Effects of Exhaust Gas Dilution on the Laminar Burning Velocity of Real-World Gasoline Fuel Flame in Air

Bhattacharya, Atreyee; Banerjee, Deb Kumar; Mamaikin, Dmitrii; Datta, Amitava; Wensing, Michael

doi:10.1021/acs.energyfuels.5b01299

Cited by 15 publications

(5 citation statements)

References 42 publications

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“…Similar correlations were reported in the literature, for example, 1 − 2 . 5 Y dil for 0–30% mass fraction of diluent by Ryan and Lestz, 20 and 1 − 2 . 06 V dil 0 . 73 for 0–30% volume fraction of diluent by Rhodes and Keck. 41 Recently, Bhattacharya et al 21 measured LBVs of gasoline-air flame in the equivalence ratio range of 0.7–1.3 by adding an inert gas up to 25% under T 0 = 423 K and p = 1 atm conditions, and formulated a quartic equation to model the diluent effect on LBV. Although the equation was complex compared to the previous correlations, it resulted in an average coefficient of 2.2 which was similar to them.…”

Section: Modeling Resultsmentioning

confidence: 99%

“…It is worth noting that the diluent effect was referred to the correlation proposed by Metghalchi and Keck 10 because of the consistent experimental findings in the literature. 8,10,20,21 The developed LBV model was validated using the measurement data of the LBV of gasoline found in the literature, and the model was applied to the CFD simulations of DISI engine under the various operating conditions to explore its prediction capability.…”

Section: Introductionmentioning

confidence: 99%

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Modeling laminar burning velocity of gasoline using an energy fraction-based mixing rule approach

Kim

Min

2018

Proceedings of the Institution of Mechanical Engineers, Part D:

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To determine an optimum combustion chamber design and engine operating strategies, computational fluid dynamics simulations of direct-injection spark-ignition engines have become an indispensable step in the powertrain development process. The laminar burning velocity of gasoline is known as an essential input parameter for combustion simulations. In this study, a new methodology for modeling the laminar burning velocity of gasoline for direct-injection spark-ignition engine simulations is proposed. Considering the gasoline as a complex mixture of hydrocarbon fuel, three hydrocarbons, iso-octane, n-heptane, and toluene were incorporated as surrogate fuel components to represent gasoline with distinct aromatic laminar flame characteristics compared to alkane. A mixing rule, based on energy fractions, was adopted to consider the compositional variation of gasoline. The laminar burning velocities of iso-octane, n-heptane, and toluene were calculated under wide thermo-chemical conditions in conjunction with detailed chemical reaction kinetics in the premixed flame simulation. Finally, a set of laminar burning velocity model equations was derived by curve-fitting the flame simulation results of each hydrocarbon component in consideration of the effect of temperature, pressure, and diluent. The laminar burning velocity model was validated against the measurement data of gasoline’s laminar burning velocity found in the literature, and was applied to the computational fluid dynamics simulation of a direct-injection spark-ignition engine under the various operating conditions to explore the prediction capability.

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Section: Modeling Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modeling laminar burning velocity of gasoline using an energy fraction-based mixing rule approach

Kim

Min

2018

Proceedings of the Institution of Mechanical Engineers, Part D:

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“…The article introduces a new method to determine correction factors for exhaust gas recirculation (EGR) from engine pressure trace data by using a reverse thermodynamic model. Using this approach, a new correlation for the effects of exhaust gas diluent on the laminar burning velocity of a EURO VI specification gasoline is derived and compared against existing models by Metghalchi and Keck [10], Rhodes and Keck [11], Fu et al [12] and Bhattacharya et al [14]. It is found that existing models tend to overestimate the impact of EGR on laminar burning velocity, probably because their derivation did not consider all chemical species contained in exhaust gas.…”

Section: Discussionmentioning

confidence: 99%

“…The most recently suggested correction factor is based on a combination of simulations and experiments. Bhattacharya et al [14] used a commercial gasoline (Shell V-Power as available in Germany) that, given the publication date of the paper, should be compliant with EURO VI regulations. For the experimental data, Bhattacharya et al used a heat flux burner to determine the stretch free laminar burning velocities with the diluent comprising of carbon dioxide and nitrogen.…”

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confidence: 99%

A Comparison of EGR Correction Factor Models Based on SI Engine Data

Smith¹,

Ruprecht²,

Roberts³

et al. 2019

SAE Int. J. Engines

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The article compares the accuracy of different exhaust gas recirculation (EGR) correction factor models under engine conditions. The effect of EGR on the laminar burning velocity of a EURO VI E10 specification gasoline (10% Ethanol content by volume) has been back calculated from engine pressure trace data, using the Leeds University Spark Ignition Engine Data Analysis (LUSIEDA) reverse thermodynamic code. The engine pressure data ranges from 5% to 25% EGR (by mass) with the running conditions, such as spark advance and pressure at intake valve closure, changed to maintain a constant engine load of 0.79 MPa gross mean effective pressure (GMEP). Based on the experimental data, a correlation is suggested on how the laminar burning velocity reduces with increasing EGR mass fraction. This correlation, together with existing models, was then implemented into the quasi-dimensional Leeds University Spark Ignition Engine (LUSIE) predictive engine code and resulting predictions are compared against measurements. It was found that the new correlation is in good agreement with experimental data for a diluent range of 5%-25%, providing the best fit for both engine loads investigated, whereas existing models tend to overpredict the reduction of burning velocity due to EGR.

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“…Jerzembeck et al 30 employed the spherically expanding flames under a constant pressure approach to understand how laminar burning velocities of standard gasoline at 10−25 bar and 373 K are affected by N 2 dilution. Lastly, Bhattacharya et al 31 measured the laminar flame speeds of gasoline/air mixtures diluted with N 2 at 423 K and 1 bar with a heat flux burner.…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

2019

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The exhaust gas recirculation effect on the laminar burning velocity (S L ) and flame stability of CO 2 -diluted isooctane/air and high/low research octane number (RON) gasoline/air mixtures was investigated by studying spherically expanding flames at a constant pressure of 1 bar and 373−473 K. Measurements were carried out in a constant volume combustion vessel. The experimental setup and methodology were validated by comparing the isooctane results with the existing literature. The results of measurements showed that flame speeds of commercial gasolines do not vary significantly with RON whereas S L values of isooctane flames are consistently slower than those of gasoline. A temperature increase of 100 K (373−473 K) yielded 51−56, 50−54, and 48−51% increases in laminar burning velocities for the high RON gasoline, low RON gasoline, and isooctane, respectively. Investigation of burned gas Markstein lengths (L b ) revealed that the flame stability of the three fuels deteriorates considerably with increasing equivalence ratio; however, the burned gas Markstein lengths were not significantly affected by the 100 K increase in initial temperature. Similar to the laminar burning velocity, the burned gas Markstein lengths of the high and low RON gasoline flames were very close, but the isooctane/air flames had slightly higher burned gas Markstein lengths. The CO 2 addition at 473 K yielded 41−46, 42−44, and 46−49% decreases in laminar burning velocities for the high RON gasoline, low RON gasoline, and isooctane, respectively, due to a combination of dilution, thermaldiffusion, and chemical effects. The chemical effect had a minor contribution of 23−25% on the decrease in the laminar burning velocity at lean and stoichiometric conditions, and its impact dropped to only 15% for rich mixtures. The addition of CO 2 also postponed the initiation of cellular formation by increasing the L b values of the three fuels. Numerical analysis was performed with the CHEMKIN software [Kee et al. PREMIX: A Fortran Program for Modeling Steady Laminar One-Dimensional Premixed Flames; Reaction Design: 1985] using the chemical mechanisms of Chaos et al. [Int.

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Effects of Exhaust Gas Dilution on the Laminar Burning Velocity of Real-World Gasoline Fuel Flame in Air

Cited by 15 publications

References 42 publications

Modeling laminar burning velocity of gasoline using an energy fraction-based mixing rule approach

Modeling laminar burning velocity of gasoline using an energy fraction-based mixing rule approach

A Comparison of EGR Correction Factor Models Based on SI Engine Data

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

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Effects of Exhaust Gas Dilution on the Laminar Burning Velocity of Real-World Gasoline Fuel Flame in Air

Cited by 15 publications

References 42 publications

Modeling laminar burning velocity of gasoline using an energy fraction-based mixing rule approach

Modeling laminar burning velocity of gasoline using an energy fraction-based mixing rule approach

A Comparison of EGR Correction Factor Models Based on SI Engine Data

Experimental and Numerical Investigation of the CO2 Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

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Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures