Multiphase drag and population balance models based on mesoscale stability condition

doi:10.11949/0438-1157.20220450

Abstract

Abstract:

Mesoscale structures and mechanisms represent one of the critical scientific problems in process engineering such as chemical, metallurgy and energy industries. Although the mathematical model of multiphase flow has made great progress in the past few decades, there are several longstanding problems including the modeling accuracy dependent on adjustable parameters, the limited model applicability, and large computation cost, etc. It is difficult for the model development to adapt to the demand of current rapid development of new technology and new processes. In fact, the multi-fluid model based on the averaging method requires several sub-models to be closed, e.g., interphase forces, coalescence/breakup kernel functions, and turbulence models. These sub-models determine the simulation accuracy of the multi-fluid model. Developing mesoscale models from the perspective of mesoscience provides new avenue through analyzing the dominant mechanisms for the evolution of heterogeneous structures in multiphase flow to improve or reconstruct the closure model. In this paper, two types of mesoscale closed models based on mesoscale stability conditions are summarized: one is used for the momentum transfer between closed phases like mesoscale drag, the other is for the evolution of the characteristic parameters of discrete phases, e.g., the mesoscale population balance model, to calculate the bubble or droplet size distribution. Then, the application of these models in multiphase flow equipment such as fluidized bed, bubble column, airlift loop reactor, stirred tank, rotor-stator emulsification is reviewed, and the future study and key scientific issues are analyzed.

Key words: multiphase flow, mesoscale, drag, population balance model, computational fluid dynamics

摘要：

介尺度结构和介尺度机制是化工、冶金、能源等过程工程中的重要科学问题。尽管多相流数理模型在过去的几十年中已取得长足进展，但仍存在准确性依赖可调参数、模型适用性有限、计算量大等问题，难以适应当前快速发展的新工艺和新过程开发的需求。实际上，基于平均化方法的多流体方程组需要若干子模型封闭，如相间作用力、聚并/破碎核函数以及湍流模型等；这些子模型决定了多流体模型的模拟准确性。从介科学角度发展介尺度物理模型为解决这些问题提供了新的思路。模型可以解析多相流非均匀结构演化的控制机制，进而改进或重构子模型。总结了基于介尺度稳定条件的两类介尺度封闭模型：一类用于封闭相间动量传递，如介尺度曳力；另一类用于封闭离散相特征参数的演化，如介尺度群体平衡模型，计算气泡或液滴尺寸。进而综述了这些模型在流化床、鼓泡塔、气升式环流反应器、搅拌槽、转定子乳化器等多相流设备中的应用，并展望了未来发展方向和关键科学问题。

关键词: 多相流, 介尺度, 曳力, 群体平衡模型, 计算流体力学

CLC Number:

TQ 021.1

Xiaoping GUAN, Ning YANG. Multiphase drag and population balance models based on mesoscale stability condition[J]. CIESC Journal, 2022, 73(6): 2427-2437.

管小平, 杨宁. 基于介尺度稳定性条件的多相流曳力与群体平衡模型[J]. 化工学报, 2022, 73(6): 2427-2437.

Figures/Tables 3

References 27

28	蒋雪冬. 基于费托合成的气-液及气-液-固鼓泡塔流体力学特性[D].西安: 西安交通大学, 2015.
	Jiang X D. Hydrodynamics analysis of gas-liquid/gas-liquid-solid bubble columns for Fischer-Tropsch synthesis[D]. Xi'an: Xi'an Jiaotong University, 2015.
29	Guan X P, Yang N. CFD simulation of bubble column hydrodynamics with a novel drag model based on EMMS approach[J]. Chemical Engineering Science, 2021, 243: 116758.
30	Hills J H. Radial nonuniformity of velocity and voidage in a bubble column[J]. Transactions of the Institution of Chemiclal Engineers, 1974, 52(1): 1-9.
31	Camarasa E, Vial C, Poncin S, et al. Influence of coalescence behaviour of the liquid and of gas sparging on hydrodynamics and bubble characteristics in a bubble column[J]. Chemical Engineering and Processing: Processing Intensification, 1999, 38(4/5/6): 329-344.
32	Xiao Q, Wang J, Yang N, et al. Simulation of the multiphase flow in bubble columns with stability-constrained multi-fluid CFD models[J]. Chemical Engineering Journal, 2017, 329: 88-99.
33	Guan X P, Yang N. Modeling of co-current and counter-current bubble columns with an extended EMMS approach[J]. Particuology, 2019, 44(3): 126-135.
34	Zhou R T, Yang N, Li J H. A conceptual model for analyzing particle effects on gas-liquid flows in slurry bubble columns[J]. Powder Technology, 2020, 365: 28-38.
35	Zhou R T, Yang N, Li J H. CFD simulation of gas-liquid-solid flow in slurry bubble columns with EMMS drag model[J]. Powder Technology, 2017, 314: 466-479.
36	Yan P, Jin H B, He G X, et al. CFD simulation of hydrodynamics in a high-pressure bubble column using three optimized drag models of bubble swarm[J]. Chemical Engineering Science, 2019, 199: 137-155.
37	Yan P, Jin H B, He G X, et al. Numerical simulation of bubble characteristics in bubble columns with different liquid viscosities and surface tensions using a CFD-PBM coupled model[J]. Chemical Engineering Research and Design, 2020, 154: 47-59.
38	Yang N, Xiao Q. A mesoscale approach for population balance modeling of bubble size distribution in bubble column reactors[J]. Chemical Engineering Science, 2017, 170: 241-250.
39	An M, Guan X P, Yang N. Modeling the effects of solid particles in CFD-PBM simulation of slurry bubble columns[J]. Chemical Engineering Science, 2020, 223: 115743.
1	Deen N G, van Sint Annaland M, Kuipers J A M. Multi-scale modeling of dispersed gas–liquid two-phase flow[J]. Chemical Engineering Science, 2004, 59(8/9): 1853-1861.
2	Drew D A. Mathematical modeling of two-phase flow[J]. Annual Review of Fluid Mechanics, 1983, 15: 261-291.
40	王珏, 杨宁. 基于EMMS方法的鼓泡塔反应器 CFD 及群平衡模拟[J]. 化工学报, 2017, 68(7): 2667-2677.
	Wang J, Yang N. CFD-PBM simulation with EMMS correctors for bubble column reactors[J]. CIESC Journal, 2017, 68(7): 2667-2677.
41	Heijnen J J, Hols J, van der Lans R G J M, et al. A simple hydrodynamic model for the liquid circulation velocity in a full-scale two-and three-phase internal airlift reactor operating in the gas recirculation regime[J]. Chemical Engineering Science, 1997, 52(15): 2527-2540.
42	Xu T T, Jiang X D, Yang N, et al. CFD simulation of internal-loop airlift reactor using EMMS drag model[J]. Particuology, 2015, 19: 124-132.
43	张佳宝, 崔丽杰, 杨宁. 曳力模型和湍流模型对内环流反应器数值模拟的影响[J]. 化工学报, 2018, 69(1): 389-395.
	Zhang J B, Cui L J, Yang N. Effects of drag model and turbulence model on simulation of air-lift internal-loop reactor[J]. CIESC Journal, 2018, 69(1): 389-395.
44	Jiang X D, Yang N, Yang B L. Computational fluid dynamics simulation of hydrodynamics in the riser of an external loop airlift reactor[J]. Particuology, 2016, 27: 95-101.
45	Lee B W, Dudukovic M P. Determination of flow regime and gas holdup in gas–liquid stirred tanks[J]. Chemical Engineering Science, 2014, 109: 264-275.
46	肖颀, 杨宁. 基于EMMS模型的搅拌釜内气液两相流数值模拟[J]. 化工学报, 2016, 67(7): 2732-2739.
	Xiao Q, Yang N. Numerical simulation of gas-liquid flow in stirred tanks based on EMMS model[J]. CIESC Journal, 2016, 67(7): 2732-2739.
47	李新菊, 管小平, 杨宁, 等. 基于能量最小多尺度曳力模型的搅拌槽内气液两相流计算液体力学模拟及实验研究[J]. 化工进展, 2017, 36(11): 4000-4009.
	Li X J, Guan X P, Yang N, et al. Experimental study and CFD simulation of gas-liquid flow in a stirred tank using the EMMS drag model[J]. Chemical Industry and Engineering Progress, 2017, 36(11): 4000-4009.
48	Guan X P, Li X J, Yang N, et al. CFD simulation of gas-liquid flow in stirred tanks: effect of drag models[J]. Chemical Engineering Journal, 2020, 386: 121554.
49	Kong L N, Li W, Han L C, et al. On the measurement of gas holdup distribution near the region of impeller in a gas–liquid stirred Rushton tank by means of γ-CT[J]. Chemical Engineering Journal, 2012, 188: 191-198.
50	Qin C P, Chen C, Xiao Q, et al. CFD-PBM simulation of droplets size distribution in rotor-stator mixing devices[J]. Chemical Engineering Science, 2016, 155: 16-26.
51	Chen C, Guan X P, Ren Y, et al. Mesoscale modeling of emulsification in rotor-stator devices(Ⅰ): A population balance model based on EMMS concept[J]. Chemical Engineering Science, 2019, 193: 171-183.
52	Chen C, Guan X P, Ren Y, et al. Mesoscale modeling of emulsification in rotor-stator devices(Ⅱ): A model framework integrating emulsifier adsorption[J]. Chemical Engineering Science, 2019, 193: 156-170.
3	Jakobsen H A, Lindborg H, Dorao C A. Modeling of bubble column reactors: progress and limitations[J]. Industrial & Engineering Chemistry Research, 2005, 44(14): 5107-5151.
4	Liao Y X, Lucas D. A literature review of theoretical models for drop and bubble breakup in turbulent dispersions[J]. Chemical Engineering Science, 2009, 64(15): 3389-3406.
5	Liao Y X, Lucas D. A literature review on mechanisms and models for the coalescence process of fluid particles[J]. Chemical Engineering Science, 2010, 65(10): 2851-2864.
6	Li J. Particle-fluid Two-phase Flow: the Energy-minimization Multi-scale Method[M]. Beijing: Metallurgical Industry Press, 1994.
7	Yang N, Chen J H, Zhao H, et al. Explorations on the multi-scale flow structure and stability condition in bubble columns[J]. Chemical Engineering Science, 2007, 62(24): 6978-6991.
8	Li J H, Huang W L, Chen J H. Possible roadmap to advancing the knowledge system and tackling challenges from complexity[J]. Chemical Engineering Science, 2021, 237: 116548.
9	Li J H, Huang W L. From multiscale to mesoscience: addressing mesoscales in mesoregimes of different levels[J]. Annual Review of Chemical and Biomolecular Engineering, 2018, 9: 41-60.
10	Li J H, Huang W L, Chen J H, et al. Mesoscience based on the EMMS principle of compromise in competition[J]. Chemical Engineering Journal, 2018, 333: 327-335.
11	Ge W, Li J H. Physical mapping of fluidization regimes—the EMMS approach[J]. Chemical Engineering Science, 2002, 57(18): 3993-4004.
12	Yang N, Chen J H, Ge W, et al. A conceptual model for analyzing the stability condition and regime transition in bubble columns[J]. Chemical Engineering Science, 2010, 65(1): 517-526.
13	Yang N, Wu Z Y, Chen J H, et al. Multi-scale analysis of gas-liquid interaction and CFD simulation of gas-liquid flow in bubble columns[J]. Chemical Engineering Science, 2011, 66(14): 3212-3222.
14	Xiao Q, Yang N, Li J H. Stability-constrained multi-fluid CFD models for gas-liquid flow in bubble columns[J]. Chemical Engineering Science, 2013, 100: 279-292.
15	Chen J H, Yang N, Ge W, et al. Modeling of regime transition in bubble columns with stability condition[J]. Industrial & Engineering Chemistry Research, 2009, 48(1): 290-301.
16	Ruzicka M C, Drahoš J, Mena P C, et al. Effect of viscosity on homogeneous-heterogeneous flow regime transition in bubble columns[J]. Chemical Engineering Journal, 2003, 96(1/2/3): 15-22.
17	Ruzicka M C, Vecer M M, Orvalho S, et al. Effect of surfactant on homogeneous regime stability in bubble column[J]. Chemical Engineering Science, 2008, 63(4): 951-967.
18	Yang N, Wang W, Ge W, et al. CFD simulation of concurrent-up gas-solid flow in circulating fluidized beds with structure-dependent drag coefficient[J]. Chemical Engineering Journal, 2003, 96(1/2/3): 71-80.
19	Wang W, Li J H. Simulation of gas-solid two-phase flow by a multi-scale CFD approach—of the EMMS model to the sub-grid level[J]. Chemical Engineering Science, 2007, 62(1/2): 208-231.
20	Wang J W, Ge W, Li J H. Eulerian simulation of heterogeneous gas-solid flows in CFB risers: EMMS-based sub-grid scale model with a revised cluster description[J]. Chemical Engineering Science, 2008, 63(6): 1553-1571.
21	Hu S W, Liu X H. A CFD-PBM-EMMS integrated model applicable for heterogeneous gas-solid flow[J]. Chemical Engineering Journal, 2020, 383: 123122.
22	Geng J W, Tian Y J, Wang W. Exploring a unified EMMS drag model for gas-solid fluidization[J]. Chemical Engineering Science, 2022, 251: 117444.
23	Nikolopoulos A, Samlis C, Zeneli M, et al. Introducing an artificial neural network energy minimization multi-scale drag scheme for fluidized particles[J]. Chemical Engineering Science, 2021, 229: 116013.
24	Yang Z, Lu B N, Wang W. Coupling artificial neural network with EMMS drag for simulation of dense fluidized beds[J]. Chemical Engineering Science, 2021, 246: 117003.
25	Lu B N, Wang W, Li J H, et al. Multi-scale CFD simulation of gas-solid flow in MIP reactors with a structure-dependent drag model[J]. Chemical Engineering Science, 2007, 62(18/19/20): 5487-5494.
26	Lu B N, Zhang J Y, Luo H, et al. Numerical simulation of scale-up effects of methanol-to-olefins fluidized bed reactors[J]. Chemical Engineering Science, 2017, 171: 244-255.
27	Chen J H, Yang N, Ge W, et al. Computational fluid dynamics simulation of regime transition in bubble columns incorporating the dual-bubble-size model[J]. Industrial & Engineering Chemistry Research, 2009, 48(17): 8172-8179.

[1]	Siyu ZHANG, Yonggao YIN, Pengqi JIA, Wei YE. Study on seasonal thermal energy storage characteristics of double U-shaped buried pipe group [J]. CIESC Journal, 2023, 74(S1): 295-301.
[2]	Mingkun XIAO, Guang YANG, Yonghua HUANG, Jingyi WU. Numerical study on bubble dynamics of liquid oxygen at a submerged orifice [J]. CIESC Journal, 2023, 74(S1): 87-95.
[3]	Ruitao SONG, Pai WANG, Yunpeng WANG, Minxia LI, Chaobin DANG, Zhenguo CHEN, Huan TONG, Jiaqi ZHOU. Numerical simulation of flow boiling heat transfer in pipe arrays of carbon dioxide direct evaporation ice field [J]. CIESC Journal, 2023, 74(S1): 96-103.
[4]	Song HE, Qiaomai LIU, Guangshuo XIE, Simin WANG, Juan XIAO. Two-phase flow simulation and surrogate-assisted optimization of gas film drag reduction in high-concentration coal-water slurry pipeline [J]. CIESC Journal, 2023, 74(9): 3766-3774.
[5]	Lei XING, Chunyu MIAO, Minghu JIANG, Lixin ZHAO, Xinya LI. Optimal design and performance analysis of downhole micro gas-liquid hydrocyclone [J]. CIESC Journal, 2023, 74(8): 3394-3406.
[6]	Linjing YUE, Yihan LIAO, Yuan XUE, Xuejie LI, Yuxing LI, Cuiwei LIU. Study on influence of pit defects on cavitation flow characteristics of throat of thick orifice plates [J]. CIESC Journal, 2023, 74(8): 3292-3308.
[7]	Dian LIN, Guomei JIANG, Xiubin XU, Bo ZHAO, Dongmei LIU, Xu WU. Preparation and drag reduction effect of silicon-based liquid-like anti-crude-oil-adhesion coatings [J]. CIESC Journal, 2023, 74(8): 3438-3445.
[8]	Yue YANG, Dan ZHANG, Jugan ZHENG, Maoping TU, Qingzhong YANG. Experimental study on flash and mixing evaporation of aqueous NaCl solution [J]. CIESC Journal, 2023, 74(8): 3279-3291.
[9]	Linzheng WANG, Yubing LU, Ruizhi ZHANG, Yonghao LUO. Analysis on thermal oxidation characteristics of VOCs based on molecular dynamics simulation [J]. CIESC Journal, 2023, 74(8): 3242-3255.
[10]	Yuying GUO, Jiaqiang JING, Wanni HUANG, Ping ZHANG, Jie SUN, Yu ZHU, Junxuan FENG, Hongjiang LU. Water-lubricated drag reduction and pressure drop model modification for heavy oil pipeline [J]. CIESC Journal, 2023, 74(7): 2898-2907.
[11]	Xiaokun HE, Rui LIU, Yuan XUE, Ran ZUO. Review of gas phase and surface reactions in AlN MOCVD [J]. CIESC Journal, 2023, 74(7): 2800-2813.
[12]	Ming DONG, Jinliang XU, Guanglin LIU. Molecular dynamics study on heterogeneous characteristics of supercritical water [J]. CIESC Journal, 2023, 74(7): 2836-2847.
[13]	Zhihang ZHENG, Junnan MA, Zihan YAN, Chunxi LU. Study on the pressure pulsation characteristics in jet influence zone of riser [J]. CIESC Journal, 2023, 74(6): 2335-2350.
[14]	Daoyin LIU, Bingqi CHEN, Zuyang ZHANG, Yan WU. Effect of agglomerate structure on drag force by numerical simulation [J]. CIESC Journal, 2023, 74(6): 2351-2362.
[15]	Chenxi LI, Yongfeng LIU, Lu ZHANG, Haifeng LIU, Jin’ou SONG, Xu HE. Quantum chemical analysis of n-heptane combustion mechanism under O₂/CO₂ atmosphere [J]. CIESC Journal, 2023, 74(5): 2157-2169.