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Evaluation of the different definitions of the convective mass transfer coefficient for water evaporation into air

Steeman, H., T'joen, C., Belleghem, M. V., Janssens, A. and Paepe, M.
2009
International Journal of Heat and Mass Transfer, 52(15-16): 3757-3766
Convective mass transfer coefficient; Evaporation; CFD; Heat and mass analogy

Steeman, H., T'joen, C., Belleghem, M. V., Janssens, A. and Paepe, M., (2009), "Evaluation of the different definitions of the convective mass transfer coefficient for water evaporation into air", International Journal of Heat and Mass Transfer, 52(15-16): 3757-3766.
Abstract:
In literature different definitions of the convective mass transfer coefficient are used by different authors. The definitions differ in the driving force used to describe mass transfer. In this paper, the limitations to the use of convective mass transfer coefficients related to four commonly used driving forces (vapour density, mass fraction, vapour pressure and mole fraction) are studied for evaporation of water into air. A theoretical study based on the adiabatic saturation process and a numerical CFD study of an existing evaporation experiment show that the use of convective mass transfer coefficients related to vapour densities is only allowed under isothermal conditions while convective mass transfer coefficients related to vapour pressure show a dependence on the total gas pressure. The use of mole or mass fractions as driving force results in values for the transfer coefficient which are little affected by the thermodynamic properties such as temperature, relative humidity and total pressure and are hence better suited to describe convective mass transport.

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Author Information and Other Publications Notes
Steeman, H.
  1. CFD modelling of HAM transport in buildings: The importance of local indoor climate
  2. Coupled simulation of heat and moisture transport in air and porous materials for the assessment of moisture related damage
  3. Modelling indoor air and hygrothermal wall interaction in building simulation: Comparison between CFD and a well-mixed zonal model
  4. On coupling 1D non-isothermal heat and mass transfer in porous materials with a multizone building energy simulation model
  5. On the applicability of the heat and mass transfer analogy in indoor air flows
  6. Sensitivity analysis of CFD coupled non-isothermal heat and moisture modelling  
T'joen, C.
     
Belleghem, M. V.
  1. Benchmark experiments for moisture transfer modelling in air and porous materials
  2. Experimental validation and sensitivity analysis of a coupled BES-HAM model
  3. On coupling 1D non-isothermal heat and mass transfer in porous materials with a multizone building energy simulation model
  4. Sensitivity analysis of CFD coupled non-isothermal heat and moisture modelling  
Janssens, A.
Building Physics, Construction and Services http://aivwww.rug.ac.be/Onderzoeksbeleid/techno2002/EN/TW/I-TW01V02.htm
  1. Application of a new type of air and vapor retarder in a self-drying sloped roof with a cathedral ceiling
  2. Benchmark experiments for moisture transfer modelling in air and porous materials
  3. CFD modelling of HAM transport in buildings: The importance of local indoor climate
  4. Condensation risk assessment
  5. Coupled simulation of heat and moisture transport in air and porous materials for the assessment of moisture related damage
  6. Experimental validation and sensitivity analysis of a coupled BES-HAM model
  7. Heat and moisture response of vented and compact cathedral ceilings: a test house evaluation
  8. Impact of whole-building hygrothermal modelling on the assessment of indoor climate in a library building
  9. Inquiry on HAMCAT codes
  10. Modelling indoor air and hygrothermal wall interaction in building simulation: Comparison between CFD and a well-mixed zonal model
  11. On coupling 1D non-isothermal heat and mass transfer in porous materials with a multizone building energy simulation model
  12. On the applicability of the heat and mass transfer analogy in indoor air flows
  13. Reliable control of interstitial condensation in lightweight roof systems, calculation and assessment methods
  14. Sensitivity analysis of CFD coupled non-isothermal heat and moisture modelling  
Paepe, M.
  1. Benchmark experiments for moisture transfer modelling in air and porous materials
  2. CFD modelling of HAM transport in buildings: The importance of local indoor climate
  3. Coupled simulation of heat and moisture transport in air and porous materials for the assessment of moisture related damage
  4. Experimental validation and sensitivity analysis of a coupled BES-HAM model
  5. Impact of whole-building hygrothermal modelling on the assessment of indoor climate in a library building
  6. On coupling 1D non-isothermal heat and mass transfer in porous materials with a multizone building energy simulation model
  7. On the applicability of the heat and mass transfer analogy in indoor air flows
  8. Sensitivity analysis of CFD coupled non-isothermal heat and moisture modelling  


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