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contributor authorL. M. Hanna
contributor authorP. W. Scherer
date accessioned2017-05-08T23:22:05Z
date available2017-05-08T23:22:05Z
date copyrightFebruary, 1986
date issued1986
identifier issn0148-0731
identifier otherJBENDY-25810#19_1.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/100928
description abstractA steady-state, one-dimensional theoretical model of human respiratory heat and water vapor transport is developed. Local mass transfer coefficients measured in a cast replica of the upper respiratory tract are incorporated into the model along with heat transfer coefficients determined from the Chilton-Colburn analogy and from data in the literature. The model agrees well with reported experimental measurements and predicts that the two most important parameters of the human air-conditioning process are: 1) the blood temperature distribution along the airway walls, and 2) the total cross-sectional area and perimeter of the nasal cavity. The model also shows that the larynx and pharynx can actually gain water over a respiratory cycle and are the regions of the respiratory tract most subject to drying. With slight modification, the model can be used to investigate respiratory heat and water vapor transport in high stress environments, pollutant gas uptake in the respiratory tract, and the connection between respiratory air-conditioning and the function of the mucociliary escalator.
publisherThe American Society of Mechanical Engineers (ASME)
titleA Theoretical Model of Localized Heat and Water Vapor Transport in the Human Respiratory Tract
typeJournal Paper
journal volume108
journal issue1
journal titleJournal of Biomechanical Engineering
identifier doi10.1115/1.3138574
journal fristpage19
journal lastpage27
identifier eissn1528-8951
keywordsHeat
keywordsWater vapor
keywordsRespiratory system
keywordsAir conditioning
keywordsDrying
keywordsMeasurement
keywordsStress
keywordsBlood
keywordsCavities
keywordsCycles
keywordsSteady state
keywordsTemperature distribution
keywordsWater
keywordsPollution
keywordsHeat transfer coefficients
keywordsEscalators AND Mass transfer
treeJournal of Biomechanical Engineering:;1986:;volume( 108 ):;issue: 001
contenttypeFulltext


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