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Investigation of Thermal Accommodation Coefficients in Time-Resolved Laser-Induced Incandescence

Daun, K. J. ; Smallwood, G. J. ; Liu, F.

ASME International ; 2008

In: Journal of Heat Transfer Vol. 130, No. 12 ( 2008-12-01)

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In: Journal of Heat Transfer, ASME International, Vol. 130, No. 12 ( 2008-12-01)

Abstract: Accurate particle sizing through time-resolved laser-induced incandescence (TR-LII) requires knowledge of the thermal accommodation coefficient, but the underlying physics of this parameter is poorly understood. If the particle size is known a priori, however, TR-LII data can instead be used to infer the thermal accommodation coefficient. Thermal accommodation coefficients measured between soot and different monatomic and polyatomic gases show that the accommodation coefficient increases with molecular mass for monatomic gases and is lower for polyatomic gases. This latter result indicates that surface energy is accommodated preferentially into translational modes over internal modes for these gases.

Type of Medium: Online Resource

ISSN: 0022-1481 , 1528-8943

URL: Article

DOI: 10.1115/1.2977549

Language: English

Publisher: ASME International

Publication Date: 2008

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A Numerical Study on the Effect of Water Addition on NO Formation in Counterflow CH4/Air Premixed Flames

Guo, Hongsheng ; Neill, W. Stuart ; Smallwood, Gregory J.

ASME International ; 2008

In: Journal of Engineering for Gas Turbines and Power Vol. 130, No. 5 ( 2008-09-01)

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In: Journal of Engineering for Gas Turbines and Power, ASME International, Vol. 130, No. 5 ( 2008-09-01)

Abstract: The effect of water addition on NO formation in counterflow CH4/air premixed flames was investigated by numerical simulation. Detailed chemistry and complex thermal and transport properties were employed. The results show that the addition of water to a flame suppresses the formation of NO primarily due to flame temperature drop. Among a lean, a stoichiometric, and a rich premixed flame, the effectiveness of water addition is most significant for the stoichiometric flame and least for the rich flame. The addition of water also reduces the formation of NO in a flame because of the chemical effect. Compared to the stoichiometric flame, the chemical effect is intensified in the lean and rich flames.

Type of Medium: Online Resource

ISSN: 0742-4795 , 1528-8919

URL: Article

DOI: 10.1115/1.2432890

Language: English

Publisher: ASME International

Publication Date: 2008

detail.hit.zdb_id: 2010437-6

detail.hit.zdb_id: 165371-4

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An Improved Soot Formation Model for 3D Diesel Engine Simulations

Boulanger, Joan ; Liu, Fengshan ; Neill, W. Stuart ; [et al.]

ASME International ; 2007

In: Journal of Engineering for Gas Turbines and Power Vol. 129, No. 3 ( 2007-07-01), p. 877-884

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In: Journal of Engineering for Gas Turbines and Power, ASME International, Vol. 129, No. 3 ( 2007-07-01), p. 877-884

Abstract: Soot formation phenomenon is far from being fully understood today and models available for simulation of soot in practical combustion devices remain of relatively limited success, despite significant progresses made over the last decade. The extremely high demand of computing time of detailed soot models make them unrealistic for simulation of multidimensional, transient, and turbulent diesel engine combustion. Hence, most of the investigations conducted in real configuration such as multidimensional diesel engines simulation utilize coarse modeling, the advantages of which are an easy implementation and low computational cost. In this study, a phenomenological three-equation soot model was developed for modeling soot formation in diesel engine combustion based on considerations of acceptable computational demand and a qualitative description of the main features of the physics of soot formation. The model was developed based on that of Tesner et al. and was implemented into the commercial STAR-CD™ CFD package. Application of this model was demonstrated in the modeling of soot formation in a single-cylinder research version of Caterpillar 3400 series diesel engine with exhaust gas recirculation (EGR). Numerical results show that the new soot formulation overcomes most of the drawbacks in the existing soot models dedicated to this kind of engineering task and demonstrates a robust and consistent behavior with experimental observation. Compared to the existing soot models for engine combustion modeling, some distinct features of the new soot model include: no soot is formed at low temperature, minimal model parameter adjustment for application to different fuels, and there is no need to prescribe the soot particle size. At the end of expansion, soot is predicted to exist in two separate regions in the cylinder: in the near wall region and in the center part of the cylinder. The existence of soot in the near wall region is a result of reduced soot oxidation rate through heat loss. They are the source of the biggest primary particles released at the end of the combustion process. The center part of the cylinder is populated by smaller soot particles, which are created since the early stages of the combustion process but also subject to intense oxidation. The qualitative effect of EGR is to increase the size of soot particles as well as their number density. This is linked to the lower in-cylinder temperature and a reduced amount of air.

Type of Medium: Online Resource

ISSN: 0742-4795 , 1528-8919

URL: Article

DOI: 10.1115/1.2718234

Language: English

Publisher: ASME International

Publication Date: 2007

detail.hit.zdb_id: 2010437-6

detail.hit.zdb_id: 165371-4

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Radiative Properties of Numerically Generated Fractal Soot Aggregates: The Importance of Configuration Averaging

Liu, Fengshan ; Smallwood, Gregory J.

ASME International ; 2010

In: Journal of Heat Transfer Vol. 132, No. 2 ( 2010-02-01)

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In: Journal of Heat Transfer, ASME International, Vol. 132, No. 2 ( 2010-02-01)

Abstract: The radiative properties of numerically generated fractal soot aggregates were studied using the numerically accurate generalized multisphere Mie-solution method. The fractal aggregates investigated in this study contain 10–600 primary particles of 30 nm in diameter. These fractal aggregates were numerically generated using a combination of the particle-cluster and cluster-cluster aggregation algorithms with fractal parameters representing flame-generated soot. Ten different realizations were obtained for a given aggregate size measured by the number of primary particles. The wavelength considered is 532 nm, and the corresponding size parameter of primary particle is 0.177. Attention is paid to the effect of different realizations of a fractal aggregate with identical fractal dimension, prefactor, primary particle diameter, and the number of primary particles on its orientation-averaged radiative properties. Most properties of practical interest exhibit relatively small variation with aggregate realization. However, other scattering properties, especially the vertical-horizontal differential scattering cross section, are very sensitive to the variation in geometrical configuration of primary particles. Orientation-averaged radiative properties of a single aggregate realization are not always sufficient to represent the properties of random-oriented ensemble of fractal aggregates.

Type of Medium: Online Resource

ISSN: 0022-1481 , 1528-8943

URL: Article

DOI: 10.1115/1.4000245

Language: English

Publisher: ASME International

Publication Date: 2010

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Clouds Over Soot Evaporation: Errors in Modeling Laser-Induced Incandescence of Soot

Smallwood, G. J. ; Snelling, D. R. ; Liu, F. ; [et al.]

ASME International ; 2001

In: Journal of Heat Transfer Vol. 123, No. 4 ( 2001-08-01), p. 814-818

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In: Journal of Heat Transfer, ASME International, Vol. 123, No. 4 ( 2001-08-01), p. 814-818

Abstract: The ambiguity and incorrect treatment of the evaporation term among some LII models in the literature are discussed. This study does not suggest that the correct formulation presented for the evaporation model is adequate, or that it reflects the soot evaporation process under intense evaporation. The emphasis is that the current evaporation model must be used correctly in the evaluation of the LII model against experimental data. Numerical results are presented to demonstrate the significance of the molecular weight associated with the heat of evaporation and the thermal velocity of carbon vapor on the results obtained with the evaporation model. Other errors frequently repeated in the literature are also identified.

Type of Medium: Online Resource

ISSN: 0022-1481 , 1528-8943

URL: Article

DOI: 10.1115/1.1370507

Language: English

Publisher: ASME International

Publication Date: 2001

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An Improved Phenomenological Soot Formation Submodel for Three-Dimensional Diesel Engine Simulations: Extension to Agglomeration of Particles into Clusters

Boulanger, Joan ; Neill, W. Stuart ; Liu, Fengshan ; [et al.]

ASME International ; 2008

In: Journal of Engineering for Gas Turbines and Power Vol. 130, No. 6 ( 2008-11-01)

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In: Journal of Engineering for Gas Turbines and Power, ASME International, Vol. 130, No. 6 ( 2008-11-01)

Abstract: An extension to a phenomenological submodel for soot formation to include soot agglomeration effects is developed. The improved submodel was incorporated into a commercial computational fluid dynamics code and was used to investigate soot formation in a heavy-duty diesel engine. The results of the numerical simulation show that the soot oxidation process is reduced close to the combustion chamber walls, due to heat loss, such that larger soot particles and clusters are predicted in an annular volume at the end of the combustion cycle. These results are consistent with available in-cylinder experimental data and suggest that the cylinder of a diesel engine must be split into several volumes, each of them with a different role regarding soot formation.

Type of Medium: Online Resource

ISSN: 0742-4795 , 1528-8919

URL: Article

DOI: 10.1115/1.2939003

Language: English

Publisher: ASME International

Publication Date: 2008

detail.hit.zdb_id: 2010437-6

detail.hit.zdb_id: 165371-4

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