Litcius/Paper detail

Wet surface wall model for latent heat exchange during evaporation

Kiao Inthavong, David F. Fletcher, Mehrdad Khamooshi, Sara Vahaji, Hana Salati

2022International Journal for Numerical Methods in Biomedical Engineering18 citationsDOIOpen Access PDF

Abstract

Air conditioning is a dual heat and mass transfer process, and the human nasal cavity achieves this through the mucosal wall surface, which is supplied with an energy source through the sub-epithelial network of capillaries. Computational studies of air conditioning in the nasal cavity have included temperature and humidity, but most studies solved these flow parameters separately, and in some cases, a constant mucosal surface temperature was used. Recent developments demonstrated that both heat and mass transfer need to be modeled. This work expands on existing modeling efforts in accounting for the nasal cavity's dual heat and mass transfer process by introducing a new subwall model, given in the Supplementary Materials. The model was applied to a pipe geometry, and a human nasal cavity was recreated from CT-scans, and six inhalation conditions were studied. The results showed that when the energy transfer from the latent heat of evaporation is included, there is a cooling effect on the mucosal surface temperature.

Topics & Concepts

Mass transferHeat transferEvaporationNasal cavityMaterials scienceAir conditioningLatent heatMechanicsThermodynamicsHumidityWork (physics)PhysicsMedicineAnatomyInhalation and Respiratory Drug DeliveryNasal Surgery and Airway StudiesAdvanced Chemical Sensor Technologies