Published online by Cambridge University Press: 01 September 2014
Air curtains are used to reduce the heat and mass exchange across open doorways. Their sealing ability is assessed in terms of the effectiveness $\def \xmlpi #1{}\def \mathsfbi #1{\boldsymbol {\mathsf {#1}}}\let \le =\leqslant \let \leq =\leqslant \let \ge =\geqslant \let \geq =\geqslant \def \Pr {\mathit {Pr}}\def \Fr {\mathit {Fr}}\def \Rey {\mathit {Re}}E$, the fraction of the exchange flow prevented by the air curtain compared to an unobstructed open door. Previous work has studied air-curtain effectiveness when the doorway is the only means of ventilating a space. In this paper, we examine the effects of additional displacement ventilation on the dynamics of the air curtain and the resulting changes in its effectiveness. The main controlling parameter is the deflection modulus $D_{m}$, which is the ratio between the momentum flux of the air curtain and the transverse forces due to the displacement ventilation. For a relatively warm interior, we find that, for small values of $D_{m}$, the air curtain is drawn inside the space by the ventilation flow. For large values of $D_{m}$, the flow through the doorway is controlled by the air curtain. A smooth transition occurs between these two regimes, and we estimate the $D_{m}$ value for the onset of this transition. Our model provides a quantitative prediction of $E(D_{m})$ in the ventilation-driven regime, and gives a qualitative description of the other two regimes. Laboratory experiments were conducted to test the proposed model. The experimental data were compared to theoretical predictions, and good agreement was found.
This movie shows the air curtain operating in the unstable regime. The left-hand side of the tank is filled with fluid of density ρland theright-hand side with fluid of density ρd. The flow through the top opening is unidirectional from light fluid half to dense fluid half of the tank. The intrusion current of dense fluid into the light fluid half of the tank along the bottom is visible. A plume of light fluid rises on the dense fluid side of the doorway. The plume origin is located slightly above the middle height of the doorway. The presence of this plume indicates that the air curtain is deflected to the dense fluid side, and that there is still bidirectional flow through the doorway
This movie shows the air curtain operating in the ventilation-driven regime. The left-hand side of the tank is filled with fluid of density ρl and the right-hand side with fluid of density ρd. The flow through the top opening is unidirectional from light fluid half to dense fluid half of the tank. The dense gravity current intrudes into the light-fluid side along the bottom of the tank. In this regime, no plume is observed on the dense fluid side of the doorway. This suggests that the air curtain is deflected completely to the light fluid side of the tank
This movie shows the air curtain operating in the transition regime. The left-hand side of the tank is filled with fluid of density ρl and the right-hand side with fluid of density ρd. The flow through the top opening is unidirectional from light fluid half to dense fluid half of the tank. The air curtain impinges on the tank bottom and there is a rising plume in the dense fluid half of the tank
This movie shows the air curtain operating in the air-curtain-driven regime. The left-hand side of the tank is filled with fluid of density ρl and the right-hand side with fluid of density ρd. The flow through the top opening is unidirectional from light fluid half to dense fluid half of the tank. The air curtain impinges on the bottom of the tank. Its flux divides equally between both sides of the tank after impingement on the bottom, so that a more pronounced plume than in the transition regime is visible in the dense fluid half of the tank