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Radiation effect on temperature distribution and NO formation in a diffusion flame under reduced gravity conditions

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Abstract

Combustion of hydrocarbon fuel is accompanied with the formation of nitric oxide (NO) amongst other harmful emissions. In this work, a numerical investigation has been made for understanding the effect of radiative heat transfer on temperature distribution and formation of thermal NO in a methane–air diffusion flame under different reduced gravity environments. Conservation equations of overall mass, species concentration, momentum and energy for the reactive flows have been numerically solved with the use of finite difference scheme. In addition to that a semi-empirical soot model and an optically thin radiation model have been incorporated in the simulation. Gravity level is varied by the changed values of acceleration due to gravity. A thermal NO model incorporated accounts for the NO formation process which is decoupled from the hydrocarbon combustion. The relevant conservation equations have been solved as a post combustion reaction process. The flame height drops marginally with the reduction of gravity. Temperature becomes more uniformly distributed at lower gravity. NO formation boosts up with the fall of gravity below normal level when no radiation effect is considered. However, when radiation is considered, NO formation declines marginally with the reduction of gravity levels. Also in this case, concentration values of NO compare substantially lower with those without radiation. The upsurge of NO formation due to decline in gravity; and on the other hand, a shrinkage in concentration values of NO due to radiation effect can be attributed mainly to the rise and fall of temperature respectively in the computational zone.

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Abbreviations

Cj :

Concentration of species

cp :

Specific heat

fv :

Soot volume fraction

g:

Acceleration due to gravity

h:

Enthalpy

k:

Absorption coefficient

Le:

Lewis number

n:

Soot particle number density

NOx :

Oxides of nitrogen

r:

Radial distance

t:

Time

v:

Velocity

Y:

Mole fraction

z:

Axial distance

ρ:

Density

\(\dot{\omega }\) :

Reaction rate

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Authors and Affiliations

  1. Department of Mechanical Engineering, Heritage Institute of Technology, East Kolkata, India

    Arup Jyoti Bhowal

  2. Department of Mechanical Engineering, Indian Institute of Engineering Science and Technology, Shibpur, West Bengal, India

    Bijan Kumar Mandal

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  1. Arup Jyoti Bhowal
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  2. Bijan Kumar Mandal
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Correspondence to Arup Jyoti Bhowal.

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Bhowal, A.J., Mandal, B.K. Radiation effect on temperature distribution and NO formation in a diffusion flame under reduced gravity conditions. Heat Mass Transfer 52, 227–243 (2016). https://doi.org/10.1007/s00231-015-1552-0

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  • DOI: https://doi.org/10.1007/s00231-015-1552-0

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