Preparation and properties of polyvinyl butyral/Al2O3 composite phase change microfibers with peapod-like structure

doi:10.16085/j.issn.1000-6613.2018-0814

Abstract

Abstract:

The peapod-like composite phase change microfibers, with both polyvinyal butyral (PVB) matrix blended with aluminum oxide (Al₂O₃) nanoparticles and with n-pentadecane encapsulated, are successfully prepared by microfluidic technology. Effects of Al₂O₃ content on the microstructures, phase change properties and thermal conductive properties of the as-prepared composite phase change microfibers are systematically investigated. The results show that n-pentadecane is effectively encapsulated into the independent micro-compartments by the dense surface of composite phase change microfibers, and the encapsulation ratio is about 30%. The addition of Al₂O₃ nanoparticles into the PVB matrix has no obvious effect on the peapod-like microstructure and phase change enthalpies of composite phase change microfibers, while significantly enhances their thermal conductive properties. Under the simulated solar irradiation, the surface temperature of the composite phase change microfibers containing 10% Al₂O₃ nanoparticles increases faster than that of phase change microfibers without Al₂O₃ nanoparticles, and the melting time of the former are shorten by 25%. The results provide valuable guidances for fabricating phase change microfibers with controllable structure, satisfactory and stability thermal conductive properties, as well as efficient and fast thermal regulation properties.

Key words: microfluidics, peapod-like structure, phase change, fibers, alumina, nanoparticles, thermal conductive properties

摘要：

利用微流控技术成功制备了聚乙烯醇缩丁醛（PVB）基材中共混氧化铝（Al₂O₃）纳米颗粒，其内部包封正十五烷的豆荚结构复合相变纤维。系统考察了Al₂O₃的含量对复合相变纤维的微观结构、相变性能和导热性能的影响规律。研究结果表明，复合相变纤维的致密表面可将正十五烷良好地包封于其内部的独立腔室内，包封率约为30%。在PVB基材中添加Al₂O₃纳米颗粒对复合相变纤维的豆荚结构和相变焓均无明显影响，但可显著提高相变纤维的导热性能。在模拟太阳光照射下，添加10% Al₂O₃纳米颗粒的复合相变纤维的表面温度比不含Al₂O₃纳米颗粒的相变纤维的表面温度升高更快，前者的熔融时间比后者缩短了25%。研究结果将为制备结构可控、具有良好、稳定导热性能和高效、快速调温性能的相变纤维提供重要的实验参考和指导。

关键词: 微流体学, 豆荚结构, 相变, 纤维, 氧化铝, 纳米粒子, 导热性能

CLC Number:

TQ342

Xiu ZHANG, Rui XIE, Wei WANG, Xiaojie JU, Zhuang LIU, Liangyin CHU. Preparation and properties of polyvinyl butyral/Al₂O₃ composite phase change microfibers with peapod-like structure[J]. Chemical Industry and Engineering Progress, 2019, 38(02): 993-999.

张秀, 谢锐, 汪伟, 巨晓洁, 刘壮, 褚良银. 豆荚结构聚乙烯醇缩丁醛/氧化铝复合相变纤维的制备及性能[J]. 化工进展, 2019, 38(02): 993-999.

Figures/Tables 7

References 28

1	CHENC Z, WANGL G, HUANGY. Crosslinking of the electrospun polyethylene glycol/cellulose acetate composite fibers as shape- stabilized phase change materials[J]. Materials Letters, 2009, 63(5): 569-571.
2	REZAEIB, ASKARIM, SHOUSHTARIA M, et al. The effect of diameter on the thermal properties of the modeled shape-stabilized phase change nanofibers (PCNs)[J]. Journal of Thermal Analysis & Calorimetry, 2014, 118(3): 1619-1629.
3	CHENC Z, WANGL G, HUANGY. Electrospun phase change fibers based on polyethylene glycol/cellulose acetate blends[J]. Applied Energy, 2011, 88(9): 3133-3139.
4	张兴祥, 王馨, 吴文健, 等. 相变材料胶囊制备与应用[M]. 北京：化学工业出版社, 2009.
	ZHANGX X, WANGX, WUW J, et al. Preparation and application of encapsulated phase change materials[M]. Beijing：Beijing Chemical Industry Press, 2009．
5	ZALBAB, MARINJ M, CABEZAL F, et al. Review on thermal energy storage with phase change: materials, heat transfer analysis and applications[J]. Applied Thermal Engineering, 2003, 23(3): 251-283.
6	ZHOUS T, CHENY, ZOUH W, et al. Thermally conductive composites obtained by flake graphite filling immiscible polyamide 6/polycarbonate blends[J]. Thermochimica Acta, 2013, 566：84-91.
7	LIA, ZHANGC, ZHANGY F. Thermally conductivities of PU composites with graphene aerogels reduced by different methods[J]. Composites：Part A, 2017, 103：161-167.
8	KHANW S, ASMATULUR, AHMEDI, et al. Thermal conductivities of electrospun PAN and PVP nanocomposite fibers incorporated with MWCNTs and NiZn ferrite nanoparticles[J]. International Journal of Thermal Sciences, 2013, 71：74-79.
9	KEH Z. Morphology and thermal performance of quaternary fatty acid eutectics/polyurethane/Ag form-stable phase change composite fibrous membranes[J]. Journal of Thermal Analysis & Calorimetry, 2017, 129(3): 1533-1545.
10	KEH Z. Preparation of electrospun LA-PA/PET/Ag form-stable phase change composite fibers with improved thermal energy storage and retrieval rates via electrospinning and followed by UV irradiation photoreduction method[J]. Fibers & Polymers, 2016, 17(8): 1198-1205.
11	KEH Z, PANGZ Y, PENGB, et al. Thermal energy storage and retrieval properties of form-stable phase change nanofibrous mats based on ternary fatty acid eutectics/polyacrylonitrile composite by magnetron sputtering of silver[J]. Journal of Thermal Analysis & Calorimetry, 2016, 123(2): 1293-1307.
12	GOLESTANEHS I, KARIMIG, BABAPOORA, et al. Thermal performance of co-electrospun fatty acid nanofiber composites in the presence of nanoparticles[J]. Applied Energy, 2018, 212：552-564.
13	BABAPOORA, KARIMIG, KHORRAMM. Fabrication and characterization of nanofiber-nanoparticle-composites with phase change materials by electrospinning[J]. Applied Thermal Engineering, 2016, 99：1225-1235.
14	CAIY B, ZONGX, ZHANGJ J, et al. The improvement of thermal stability and conductivity via incorporation of carbon nanofibers into electrospun ultrafine composite fibers of lauric acid/polyamide 6 phase change materials for thermal energy storage[J]. International Journal of Green Energy, 2014, 11(8): 861-875.
15	CAIY B, XUX L, GAOC T, et al. Effects of carbon nanotubes on morphological structure, thermal and flammability properties of electrospun composite fibers consisting of lauric acid and polyamide 6 as thermal energy storage materials[J]. Fibers & Polymers, 2012, 13(7): 837-845.
16	CAIY B, GAOC T, ZHANGT, et al. Influences of expanded graphite on structural morphology and thermal performance of composite phase change materials consisting of fatty acid eutectics and electrospun PA6 nanofibrous mats[J]. Renewable Energy, 2013, 57(3): 163-170.
17	KEH Z, PANGZ Y, XUY F, et al. Graphene oxide improved thermal and mechanical properties of electrospun methyl stearate/ polyacrylonitrile form-stable phase change composite nanofibers[J]. Journal of Thermal Analysis & Calorimetry, 2014, 117(1): 109-122.
18	ZONGX, CAIY B, SUNG Y, et al. Fabrication and characterization of electrospun SiO₂ nanofibers absorbed with fatty acid eutectics for thermal energy storage/retrieval[J]. Solar Energy Materials & Solar Cells, 2015, 132：183-190.
19	DAIL M, CHANGD W, BAEKJ B, et al. Carbon nanomaterials for advanced energy conversion and storage[J]. Small, 2012, 8(8): 1130-1166.
20	JIANS J, ZHUJ, JIANGS H, et al. Nanofibers with diameter below one nanometer from electrospinning[J]. RSC Advances, 2018, 8(9): 4794-4802.
21	GOLESTANEHS I, MOSALLANEJADA, KARIMIG, et al. Fabrication and characterization of phase change material composite fibers with wide phase-transition temperature range by co-electrospinning method[J]. Applied Energy, 2016, 182：409-417.
22	BABAPOORA, KARIMIG, GOLESTANEHS I, et al. Coaxial electro-spun PEG/PA6 composite fibers: fabrication and characterization[J]. Applied Thermal Engineering, 2017, 118：398-407.
23	温国清, 谢锐, 巨晓洁, 等. 多壁碳纳米管/聚乙烯醇缩丁醛复合相变纤维的制备与性能[J]. 化工进展, 2015, 34(10): 3688-3718.
	WENG Q, XIER, JUX J, et al. Preparation and properties of MWNT/polyvinyl butyral composite phase change fibers[J]. Chemical Industry and Engineering Process, 2015, 34(10): 3688-3718.
24	YUY, WENH, MA J Y, et al. Flexible fabrication of biomimetic bamboo-like hybrid microfibers[J]. Advanced Materials, 2014, 26(16): 2494-2499.
25	HEX H, WANGW, DENGK, et al. Microfluidic fabrication of chitosan microfibers with controllable internals from tubular to peapod-like structures[J]. RSC Advances, 2015, 5(2): 928-936.
26	LIANGW G, YANGC, WENG Q, et al. A facile and controllable method to encapsulate phase change materials with non-toxic and biocompatible chemicals[J]. Applied Thermal Engineering, 2014, 70(1): 817-826.
27	WENG Q, XIER, LIANGW G, et al. Microfluidic fabrication and thermal characteristics of core-shell phase change microfibers with high paraffin content[J]. Applied Thermal Engineering, 2015, 87：471-480.
28	孙少兴, 谢锐, 巨晓洁, 等．同轴静电纺丝制备低温相变纤维及其性能研究[J]. 化工新型材料, 2016, 44(8): 59-65．
	SUNS X, XIER, JUX J, et al. Preparation and performance of nanofiber with low phase change temperature via coaxial electrospinning[J]. New Chemical Materials, 2016, 44(8): 59-65．

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Preparation and properties of polyvinyl butyral/Al₂O₃ composite phase change microfibers with peapod-like structure

豆荚结构聚乙烯醇缩丁醛/氧化铝复合相变纤维的制备及性能

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References 28

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