Litcius/Paper detail

Do increased flow rates in displacement ventilation always lead to better results?

Rui Yang, Chong Shen Ng, Kai Leong Chong, Roberto Verzicco, Detlef Lohse

2021Journal of Fluid Mechanics48 citationsDOIOpen Access PDF

Abstract

Indoor ventilation is essential for a healthy and comfortable living environment. A key issue is to discharge anthropogenic air contamination such as CO $_2$ gas or, of potentially more direct consequence, airborne respiratory droplets. Here, by employing direct numerical simulations, we study mechanical displacement ventilation with a wide range of ventilation rates $Q$ from 0.01 to 0.1 m $^3$ s $^{-1}$ person $^{-1}$ . For this ventilation scheme, a cool lower zone is established beneath a warm upper zone with interface height $h$ , which depends on $Q$ . For weak ventilation, we find the scaling relation $h\sim Q^{3/5}$ , as suggested by Hunt & Linden ( Build. Environ. , vol. 34, 1999, pp. 707–720). Also, the CO $_{2}$ concentration decreases with $Q$ within this regime. However, for too strong ventilation, the interface height $h$ becomes insensitive to $Q$ , and the ambient averaged CO $_2$ concentration decreases towards the ambient value. At these values of $Q$ , the concentrations of pollutants are very low and so further dilution has little effect. We suggest that such scenarios arise when the vertical kinetic energy associated with the ventilation flow is significant compared with the potential energy of the thermal stratification.

Topics & Concepts

Displacement ventilationVentilation (architecture)Environmental scienceStratification (seeds)DilutionMechanicsPollutantAtmospheric sciencesMaterials sciencePhysicsMeteorologyThermodynamicsChemistryBotanyOrganic chemistryDormancyBiologySeed dormancyGerminationInfection Control and VentilationWind and Air Flow StudiesBuilding Energy and Comfort Optimization