Detailed Studies Of Soot Formation In Laminar Diffusion Flames For Application To Modeling Studies

Detailed Studies of Soot Formation in Laminar Diffusion Flames for Application to Modeling Studies

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Page : 104 pages

File Size : 36,30 MB

Release : 1996

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An investigation of soot formation in laminar diffusion flames showed that soot particle surface growth under laminar diffusion flame conditions ceases because of the depletion of hydrocarbon species and not soot particle reactivity loss due to thermal aging of the particles. This result was obtained through direct species concentration measurements under well-controlled conditions, while the particle reactivity effects were calculated based on premixed flame results along with particle temperature/time information available from earlier laminar diffusion flame studies. Comparisons with a soot formation model which incorporated detailed chemistry effects showed good agreement in terms of predicted and measured species concentration and soot particle field evolution. In addition, a novel technique for measuring soot volume fraction was developed based on laser-induced incandescence and was successfully applied to similar laminar diffusion flame studies. This technique was extended to droplet and turbulent diffusion flame conditions where a two-dimensional imaging approach was employed to measure soot volume fraction. Finally, the complete data set from these studies was assembled in a form suitable for dissemination on computer diskettes throughout the research community for comparison with modeling efforts.





Detailed Modeling of Soot Formation/oxidation in Laminar Coflow Diffusion Flames

Author : Qingan Zhang

Publisher :

Page : 0 pages

File Size : 21,38 MB

Release : 2009

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ISBN : 9780494609002

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The first goal of this thesis is to develop and validate a modeling tool into which fundamental combustion chemistry and aerosol dynamics theory are implemented for investigating soot formation/oxidation in multi-dimensional laminar coflow diffusion flames taking into account soot polydispersity and fractal-like aggregate structure. The second goal is to use the tool to study soot aggregate formation/oxidation in experimentally studied laminar coflow diffusion flames to advance the understanding of soot aggregate formation/oxidation mechanism. The first part of the thesis deals with the large CPU time problem when detailed models are coupled together. Using the domain decomposition method, a high performance parallel flame code is successfully developed. An advanced sectional aerosol dynamics model which can model fractal-like aggregate structure is successfully implemented into the parallel flame code. The performance of the parallel code is demonstrated through its application to the modeling of soot formation/oxidation in a laminar coflow CH4/air diffusion flame. The parallel efficiency reaches as high as 83%. In the third part of the thesis, the effects of oxidation-driven soot aggregate fragmentation on aggregate structure and soot oxidation rate are studied. Three fragmentation models with different fragmentation patterns are developed and implemented into the sectional aerosol dynamics model. The implementation of oxidation-driven aggregate fragmentation significantly improves the prediction of soot aggregate structure in the soot oxidation region. The second part of the thesis numerically explores soot aggregate formation in a laminar coflow C2H4/air diffusion flame using detailed PAH-based combustion chemistry and a PAH-based soot formation/oxidation model. Compared to the measured data, flame temperature, axial velocity, C2 H2 and OH concentrations, soot volume fraction, the average diameter and the number density of primary particles are reasonably well predicted. However, it is very challenging to predict effectively the average degree of particle aggregation. To do so, particle-particle and fluid-particle interactions that may cause non-unitary soot coagulation efficiency need to be considered. The original coagulation model is enhanced in this thesis to accommodate soot coagulation efficiency. Different types of soot coagulation efficiency are numerically investigated. It is found that a simple adjustment of soot coagulation efficiency from 100% to 20% provides good predictions on soot aggregate structure as well as flame properties.



Soot Formation in Combustion

Author : Henning Bockhorn

Publisher : Springer Science & Business Media

Page : 595 pages

File Size : 33,96 MB

Release : 2013-03-08

Category : Science

ISBN : 3642851673

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Book Description

Soot Formation in Combustion represents an up-to-date overview. The contributions trace back to the 1991 Heidelberg symposium entitled "Mechanism and Models of Soot Formation" and have all been reedited by Prof. Bockhorn in close contact with the original authors. The book gives an easy introduction to the field for newcomers, and provides detailed treatments for the specialists. The following list of contents illustrates the topics under review:



Flow/Soot-Formation Interactions in Nonbuoyant Laminar Diffusion Flames

Author : National Aeronautics and Space Administration (NASA)

Publisher : Createspace Independent Publishing Platform

Page : 110 pages

File Size : 18,61 MB

Release : 2018-06-15

Category :

ISBN : 9781721129454

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Book Description

This is the final report of a research program considering interactions between flow and soot properties within laminar diffusion flames. Laminar diffusion flames were considered because they provide model flame systems that are far more tractable for theoretical and experimental studies than more practical turbulent diffusion flames. In particular, understanding the transport and chemical reaction processes of laminar flames is a necessary precursor to understanding these processes in practical turbulent flames and many aspects of laminar diffusion flames have direct relevance to turbulent diffusion flames through application of the widely recognized laminar flamelet concept of turbulent diffusion flames. The investigation was divided into three phases, considering the shapes of nonbuoyant round laminar jet diffusion flames in still air, the shapes of nonbuoyant round laminar jet diffusion flames in coflowing air, and the hydrodynamic suppression of soot formation in laminar diffusion flames. Dai, Z. and Lin, K.-C. and Sunderland, P. B. and Xu, F. and Faeth, G. M. Glenn Research Center NAG3-661



Numerical Simulation of AxiSymmetric Laminar Diffusion Flames with Soot

Author : Adhiraj Dasgupta

Publisher :

Page : pages

File Size : 11,52 MB

Release : 2015

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Detailed numerical modeling of combustion phenomena, soot formation, and radi-ation is an active area of research. In this work a general-purpose, pressure-based,finite volume code for modeling laminar diffusion flames has been incorporatedinto the CFD code OpenFOAM. The code uses a mixture-averaged model for thecalculation of transport coefficients, and can be used to perform detailed modelingof multi-dimensional laminar flames using realistic molecular transport, and withdetailed chemical mechanisms containing hundreds of chemical species and reac-tions. Two soot models have been incorporated into the code: a semi-empiricaltwo-equation model, as well as a detailed Method of Moments with InterpolativeClosure (MOMIC). An emission-only, optically-thin radiation model has also beenincluded in the code to account for the radiative heat loss, and sophisticated radia-tion models with detailed calculations of spectral properties and radiative intensityhave also been included. The flame code showed excellent scalability on massivelydistributed, high-performance computer systems. The code has been validated bymodeling four axisymmetric, co-flowing laminar diffusion flames, and the resultshave been found to be mostly within experimental uncertainty, and comparableto results reported in the literature for the same and similar configurations. Anumber of parametric studies to study the effects of detailed gas-phase chemistry,soot models and radiation have also been performed on these flame configurations.It has been found that the flames considered in this work are all optically thin,and so the simple, emission-only, optically-thin radiation model can be used tomodel these flames with good accuracy and a reasonable computational effort. Inparticular, the detailed radiation models increase the computational cost by twoorders of magnitude, and thus their applicability in a detailed calculation may belimited.It was found that the two-equation soot model used in conjunction with a gas-phase mechanism that adequately describes the combustion of C2 hydrocarbons produces results in close agreement with experimental data for a 1-bar ethylene-airflame, a 10 bar methane-air flame, as well as an ethane-air flame at 10 bar. Thedetailed MOMIC soot model requires the use of a larger, more detailed gas-phasechemical mechanism containing polycyclic aromatic hydrocarbons (PAH) with fourrings, and thus the computational cost associated with the MOMIC soot modelis significantly higher. The detailed model was used to model the flames, andcomputed soot levels were within a factor of two of the experimental values, whichis typically considered good agreement considering the complex physics involved.The last flame studied using both the soot models was a N2 -diluted ethylene-airflame, in which the predicted values of major gas-phase species were seen to be closeto the experimental values, but the soot levels were off by an order of magnitude.Notwithstanding the lack of agreement with measurements for this flame, the flamesolver with the soot models was demonstrated to be a robust, scalable, and generalcode with potential applications to a variety of laminar flames in the non-premixed,partially premixed and premixed regimes.







Fuel Structure and Pressure Effects on the Formation of Soot Particles in Diffusion Flames

Author : Robert J. Santoro

Publisher :

Page : 67 pages

File Size : 19,50 MB

Release : 1990

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ISBN :

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Studies emphasizing the effects of fuel concentration and operating pressure on the formation of soot particles have been conducted in a series of laminar diffusion flames. These experiments have shown that fuel concentration has a measurable effect on the amount of soot formed in the flame. However, a simple, constant proportionality between the fuel concentration and soot volume fraction has not been found to apply for the range of flow conditions studied. This observation is believed to be a result of flame residence time and diffusion effects which mitigate the consequences of reduced initial fuel concentration. Comparisons with simple laminar diffusion flame models are currently being used to investigate the relationship between initial fuel concentration and local flame concentration fields. Similar studies of soot formation in laminar diffusion flames as a function of operating pressure have also been completed for ethene, ethane and propene fuel species. Keywords: Soot formation, Soot particles, Diffusion flames. (JES).



Prediction of Soot Formation in Laminar Opposed Diffusion Flame with Detailed and Reduced Reaction Mechanisms

Author : Hojoon Chang

Publisher :

Page : pages

File Size : 18,75 MB

Release : 2004

Category : Combustion

ISBN :

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Book Description

The present work focuses on a computational study of a simplified soot model to predict soot production and destruction in methane/oxidizer (O2 and N2) and ethylene/air flames using a one-dimensional laminar opposed diffusion flame setup. Two different detailed reaction mechanisms (361 reactions & 61 species for methane/oxidizer flame and 527 reactions & 99 species for ethylene/air flame) are used to validate the simplified soot model in each flame. The effects of strain rate and oxygen content on the soot production and destruction are studied, and the soot related properties such as soot volume fraction, particle number density and particle diameter are compared with published results. The results show reasonable agreement with data and that the soot volume fraction decreases with higher strain rate and lower oxygen content. The simplified soot model has also been used with two reduced reaction mechanisms (12-step, 16-species for methane flame and 20-species for ethylene flame) since such reduced mechanisms are computationally more efficient for practical application. The profiles of the physical properties and the major species are in excellent agreement with the results using the detailed reaction mechanisms. However, minor hydrocarbon-species such as acetylene (C2H2) that is the primary pyrolysis species in the simplified soot model is significantly over predicted and this, in turn, results in an over-prediction of soot production. Finally, the reduced reaction mechanism is modified to get more accurate prediction of the minor hydrocarbon-species. The modified reduced reaction mechanism shows that the soot prediction can be improved by improving the predictions of the key minor species.