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液滴撞击超亲水表面铺展之后形成的薄液膜铺展直径是喷雾冷却、降膜蒸发等传热传质过程的一项关键控制参数. 以往模型在预测超亲水表面惯性力驱动下的最大铺展直径时, 存在低韦伯数下呈反常趋势、高韦伯数下预测值偏低等问题. 针对上述问题, 本文采用高速摄像技术研究液滴撞击过程中的铺展水力学特性, 发现了以往模型未完全考虑超亲水表面的铺展特性: 球冠状液膜、高黏性阻力及重力势能做功. 本文考虑了液膜球冠形态、重力势能、辅助耗散, 修正了以往最大铺展直径的预测模型, 并建立了适用于超亲水表面最大铺展直径的预测模型. 通过对铺展过程中各能量成分分析发现, 在超亲水表面上动能、表面能、重力势能均转化为黏性耗散能, 其中: 在低韦伯数下, 表面能转化为黏性耗散能占主要作用; 在高韦伯数下, 动能转化为黏性耗散能占主要作用. 并且, 在低韦伯数下, 重力势能和辅助耗散的引入对于准确预测超亲水表面最大铺展直径具有重要作用. 将模型预测结果与实验结果比较发现, 本模型成功消除了以往模型在低韦伯数下的反常趋势, 且能较好预测宽韦伯数范围下超亲水表面最大铺展直径. 同时, 本模型可以预测亲水和疏水固体表面的液滴最大铺展直径. 超亲水表面最大铺展直径的准确预测模型的提出对喷雾冷却, 降膜蒸发中提高和控制流体铺展距离和传热效率具有重要意义.Liquid droplets impacting on the solid surface is an ubiquitous phenomenon in natural, agricultural, and industrial processes. The maximum spreading diameter of a liquid droplet impacting on a solid surface is a significant parameter in the industrial applications such as inkjet printing, spray coating, and spray cooling. However, former models cannot accurately predict the maximum spreading diameter on a superhydrophilic surface, especially under low Weber number (We). In this work, the spreading characteristics of a water droplet impacting on a superhydrophilic surface are explored by high-speed technique. The spherical cap of the spreading droplet, gravitational potential energy, and auxiliary dissipation are introduced into the modified theoretical model based on the energy balance. The model includes two viscous dissipation terms: the viscous dissipation of the initial kinetic energy and the auxiliary dissipation in spontaneous spreading. The energy component analysis in the spreading process shows that the kinetic energy, surface energy, and gravitational potential energy are all transformed into the viscous dissipation on the superhydrophilic surface. The transformation of surface energy into viscous dissipation is dominant at lower We while the transformation of kinetic energy into viscous dissipation is dominant at higher We. It is found that the gravitational potential energy and auxiliary dissipation play a significant role in spreading performance at low We according to the energy component analysis. Moreover, the energy components predicted by the modified model accord well with the experimental data. As a result, the proposed model can predict the maximum spreading diameter of a droplet impacting on the superhydrophilic surface accurately. Furthermore, the model proposed in this work can predict the maximum spreading diameter of the droplet impacting on the hydrophilic surface and hydrophobic surface. The results of this work are of great significance for controlling droplet spreading diameter in spray cooling and falling film evaporation.
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Keywords:
- superhydrophilic surfaces /
- maximum spreading diameter /
- gravitational potential energy /
- auxiliary dissipation
[1] Liang G, Mudawar I 2016 Int. J. Heat Mass Transfer 101 577Google Scholar
[2] 马学虎, 兰忠, 王凯, 陈彦松, 程雅琦, 杜宾港, 叶轩 2018 化工学报 69 9Google Scholar
Ma X H, Lan Z, Wang K, Chen Y S, Cheng Y Q, Du B G, Ye X 2018 J. Chem. Ind. Eng. 69 9Google Scholar
[3] Snoeijer J H, Andreotti B 2013 Annu. Rev. Fluid Mech. 45 269Google Scholar
[4] 朱君悦, 段远源, 王晓东, 闵琪 2014 化工学报 65 765Google Scholar
Zhu J Y, Duan Y Y, Wang X D, Min Q 2014 J. Chem. Ind. Eng. 65 765Google Scholar
[5] 刘海龙, 沈学峰, 王睿, 曹宇, 王军锋 2018 力学学报 50 1024Google Scholar
Liu H L, Shen X F, Wang R, Cao Y, Wang J F 2018 Acta Mech. Sin. 50 1024Google Scholar
[6] 闵琪, 段远源, 王晓东, 吴莘馨 2013 热科学与技术 12 335Google Scholar
Min Q, Duan Y Y, Wang X D, Wu X X 2013 J. Therm. Sci. Technol. 12 335Google Scholar
[7] Hu H B, Chen L B, Bao L Y, Huang S H 2014 Chin. Phys. B 23 074702Google Scholar
[8] Sun Z H, Han R J 2008 Chin. Phys. B 17 3185Google Scholar
[9] Wang Y B, Wang Y F, Gao S R, Yang Y R, Wang X D, Chen M 2020 Langmuir 36 9306Google Scholar
[10] Hu H B, Huang S H, Chen L B 2013 Chin. Phys. B 22 084702Google Scholar
[11] Song M, Liu Z, Ma Y, Dong Z, Wang Y, Jiang L 2017 NPG Asia Mater. 9 1Google Scholar
[12] 王高远, 胥蕊娜, 陈剑楠, 陈学, 姜培学 2018 工程热 39 1797Google Scholar
Wang G Y, Xu R N, Chen J N, Chen X, Jiang P X 2018 J. Eng. Thermphys. 39 1797Google Scholar
[13] Lin S, Zhao B, Zou S, Guo J, Wei Z, Chen L 2018 J. Colloid Interface Sci. 516 86Google Scholar
[14] Lee J B, Derome D, Guyer R, Carmeliet J 2016 Langmuir 32 1299Google Scholar
[15] Tang C, Qin M, Weng X, Zhang X, Zhang P, Li J, Huang Z 2017 Int. J. Multiphase Flow 96 56Google Scholar
[16] 荣松, 沈世全, 王天友, 车志钊 2019 68 154701Google Scholar
Rong S, Shen S Q, Wang T Y, Che Z Z 2019 Acta Phys. Sin. 68 154701Google Scholar
[17] Ding B, Wang H, Zhu X, Chen R, Liao Q 2018 Int. J. Heat Mass Transfer 124 1025Google Scholar
[18] 范瑶, 王宏, 朱恂, 黄格永, 丁玉栋, 廖强 2016 化工学报 67 2709Google Scholar
Fan Y, Wang H, Zhu X, Huang G Y, Ding Y D, Liao Q 2016 J. Chem. Ind. Eng. 67 2709Google Scholar
[19] Ding B, Wang H, Zhu X, Chen R, Liao Q 2019 Int. J. Heat Mass Transfer 138 844Google Scholar
[20] Chen M, Wu D, Chen D, Deng J, Liu H, Jiang J 2020 Chem. Eng. Sci. 226 115864Google Scholar
[21] 焦云龙, 刘小君, 逄明华, 刘焜 2016 65 016801Google Scholar
Jiao Y L, Liu X J, Pang M H, Liu K 2016 Acta Phys. Sin. 65 016801Google Scholar
[22] 叶学民, 李永康, 李春曦 2016 65 234701Google Scholar
Ye X M, Li Y K, Li C X 2016 Acta Phys. Sin. 65 234701Google Scholar
[23] Roisman I V 2009 Phys. Fluids 21 052104Google Scholar
[24] Liang G, Chen Y, Chen L, Shen S 2019 Ind. Eng. Chem. Res. 58 10053Google Scholar
[25] Laan N, de Bruin K G, Bartolo D, Josserand C, Bonn D 2014 Phys. Rev. Appl. 2 044018Google Scholar
[26] Lee J B, Laan N, de Bruin K G, Skantzaris G, Shahidzadeh N, Derome D, Carmeliet J, Bonn D 2016 J. Fluid Mech. 786 R4Google Scholar
[27] Chandra S, Avedisian C T 1991 Proc. R. Soc. A 432 13Google Scholar
[28] Pasandideh‐Fard M, Qiao Y M, Chandra S, Mostaghimi J 1996 Phys. Fluids 8 650Google Scholar
[29] Mao T, Kuhn D C S, Tran H 1997 AlChE J. 43 2169Google Scholar
[30] Ukiwe C, Kwok D Y 2005 Langmuir 21 666Google Scholar
[31] Huang H M, Chen X P 2018 Phys. Fluids 30 022106Google Scholar
[32] Park H, Carr W W, Zhu J, Morris J F 2003 AlChE J. 49 2461Google Scholar
[33] Li Ri, Ashgriz Nasser, Sanjeev C 2010 J. Fluids Eng. 132 061302Google Scholar
[34] Gao X, Li R 2014 AlChE J. 60 2683Google Scholar
[35] Wang F, Yang L, Wang L, Zhu Y, Fang T 2019 Langmuir 35 3204Google Scholar
[36] Panda A, Pati A R, Saha B, Kumar A, Mohapatra S S 2019 Chem. Eng. Sci. 207 527Google Scholar
[37] Zhang Z, Jiang P X, Christopher D M, Liang X-G 2015 Int. J. Heat Mass Transfer 80 26Google Scholar
[38] Zheng Y, Ma X, Li Y, Jiang R, Wang K, Lan Z, Liang Q 2017 Appl. Therm. Eng. 111 1548Google Scholar
[39] Nam Y, Ju Y S 2013 J. Adhes. Sci. Technol. 27 2163Google Scholar
[40] Vadillo D C, Soucemarianadin A, Delattre C, Roux D C D 2009 Phys. Fluids 21 122002Google Scholar
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图 1 液滴铺展实验系统(A: 高速摄像机(Photron APX RS); B: 高速摄像机(Photron Mini UX100); C: 微量注射泵(LSP01-1 BH); D: 液滴生成装置; E: 恒温台; F: 高亮光源; G: 数据采集设备; G: 精确自动控制位移的直线位移滑台)
Fig. 1. The droplet spreading experiment platform. (A: high speed camera (Photron APX RS); B: high speed camera (Photron Mini UX100); C: micro syringe pump (LSP01-1 BH); D: droplet generating device; E: heating platform; F: diffuse light source; G: data acquisition computer; H: linear displacement slide.
表 1 基于能量守恒的最大铺展因子的预测模型
Table 1. Theoretical models for predicting the maximum spreading factor.
文献 最大铺展模型预测表达式 表面润湿
性/(°)We 液滴形态 Lee等[14] $\begin{aligned} \rho {V_0}{D_0} + 12\sigma\qquad\qquad\qquad\qquad\quad\qquad\qquad\qquad\qquad \\= 3\sigma (1 - \cos \theta )\beta _{\rm{m} }^2 + 8\sigma \dfrac{1}{ { {\beta _{\rm{m} } } } } + 3\sqrt { {b / c} } \rho V_{\rm{0} }^2{D_0}\beta _{\rm{m} }^{ {5 / 2} }\dfrac{1}{ {\sqrt {Re} } }\end{aligned}$ 60—115 1—290 圆饼 Chandra等[27] $\dfrac{3}{2}\dfrac{ {We} }{ {Re} }\beta _{\rm{m} }^4 + \left( {1 - \cos \theta } \right)\beta _{\rm{m} }^2 - \left( {\dfrac{1}{3}We + 4} \right) = 0$ ~32 ~43 圆饼 Pasandideh-
Fard等[28]${\beta _{\rm{m} } } = \sqrt {\dfrac{ {We + 12} }{ {3\left( {1 - \cos {\theta _{\rm{a} } } } \right) + 4\left( { { {We} / {\sqrt {Re} } } } \right)} } }$ 27—140 27—447 圆饼 Mao等[29] $\left( {\dfrac{ {1 - \cos \theta } }{4} + 0.35\dfrac{ {We} }{ {\sqrt {Re} } } } \right)\beta _{\rm{m} }^4 - \left( {\dfrac{ {We} }{ {12} } + 1} \right)\beta + \dfrac{2}{3} = 0$ 30—120 5—1000 圆饼 Ukiwe等[30] $\left( {We + 12} \right){\beta _{\rm{m} } } = 8 + \beta _{\rm{m} }^3\left[ {3\left( {1 - \cos \theta } \right) + 4\dfrac{ {We} }{ {\sqrt {Re} } } } \right]$ 57—90 18—370 圆饼 Huang等[31] $\begin{aligned}\frac{3}{4}\left( {\frac{ {We} }{ {\sqrt {Re} } } + \frac{ {We^*} }{ {\sqrt {Re^*} } } } \right)\beta _{\rm{m} }^4 + 3\left( {1 - \cos {\theta _{\rm{a} } } } \right)\beta _{\rm{m} }^3 \qquad\\ - \left( {We + 12} \right){\beta _{\rm{m} } } + 8 = 0, ~~{V_0} < V^* \qquad\qquad\qquad\end{aligned}$
$\begin{aligned} \frac{3}{4}\left( {\frac{ {We} }{ {\sqrt {Re} } } + \frac{ {We^*} }{ {\sqrt {Re^*} } }\frac{ {Re^*} }{ {Re} } } \right)\beta _{\rm{m} }^4 + 3\left( {1 - \cos {\theta _{\rm{a} } } } \right)\beta _{\rm{m} }^3 \\ - \left( {We + 12} \right){\beta _{\rm{m} } } + 8 = 0,~~ {V_0} > V^*\qquad\qquad\qquad \end{aligned}$64—110 2—500 圆饼 Park等[32] $\begin{aligned} \left( {0.33\frac{ {We} }{ {\sqrt {Re} } } - \frac{1}{4}\cos \theta + \frac{1}{2}\left( {\frac{ {1 - \cos {\theta _{\rm{a} } } } }{ { { {\sin }^2}{\theta _{\rm{a} } } } } } \right)} \right)\beta _{\rm{m} }^2 \\ - 1 - \frac{ {We} }{ {12} } + \frac{ {\Delta {E_{\rm{s} } } } }{ { {\text{π} }D_0^2\sigma } } = 0 \qquad\qquad\qquad\qquad\quad\end{aligned}$ 31—113 0.2—180 球冠 Li等[33] $\dfrac{ {We} }{ {12} }\left( {1 - {C_{\rm{k} } } - \dfrac{3}{ {2\sqrt {Re} } }\displaystyle\int_{ {H_{\rm{m} } } }^{ {H_{\rm{s} } } } { {d^2}{\rm{d} }h} } \right) = {C_{\rm{S} } }P\left( { {D_{\rm{e} } } } \right) - P\left( { {D_{ {\rm{max} } } } } \right)$ 30—150 0—10 球冠 Gao等[34] $\begin{aligned} 1 + \frac{ {We} }{ {12} } = \frac{1}{6}\left[ {\frac{1}{ { { {\hat r}_{\rm{c} } } } } + \frac{1}{ { { {\hat R}_{\rm{c} } } } } } \right] + 4{\theta _{\rm{a} } }{ {\hat r}_{\rm{c} } }{ {\hat R}_{\rm{c} } } + {\left( { { {\hat R}_{\rm{c} } } - { {\hat r}_{\rm{c} } }\sin {\theta _{\rm{a} } } } \right)^2} \\ + {\left( { { {\hat R}_{\rm{c} } } + { {\hat r}_{\rm{c} } }\sin {\theta _{\rm{a} } } } \right)^2}\left( {\frac{4}{3}\frac{ {We} }{ {\sqrt {Re} } } - \cos {\theta _{\rm{a} } } } \right) \qquad\quad\end{aligned}$ 74—155 135—210 圆环 Wang等[35] $\begin{aligned} We + 12 =\qquad \qquad\qquad \qquad\qquad \qquad\qquad\qquad\qquad\qquad\qquad \qquad\\ \frac{3}{4}\left( {\frac{ {We} }{ {\sqrt {Re} } } + \alpha \frac{ {W{e_{\rm{c} } } } }{ {\sqrt {R{e_{\rm{c} } } } } } } \right)\beta _{\rm{m} }^3 + 3\left( {1 - \cos {\theta _{\rm{a} } } } \right)\beta _{\rm{m} }^2 + 12\bigg\{ \frac{ {\xi _{\rm{r} }^2} }{ { { {\left( {1 - \cos {\theta _{\rm{m} } } } \right)}^2} } } \\ \times \bigg[ {\sin ^2}{\theta _{\rm{m} } } - \frac{ { {\beta _{\rm{m} } } } }{ { {\xi _{\rm{r} } } } }\sin {\theta _{\rm{m} } }(1 - \cos {\theta _{\rm{m} } }) + 2(1 - \cos {\theta _{\rm{m} } }) \bigg] \qquad \qquad \qquad \\ \left. + 2{\xi _{\rm{r} } }\left( {\frac{ { {\beta _{\rm{m} } } } }{2} - {\xi _{\rm{r} } }\frac{ {\sin {\theta _{\rm{m} } } } }{ {1 - \cos {\theta _{\rm{m} } } } } } \right)\left( {\left| {1 - \kappa } \right| + \frac{ { {\theta _{\rm{m} } } } }{ {1 - \cos {\theta _{\rm{m} } } } } } \right) \right\}\qquad\qquad \quad \end{aligned}$ 34—100 0.1—427 环状-薄片 表 2 超亲水表面最大铺展因子βm实验结果与以往典型模型预测值[27-32]之间的比较
Table 2. Comparison of previous model[27-32] prediction value of βm with experimental data
V0/(m·s–1) We βm-exp Chandra 等[27] Pasandideh-Fard 等[28] Mao等[29] Park等[32] Ukiwe 等[30] Huang等[31] 0.25 1.91 3.41 2.4 6.37 3.05 11.31 5.84 0.58 0.44 5.90 3.46 2.1 4.82 2.55 7.93 4.42 0.44 0.60 10.77 3.60 1.97 4.37 2.41 6.67 4.02 0.35 0.71 15.26 3.82 1.93 4.20 2.37 6.09 3.90 0.29 0.93 25.59 3.93 1.89 4.07 2.35 5.41 3.82 0.20 130 51.17 4.08 1.90 4.08 2.38 4.9 3.93 0.12 1.50 68.59 4.26 1.91 4.13 2.41 4.78 3.93 0.10 1.89 109.3 4.43 1.93 4.26 2.47 4.67 4.07 0.06 2.35 168.98 4.70 1.97 4.42 2.54 4.66 4.24 0.04 2.8 239.89 4.90 2.00 4.57 2.60 4.72 4.39 0.03 3.08 290.08 5.00 2.02 4.67 2.64 4.76 4.48 0.02 表 3 本文模型预测值与文献[28,29]中不同润湿性表面的最大铺展因子的实验值对比
Table 3. Comparison of current theoretical model of βm with experimental data in literature[28,29].
固体/液体 D0, mm V0/(m·s–1) We θ/(°) βm-exp βm-model (βm-exp–βm-model)/ βm-model 玻璃/水 2.7 0.55 11.21 37 1.77 2.41 0.26 玻璃/水 2.7 0.82 24.91 37 2.20 2.74 0.19 玻璃/水 2.7 1.00 37.05 37 2.53 2.94 0.14 玻璃/水 2.7 1.58 92.48 37 3.11 3.51 0.11 玻璃/水 2.7 1.86 128.17 37 3.70 3.81 0.03 玻璃/水 2.7 2.77 284.26 37 4.50 4.48 0.00 玻璃/水 2.7 3.72 512.67 37 4.94 4.89 0.01 不锈钢/水 2.7 0.55 11.21 67 1.67 1.95 0.14 不锈钢/水 2.7 0.82 24.91 67 2.16 2.28 0.05 不锈钢/水 2.7 1.00 37.05 67 2.34 2.51 0.06 不锈钢/水 2.7 1.58 92.48 67 3.09 3.13 0.01 不锈钢/水 2.7 1.86 128.17 67 3.67 3.38 0.08 不锈钢/水 2.7 2.77 284.26 67 4.42 4.15 0.06 不锈钢/水 2.7 3.72 512.67 67 4.88 4.65 0.05 石蜡/水 2.7 0.55 11.21 97 1.65 1.58 0.04 石蜡/水 2.7 0.82 24.91 97 2.10 1.91 0.10 石蜡/水 2.7 1.00 37.05 97 2.26 2.13 0.06 石蜡/水 2.7 1.58 92.48 97 3.01 2.79 0.07 石蜡/水 2.7 1.86 128.17 97 3.60 3.09 0.16 石蜡/水 2.7 2.77 284.26 97 4.32 3.89 0.11 石蜡/水 2.7 3.72 512.67 97 4.78 4.44 0.08 蜂蜡/水 0.62 2.61 59 111 2.65 2.19 0.21 蜂蜡/水 0.78 3.29 118 111 3.18 2.76 0.15 蜂蜡/水 0.89 3.71 171 111 3.45 3.09 0.11 蜂蜡/水 0.98 4.00 219 111 3.79 3.33 0.14 蜂蜡/水 1.05 4.28 271 111 3.91 3.53 0.10 -
[1] Liang G, Mudawar I 2016 Int. J. Heat Mass Transfer 101 577Google Scholar
[2] 马学虎, 兰忠, 王凯, 陈彦松, 程雅琦, 杜宾港, 叶轩 2018 化工学报 69 9Google Scholar
Ma X H, Lan Z, Wang K, Chen Y S, Cheng Y Q, Du B G, Ye X 2018 J. Chem. Ind. Eng. 69 9Google Scholar
[3] Snoeijer J H, Andreotti B 2013 Annu. Rev. Fluid Mech. 45 269Google Scholar
[4] 朱君悦, 段远源, 王晓东, 闵琪 2014 化工学报 65 765Google Scholar
Zhu J Y, Duan Y Y, Wang X D, Min Q 2014 J. Chem. Ind. Eng. 65 765Google Scholar
[5] 刘海龙, 沈学峰, 王睿, 曹宇, 王军锋 2018 力学学报 50 1024Google Scholar
Liu H L, Shen X F, Wang R, Cao Y, Wang J F 2018 Acta Mech. Sin. 50 1024Google Scholar
[6] 闵琪, 段远源, 王晓东, 吴莘馨 2013 热科学与技术 12 335Google Scholar
Min Q, Duan Y Y, Wang X D, Wu X X 2013 J. Therm. Sci. Technol. 12 335Google Scholar
[7] Hu H B, Chen L B, Bao L Y, Huang S H 2014 Chin. Phys. B 23 074702Google Scholar
[8] Sun Z H, Han R J 2008 Chin. Phys. B 17 3185Google Scholar
[9] Wang Y B, Wang Y F, Gao S R, Yang Y R, Wang X D, Chen M 2020 Langmuir 36 9306Google Scholar
[10] Hu H B, Huang S H, Chen L B 2013 Chin. Phys. B 22 084702Google Scholar
[11] Song M, Liu Z, Ma Y, Dong Z, Wang Y, Jiang L 2017 NPG Asia Mater. 9 1Google Scholar
[12] 王高远, 胥蕊娜, 陈剑楠, 陈学, 姜培学 2018 工程热 39 1797Google Scholar
Wang G Y, Xu R N, Chen J N, Chen X, Jiang P X 2018 J. Eng. Thermphys. 39 1797Google Scholar
[13] Lin S, Zhao B, Zou S, Guo J, Wei Z, Chen L 2018 J. Colloid Interface Sci. 516 86Google Scholar
[14] Lee J B, Derome D, Guyer R, Carmeliet J 2016 Langmuir 32 1299Google Scholar
[15] Tang C, Qin M, Weng X, Zhang X, Zhang P, Li J, Huang Z 2017 Int. J. Multiphase Flow 96 56Google Scholar
[16] 荣松, 沈世全, 王天友, 车志钊 2019 68 154701Google Scholar
Rong S, Shen S Q, Wang T Y, Che Z Z 2019 Acta Phys. Sin. 68 154701Google Scholar
[17] Ding B, Wang H, Zhu X, Chen R, Liao Q 2018 Int. J. Heat Mass Transfer 124 1025Google Scholar
[18] 范瑶, 王宏, 朱恂, 黄格永, 丁玉栋, 廖强 2016 化工学报 67 2709Google Scholar
Fan Y, Wang H, Zhu X, Huang G Y, Ding Y D, Liao Q 2016 J. Chem. Ind. Eng. 67 2709Google Scholar
[19] Ding B, Wang H, Zhu X, Chen R, Liao Q 2019 Int. J. Heat Mass Transfer 138 844Google Scholar
[20] Chen M, Wu D, Chen D, Deng J, Liu H, Jiang J 2020 Chem. Eng. Sci. 226 115864Google Scholar
[21] 焦云龙, 刘小君, 逄明华, 刘焜 2016 65 016801Google Scholar
Jiao Y L, Liu X J, Pang M H, Liu K 2016 Acta Phys. Sin. 65 016801Google Scholar
[22] 叶学民, 李永康, 李春曦 2016 65 234701Google Scholar
Ye X M, Li Y K, Li C X 2016 Acta Phys. Sin. 65 234701Google Scholar
[23] Roisman I V 2009 Phys. Fluids 21 052104Google Scholar
[24] Liang G, Chen Y, Chen L, Shen S 2019 Ind. Eng. Chem. Res. 58 10053Google Scholar
[25] Laan N, de Bruin K G, Bartolo D, Josserand C, Bonn D 2014 Phys. Rev. Appl. 2 044018Google Scholar
[26] Lee J B, Laan N, de Bruin K G, Skantzaris G, Shahidzadeh N, Derome D, Carmeliet J, Bonn D 2016 J. Fluid Mech. 786 R4Google Scholar
[27] Chandra S, Avedisian C T 1991 Proc. R. Soc. A 432 13Google Scholar
[28] Pasandideh‐Fard M, Qiao Y M, Chandra S, Mostaghimi J 1996 Phys. Fluids 8 650Google Scholar
[29] Mao T, Kuhn D C S, Tran H 1997 AlChE J. 43 2169Google Scholar
[30] Ukiwe C, Kwok D Y 2005 Langmuir 21 666Google Scholar
[31] Huang H M, Chen X P 2018 Phys. Fluids 30 022106Google Scholar
[32] Park H, Carr W W, Zhu J, Morris J F 2003 AlChE J. 49 2461Google Scholar
[33] Li Ri, Ashgriz Nasser, Sanjeev C 2010 J. Fluids Eng. 132 061302Google Scholar
[34] Gao X, Li R 2014 AlChE J. 60 2683Google Scholar
[35] Wang F, Yang L, Wang L, Zhu Y, Fang T 2019 Langmuir 35 3204Google Scholar
[36] Panda A, Pati A R, Saha B, Kumar A, Mohapatra S S 2019 Chem. Eng. Sci. 207 527Google Scholar
[37] Zhang Z, Jiang P X, Christopher D M, Liang X-G 2015 Int. J. Heat Mass Transfer 80 26Google Scholar
[38] Zheng Y, Ma X, Li Y, Jiang R, Wang K, Lan Z, Liang Q 2017 Appl. Therm. Eng. 111 1548Google Scholar
[39] Nam Y, Ju Y S 2013 J. Adhes. Sci. Technol. 27 2163Google Scholar
[40] Vadillo D C, Soucemarianadin A, Delattre C, Roux D C D 2009 Phys. Fluids 21 122002Google Scholar
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