the processes which lead to particulate matter emissions. Two classes of compounds were investigated - oxygenates and nitro-alkanes. Experiments were performed on a premixed ethylene/air flame with two oxygenated additives - ethanol and dimethyl ether (DME). The experiments were conducted at two equivalence ratios, φ = 2.34 and φ = 2.64, and two levels of ethanol or DME, 5% and 10% oxygen in mass of the fuel, were added to the fuel at each equivalence ratio. The experimental results show that both ethanol and DME reduced aromatic species and soot, and they were more effective at φ = 2.34 than at φ = 2.64. The comparison between ethanol and DME shows that, at Ф = 2.34, DME is more effective than ethanol on PAH and soot reduction; however, at φ = 2.64, there is no detectable difference between these two additives on the aromatic species and soot suppression. A chemical model, Howard-DME-Ethanol (HDE) mechanism, was used to investigate the chemical processes leading to the abatement of aromatic species and soot by ethanol and DME. The analysis shows that these reduction effects result from the removal of carbon from the pathway to aromatic species formation. DME is more iv effective than ethanol in reducing soot precursors, because more carbon in DME is removed from the participation of aromatic formation than that in ethanol. This difference is due to the molecular structure difference between ethanol and DME. Screening studies of the nitro-alkanes showed them to be effective in reducing soot. The primary mechanism of soot reduction was hypothesized to be linked to NO , so 2 a modeling study of NO addition to premixed flames was undertaken. 2 A chemical model, Howard-NO (HN) mechanism, was used to investigate the 2 chemical processes leading to the effect of NO on aromatic species and soot reduction. 2 The mechanism analysis shows that the addition of NO increases the level of OH 2 radicals in the flame, through reactions of NO +H⇒NO+OH, HO +NO⇒NO +OH. 2 2 2 Then the increased OH decreases the level of H by reactions H +OH⇒H O+H. The 2 2 2 lower level of H increases the reaction rate of H CCCH+H⇒C H +H , and results a 2 2 3 2 2 lower level of H CCCH. Since all C H comes from H CCCH through reaction 2 6 6 2 2H CCCH⇒C H , low level H CCCH leads to a reduction of C H . As a key element 2 6 6 2 6 6 during the aromatic species growth, low level of C H leads to suppression of overall 6 6 aromatic species formation and growth. v TABLE OF CONTENTS ABSTRACT.......................................................................................................................iii TABLE OF CONTENTS....................................................................................................v LIST OF FIGURES.........................................................................................................viii LIST OF TABLES...........................................................................................................xiii NOMENCLATURE........................................................................................................xiv ACKNOWLEDGEMENTS.............................................................................................xvi Chapter 1 INTRODUCTION..............................................................................................................1 1.1 Motivation...........................................................................................................1 1.2 Objectives...........................................................................................................5 1.3 Soot Formation....................................................................................................8 1.3.1 Soot Particle Precursor and Particle Nucleation.........................................8 1.3.2 Particle Coagulation..................................................................................12 1.3.3 Soot Growth..............................................................................................14 1.3.4 Soot Oxidation..........................................................................................20 1.4 General Soot Physical Properties......................................................................21 1.5 Soot Reduction by Additives............................................................................24 1.5.1 Inert Diluents............................................................................................25 1.5.2 Gaseous Additives....................................................................................26 1.5.3 Metallic Additives.....................................................................................28 1.5.4 Oxygenated Additives...............................................................................30 Chapter 2 PRINCIPLES OF DIAGNOSTIC METHODS................................................................36 2.1 Laser-induced Incandescence...........................................................................37 2.1.1 Theoretical Analysis.................................................................................38 2.1.2 Experimental Considerations....................................................................41 2.1.2.1 Laser Excitation: Intensity Profile, Energy, and Wavelength...............43 2.1.2.2 Spectral Detection Region....................................................................46 2.1.2.3 Detection Gate Width and Timing........................................................47 2.1.2.4 Calibration.............................................................................................49 2.1.2.4.1 Calibration via Laser Extinction.....................................................49 2.1.2.4.2 Calibration via Cavity Ringdown...................................................50 vi 2.1.2.4.3 Calibration via Gravimetric Techniques.........................................51 2.1.2.4.4 Calibration via 3-Color Pyrometry.................................................52 2.1.2.4.5 General Concerns in Calibrating LII...............................................53 2.2 Laser Extinction................................................................................................54 2.3 Laser-induced Fluorescence..............................................................................59 2.3.1 Theory of Laser-induced Fluorescence.....................................................60 2.3.2 LIF Calibration..........................................................................................65 2.4 Temperature Measurement...............................................................................66 Chapter 3 EXPERIMENTAL APPROACH......................................................................................69 3.1 Materials...........................................................................................................69 3.2 Experimental Approach....................................................................................71 Chapter 4 EXPERIMENTAL RESULTS AND MODELING ANALYSIS FOR ETHANOL AND DME..................................................................................................................................83 4.1 Experimental Results........................................................................................84 4.1.1 Temperature Profiles.................................................................................84 4.1.2 Spectra Scanning and PAH Concentration Profiles..................................91 4.1.3 Soot Volume Fraction Profiles..................................................................95 4.1.4 Effect of Additives on PAH and Soot Volume Fraction Profiles.............97 4.2 Modeling Analysis..........................................................................................106 4.2.1 DME Consumption.................................................................................109 4.2.2 Ethanol Consumption..............................................................................114 4.2.3 Effect of Molecular Structure of Additives............................................120 4.2.4 Effect of Temperature.............................................................................121 Chapter 5 MODELING STUDY OF NO ON SOOT REDUCTION............................................123 2 5.1 Modeling Conditions......................................................................................123 5.2 Chemical Mechanisms....................................................................................124 5.3 Validation of Combined Mechanisms............................................................125 5.4 Reaction Pathways..........................................................................................133 5.4.1 Fuel Destruction to Benzene...................................................................134 5.4.2.1 Ethylene Consumption........................................................................134 5.4.2.2 Benzene Formation.............................................................................137 5.4.2 PAH Growth...........................................................................................141 5.4.2.1 Naphthalene (C H ) Formation.........................................................141 10 8 5.4.2.2 Phenanthrene (A3) Formation.............................................................144 vii 5.4.2.3 Pyrene Formation................................................................................148 5.5 Mechanisms of Soot Reduction......................................................................153 5.5.1 Overview.................................................................................................153 5.5.2 Chemical Effect of NO ..........................................................................153 2 5.5.2.1 NO Reactions.....................................................................................153 2 5.5.2.2 Effect of NO on Benzene Formation.................................................160 2 5.5.2.3 Effect of NO on PAH Growth...........................................................174 2 5.5.3 Effect of Temperature.............................................................................183 5.5.3.1 Temperature Effect on Benzene Formation........................................187 5.5.3.2 Temperature Effect on C H Formation.............................................198 8 6 Chapter 6 CONCLUSIONS AND SUGGESTIONS FOR FUTURE WORK................................210 6.1 Conclusions...........................................................................................................210 6.2 Suggestions for Future Work................................................................................212 REFERENCES...............................................................................................................214 APPENDIX Reactions for HN mechanism...................................................................229 viii LIST OF FIGURES Figure 1-1 Jet-Propulsion Fuel 8. .....................................................................................3 Figure 1-2 Laboratory flames and reactors with associated chemical and physical processes. ...................................................................................................................6 Figure 1-3 TEM photograph of typical soot aggregates emitted form long residence time turbulent acetylene/air diffusion flames where emitted soot properties were independent of residence time.16...............................................................................13 Figure 1-4 Total surface area of soot particles per cm3 = π <d2>N, as a function of age for flames of 3 stoichiometries:◇, C/O=0.79; □,0.76; △, 0.7. ............................15 Figure 1-5 Upper portion: volume fraction of soot as a function of time for flames with six different stoichiometries, as shown. The approximately 15 data points for each curve are omitted for clearity. Lower portion: specific surface growth rates as a function of time. .......................................................................................................15 Figure 1-6 Effect of the relative reactivity of soot and ΣPAH. C/O=0.79. (□) 10mm,(Δ) 17mm, (●) 25mm. ..................................................................................................19 Figure 1-7 Collision efficiencies at different distances from burner. γ (×104) : acetylene-soot (□) C/O = 0.70, (○) C/O = 0.79; γ : (■)C/O = 0.70,(●) C/O = 0.79. .....19 PAH-soot Figure 1-8 Sketch of the structure of soot emitted from a diesel engine. .......................23 Figure 1-9 Influence of various gaseous additives on the critical C/O-ratio for the onset of sooting in an ethylene/air flame. ..........................................................................26 Figure 1-10 Influence of gaseous additives on the downstream ( t ≈ 30 ms ) soot yield in an ethylene/air flame. C/O ~ 0.76, fv~ 1.5 x 10-7 ...............................................26 Figure 1-11 Smoke emissions from diesel engines with oxygenated additives, from Miyamoto et al. ........................................................................................................31 Figure 1-12 Acetylene concentration evolution of fuels with about same centane number. In the figure, intervals of confidence of 80% are indicated. Test condition: engine speed = 1250 rpm, 4.5 bar of i.m.e.p., start of combustion = TDC. ........................33 Figure 2-1 Optical setup for 2-D LII measurements. LDF – laminar diffusion flame, BB – beam block, DM – dichroic mirror, ½-λ - half-wave plate, GL – Glan-Laser prism, A – aperture, P – prism, CL – cylindrical lens, SL – spherical lens, and ICCD – intensified CCD. ......................................................................................................42 Figure 2-2 Fluence dependence of LII measured in steady laminar diffusion flames. Data were collected at H = 20 mm in the ethylenec/air flame for detection gate durations of 19 ns (+) and 85 ns (◊) – both gates opening coincident with the arrival of the ≈ 5 ns laser pulse. Data are also shown for the methane/air flame at H = 50 mm with 85 ns gate (●). Raw signals for each condition have been normalized to a value of 1.0 at a fluence of 0.6 J/cm2. The solid line shown is the least-squares power-law fit of the methane data for fluences greater than 0.03 J/cm2; the fit follows the expression signal ∝ fluence 0.34. reference [89].......................................................44 ix Figure 2-3 Temporal profile of a LII signal obtained in the ethene-air laminar diffusion flame at heights of 10 and 30 mm above the fuel tube exit and at the radial locations corresponding to peak soot volume fraction for these heights.................................48 Figure 2-4 Extinction by a collection of particles. ..........................................................54 Figure 2-5 Schematic diagram of two-level model of induced fluorescence..................61 Figure 3-1 Chemical structure of ethanol and DME........................................................70 Figure 3-2 Schematic diagram of experimental setup.....................................................72 Figure 3-3 Schematic diagram of fuel, additive, and air supply systems........................72 Figure 3-4 The size of PAH and their spectral properties. .............................................76 Figure 3-5 Diagram of the Thermocouple Arrangement.................................................80 Figure 4-1 Temperature profiles of premixed ethylene/air flame, with and without ethanol and DME addition........................................................................................85 Figure 4-2 Flame temperature profiles from Intal and Senkan.144...................................88 Figure 4-3 Pictures of the ethylene/air flames with and without additives. (Digital Camera Setting: F=2.8, Time=1/800 s)....................................................................90 Figure 4-4 Fluorescence spectra. (a) φ = 2.34; (b) φ = 2.64............................................91 Figure 4-5 Fluorescence spectra of laminar premixed ethylene/air flat flame at different heights above the burner surface.145..........................................................................92 Figure 4-6 Normalized fluorescence intensity profiles of small PAH.............................94 Figure 4-7 Normalized fluorescence intensity profiles of large PAH.............................94 Figure 4-8 Comparison of soot volume fraction measurement results............................95 Figure 4-9 The effect of ethanol on small PAH profiles.................................................98 Figure 4-10 The effect of ethanol on large PAH profiles................................................98 Figure 4-11 The effect of ethanol on soot profiles..........................................................99 Figure 4-12 Comparison of ethanol effects on soot volume fraction profiles at Ф=2.34. .................................................................................................................................101 Figure 4-13 The effect of DME on small PAH profiles................................................102 Figure 4-14 The effect of DME on large PAH profiles.................................................102 Figure 4-15 The effect of DME on soot profiles...........................................................103 Figure 4-16 Comparison of the effects of ethanol and DME on small PAH profiles....104 Figure 4-17 Comparison of the effects of ethanol and DME on large PAH profiles....105 Figure 4-18 Comparison of the effects of ethanol and DME on soot profiles...............105 Figure 4-19 Comparison of the effects of ethanol and DME on predicted small PAH profiles....................................................................................................................107 Figure 4-20 Comparison of the effects of ethanol and DME on predicted large PAH profiles....................................................................................................................108 Figure 4-21 Comparison of the effects of ethanol and DME on predicted soot profiles108 Figure 4-22 Reaction flux diagram of DME consumption............................................109 Figure 4-23 Reaction flux diagram of CH consumption with 5% oxygen in the fuel by 3 the addition of DME at Ф=2.34..............................................................................111 x Figure 4-24 Reaction flux diagram of CH consumption with 5% oxygen in the fuel by 3 the addition of DME at Ф=2.64..............................................................................113 Figure 4-25 Reaction flux diagram of ethanol consumption with 5% oxygen in the fuel by the addition of ethanol at Ф=2.34......................................................................115 Figure 4-26 Reaction flux diagram of CH consumption with 5% oxygen in the fuel by 3 the addition of ethanol at Ф=2.34...........................................................................117 Figure 4-27 Reaction flux diagram of ethanol consumption with 5% oxygen in the fuel by the addition of ethanol at Ф=2.64......................................................................118 Figure 4-28 Reaction flux diagram of CH consumption with 5% oxygen in the fuel by 3 the addition of ethanol at Ф=2.64...........................................................................119 Figure 4-29 Mole concentration profiles of pyrene calculated using original and adjusted temperature profiles................................................................................................122 Figure 5-1 Comparison between Howard and HN mechanisms at Φ =2.34..................126 Figure 5-2 Comparison between Howard and HN mechanisms at Φ =2.64..................126 Figure 5-3 Small PAH profiles......................................................................................129 Figure 5-4 Large PAH profiles......................................................................................129 Figure 5-5 Soot volume fraction with and without NO at two equivalence ratios.......132 2 Figure 5-6 Reaction flux diagram of C H consumption at Ф=2.34.............................135 2 4 Figure 5-7 Reaction flux diagram of C H consumption at Ф=2.64.............................136 2 4 Figure 5-8 Reaction flux diagram of benzene production and destruction at Ф=2.34..138 Figure 5-9 Net production rate of benzene at Ф = 2.34.................................................139 Figure 5-10 Net production rate of benzene at Ф = 2.64...............................................140 Figure 5-11 Reaction flux diagram of C H production and destruction at Ф=2.34....142 10 8 Figure 5-12 Reaction flux diagram of C H production and destruction at Ф=2.64....142 10 8 Figure 5-13 Reaction flux diagram of A3 production and destruction at Ф=2.34.........145 Figure 5-14 Reaction flux diagram of A3 production and destruction at Ф=2.64.........146 Figure 5-15 Reaction flux diagram of pyrene (C H ) production and destruction at 16 10 Ф=2.34....................................................................................................................149 Figure 5-16 Reaction flux diagram of pyrene (C H ) production and destruction at 16 10 Ф=2.64....................................................................................................................150 Figure 5-17 Carbon flux among PAHs at Ф=2.34.........................................................152 Figure 5-18 Carbon flux among PAHs at Ф=2.64.........................................................152 Figure 5-19 Flux diagram of nitrogen atoms introduced by NO at Ф=2.34.................154 2 Figure 5-20 Flux diagram of NO consumption at Ф=2.34...........................................156 2 Figure 5-21 Flux diagram of NO consumption at Ф=2.64...........................................157 2 Figure 5-22 Mole concentration profiles of OH at Ф=2.34...........................................159 Figure 5-23 Mole concentration profiles of OH at Ф=2.64...........................................159 Figure 5-24 Mole concentration profiles of benzene.....................................................160 Figure 5-25 Net production rate of C H at Ф=2.34......................................................161 6 6 Figure 5-26 Net production rate of H CCCH at Ф=2.34...............................................162 2 Figure 5-27 Net production of H CCCH at Ф=2.34......................................................164 2 Figure 5-28 Total production and consumption of H CCCH at Ф=2.34......................165 2

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investigate the chemical processes leading to the abatement of aromatic species and soot by ethanol and effective than ethanol in reducing soot precursors, because more carbon in DME is removed from the simultaneously occurring coagulation and surface growth, and the transition to the chain-.
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