Influence of interfacial effect of mesoporous materials on heat transport characteristics of mixed nitrate composite phase change materials
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摘要: 随着化石燃料的快速消耗,能源安全、气候变化问题日益突出,清洁、可持续能源发展技术及储能技术的研究成为热点。本文采用分子动力学模拟和实验研究相结合的方式,展开界面效应对混合硝酸盐复合相变材料(CPCM)热输运特性的影响研究。首先分别采用激光导热仪和差示扫描量热仪测试了CPCM的热导率和比热容。然后使用Materials Studio软件建立共晶状态下不同NaNO3和KNO3配比、不同骨架的CPCM模型,对其热导率和定压比热进行分子动力学模拟计算,通过径向分布函数、界面结合能和体热膨胀系数的变化分析了实验结果的内在机制,进而深入分析了界面效应与混合硝酸盐配比对热物性影响的竞争关系。结果表明:NaNO3与KNO3质量比为4∶6时离子间相互作用弱于其他配比,界面结合能最大,热导率最大。界面结合能的增加对热导率的增强强于离子间相互作用的减弱对热导率的削弱,界面效应在CPCM热导率的变化中占主导地位;CPCM定压比热受离子对比例变化及骨架材料变化的影响,界面结合能及离子间相互作用对定压比热没有明显影响。Abstract: With the rapid consumption of fossil fuels, the issues of energy security and climate change are becoming increasingly prominent. The research of clean and sustainable energy development technology and energy storage technology has become a hot topic. By combining molecular dynamics simulation and experimental research, the influence of interface effects on the heat transport characteristics of mixed nitrate composite phase change materials (CPCM) was studied. Firstly, the thermal conductivity and specific heat capacity of CPCM were measured by laser thermal conductivity meter and differential scanning calorimeter respectively. Then Materials Studio software was used to establish the models of composite phase change materials with different NaNO3 and KNO3 ratios in eutectic states and different skeletons and the molecular dynamics simulation calculation of its thermal conductivity and specific heat at constant pressure was carried out. The internal mechanism of the experimental results was analyzed through the changes in radial distribution function, interface binding energy, and bulk thermal expansion coefficient, and then the competitive relationship between the interface effect and the mixed nitrate ratio on the thermal properties was further analyzed. The results show that when the mass ratio of NaNO3 and KNO3 is 4∶6, the interaction between ions is weaker than other ratios, and the interface binding energy and thermal conductivity are the largest. An increase in interfacial binding energy enhances the thermal conductivity more strongly than a decrease in the interaction between ions weakens the thermal conductivity, the interfacial effect plays a dominant role in the change in the thermal conductivity of CPCM. The specific heat of CPCM at constant pressure is affected by the change of ratio and skeleton material, interfacial binding energy and ionic interaction have no obvious effect on specific heat at constant pressure.
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图 1 混合硝酸盐复合相变材料(CPCM)制备过程:(a) 混合硝酸盐/多孔铝硅酸盐陶瓷CPCM;(b) 混合硝酸盐/多孔骨架CPCM
Figure 1. Preparation of mixed nitrate composite phase change material (CPCM): (a) Mixed nitrate/porous aluminosilicate ceramic CPCM; (b) Mixed nitrate/porous skeleton CPCM
图 2 混合硝酸盐CPCM的TEM图像:(a) [质量比w(NaNO3∶KNO3)=4∶6]/陶瓷;(b) [w(NaNO3∶KNO3)=4∶6]/Al2O3
Figure 2. TEM images of mixed nitrate CPCM: (a) [Mass ratio w(NaNO3∶KNO3)=4∶6]/ceramic; (b) [w(NaNO3∶KNO3)=4∶6]/Al2O3
图 3 (a) KNO3和NaNO3的单晶胞模型;(b) Al2O3和SiO2的单晶胞模型
Figure 3. (a) KNO3 and NaNO3 single cell models; (b) Al2O3 and SiO2 single cell models
图 4 不同KNO3和NaNO3的质量比下建立的混合硝酸盐复合相变材料模型
Figure 4. Models of mixed nitrate composite phase change materials were established with different mass ratios of KNO3 and NaNO3
图 6 NaNO3∶KNO3=4∶6的混合硝酸盐/Al2O3 CPCM的DSC测试
Figure 6. DSC test of NaNO3∶KNO3=4∶6 mixed nitrate/Al2O3 CPCM
图 7 混合硝酸盐复合相变材料定压比热实验:(a)固态比热;(b)液态比热;
Figure 7. Experiment on specific heat of mixed nitrate composite phase change materials at constant pressure: (a) Solid specific heat; (b) Liquid specific heat
图 8 陶瓷材料界面下离子之间的径向分布函数g(r):(a) K+-Na+;(b) K+-N−;(c) Na+-N−;(d) K+-Al3+;(e) K+-Si4+;(f) Na+-Al3+;(g) Na+-Si4+
Figure 8. Radial distribution function g(r) between ions at the interface of ceramic materials: (a) K+-Na+; (b) K+-N−; (c) Na+-N−; (d) K+-Al3+; (e) K+-Si4+; (f) Na+-Al3+; (g) Na+-Si4+
r—Radius
图 9 Al2O3介孔材料界面下离子之间的径向分布函数:(a) K+-Na+;(b) K+-N−;(c) Na+-N−;(d) K+-Al3+;(e) Na+-Al3+
Figure 9. Radial distribution function between ions at the interface of Al2O3 mesoporous material: (a) K+-Na+; (b) K+-N−; (c) Na+-N−; (d) K+-Al3+; (e) Na+-Al3+
图 10 SiO2介孔材料界面下离子之间的径向分布函数:(a) K+-Na+;(b) K+-N−;(c) Na+-N−;(d) K+-Si4+;(e) Na+-Si4+
Figure 10. Radial distribution function between ions at the interface of SiO2 mesoporous materials:(a) K+-Na+; (b) K+-N−; (c) Na+-N−; (d) K+-Si4+; (e) Na+-Si4+
图 12 不同骨架下混合硝酸盐CPCM体热膨胀系数和体积:(a) SiO2骨架;(b) Al2O3骨架;(c) 陶瓷骨架;(d) 体积
Figure 12. Coefficient of thermal expansion and volume of mixed nitrate CPCM under different skeletons: (a) SiO2; (b) Al2O3; (c) Ceramic; (d) Volume
图 13 不同骨架下混合硝酸盐CPCM热导率:(a) SiO2骨架;(b) Al2O3骨架;(c) 陶瓷骨架
Figure 13. Thermal conductivity of mixed nitrate CPCM under different skeletons: (a) SiO2; (b) Al2O3; (c) Ceramic
图 14 不同骨架下混合硝酸盐CPCM定压比热容:(a) Al2O3骨架;(b) SiO2骨架;(c) 陶瓷骨架
Figure 14. Specific heat capacity at constant pressure of mixed nitrate CPCM under different skeletons: (a) Al2O3; (b) SiO2; (c) Ceramic
图 15 不同骨架下混合硝酸盐CPCM定压比热:(a) 熔化前SiO2骨架;(b) 熔化后SiO2骨架;(c) 熔化前陶瓷骨架;(d) 熔化后陶瓷骨架;(e) 熔化前Al2O3骨架;(f) 熔化后Al2O3骨架
Figure 15. Specific heat at constant pressure of mixed nitrate CPCM under different skeletons: (a) SiO2 skeleton before melting; (b) SiO2 skeleton after melting; (c) Ceramic skeleton before melting; (d) Ceramic skeleton after melting; (e) Al2O3 skeleton before melting; (f) Al2O3 skeleton after melting
表 1 材料信息
Table 1. Material information
Materials Manufacturers Purity KNO3 Sinopharm Chemical Reagent
CO., LTD.Analytical purity NaNO3 Sinopharm Chemical Reagent
CO., LTD.Analytical purity Al2O3 Sinopharm Chemical Reagent
CO., LTD.Analytical purity Al(OH)3 Tianjin Damao Chemical
Reagent FactoryAnalytical purity Diatomite Tianjin Damao Chemical
Reagent FactoryAnalytical purity Citrin Shanghai AIbi Chemical
Reagent CO., LTD.99.5% Gelatin Tianjin Bodi Chemical CO., LTD. 99.5% SBA-15 Beijing Solaibao Technology
CO., LTD.100%Si Anhydrous ethanol Sinopharm Chemical Reagent
CO., LTD.99.5% Note: SBA-15—SiO2 molecular sieve. 
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表 2 混合硝酸盐复合相变材料离子数
Table 2. Ions of mixed nitrate composite phase change material
CPCM Nitrate ions Skeleton molecule Scale/nm Na+ K+ NO3− Al2O3 SiO2 [w(NaNO3∶KNO3)=6∶4]/Al2O3 180 101 281 287 0 6-7 [w(NaNO3∶KNO3)=6∶4]/SiO2 180 101 281 0 473 6-7 [w(NaNO3∶KNO3)=6∶4]/ceramic 180 101 281 77 363 6-7 [w(NaNO3∶KNO3)=5∶5]/Al2O3 151 127 278 294 0 6-7 [w(NaNO3∶KNO3)=5∶5]/SiO2 151 127 278 0 473 6-7 [w(NaNO3∶KNO3)=5∶5]/ceramic 151 127 278 77 363 6-7 [w(NaNO3∶KNO3)=4∶6]/Al2O3 126 159 285 308 0 6-7 [w(NaNO3∶KNO3)=4∶6]/SiO2 126 159 285 0 495 6-7 [w(NaNO3∶KNO3)=4∶6]/ceramic 126 159 285 77 363 6-7 [w(NaNO3∶KNO3)=9∶1]/Al2O3 265 25 290 287 0 6-7 [w(NaNO3∶KNO3)=9∶1]/SiO2 265 25 290 0 462 6-7 [w(NaNO3∶KNO3)=9∶1]/ceramic 265 25 290 70 330 6-7
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表 3 混合硝酸盐CPCM熔化前后比热
Table 3. Specific heat of mixed nitrate CPCM before and after melting
CPCM Specific heat
of solid state/
(J·g−1·K−1)Specific heat
of liquid/
(J·g−1·K−1)[w(NaNO3∶KNO3)=6∶4]/Al2O3 1.15568 1.4600 [w(NaNO3∶KNO3)=6∶4]/SiO2 0.97800 1.2940 [w(NaNO3∶KNO3)=6∶4]/ceramic 1.09350 1.3320 [w(NaNO3∶KNO3)=5∶5]/Al2O3 1.14009 1.4200 [w(NaNO3∶KNO3)=5∶5]/SiO2 0.96400 1.2680 [w(NaNO3∶KNO3)=5∶5]/ceramic 1.04930 1.3225 [w(NaNO3∶KNO3)=4∶6]/Al2O3 1.10329 1.3510 [w(NaNO3∶KNO3)=4∶6]/SiO2 0.93000 1.2040 [w(NaNO3∶KNO3)=4∶6]/ceramic 1.01350 1.2865 [w(NaNO3∶KNO3)=9∶1]/Al2O3 1.07772 1.3150 [w(NaNO3∶KNO3)=9∶1]/SiO2 0.92200 1.1360 [w(NaNO3∶KNO3)=9∶1]/ceramic 0.99250 1.2535
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