掺镁碳酸熔盐液体导热特性

doi:10.11949/j.issn.0438-1157.20170042

化工学报 ›› 2017, Vol. 68 ›› Issue (11): 4407-4413.DOI: 10.11949/j.issn.0438-1157.20170042

• 材料化学工程与纳米技术 • 上一篇下一篇

掺镁碳酸熔盐液体导热特性

丁静¹, 黄成龙¹, 杜丽禅¹, 田禾青¹, 魏小兰², 邓素妍¹, 王维龙¹

1 中山大学工学院, 广东广州 510006;
2 华南理工大学传热强化与过程节能教育部重点实验室, 广东广州 510640

收稿日期:2017-01-10 修回日期:2017-08-02 出版日期:2017-11-05 发布日期:2017-11-05
通讯作者: 王维龙
基金资助:
国家自然科学基金项目（U1507113，51436009）；广东省科技计划项目（2015A010106006）；广东省自然科学基金项目（2016A030313362）。

Thermal conductivity of liquid carbonate salt doped with magnesium powder

DING Jing¹, HUANG Chenglong¹, DU Lichan¹, TIAN Heqing¹, WEI Xiaolan², DENG Suyan¹, WANG Weilong¹

1 School of Engineering, Sun Yat-Sen University, Guangzhou 510006, Guangdong, China;
2 Key Laboratory of Enhanced Heat Transfer and Energy Conservation of Ministry of Education, South China University of Technology, Guangzhou 510640, Guangdong, China

Received:2017-01-10 Revised:2017-08-02 Online:2017-11-05 Published:2017-11-05
Supported by:
supported by the National Natural Science Foundation of China (U1507113, 51436009), the Science and Technology Planning Project of Guangdong Province (2015A010106006) and the Natural Science Foundation of Guangdong Province (2016A030313362).

摘要/Abstract

摘要：

为克服碳酸熔盐热导率较低的不足，提出通过向三元碳酸熔盐（Li₂CO₃-Na₂CO₃-K₂CO₃）掺杂金属镁粉来改善导热性能的新思路，采用静态熔融法制备了掺杂1%、2%掺镁碳酸熔盐复合材料。采用扫描电镜-X射线能谱、阿基米德法、差示扫描量热法（DIN比热测试标准）和激光闪光法，分别观察了掺镁碳酸熔盐形貌结构，测量了熔盐和复合熔盐液体的密度、比热容、热扩散系数，最后计算获得复合熔盐液体的热导率。研究结果表明，镁粉的加入改变了纯盐（三元碳酸熔盐）的形貌结构，熔体内形成大量的2~5 μm球体颗粒，与纯盐相比，1%掺镁碳酸熔盐液体密度、热扩散系数和热导率都得到增强，液体比热容减小，复合熔盐液体的平均热导率增加了21.67%；2%掺镁碳酸熔盐液体密度、热扩散系数和热导率同样得到增强，虽然复合熔盐液体的比热容减小，但其平均热导率仍然增加了19.07%。1%掺镁碳酸熔盐具有更高的液体密度、热扩散系数和热导率，可作为传热介质在太阳能热发电传蓄热系统推广。

关键词: 太阳能, 碳酸熔盐, 复合材料, 镁粉, 制备, 热导率, 液体

Abstract:

In order to improve the low thermal conductivity performance of carbonate molten salt, it is proposed to dope metal magnesium powder with ternary carbonate molten salt (Li₂CO₃-Na₂CO₃-K₂CO₃) to strengthen the thermal conductivity. The static melting method was used to prepare the composite carbonate salts with 1%(mass) or 2%(mass) magnesium powder. The morphology, structure, liquid density, specific heat capacity, and thermal diffusivity were characterized by the scanning electron microscope-energy dispersive X-ray spectrometer (SEM-EDX), Archimedes method, the differential scanning calorimeter (DIN specific heat measure standard) and the laser flash method, respectively. The thermal conductivity was finally calculated based on the density, specific heat capacity, and thermal diffusivity. The results showed that the introducing of magnesium powder changed the morphology of pure eutectic (ternary carbonate salt), a large number of spherical particles (2-5 μm) were detected in the composite salts. Comparison with the pure eutectic, the liquid density, thermal diffusivity and thermal conductivity of salt compound doped magnesium powder were enhanced, and the liquid specific heat capacity was diminished. The mean thermal conductivity of salt compound doped with 1% or 2% magnesium powder was enhanced by 21.67% and 19.07%, respectively. So, the 1% salt composite should be the promising HTF due to the enhancement of density, thermal diffusivity and thermal conductivity.

Key words: solar energy, carbonate salt, composites, magnesium powder, preparation, thermal conductivity, liquid

中图分类号:

TK02

丁静, 黄成龙, 杜丽禅, 田禾青, 魏小兰, 邓素妍, 王维龙. 掺镁碳酸熔盐液体导热特性[J]. 化工学报, 2017, 68(11): 4407-4413.

DING Jing, HUANG Chenglong, DU Lichan, TIAN Heqing, WEI Xiaolan, DENG Suyan, WANG Weilong. Thermal conductivity of liquid carbonate salt doped with magnesium powder[J]. CIESC Journal, 2017, 68(11): 4407-4413.

参考文献 23

[1]	KANNAN N, VAKEESAN D. Solar energy for future world:a review[J]. Renewable and Sustainable Energy Reviews, 2016, 62:1092-1105.
[2]	盛玲霞, 李佳燕, 赵豫红. 塔式太阳能电站接收器的建模及动态仿真[J]. 化工学报, 2016, 67(3):736-742. SHENG L X, LI J Y, ZHAO Y H. Modeling and dynamic simulation of receiver in a solar tower station[J]. CIESC Journal, 2016, 67(3):736-742.
[3]	BALGHOUTHI M, TRABELSI S E, AMARA M B, et al. Potential of concentrating solar power (CSP) technology in Tunisia and the possibility of interconnection with Europe[J]. Renewable and Sustainable Energy Reviews, 2016, 56:1227-1248.
[4]	VIGNAROOBAN K, XU X H, ARVAY A, et al. Heat transfer fluids for concentrating solar power systems-a review[J]. Applied Energy, 2015, 146:383-396.
[5]	LIU M, TAY N S, BELL S, et al. Review on concentrating solar power plants and new developments in high temperature thermal energy storage technologies[J]. Renewable and Sustainable Energy Reviews, 2016, 53:1411-1432.
[6]	崔武军, 吴玉庭, 熊亚选, 等. 低熔点熔盐蓄热罐内温度分布与散热损失实验[J]. 化工学报, 2014, 65(S1):162-167. CUI W J, WU Y T, XIONG Y X, et al. Temperature distribution and heat loss experiments of low melting point molten salt heat storage tank[J]. CIESC Journal, 2014, 65(S1):162-167.
[7]	LIU M, SAMAN W, BRUNO F. Review on storage materials and thermal performance enhancement techniques for high temperature phase change thermal storage systems[J]. Renewable and Sustainable Energy Reviews, 2012, 16:2118-2132.
[8]	WICAKSONO H, ZHANG X, FUJIWARA S, et al. Measurements of thermal conductivity and thermal diffusivity of molten carbonates[J]. The Reports of Institute of Advanced Material Study Kyushu University, 2001, 15:165-168.
[9]	SHIN D, BANERJEE D. Enhanced thermal properties of SiO2 nanocomposite for solar thermal energy storage applications[J]. International Journal of Heat and Mass Transfer, 2015, 84:898-902.
[10]	OYA T, NOMURA T, TSUBOTA M, et al. Thermal conductivity enhancement of erythritol as PCM by using graphite and nickel particles[J]. Applied Thermal Engineering, 2013, 61:825-828.
[11]	WEST R E. High temperature sensible heat storage[J]. Energy, 1985, 10(10):1165-1175.
[12]	JORGENSEN G, SCHISSEL P, BURROWS R. Optical properties of high-temperature materials for direct absorption receivers[J]. Solar Energy Materials, 1985, 14(3/4/5):385-394.
[13]	COYLE R T, THOMAS T M, SCHISSEL P, et al. Corrosion of selected alloys in eutectic lithium-sodium-potassium carbonate at 900℃[R]. Golden:Solar Energy Research Institnte, 1986.
[14]	GHERIBI A E, TORRES J A, CHARTRAND P. Recommended values for the thermal conductivity of molten salts between the melting and boiling points[J]. Solar Energy Materials & Solar Cells, 2014, 126:11-25.
[15]	SHIBATA H, OHTA H, YOSHIDA H. Thermal diffusivity of molten carbonates at elevated temperatures[J]. High Temperature Material Processes, 2002, 21(3):139-142.
[16]	AN X H, CHENG J H, ZHANG P, et al. Determination and evaluation of the thermo-physical properties of an alkali carbonate eutectic molten salt[J]. Faraday Discussions, 2016, 190:327-338.
[17]	OTSUBO S, NAGASAKA Y, NAGASHIMA A. Experimental study on the forced Rayleigh scattering method using CO2 laser(Ⅲ):Measurement of molten single carbonates and their binary and ternary mixtures[J]. Nihon Kikai Gakkai Ronbunshu B Hen/Transactions of the Japan Society of Mechanical Engineers Part B, 1998, 64(619):806-813.
[18]	PELTON A D, BALE C W, LIN P L. Calculation of phase diagrams and thermodynamic properties of 14 additive and reciprocal ternary systems containing Li2CO3, Na2CO3, K2CO3, Li2SO4, Na2SO4, K2SO4, LiOH, NaOH, and KOH[J]. Canadian Journal of Chemistry, 1984, 62(3):457-474.
[19]	黎文献. 镁及镁合金[M]. 长沙:中南大学出版社, 2005:2-8. LI W X. Magnesium and Magnesium Alloys[M]. Changsha:Central South University Press, 2005:2-8.
[20]	徐日瑶. 镁冶金学[M]. 北京:冶金工业出版社, 1981:3. XU R Y. Magnesium Metallurgy[M]. Beijing:Metallurgical Industry Press, 1981:3.
[21]	高自省. 镁及镁合金防腐与表面强化生产技术[M]. 北京:冶金工业出版社, 2012:1. GAO Z X. Magnesium and Magnesium Alloy Corrosion and Surface Hardening Production Technology[M]. Beijing:Metallurgical Industry Press, 2012:1.
[22]	MIN S, BLUMM J, LINDEMANN A. A new laser flash system for measurement of the thermo-physical properties[J]. Thermochimica Acta, 2007, 455:46-49.
[23]	BAIK H T, SHIN D. Experimental validation of enhanced heat capacity of ionic liquid-based nanomaterial[J]. Applied Physics Letters, 2013, 102:173906.

掺镁碳酸熔盐液体导热特性

Thermal conductivity of liquid carbonate salt doped with magnesium powder

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献 23

相关文章 15

编辑推荐

Metrics

本文评价

[1]	叶展羽, 山訸, 徐震原. 用于太阳能蒸发的折纸式蒸发器性能仿真[J]. 化工学报, 2023, 74(S1): 132-140.
[2]	王琪, 张斌, 张晓昕, 武虎建, 战海涛, 王涛. 氯铝酸-三乙胺离子液体/P₂O₅催化合成伊索克酸和2-乙基蒽醌[J]. 化工学报, 2023, 74(S1): 245-249.
[3]	车睿敏, 郑文秋, 王小宇, 李鑫, 许凤. 基于离子液体的纤维素均相加工研究进展[J]. 化工学报, 2023, 74(9): 3615-3627.
[4]	陈美思, 陈威达, 李鑫垚, 李尚予, 吴有庭, 张锋, 张志炳. 硅基离子液体微颗粒强化气体捕集与转化的研究进展[J]. 化工学报, 2023, 74(9): 3628-3639.
[5]	程业品, 胡达清, 徐奕莎, 刘华彦, 卢晗锋, 崔国凯. 离子液体基低共熔溶剂在转化CO₂中的应用[J]. 化工学报, 2023, 74(9): 3640-3653.
[6]	王俐智, 杭钱程, 郑叶玲, 丁延, 陈家继, 叶青, 李进龙. 离子液体萃取剂萃取精馏分离丙酸甲酯+甲醇共沸物[J]. 化工学报, 2023, 74(9): 3731-3741.
[7]	陈杰, 林永胜, 肖恺, 杨臣, 邱挺. 胆碱基碱性离子液体催化合成仲丁醇性能研究[J]. 化工学报, 2023, 74(9): 3716-3730.
[8]	米泽豪, 花儿. 基于DFT和COSMO-RS理论研究多元胺型离子液体吸收SO₂气体[J]. 化工学报, 2023, 74(9): 3681-3696.
[9]	宋明昊, 赵霏, 刘淑晴, 李国选, 杨声, 雷志刚. 离子液体脱除模拟油中挥发酚的多尺度模拟与研究[J]. 化工学报, 2023, 74(9): 3654-3664.
[10]	齐聪, 丁子, 余杰, 汤茂清, 梁林. 基于选择吸收纳米薄膜的太阳能温差发电特性研究[J]. 化工学报, 2023, 74(9): 3921-3930.
[11]	杨绍旗, 赵淑蘅, 陈伦刚, 王晨光, 胡建军, 周清, 马隆龙. Raney镍-质子型离子液体体系催化木质素平台分子加氢脱氧制备烷烃[J]. 化工学报, 2023, 74(9): 3697-3707.
[12]	陆俊凤, 孙怀宇, 王艳磊, 何宏艳. 离子液体界面极化及其调控氢键性质的分子机理[J]. 化工学报, 2023, 74(9): 3665-3680.
[13]	郑佳丽, 李志会, 赵新强, 王延吉. 离子液体催化合成2-氰基呋喃反应动力学研究[J]. 化工学报, 2023, 74(9): 3708-3715.
[14]	傅予, 刘兴翀, 王瀚雨, 李海敏, 倪亚飞, 邹文静, 雷月, 彭永姗. F₃EACl修饰层对钙钛矿太阳能电池性能提升的研究[J]. 化工学报, 2023, 74(8): 3554-3563.
[15]	胡兴枝, 张皓焱, 庄境坤, 范雨晴, 张开银, 向军. 嵌有超小CeO₂纳米粒子的碳纳米纤维的制备及其吸波性能[J]. 化工学报, 2023, 74(8): 3584-3596.