Experimental study on effect of surfactants on subcooled pool boiling characteristics of pure water working medium

doi:10.11949/0438-1157.20211168

Abstract

Abstract:

The effects of Tween20, Span20 and their composite surfactants on the subcooled pool boiling heat transfer characteristics of pure water are studied. Based on the experimental results and the analysis of basic physical properties such as surface tension, contact angle and critical micelle concentration, it is found that the effect of an identical surfactant on boiling heat transfer is determined by its addition type, concentration and heat flux. On one hand, different from saturated boiling, Tween20 added in water can effectively reduce the temperature of onset of nucleate boiling and wall superheat under subcooling condition, but this boiling heat transfer strengthening effect is weakened at high heat flux conditions. On the other hand, Span20 in water only shows the boiling strengthening effect when its concentration is low, and the increase of Span20 concentration will lead to a large increase of wall superheat. Moreover, although both Tween20 and Span20 have the potential to enhance boiling heat transfer, the composite of Tween20 and Span20 surfactants deteriorates heat transfer in the concentration range tested in present experiment. The above research results can provide a basic basis for the analysis of the subcooled pool boiling heat transfer characteristics of the heat transfer-enhanced composite working fluid and provide guidance for its preparation.

Key words: boiling heat transfer, phase change, surfactant, composite, interfacial tension, critical micelle concentration

摘要：

以Tween20、Span20及两者复配物为表面活性剂，实验研究了其对水过冷池沸腾传热特性影响。基于实验结果与表面张力、接触角、临界胶束浓度等基础物性分析发现，单一表面活性剂对沸腾传热的影响由其添加种类、浓度及热通量共同决定。一方面，不同于饱和沸腾情形，过冷状态下Tween20能够有效降低沸腾起始点温度与壁面过热度，但其沸腾强化效果在高热通量下减弱；另一方面，Span20只在低浓度下表现出强化效果，其浓度增大将引起壁面过热度大幅攀升。此外，尽管Tween20与Span20都具有强化沸腾传热的潜力，但两者复配表面活性剂在实验研究浓度范围内均恶化了沸腾传热过程。研究结果可为传热强化复合工质过冷池沸腾传热特性分析提供基础依据，并为其配制提供指导。

关键词: 沸腾传热, 相变, 表面活性剂, 复配, 界面张力, 临界胶束浓度

CLC Number:

TK 124

Zhen YANG, Yuanpeng YAO, Yun LI, Huiying WU. Experimental study on effect of surfactants on subcooled pool boiling characteristics of pure water working medium[J]. CIESC Journal, 2022, 73(3): 1093-1101.

杨振, 姚元鹏, 李昀, 吴慧英. 表面活性剂对水过冷池沸腾特性影响实验研究[J]. 化工学报, 2022, 73(3): 1093-1101.

Figures/Tables 13

Fig.1 Schematic diagram of the experimental set-up

Fig.2 Schematic diagram of the heating part

Table 1 Uncertainties of experimental parameters

热通量/(W·cm^-2)	E_q /%	E_T_w/%	E_h /%
34.4	5.93	0.107	5.98
180.9	3.13	0.188	3.35

Fig.3 Comparison of saturated pool boiling curves of water between correlations[18-19] and experimental data[20-22] reported in literatures

Fig.4 Effects of Tween20 on subcooled pool boiling characteristics of water

Fig.5 Effects of Tween20 on saturated pool boiling characteristics of water

Table 2 Effects of Tween20 on ONB

浓度/(ml·L^-1)	ONB/℃
0	111.9
0.05	110.6
0.5	108.4
1	108.2

Fig.6 Effects of Tween20 on surface tension and contact angle

Fig.7 Temperature fluctuations of boiling surface under high heat flux

Fig.8 Effects of Span20 on subcooled pool boiling characteristics of water

Fig.9 Effects of Tween20-Span20 on subcooled pool boiling characteristics of water

Fig.10 Images of bubble morphology affected by surfactants (q=69 W·cm-2)

Fig.11 Evolutions of bubbles affected by Span20 and Tween20-Span20 (q=69 W·cm-2)

References 30

1	魏进家, 张永海. 柱状微结构表面强化沸腾换热研究综述[J]. 化工学报, 2016, 67(1): 97-108.
	Wei J J, Zhang Y H. Review of enhanced boiling heat transfer over micro-pin-finned surfaces[J]. CIESC Journal, 2016, 67(1): 97-108.
2	牟帅, 赵长颖, 徐治国. 局部表面改性紫铜方柱阵列池沸腾传热特性和机理[J]. 化工学报, 2019, 70(4): 1291-1301.
	Mou S, Zhao C Y, Xu Z G. Pool boiling heat transfer performance and mechanism of square copper pillar arrays with partially-modified surface[J]. CIESC Journal, 2019, 70(4): 1291-1301.
3	Cheng X, Yao Y P, Wu H Y. An experimental investigation of flow boiling characteristics in silicon-based groove-wall microchannels with different structural parameters[J]. International Journal of Heat and Mass Transfer, 2021, 168: 120843.
4	Liang G T, Mudawar I. Review of pool boiling enhancement with additives and nanofluids[J]. International Journal of Heat and Mass Transfer, 2018, 124: 423-453.
5	黄玉媛. 精细化工配方常用原料手册[M]. 广州: 广东科技出版社, 1998.
	Huang Y Y. Manual of Common Raw Materials for Fine Chemical Formula[M]. Guangzhou: Guangdong Science & Technology Press, 1998.
6	Mahamod W, Abdulah D K, Lim W H, et al. Emulsion properties of mixed Tween20-Span20 in non-aqueous system[J]. Pertanika Journal of Science & Technology, 2002, 10(2): 153-160.
7	Wu W T, Yang Y M, Maa J R. Enhancement of nucleate boiling heat transfer and depression of surface tension by surfactant additives[J]. Journal of Heat Transfer, 1995, 117(2): 526-529.
8	Ravikumar S V, Jha J M, Sarkar I, et al. Enhancement of heat transfer rate in air-atomized spray cooling of a hot steel plate by using an aqueous solution of non-ionic surfactant and ethanol[J]. Applied Thermal Engineering, 2014, 64(1/2): 64-75.
9	Bhatt N H, Lily, Raj R, et al. Enhancement of heat transfer rate of high mass flux spray cooling by ethanol-water and ethanol-tween20-water solution at very high initial surface temperature[J]. International Journal of Heat and Mass Transfer, 2017, 110: 330-347.
10	Ravikumar S V, Haldar K, Jha J M, et al. Heat transfer enhancement using air-atomized spray cooling with water-Al₂O₃ nanofluid[J]. International Journal of Thermal Sciences, 2015, 96: 85-93.
11	Dombek G, Nadolny Z, Marcinkowska A. Effects of nanoparticles materials on heat transfer in electro-insulating liquids[J]. Applied Sciences, 2018, 8(12): 2538.
12	Lin C Y, Wang J C, Chen T C. Analysis of suspension and heat transfer characteristics of Al₂O₃ nanofluids prepared through ultrasonic vibration[J]. Applied Energy, 2011, 88(12): 4527-4533.
13	Shiau B J, Sabatini D A, Harwell J H. Properties of food grade (edible) surfactants affecting subsurface remediation of chlorinated solvents[J]. Environmental Science & Technology, 1995, 29(12): 2929-2935.
14	尹博, 杨佐毅, 王玉洁, 等. 表面活性剂对苯胺和偶氮苯的增溶作用研究[J]. 环境科学与技术, 2016, 39(12): 46-50, 123.
	Yin B, Yang Z Y, Wang Y J, et al. Study on the surfactant’s solubilization to aniline and azobenzene[J]. Environmental Science & Technology, 2016, 39(12): 46-50, 123.
15	Pey C M, Maestro A, Solé I, et al. Optimization of nano-emulsions prepared by low-energy emulsification methods at constant temperature using a factorial design study[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2006, 288(1/2/3): 144-150.
16	Kandlikar S G. Controlling bubble motion over heated surface through evaporation momentum force to enhance pool boiling heat transfer[J]. Applied Physics Letters, 2013, 102(5): 051611.
17	Moffat R J. Describing the uncertainties in experimental results[J]. Experimental Thermal and Fluid Science, 1988, 1(1): 3-17.
18	Rohsenow W M. A method of correlating heat transfer data for surface boiling of liquids[J]. Trans. ASME, 1952,74: 969-976.
19	Li Y Y, Chen Y J, Liu Z H. A uniform correlation for predicting pool boiling heat transfer on plane surface with surface characteristics effect[J]. International Journal of Heat and Mass Transfer, 2014, 77: 809-817.
20	Neto A R, Oliveira J L G, Passos J C. Heat transfer coefficient and critical heat flux during nucleate pool boiling of water in the presence of nanoparticles of alumina, maghemite and CNTs[J]. Applied Thermal Engineering, 2017, 111: 1493-1506.
21	Mao L, Zhou W B, Hu X G, et al. Pool boiling performance and bubble dynamics on graphene oxide nanocoating surface[J]. International Journal of Thermal Sciences, 2020, 147: 106154.
22	Yang Y P, Ji X B, Xu J L. Pool boiling heat transfer on copper foam covers with water as working fluid[J]. International Journal of Thermal Sciences, 2010, 49(7): 1227-1237.
23	Li C, Wang Z K, Wang P I, et al. Nanostructured copper interfaces for enhanced boiling[J]. Small, 2008, 4(8): 1084-1088.
24	Zhang J T, Manglik R M. Nucleate pool boiling of aqueous polymer solutions on a cylindrical heater[J]. Journal of Non-Newtonian Fluid Mechanics, 2005, 125(2/3): 185-196.
25	Hetsroni G, Mosyak A, Pogrebnyak E, et al. Bubble growth in saturated pool boiling in water and surfactant solution[J]. International Journal of Multiphase Flow, 2006, 32(2): 159-182.
26	Hetsroni G, Gurevich M, Mosyak A, et al. Effect of surfactant concentration on saturated flow boiling in vertical narrow annular channels[J]. International Journal of Multiphase Flow, 2007, 33(11): 1141-1152.
27	Hu Z C, Gu J Q, Song X N, et al. Pool boiling heat transfer of aqueous surfactant solutions[C]//2011 Fourth International Conference on Intelligent Computation Technology and Automation. Shenzhen, China, 2011: 841-844.
28	Gouda R K, Pathak M, Kaleem K M. A biosurfactant as prospective additive for pool boiling heat transfer enhancement[J]. International Journal of Heat and Mass Transfer, 2020, 150: 119292.
29	Cheng L X, Mewes D, Luke A. Boiling phenomena with surfactants and polymeric additives: a state-of-the-art review[J]. International Journal of Heat and Mass Transfer, 2007, 50(13/14): 2744-2771.
30	Ahmmed K T, Syeda S R. Enhancement of nucleate pool boiling heat transfer with sodium oleate[J]. Journal of Chemical Engineering, 2017, 29(1): 44-48.

[1]	Shuangxing ZHANG, Fangchen LIU, Yifei ZHANG, Wenjing DU. Experimental study on phase change heat storage and release performance of R-134a pulsating heat pipe [J]. CIESC Journal, 2023, 74(S1): 165-171.
[2]	He JIANG, Junfei YUAN, Lin WANG, Guyu XING. Experimental study on the effect of flow sharing cavity structure on phase change flow characteristics in microchannels [J]. CIESC Journal, 2023, 74(S1): 235-244.
[3]	Yanpeng WU, Qianlong LIU, Dongmin TIAN, Fengjun CHEN. A review of coupling PCM modules with heat pipes for electronic thermal management [J]. CIESC Journal, 2023, 74(S1): 25-31.
[4]	Xin YANG, Xiao PENG, Kairu XUE, Mengwei SU, Yan WU. Preparation of molecularly imprinted-TiO₂ and its properties of photoelectrocatalytic degradation of solubilized PHE [J]. CIESC Journal, 2023, 74(8): 3564-3571.
[5]	Xingzhi HU, Haoyan ZHANG, Jingkun ZHUANG, Yuqing FAN, Kaiyin ZHANG, Jun XIANG. Preparation and microwave absorption properties of carbon nanofibers embedded with ultra-small CeO₂ nanoparticles [J]. CIESC Journal, 2023, 74(8): 3584-3596.
[6]	Haopeng SHI, Dawen ZHONG, Xuexin LIAN, Junfeng ZHANG. Experimental study on the downward-facing surface enhanced boiling heat transfer of multiscale groove-fin structures [J]. CIESC Journal, 2023, 74(7): 2880-2888.
[7]	Fangzhe SHI, Yunhua GAN. Numerical simulation of start-up characteristics and heat transfer performance of ultra-thin heat pipe [J]. CIESC Journal, 2023, 74(7): 2814-2823.
[8]	Meibo XING, Zhongtian ZHANG, Dongliang JING, Hongfa ZHANG. Enhanced phase change energy storage/release properties by combining porous materials and water-based carbon nanotube under magnetic regulation [J]. CIESC Journal, 2023, 74(7): 3093-3102.
[9]	Yuanliang ZHANG, Xinqi LUAN, Weige SU, Changhao LI, Zhongxing ZHAO, Liqin ZHOU, Jianmin CHEN, Yan HUANG, Zhenxia ZHAO. Study on selective extraction of nicotine by ionic liquids composite extractant and DFT calculation [J]. CIESC Journal, 2023, 74(7): 2947-2956.
[10]	Ao ZHANG, Yingwu LUO. Low modulus, high elasticity and high peel adhesion acrylate pressure sensitive adhesives [J]. CIESC Journal, 2023, 74(7): 3079-3092.
[11]	Jie WANG, Xiaolin QIU, Ye ZHAO, Xinyang LIU, Zhongqiang HAN, Yong XU, Wenhan JIANG. Preparation and properties of polyelectrolyte electrostatic deposition modified PHBV antioxidant films [J]. CIESC Journal, 2023, 74(7): 3068-3078.
[12]	Bin CAI, Xiaolin ZHANG, Qian LUO, Jiangtao DANG, Liyuan ZUO, Xinmei LIU. Research progress of conductive thin film materials [J]. CIESC Journal, 2023, 74(6): 2308-2321.
[13]	Zhangning CUI, Zixuan HU, Lei WU, Jun ZHOU, Gan YE, Tiantian LIU, Qiuli ZHANG, Yonghui SONG. Research progress on the water resistance of degradable cellulose-based materials [J]. CIESC Journal, 2023, 74(6): 2296-2307.
[14]	Zhen LI, Bo ZHANG, Liwei WANG. Development and properties of PEG-EG solid-solid phase change materials [J]. CIESC Journal, 2023, 74(6): 2680-2688.
[15]	Shaoyun CHEN, Dong XU, Long CHEN, Yu ZHANG, Yuanfang ZHANG, Qingliang YOU, Chenglong HU, Jian CHEN. Preparation and adsorption properties of monolayer polyaniline microsphere arrays [J]. CIESC Journal, 2023, 74(5): 2228-2238.