Evaluation of moisture sorption models and modified Mualem model for prediction of desorption isotherm for wood materials

Evaluation of moisture sorption models and modified Mualem model for prediction of desorption isotherm for wood materials

Modeling of heat and moisture transport in wood based materials requires the knowledge of material properties such as sorption isotherms. Several water vapor sorption models available in literature are evaluated by fitting the sorption isotherm data of spruce (Picea abies) at 23 °C. To take temperat...

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Veröffentlicht in:Building and environment 2015-10, Vol.92, p.387-395
Hauptverfasser: Zhang, Xiaobo, Zillig, Wolfgang, Künzel, Hartwig M., Zhang, Xu, Mitterer, Christoph
Format: Artikel
Sprache:eng
Schlagworte:
Construction
Desorption
Fittings
GAB model
Isotherms
Mathematical models
Moisture
Moisture chemical potential
Mualem model
Picea abies
Sorption
Sorption isotherm
Temperature dependent models
Thermodynamic model
Wood
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container_end_page 395
container_issue
container_start_page 387
container_title Building and environment
container_volume 92
creator Zhang, Xiaobo
Zillig, Wolfgang
Künzel, Hartwig M.
Zhang, Xu
Mitterer, Christoph
description Modeling of heat and moisture transport in wood based materials requires the knowledge of material properties such as sorption isotherms. Several water vapor sorption models available in literature are evaluated by fitting the sorption isotherm data of spruce (Picea abies) at 23 °C. To take temperature effect into account, temperature dependent sorption models are adopted to fit the sorption data of Klinki pine at four temperatures. The results show that the Guggenheim-Anderson-de Boer (GAB) model, thermodynamic model and Dubinin-Astakhov (DA) function based on Polanyi moisture chemical potential have comparable excellent performances for fitting of sorption data. A modified Mualem model with a variable exponent, which is established based on similarity hypothesis, is used to generate desorption isotherm from measured adsorption isotherm. Only another intermediate point on desorption isotherm needs to be measured for the calibration of the exponent. If the sorption history of desorption isotherm is unknown, the measured desorption point will be preferred as the starting point for predicting desorption isotherm. Therefore, the experimental efforts to determine the main isotherm branches can be greatly reduced. •The suitability of moisture sorption models are evaluated for wood materials.•Temperature effect on moisture sorption is taken into consideration.•A modified Mualem model is proposed for generating desorption isotherm from adsorption isotherm.
doi_str_mv 10.1016/j.buildenv.2015.05.021
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source Elsevier ScienceDirect Journals
subjects Construction
Desorption
Fittings
GAB model
Isotherms
Mathematical models
Moisture
Moisture chemical potential
Mualem model
Picea abies
Sorption
Sorption isotherm
Temperature dependent models
Thermodynamic model
Wood
title Evaluation of moisture sorption models and modified Mualem model for prediction of desorption isotherm for wood materials
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