A generalized k−ϵ model for turbulence modulation in dispersion and suspension flows

IF 3.6 2区 工程技术 Q1 MECHANICS International Journal of Multiphase Flow Pub Date : 2023-06-22 DOI:10.1016/j.ijmultiphaseflow.2023.104549
Roar Skartlien , Teresa L. Palmer , Olaf Skjæraasen
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Abstract

A large amount of published data show that particles with diameter above 10% of the turbulence integral length scale (D/l>0.1) tend to increase the turbulent kinetic energy of the carrier fluid above the single-phase value, and smaller particles tend to suppress it. We attempted to remove limitations in earlier modeling efforts for solids on the coupling between the particles and turbulence, and better fits to the turbulence modulation amplitude as function of D/l was achieved for a number of data sets. Explicit algebraic forms of the full model were derived using asymptotic analysis, and these are general enough for application to emulsions, bubbles and solids in bulk regions of multiphase turbulent flow.

Rigorous particle-kinetic theory was used to derive the work exchanged between the particles and the fluid due to both drag and added mass forces, where the latter is essential for low or moderate particle/fluid density ratios, enabling a well justified model also for emulsions and bubbles. A novel sub-model for turbulence production by vortex shedding due to turbulence-generated slip velocity was incorporated, where earlier models took the slip velocity as an input parameter. The correct asymptotic limit of vanishing turbulence modulation for small tracer particles was also provided, giving better fit to the data for small particles.

We found that turbulence augmentation for large diameter solids is due to vortex shedding, and turbulence suppression for small diameters is due to mainly to turbulent drag forces and extra fluid dissipation – a conclusion that agrees with earlier models for solids, despite their possible shortcomings. An important finding is that the mechanisms for turbulence suppression for bubbles and emulsion droplets are similar to those of solids, but with the addition of added mass scaling factors. Another important observation is that augmentation may not occur at all for bubbles or emulsion droplets since the larger diameters require moderate turbulence levels to prevent breakup, so that vortex shedding may be insignificant.

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离散和悬浮流湍流调制的广义k−ε模型
大量已发表的数据表明,粒径在湍流积分长度尺度(D/l>0.1)的10%以上的颗粒会使载液的湍流动能增加到单相值以上,而较小的颗粒则会抑制载液的湍流动能。我们试图消除早期固体模型对颗粒和湍流之间耦合的限制,并且在许多数据集上实现了更好地拟合湍流调制幅度作为D/l的函数。利用渐近分析导出了完整模型的显式代数形式,这些形式足以适用于多相湍流大块区域的乳液、气泡和固体。采用严格的粒子动力学理论推导了由于阻力和附加质量力而导致的颗粒和流体之间的功交换,其中后者对于低或中等颗粒/流体密度比是必不可少的,这也为乳液和气泡提供了一个合理的模型。在以滑移速度为输入参数的基础上,提出了一种新的湍流滑移速度涡脱落产生湍流的子模型。给出了小示踪粒子的消失湍流调制的正确渐近极限,使小粒子的数据得到了更好的拟合。我们发现,大直径固体的湍流增强是由于涡流脱落,而小直径固体的湍流抑制主要是由于湍流阻力和额外的流体耗散——这一结论与早期固体模型一致,尽管它们可能存在缺点。一个重要的发现是,气泡和乳状液滴的湍流抑制机制与固体相似,但增加了额外的质量尺度因子。另一个重要的观察结果是,气泡或乳化液液滴可能根本不会发生增强,因为较大的直径需要适度的湍流水平来防止破裂,因此涡流脱落可能微不足道。
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来源期刊
CiteScore
7.30
自引率
10.50%
发文量
244
审稿时长
4 months
期刊介绍: The International Journal of Multiphase Flow publishes analytical, numerical and experimental articles of lasting interest. The scope of the journal includes all aspects of mass, momentum and energy exchange phenomena among different phases such as occur in disperse flows, gas–liquid and liquid–liquid flows, flows in porous media, boiling, granular flows and others. The journal publishes full papers, brief communications and conference announcements.
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