Direct numerical simulation of jets in cross-flow

Yao, Yufeng; Petty, D. G.; Barrington, P.E.; Yao, Jun; Mason, P.

doi:10.1080/10618560600909945

Cited by 10 publications

(3 citation statements)

References 16 publications

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“…All other variables follow the standard notations as seen in Yao et al (2006). The code was developed for compressible flow.…”

Section: Numerical Techniquementioning

confidence: 99%

“…In this application, we adopt low Mach number (~ 0.2) to reduce the compressibility effects. The code has been parallelized using the MPI library and validated extensively for numerous configurations including laminar boundary layer and channel flows (Yao et al, 2000), turbulent boundary layer (Yao et al, 2000), turbulent channel flows (Sandham et al, 2002;Hu et al, 2003), transonic flow over a bump geometry with shock/boundary layer and most recently jet in cross-flow (Yao et al, 2006).…”

Section: Numerical Techniquementioning

confidence: 99%

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Numerical visualization of vortex flow behavior in square jets in cross-flow

Maidi

Yao

2008

J Vis

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Direct numerical simulations have been performed in this study to visualize the flow behavior of single and multiple square jets issuing normally into a cross-flow. Three configurations are considered, a single jet located in the centre of the domain, twin jets in side-by-side (SBS) arrangement in the spanwise direction and triple jets in tandem arrangement with twin jets at the front and a third jet in downstream along the centre line. Simulation uses a jet to cross-flow velocity ratio of 2.5 and the Reynolds number 225, based on the free-stream quantities and the jet width. While the vortical structures predicted from single jet case were in good qualitatively agreement with the findings of other researchers, our results show that the process of merging between two counter-rotating vortex pairs (CRVP) in twin jets configurations is strongly dependent on the jet-to-jet edge distance. Further downstream in the far-field, results from the SBS twin jets show a most dominating larger CRVP accompanied with a smaller inner vortex pair. The observations are in good qualitative agreement with the experimental findings in the literature. The resulting flow structures of triple jets in tandem configuration have revealed, for the first time, more complicated flow interactions between individual jets and cross-flow, providing further insights of complex flow physics and its potential engineering applications.

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“…All other variables follow the standard notations as seen in Yao et al (2006). The code was developed for compressible flow.…”

Section: Numerical Techniquementioning

confidence: 99%

Section: Numerical Techniquementioning

confidence: 99%

Numerical visualization of vortex flow behavior in square jets in cross-flow

Maidi

Yao

2008

J Vis

Self Cite

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“…Over the past few decades, many researchers have devoted efforts to studying the mechanisms and the macroscale features of the transverse jet mixing process. For the mixing mechanisms, particularly the generation and evolution of the vortex structures, specific attention is generally paid to the single transverse jet, − about which extensive studies have been reviewed by Mahesh and Karagozian. , A general consensus is that the interactions of the jet and crossflow creates the vortex systems such as the counter-rotating vortex pair (CVP), jet shear-layer vortices in the nearfield region, horseshoe vortices wrapping around the jet column, and wake vortices in the lee of the jet.…”

Section: Introductionmentioning

confidence: 99%

Turbulent Characteristics and Design of Transverse Jet Mixers with Multiple Orifices

Luo

Fang

et al. 2016

Ind. Eng. Chem. Res.

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We investigated and compared the turbulent characteristics of two-liquid mixing in single-orifice and multiorifice-impinging transverse (MOIT) jet mixers through large eddy simulations and the planar laser-induced fluorescence technique. Our focus is on evaluating the roles played by the interactions among the jets in the mixing intensification. The turbulent vortex structures, time-averaged mean concentration distributions, root-mean-square of the concentration fluctuations, probability density function, and power spectral density are discussed. For the MOIT jet mixer with large jet-to-crossflow velocity ratios, direct impingement of the jets enhances the mixing by speeding up the evolution of the counter-rotating vortex pairs, resulting in reduction in the vortex scale, increasing the vortex magnitude, and homogenizing the vortex distribution. The effect of the mixer scale-up on the turbulent characteristics was also studied. Moreover, we selected a specific MOIT jet mixer to perform optimization of the orifice number and diameter of the jet flow with fixed other parameters.

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