Investigation of Discrete Population Balance Models and Breakage Kernels for Dilute Emulsification Systems

Single gas bubbles have been injected into an stirred liquid tank and the eventual breakup process of the bubbles was examined through high-speed imaging. Experimental observations of the breakup probability, breakup time, number of daughter bubbles and daughter bubble size distribution have been collected. The occurrence of non-equal-size breakup events dominated over equal-size breakup events. The frequency of binary and multiple breakup events was about equal. The largest uncertainty is associated with the determination of the breakup time because the bubbles take continuously altering deformed shapes already from the point of injection into the tank. The present experimental data do not support the standard model assumption regarding the number of daughter particles. The active breakup zone in the stirred tank was in the large velocity field close to the radial impeller. It is not evident whether the breakup events are due to time average shear or pressures and velocity fluctuations.

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“…The average energy dissipation rate of the tank was estimated from the power number equation given by (Becker et al 2011;Jakobsen, 2014) …”

Section: Methodsmentioning

confidence: 99%

Single Air Bubble Breakup Experiments in Stirred Water Tank

Solsvik

Jakobsen

2015

International Journal of Chemical Reactor Engineering

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“…Detailed models using the locally polydisperse approach give more information on the secondary phase behavior (Dhanasekharan et al [20]; Venneker et al [21]). The most used methods of locally polydisperse models are the Method of Classes (CM) (Balakin et al [22]; Bannari et al [1]; Becker et al [23]; Kumar and Ramkrishna [24]; Kumar and Ramkrishna [25]; Puel et al [26]), Quadrature Method of Moments (QMOM) (McGraw [27]; Marchisio et al [28]; Marchisio et al [29]; Marchisio et al [30]; Sanyal et al [31]) and Direct Quadrature Method of Moments (DQMOM) (Silva and Lage [32]; Selma et al [33]; Marchisio and Fox [34]). The method of classes, while intuitive and accurate, is computationally intensive due to the large number of classes required to finely discretize the Number Density Function (NDF) with a large number of classes.…”

Section: Introductionmentioning

confidence: 99%

Modelling of Bubbly Flow Using CFD-PBM Solver in OpenFOAM: Study of Local Population Balance Models and Extended Quadrature Method of Moments Applications

2018

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Abstract:In order to optimize and design new bubbly flow reactors, it is necessary to predict the bubble behavior and properties with respect to the time and location. In gas-liquid flows, it is easily observed that the bubble sizes may vary widely. The bubble size distribution is relatively sharply defined, and bubble rises are uniform in homogeneous flow; however bubbles aggregate, and large bubbles are formed rapidly in heterogeneous flow. To assist in the analysis of these systems, the volume, size and other properties of dispersed bubbles can be described mathematically by distribution functions. Therefore, a mathematical modeling tool called the Population Balance Model (PBM) is required to predict the distribution functions of the bubble motion and the variation of their properties. In the present paper, two rectangular bubble columns and a water electrolysis reactor are modeled using the open-source Computational Fluid Dynamic (CFD) package OpenFOAM. Furthermore, the Method of Classes (CM) and Quadrature-based Moments Method (QBMM) are described, implemented and compared using the developed CFD-PBM solver. These PBM tools are applied in two bubbly flow cases: bubble columns (using a Eulerian-Eulerian two-phase approach to predict the flow) and a water electrolysis reactor (using a single-phase approach to predict the flow). The numerical results are compared with measured data available in the scientific literature. It is observed that the Extended Quadrature Method of Moments (EQMOM) leads to a slight improvement in the prediction of experimental measurements and provides a continuous reconstruction of the Number Density Function (NDF), which is helpful in the modeling of gas evolution electrodes in the water electrolysis reactor.

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“…Schütz et al [18] studied the droplet-droplet interaction effects like droplet breakup and coalescence in a de-watering hydrocyclone utilizing a CFD method with Lehr model. Noroozi et al [19] investigated the effects of breakage and coalescence on de-oiling hydrocyclone performance using a simulation model which is developed coupling the numerical However, the assumption that the liquid droplets behave like gas molecules has some limitations [20] . Droplets with higher density and viscosity have lower breakage rate than bubbles.…”

Section: Introductionmentioning

confidence: 99%

Analysis of droplet behavior in a de-oiling hydrocyclone

Huang

2016

Journal of Dispersion Science and Technology

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A mechanical separation process in a de-oiling hydrocyclone is described in which disperse oil droplets are separated from a continuous water phase. This separation process is influenced by the droplet breakage and coalescence. Based on experimental data and simulation results in a stirred tank, a modified breakage model which can be applied to droplet breakage in the de-oiling hydrocyclone is developed. Then, a simulation model is developed coupling the numerical solution of the flow field in the hydrocyclone based on computational fluid dynamics with population balances. The homogenous discrete method and the inhomogeneous discrete method are applied for solving population balance model (PBM). The investigations show that the numerical results obtained by the simulation model coupled with the modified PBM using the inhomogeneous discrete method are good accordance with experimental data under high flow rate. According to this simulation model, the effect of three different inlet designs on the separation efficiency of the de-oiling hydrocyclone has been discussed. The results indicate that the separation efficiency of the de-oiling hydrocyclone can be improved with an appropriate inlet design. Downloaded by [University of California, San Diego] at 03:21 28 March 2016 2

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Investigation of Discrete Population Balance Models and Breakage Kernels for Dilute Emulsification Systems

Cited by 37 publications

References 48 publications

Single Air Bubble Breakup Experiments in Stirred Water Tank

Single Air Bubble Breakup Experiments in Stirred Water Tank

Modelling of Bubbly Flow Using CFD-PBM Solver in OpenFOAM: Study of Local Population Balance Models and Extended Quadrature Method of Moments Applications

Analysis of droplet behavior in a de-oiling hydrocyclone

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