Vijaya Damodara scite author profile

A reduced combustion mechanism containing 50 C-C species and soot precursors has been developed and validated against experimental data. The combustion mechanism is then employed in the computational fluid dynamics (CFD) of modeling of soot emission and combustion efficiency (CE) of controlled flares for which experimental soot and CE data are available. The validated CFD modeling tools are useful for oil, gas, and chemical industries to comply with U.S. Environmental Protection Agency's (EPA) mandate to achieve smokeless flaring with a high CE.

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Combustion mechanism development and CFD simulation for the prediction of soot emission during flaring

Wang

Lou

Chen

et al. 2016

Front. Chem. Sci. Eng.

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On Numerical Simulation of Black Carbon (Soot) Emissions from Non-Premixed Flames

Patki¹,

Li²,

Chen³

et al. 2014

GEP

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Soot emissions (PM 2.5) from land-based sources pose a substantial health risk, and now are subject to new and tougher EPA regulations. Flaring produces significant amount of particulate matter in the form of soot, along with other harmful gas emissions. A few experimental studies have previously been done on flames burning in a controlled condition. In these lab-experiments, great effort is needed to collect, sample, and analyze the soot so that the emission rate can be calculated. Soot prediction in flares is tricky due to variable conditions such as radiation and surrounding air available for combustion. Work presented in this paper simulates some lab-scale flares in which soot yield for methane flame mixture was measured under different conditions. The focus of this paper is on soot modeling with various flair operating conditions. The computational fluid dynamics software ANSYS Fluent 13 is used. Different soot models were explored along with other chemistry mechanisms. The effect of radiation models, quantity of air supplied, different fuel mixture and its effect over soot formations were also studied.

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Flare performance modeling and set point determination using artificial neural networks

Damodara

Alphones

Chen

et al. 2019

Int J Energy Environ Eng

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Current EPA regulations mandate a minimum combustion zone heating value of 270 BTU/scf and a net heating value dilution parameter of NHV dil ≥ 22 BTU/ft 2 for all steam/air/non-assisted flares while maintaining a high combustion efficiency (CE). To achieve the target performance along with satisfying the EPA regulations, it is necessary to understand the influence of various operating parameters. Studying the effect of operating parameters through experiments is both expensive and time consuming. It is more cost effective to use validated models to guide flare operations. In this study, controlled flare test data conducted from 1983 to 2014 with a wide range of exit velocities, heating values, and fuel compositions have been modeled. The purpose of this study is to develop models that can be robustly used in the industry to achieve the desired CE without visible emissions (smoke). Steam-/air-assist rates, exit velocity, and the vent gas composition, which can be either controlled or measured in flare operations, are used as independent variables in the models. Neural network (NN) models were developed for the air-assisted, steam-assisted, and non-assisted flares using various types of fuels like propylene, propane, natural gas, methane, and ethylene. The flare performance models such as CE and opacity were developed using neural network toolbox in MATLAB. NN models for steam and air-assisted flare tests are in good agreement with experimental data and have been demonstrated by the average correlation coefficient of 0.95 and 0.97 for air-assisted and steam-assisted flare data, respectively. The very low mean absolute errors of 1.1% and 1.4% for air-assisted and steam-assisted flare data, respectively, also indicate the robustness of the NN models. 2-D and 3-D contour plots are presented to show the effect of key operating parameters. The set points (amount of steam/air/make-up fuel required) at the Incipient Smoke Point (ISP) and for Smokeless Flaring (SLF) have been developed based on the neural network models performed in this study. Desirable operating inputs can be set for the ISP and for SLF (Opacity ≤ Opacity ISP ) subject to heating value constraints (NHV dil ≥ 22 BTU/ft 2 & NHV CZ ≥ 270 BTU/scf) with a high CE (≥ 96.5%) for the 1984 EPA and 2010 TCEQ flare study test cases.

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Reduced Combustion Mechanism for C₁-C₄ Hydrocarbons and its Application in CFD Flare Modeling

Damodara¹,

Chen²,

Lou³

et al. 2016

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Vijaya Damodara

Reduced combustion mechanism for C₁–C₄ hydrocarbons and its application in computational fluid dynamics flare modeling

Combustion mechanism development and CFD simulation for the prediction of soot emission during flaring

On Numerical Simulation of Black Carbon (Soot) Emissions from Non-Premixed Flames

Flare performance modeling and set point determination using artificial neural networks

Reduced Combustion Mechanism for C₁-C₄ Hydrocarbons and its Application in CFD Flare Modeling

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Vijaya Damodara

Reduced combustion mechanism for C1–C4 hydrocarbons and its application in computational fluid dynamics flare modeling

Combustion mechanism development and CFD simulation for the prediction of soot emission during flaring

On Numerical Simulation of Black Carbon (Soot) Emissions from Non-Premixed Flames

Flare performance modeling and set point determination using artificial neural networks

Reduced Combustion Mechanism for C1-C4 Hydrocarbons and its Application in CFD Flare Modeling

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Product

Resources

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Reduced combustion mechanism for C₁–C₄ hydrocarbons and its application in computational fluid dynamics flare modeling

Reduced Combustion Mechanism for C₁-C₄ Hydrocarbons and its Application in CFD Flare Modeling