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·1786· 精细化工 FINE CHEMICALS 第 37 卷

organic coconut oil as a natural phase change material for thermo- Energy Storage Science and Technology (储能科学与技术), 2019,
regulating cellulosic fabrics[J]. Cellulose, 2019, 26(16): 8939-8950. 8(2): 371-378.
[25] LYU J L, LIU Z W, WU X H, et al. Nanofibrous kevlar aerogel films [38] ZHU J Q (朱教群), SONG Y (宋轶), ZHOU W B (周卫兵), et al.
and their phase change composites for highly efficient infrared The use of carbon materials for enhancing heat transfer of organic
stealth[J]. ACS Nano, 2019, 13(2): 2236-2245. based composite phase change materials: A review[J]. Energy Storage
[26] LU Y, XIAO X D, FU J, et al. Novel smart textile with phase change Science and Technology (储能科学与技术), 2017, 6(2): 213-222.
materials encapsulated core-sheath structure fabricated by coaxial [39] LI Y, CAO X L, ZHANG N, et al. Thermal reliability of typical fatty
electrospinning[J]. Chemical Engineering Journal, 2019, 355(1): acids as phase change materials based on 10, 000 accelerated thermal
532-539. cycles[J]. Sustainable Cities and Society, 2019, 46(3): 101380.
[27] LUO D J, WEI F J, SHAO H J, et al. Shape stabilization, thermal [40] QIU F, SONG S K, LI D, et al. Experimental investigation on
energy storage behavior and thermal conductivity enhancement of improvement of latent heat and thermal conductivity of shape-stable
ﬂexible parafﬁn/MWCNTs/PP hollow ﬁber membrane composite phase-change materials using modified fly ash[J]. Journal of Cleaner
phase change materials[J]. Journal of Materials Science, 2018, 53(22): Production, 2020, 246(10): 118952.
15500-15513. [41] WU S Y, MA X Y, PENG D Q, et al. The phase change property of
[28] SHILI H, FAHEM K, HARMAND S, et al. Thermal control of lauric acid confined in carbon nanotubes as nano-encapsulated phase
electronic components using a liquid around the phase change change materials[J]. Journal of Thermal Analysis and Calorimetry,
material[J/OL]. Journal of Thermal Analysis and Calorimetry, 2019, 2019, 136(6): 2353-2361.
[2019-06-24] https: //doi. org/10. 1007/s10973-019-08877-3. [42] SARI A, Al-AHMED A, BICER A, et al. Investigation of thermal
[29] WU W X, WU W, WANG S F. Form-stable and thermally induced properties and enhanced energy storage/release performance of silica
flexible composite phase change material for thermal energy storage fume/myristic acid composite doped with carbon nanotubes[J].
and thermal management applications[J]. Applied Energy, 2019, Renewable Energy, 2019, 140(11): 779-788.
236(3): 10-21. [43] YANG G, YI Y J, LEE J W, et al. Carbon-filled organic phase change
[30] MALEKI M, IMANI A, AHMADI R, et al. Low-cost carbon foam as materials for thermal energy storage: A review[J]. Molecules, 2019,
a practical support for organic phase change materials in thermal 24(11): 2-17.
management[J]. Applied Energy, 2020, 258(2): 114108. [44] YANG Y H (杨岳澔), CHENG X M (程晓敏), LI D (李丹), et al.
[31] SFARRA S, PERILLI S, GUERRINI M, et al. On the use of phase Properties of stearic acid/modified carbon nanotube composite phase
change materials applied on cork-coconut-cork panels[J]. Journal of change materials[J]. Energy Storage Science and Technology (储能
Thermal Analysis and Calorimetry, 2019, 138(6): 4061-4090. 科学与技术), 2019, 8(4): 759-763.
[32] CHEN X, GAO H Y, HAI G T, et al. Carbon nanotube bundles [45] WANG B (王博), ZHU X Q (朱孝钦), HU J (胡劲), et al. Nano-
assembled flexible hierarchical frame work based phase change material graphite enhanced thermal conductivity of decanoic acid-tetradecyl
composites for thermal energy harvesting and thermotherapy[J]. Energy alcohol composite phase change material[J]. Materials Reports (材料
Storage Materials, 2020, 26(3): 129-137. 导报), 2019, 33(22): 3815-3819.
[33] YU C, YOU J R, SONG Y S. Encapsulated phase change material [46] RANJBAR S, MASOUMI H, KHOSHKHOO R H, et al.
embedded by graphene powders for smart and flexible thermal Experimental investigation of stability and thermal conductivity
response[J]. Fibers and Polymers, 2019, 20(3): 545-554. of phase change materials containing pristine and functionalized
[34] YADAV C, SAHOO R R. Exergy and energy comparison of organic multi-walled carbon nanotubes[J]. Journal of Thermal Analysis
phase change materials based thermal energy storage system integrated and Calorimetry, 2019,147: 1-14.
with engine exhaust[J]. Journal of Energy Storage, 2019, 24(4): 100773. [47] WANG W T, MALIK M U, QIU J J, et al. Electromagnetic and solar
[35] LIU H, WANG X D, WU D Z, et al. Fabrication and applications of energy conversion and storage based on Fe 3O 4 functionalised graphene/
dual-responsive microencapsulated phase change material with enhanced phase change material nanocomposites[J]. Chemical Engineering
solar energy-storage and solar photocatalytic effectiveness[J]. Solar Journal, 2019, 358 (4): 1279-1286.
Energy Materials and Solar Cells, 2019, 193(5): 184-197. [48] WANG W T, FAN X Q, QIU J J, et al. Extracorporeal magnetic
[36] GAO L, GENG S X, ZHANG S B, et al. Preparation and thermal thermotherapy materials for self-controlled temperature through phase
properties of palmitic acid/expanded graphite/carbon fiber composite transition[J]. Energy Conversion and Management, 2019, 196(17):
phase change materials for thermal energy storage[J/OL]. Journal of 1299-1305.
Thermal Analysis and Calorimetry, 2019, [2019-06-18]. https://doi. [49] WEI X, XUE F, QI X D, et al. Photo and electro-responsive phase
org/10. 1007/s10973-019-08755-y. change materials based on highly anisotropic microcrystalline cellulose/
[37] XU Z (徐众), HUANG P (黄平), WU E H (吴恩辉), et al. Analysis graphene nanoplatelet structure[J]. Applied Energy, 2019, 236(3):
of resistivity of expanded graphite /paraffin phase change material[J]. 70-80.

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