Impact of inlet design on mass transfer in gas–liquid rectangular microchannels

Fries, Donata M.; Rohr, Philipp Rudolf von

doi:10.1007/s10404-008-0292-6

Cited by 43 publications

(38 citation statements)

References 15 publications

(18 reference statements)

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“…44,45 In general, increasing the gas velocity at a constant liquid velocity leads to shorter liquid slugs, and our experimental results demonstrated this principle, as shown in Figure 8a. Moreover, some researchers [46][47][48] had proposed empirical correlations for predicting the length of liquid slug of Taylor flow in microchannels due to its importance. In these correlations, the liquid slug length was correlated by considering Reynolds number, capillary number and gas holdup, and the Reynolds number was most emphasized.…”

Section: Effect Of Superficial Gas Velocity On Hydrodynamics and Liqumentioning

confidence: 99%

Influence of hydrodynamics on liquid mixing during Taylor flow in a microchannel

Chen

Yuan

2011

AIChE Journal

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in Wiley Online Library (wileyonlinelibrary.com).The miscible liquid-liquid two phases based on Taylor flow in microchannels was investigated by high-speed imaging techniques and Villermaux/Dushman reaction. The mixing based on Taylor flow was much better compared with that without introducing gas in microchannels, even the ideal micromixing performance could be obtained under optimized superficial gas and liquid velocities. In the mixing process based on Taylor flow, the superficial gas and liquid velocities affected the lengths and the velocities of Taylor bubble and liquid slug, and finally the micromixing performance. The formation process of Taylor flow in the inlets, the initial uniform distribution of reactants and the internal circulations in the liquid slug, and the thin liquid films all improved the mixing performance. Furthermore, a modified Peclet number that represented the relative importance of diffusion and convection in the mixing process was proposed for explaining and anticipating micromixing efficiency.

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Section: Effect Of Superficial Gas Velocity On Hydrodynamics and Liqumentioning

confidence: 99%

Influence of hydrodynamics on liquid mixing during Taylor flow in a microchannel

Chen

Yuan

2011

AIChE Journal

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“…Generally, the models performed well with respect to their own data set, but poorly against external data sets. The major issue is that many of the models treat α and β as fitting parameters in the development of empirical correlations for the specific T-junction design under study [8,11,[16][17][18][19][20]. These correlations take the general form of…”

Section: Introductionmentioning

confidence: 99%

Droplet formation in microfluidic T-junction generators operating in the transitional regime. I. Experimental observations

2012

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This is the first part of a two-part study on the generation of droplets at a microfluidic T-junction operating in the transition regime where confinement of the droplet creates a large squeezing pressure that influences droplet formation. In this regime, the operation of the T-junction depends on the geometry of the intersection (height-to-width ratio, inlet width ratio), capillary number, flow ratio, and viscosity ratio of the two phases. Here in paper I we presented our experimental observations through the analysis of high-speed videos of the droplet formation process. Various parameters are tracked during the formation cycle such as the shape of the droplet (penetration depth and neck), interdroplet spacing, production rate, and flow of both phases across several T-junction designs and flow conditions. Generally, the formation process is defined by a two-stage model consisting of an initial filling stage followed by a necking stage. However, video evidence suggests the inclusion of a third stage, which we term the lag stage, at the beginning of the formation process that accounts for the retraction of the interface back into the injection channel after detachment. Based on the observations made in this paper, a model is developed to describe the formation process in paper II, which can be used to understand the design and operation of T-junction generators in the transition regime.

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“…At increased continuous phase flow rate, the droplets become smaller due to increased shear on the emerging droplets (Fries & Rudolf von Rohr 2009;Yeom & Lee 2011a). When the capillary number and the flow rate ratio are kept constant, the normalised droplet size is dependent on the geometry and increases with decreasing continuous phase channel width (Fries & Rudolf von Rohr 2009;Garstecki et al 2006;Gupta & Kumar 2010a;Wehking et al 2013).…”

Section: Channel Dimensionsmentioning

confidence: 98%

“…Droplets and bubbles formed in the squeezing or dripping regime decrease in size with decreasing the dispersed phase channel width (Christopher et al 2008;Fries & Rudolf von Rohr 2009;Yeom & Lee 2011a), further it was found that the effect of the dispersed phase channel width on droplet volume is larger at low capillary number (Christopher et al 2008). For the critical capillary numbers related to transitions between regimes; increasing the aspect ratio decreases Ca c for transition from dripping to jetting and to parallel flow (Chen et al 2012;Garstecki et al 2006), whereas the transition from squeezing to dripping is hardly affected (Wehking et al 2013).…”

Section: Channel Dimensionsmentioning

confidence: 99%

“…The break-up mechanism is different from that in T-junctions, leading to smaller droplets (Steegmans, Schroën, et al 2009a); interestingly their size was not influenced by the angle of the junction (Steegmans, Schroën, et al 2010;Yeom & Lee 2011a). For bubbles, it was reported that bubble volume decreased with increasing junction angle, which was attributed to differences in the initial width of the neck (Fries & Rudolf von Rohr 2009;Tan et al 2009). …”

Section: Junction Designmentioning

confidence: 99%

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Microfluidic methods to study emulsion formation

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Impact of inlet design on mass transfer in gas–liquid rectangular microchannels

Cited by 43 publications

References 15 publications

Influence of hydrodynamics on liquid mixing during Taylor flow in a microchannel

Influence of hydrodynamics on liquid mixing during Taylor flow in a microchannel

Droplet formation in microfluidic T-junction generators operating in the transitional regime. I. Experimental observations

Microfluidic methods to study emulsion formation

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