An Experimental and Numerical Analysis of Puff Hydrodynamics

The permeability of a tobacco rod in a cigarette increases as it converts into char and ash in the coal. The hot coal introduces a significant resistance to the air flow when air passes through. Through a series of experiments, the cigarette burn line and burn rate, the centerline temperature, and t...

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Main Authors: Saidi MS, Hajaligol MR, Rasouli F
Format: Article
Language:English
Published: Sciendo 2004-10-01
Series:Beiträge zur Tabakforschung International
Online Access:https://doi.org/10.2478/cttr-2013-0776
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spelling doaj-ef3425e2f40d4255918f3432e3ba3ffd2021-09-06T19:22:14ZengSciendoBeiträge zur Tabakforschung International1612-92372004-10-0121315716610.2478/cttr-2013-0776cttr-2013-0776An Experimental and Numerical Analysis of Puff HydrodynamicsSaidi MS0Hajaligol MR1Rasouli F2Isfahan University of Technology, Isfahan, IranPhilip Morris USA, Research Center, Richmond, Virginia 23234, USAPhilip Morris USA, Research Center, Richmond, Virginia 23234, USAThe permeability of a tobacco rod in a cigarette increases as it converts into char and ash in the coal. The hot coal introduces a significant resistance to the air flow when air passes through. Through a series of experiments, the cigarette burn line and burn rate, the centerline temperature, and the pressure drop were measured for continuous puffing conditions. The gas viscosity was calculated from the temperature distribution inside the cigarette and applying Sutherland's law. Then, the experimental setup was mathematically modeled from a commercially available CFD (Computational Fluid Dynamics) code and, by matching the numerical and experimental results, the changes in coal and filter permeability during puffing were estimated. The numerical simulation successfully reproduced the results of experiments on the air flow through the coal, ventilation holes and paper wrapper.https://doi.org/10.2478/cttr-2013-0776
collection DOAJ
language English
format Article
sources DOAJ
author Saidi MS
Hajaligol MR
Rasouli F
spellingShingle Saidi MS
Hajaligol MR
Rasouli F
An Experimental and Numerical Analysis of Puff Hydrodynamics
Beiträge zur Tabakforschung International
author_facet Saidi MS
Hajaligol MR
Rasouli F
author_sort Saidi MS
title An Experimental and Numerical Analysis of Puff Hydrodynamics
title_short An Experimental and Numerical Analysis of Puff Hydrodynamics
title_full An Experimental and Numerical Analysis of Puff Hydrodynamics
title_fullStr An Experimental and Numerical Analysis of Puff Hydrodynamics
title_full_unstemmed An Experimental and Numerical Analysis of Puff Hydrodynamics
title_sort experimental and numerical analysis of puff hydrodynamics
publisher Sciendo
series Beiträge zur Tabakforschung International
issn 1612-9237
publishDate 2004-10-01
description The permeability of a tobacco rod in a cigarette increases as it converts into char and ash in the coal. The hot coal introduces a significant resistance to the air flow when air passes through. Through a series of experiments, the cigarette burn line and burn rate, the centerline temperature, and the pressure drop were measured for continuous puffing conditions. The gas viscosity was calculated from the temperature distribution inside the cigarette and applying Sutherland's law. Then, the experimental setup was mathematically modeled from a commercially available CFD (Computational Fluid Dynamics) code and, by matching the numerical and experimental results, the changes in coal and filter permeability during puffing were estimated. The numerical simulation successfully reproduced the results of experiments on the air flow through the coal, ventilation holes and paper wrapper.
url https://doi.org/10.2478/cttr-2013-0776
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