Numerical simulation of droplet impacting liquid film with bubbles in spray cooling

doi:10.16085/j.issn.1000-6613.2021-0846

Abstract

Abstract:

In the nucleate boiling zone of the spray cooling, the impact of the droplets with the liquid film and the bubbles in the liquid film has an important effect on the process heat transfer. A two-dimensional numerical model of a droplet impacting liquid film with bubbles was established. The model using water as the cooling fluid was used to simulate the impact process and heat transfer laws. The results showed that when the We was 6.94 and the quantity of dimension one liquid film thickness was 0.5(corresponding droplet velocity 0.5m/s, liquid film thickness 1mm), the liquid film was not disturbed significantly, and the motion shape was similar to ripples. When the We increased to 111.11(corresponding droplet velocity 2m/s), the gauge pressure at the junction of the droplet and the liquid film reached 6000Pa, which became the driving force of the neck jet phenomenon and gradually developed into a crown splash. The existence of bubbles hindered contact between the droplet and the heating surface, but as the bubbles burst, the droplet directly contact the heating surface, which made the surface heat transfer coefficient near the impact point much larger than other areas. The peak value of the surface heat transfer coefficient increased with the decrease of the liquid film thickness, or with the increase of the droplet velocity. The research results can provide a basis for further research on spray cooling system.

Key words: droplet impact, spray cooling, two-phase flow, bubble entrainment, numerical simulation

摘要：

在喷雾冷却过程的核态沸腾区，液滴与液膜及液膜内气泡的撞击对过程传热有重要影响。本文建立以水为冷却工质的单液滴撞击带气泡液膜的二维数值模型，模拟研究过程现象和传热规律。结果表明，We为6.94、量纲为1的液膜厚度为0.5（对应液滴速度0.5m/s、液膜厚度1mm）时，撞击过程中液膜扰动不显著、运动形态近似波纹；当We增大到111.11（对应液滴速度2m/s）时，撞击过程中液滴与液膜接合处的表压达到6000Pa，成为颈部射流现象的推动力，并逐步发展形成冠状水花；撞击过程中气泡的存在会阻碍液滴与加热表面的直接接触，但随着气泡的破裂，液滴与加热表面直接接触换热，使撞击点附近表面传热系数远大于其他区域，提高了传热能力，且液膜厚度越小、液滴速度越大，表面传热系数峰值越高。研究结果可为喷雾冷却系统的进一步研究提供理论依据。

关键词: 液滴撞击, 喷雾冷却, 两相流, 气泡夹带, 数值模拟

CLC Number:

O359.1

ZHANG Chunchao, PAN Yanqiu, DU Yujie, GAO Shilei, YU Lu. Numerical simulation of droplet impacting liquid film with bubbles in spray cooling[J]. Chemical Industry and Engineering Progress, 2022, 41(4): 1735-1741.

张春超, 潘艳秋, 杜宇杰, 高石磊, 俞路. 喷雾冷却中液滴撞击带气泡液膜的数值模拟[J]. 化工进展, 2022, 41(4): 1735-1741.

Figures/Tables 9

References 20

1	MUDAWAR I. Recent advances in high-flux, two-phase thermal management[J]. Journal of Thermal Science and Engineering Applications, 2013, 5(2): 021012.
2	BOSTANCI H, RINI D P, KIZITO J P, et al. High heat flux spray cooling with ammonia: investigation of enhanced surfaces for CHF[J]. International Journal of Heat and Mass Transfer, 2012, 55(13/14): 3849-3856.
3	YANG J, CHOW L C, PAIS M R. Nucleate boiling heat transfer in spray cooling[J]. Journal of Heat Transfer, 1996, 118(3): 668-671.
4	张亚东, 张伟, 秦朔. 喷雾冷却换热机理研究进展[J]. 制冷技术, 2020, 40(1): 34-41, 53.
	ZHANG Yadong, ZHANG Wei, QIN Shuo. Research progress of spray cooling heat transfer mechanism[J]. Chinese Journal of Refrigeration Technology, 2020, 40(1): 34-41, 53.
5	LIANG G T, MUDAWAR I. Review of spray cooling—Part 1: Single-phase and nucleate boiling regimes, and critical heat flux[J]. International Journal of Heat and Mass Transfer, 2017, 115: 1174-1205.
6	BREITENBACH J, ROISMAN I V, TROPEA C. From drop impact physics to spray cooling models: a critical review[J]. Experiments in Fluids, 2018, 59(3): 1-21.
7	RIEBER M, FROHN A. A numerical study on the mechanism of splashing[J]. International Journal of Heat and Fluid Flow, 1999, 20(5): 455-461.
8	NIKOLOPOULOS N, THEODORAKAKOS A, BERGELES G. Three-dimensional numerical investigation of a droplet impinging normally onto a wall film[J]. Journal of Computational Physics, 2007, 225(1): 322-341.
9	GUO Y L, WEI L, LIANG G T, et al. Simulation of droplet impact on liquid film with CLSVOF[J]. International Communications in Heat and Mass Transfer, 2014, 53: 26-33.
10	梁刚涛, 沈胜强, 杨勇. 单液滴撞击平面液膜飞溅过程的CLSVOF模拟[J]. 热科学与技术, 2012, 11(1): 8-12.
	LIANG Gangtao, SHEN Shengqiang, YANG Yong. CLSVOF simulation for splashing of single drop impact on flat liquid film[J]. Journal of Thermal Science and Technology, 2012, 11(1): 8-12.
11	梁刚涛, 郭亚丽, 沈胜强. 液滴撞击液膜的射流与水花形成机理分析[J]. 物理学报, 2013, 62(2): 024705.
	LIANG Gangtao, GUO Yali, SHEN Shengqiang. Analysis of liquid sheet and jet flow mechanism after droplet impinging onto liquid film[J]. Acta Physica Sinica, 2013, 62(2): 024705.
12	李大树, 仇性启, 郑志伟, 等. 液滴碰撞液膜复合level set-VOF法的数值分析[J]. 高校化学工程学报, 2017, 31(3): 570-578.
	LI Dashu, QIU Xingqi, ZHENG Zhiwei, et al. Numerical analysis of a coupled level set-VOF method for the study of droplet impact on wetted surface[J]. Journal of Chemical Engineering of Chinese Universities, 2017, 31(3): 570-578.
13	TAO Y J, HUAI X L, LI Z G. Numerical simulation of vapor bubble growth and heat transfer in a thin liquid film[J]. Chinese Physics Letters, 2009, 26(7): 074701.
14	HOU Y, TAO Y J, HUAI X L. Numerical simulation of droplets impacting on a liquid film with a vapor bubble growing[J]. Chinese Physics Letters, 2014, 31(1): 014701.
15	GUO Y L, WANG F, GONG L Y, et al. Evolution and heat transfer after droplet impact on heated liquid film with vapor bubbles inside[J]. Numerical Heat Transfer B: Fundamentals, 2019, 76(5): 273-284.
16	BRACKBILL J U, KOTHE D B, ZEMACH C. A continuum method for modeling surface tension[J]. Journal of Computational Physics, 1992, 100(2): 335-354.
17	郭加宏, 戴世强, 代钦. 液滴冲击液膜过程实验研究[J]. 物理学报, 2010, 59(4): 2601-2609.
	GUO Jiahong, DAI Shiqiang, DAI Qin. Experimental research on the droplet impacting on the liquid film[J]. Acta Physica Sinica, 2010, 59(4): 2601-2609.
18	COSSALI G E, MARENGO M, COGHE A, et al. The role of time in single drop splash on thin film[J]. Experiments in Fluids, 2004, 36(6): 888-900.
19	DEEGAN R D, BRUNET P, EGGERS J. Complexities of splashing[J]. Nonlinearity, 2008, 21(1): C1-C11.
20	YARIN A L, WEISS D A. Impact of drops on solid surfaces: self-similar capillary waves, and splashing as a new type of kinematic discontinuity[J]. Journal of Fluid Mechanics, 1995, 283: 141-173.

[1]	XU Ruosi, TAN Wei. Flow field simulation and fluid-structure coupling analysis of C-tube pool boiling two-phase flow model [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 47-55.
[2]	GUO Qiang, ZHAO Wenkai, XIAO Yonghou. Numerical simulation of enhancing fluid perturbation to improve separation of dimethyl sulfide/nitrogen via pressure swing adsorption [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 64-72.
[3]	SHAO Boshi, TAN Hongbo. Simulation on the enhancement of cryogenic removal of volatile organic compounds by sawtooth plate [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 84-93.
[4]	WANG Tai, SU Shuo, LI Shengrui, MA Xiaolong, LIU Chuntao. Dynamic behavior of single bubble attached to the solid wall in the AC electric field [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 133-141.
[5]	CHEN Kuangyin, LI Ruilan, TONG Yang, SHEN Jianhua. Structure design of gas diffusion layer in proton exchange membrane fuel cell [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 246-259.
[6]	YANG Yudi, LI Wentao, QIAN Yongkang, HUI Junhong. Analysis of influencing factors of natural gas turbulent diffusion flame length in industrial combustion chamber [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 267-275.
[7]	CHEN Lin, XU Peiyuan, ZHANG Xiaohui, CHEN Jie, XU Zhenjun, CHEN Jiaxiang, MI Xiaoguang, FENG Yongchang, MEI Deqing. Investigation on the LNG mixed refrigerant flow and heat transfer characteristics in coil-wounded heat exchanger (CWHE) system [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4496-4503.
[8]	LIU Xuanlin, WANG Yikai, DAI Suzhou, YIN Yonggao. Analysis and optimization of decomposition reactor based on ammonium carbamate in heat pump [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4522-4530.
[9]	LUO Cheng, FAN Xiaoyong, ZHU Yonghong, TIAN Feng, CUI Louwei, DU Chongpeng, WANG Feili, LI Dong, ZHENG Hua’an. CFD simulation of liquid distribution in different distributors in medium-low temperature coal tar hydrogenation reactor [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4538-4549.
[10]	ZHAO Xi, MA Haoran, LI Ping, HUANG Ailing. Simulation analysis and optimization design of mixing performance of staggered impact micromixer [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4559-4572.
[11]	YE Zhendong, LIU Han, LYU Jing, ZHANG Yaning, LIU Hongzhi. Optimization of thermochemical energy storage reactor based on calcium and magnesium binary salt hydrates [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4307-4314.
[12]	YU Junnan, YU Jianfeng, CHENG Yang, QI Yibo, HUA Chunjian, JIANG Yi. Performance prediction of variable-width microfluidic concentration gradient chips by deep learning [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3383-3393.
[13]	SHAN Xueying, ZHANG Meng, ZHANG Jiafu, LI Lingyu, SONG Yan, LI Jinchun. Numerical simulation of combustion of flame retardant epoxy resin [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3413-3419.
[14]	WANG Shuo, ZHANG Yaxin, ZHU Botao. Prediction of erosion life of coal water slurry pipeline based on grey prediction model [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3431-3442.
[15]	ZHOU Longda, ZHAO Lixin, XU Baorui, ZHANG Shuang, LIU Lin. Advances in electrostatic-cyclonic coupling enhanced multiphase media separation research [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3443-3456.