Abstract
Air curtains (ACs) employ plane turbulent jets to separate two environments in terms of heat and mass transfer, while still allowing unrestricted access through the opening between these environments. Most previous studies focused on ACs discharged from nozzles located just above the opening. However, in some cases ACs have to be installed close to the ceiling at a substantial distance from the top of the opening. The AC blown downwards along the vertical wall then first resembles a wall jet and after reaching the top of the opening starts resembling a free jet. The present study analyzes the behavior and performance of an AC with upstream wall above the opening. 2D steady RANS CFD simulations are performed based on grid-sensitivity analyses and validation with experimental data for a wall jet and a free jet. The total opening height is 4 m and vertical walls of 0.5 m, 1 m and 2 m, partly closing this opening, are considered. AC performance is evaluated both with the separation efficiency η (based on infiltration) and the adapted separation efficiency η* (based on infiltration and exfiltration). It is shown that the presence of the wall reduces jet decay. The longer the wall, the larger the jet momentum over the opening height. This reduces infiltration and increases η, but it increases exfiltration and therefore decreases η*. In practice, the jet discharge velocity (jet momentum) will have to be adjusted to keep high η*.
Highlights
Air curtains (ACs) employ plane turbulent impinging jets (PTIJ) to separate two environments in terms of heat and mass transfer, while still allowing an unrestricted transfer of persons and products between these environments
In practice, sometimes the AC discharge nozzle has to be installed close to the ceiling at a larger dis tance from the opening. Both in situations with a maximum distance of 0.5 m and in situations with a larger distance, the air jet flowing from the discharge nozzle of the AC towards the opening first develops as a wall jet, and after reaching the top of the opening this wall jet becomes a free jet, until a certain distance from the floor where adverse pressure build-up will mark the beginning of the jet impingement region
This study presents numerical simulations with computational fluid dynamics (CFD) to investigate the behavior and separation efficiency of an AC when it first flows along a wall before reaching the opening
Summary
Air curtains (ACs) employ plane turbulent impinging jets (PTIJ) to separate two environments in terms of heat and mass transfer, while still allowing an unrestricted transfer of persons and products between these environments. In practice, sometimes the AC discharge nozzle has to be installed close to the ceiling at a larger dis tance from the opening Both in situations with a maximum distance of 0.5 m and in situations with a larger distance, the air jet flowing from the discharge nozzle of the AC towards the opening first develops as a wall jet, and after reaching the top of the opening this wall jet becomes a free jet, until a certain distance from the floor where adverse pressure build-up will mark the beginning of the jet impingement region. A free jet on the other hand is not constrained by the presence of a wall It consists of a potential core region, a transitional region, a self-similar region and a termination region.
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