Citation: HE Yufang, YAN Pinping, HUANG Baoquan, LUO Fubin, LI Hongzhou, QIAN Qingrong, CHEN Qinghua. Thermal Conductivity and Crystallization Behavior of Polyethylene Glycol/Boron Nitride Phase Change Composites[J]. Chinese Journal of Applied Chemistry, ;2020, 37(6): 650-657. doi: 10.11944/j.issn.1000-0518.2020.06.200031 shu

Thermal Conductivity and Crystallization Behavior of Polyethylene Glycol/Boron Nitride Phase Change Composites

Polymer Resources Green Recycling Engineering Research Center of the Ministry of Education, College of Environmental Science and Engineering, Fujian Normal University, Fuzhou 350007, China

Corresponding author: LUO Fubin, luofubin@fjnu.edu.cn LI Hongzhou, lihongzhou@fjnu.edu.cn
Received Date: 28 January 2020
Revised Date: 20 February 2020
Accepted Date: 14 April 2020

Fund Project: the Foundation of Quangang Petrochemical Research Institute, Fujian Normal University 2018YJY03the National Natural Science Foundation of China 51903049Supported by the National Natural Science Foundation of China(No.51903049), and the Foundation of Quangang Petrochemical Research Institute, Fujian Normal University(No.2018YJY03)

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In this paper, polyethylene glycol/boron nitride (PEG/BN) phase change composite was prepared by molten blending method and the influence of the flake size of BN on the thermal conductivity and crystallization behavior of phase change composites was studied. The microstructure, thermal conductivity and phase transition performance of the prepared composites were investigated by scanning electron microscope (SEM), thermal constant analyzer, infrared thermal imaging analyzer and differential scanning calorimeter (DSC). The DSC results of were analyzed by Mo Zhishen method. Results show that larger diameter (50 μm) BN can improve the thermal conductivity of PEG more effectively. When the weight fraction of BN filler content is 40%, the thermal conductivity of phase change composite can reach 5.04 W/(m·K). Under conditions of rapid cooling, BN filler with a diameter of 50 μm can shorten the semi crystallization time and increase the crystallization rate of PEG, and make the phase change composites have a large phase change enthalpy.
- polyethylene glycol,
- thermal conductivity,
- nonisothermal crystallization kinetics
1. [1]
  Lin M, Wang C C. Preparation and Characterization of GO/PEG Photo-thermal Conversion Form-Stable Composite Phase Change Materials[J]. Renew Energy, 2019,141:1005-1012.
2. [2]
  CHEN Suqing, HUANG Guobo, BAO Jianshe. Preparation and Properties of Phase Change Energy Storage Materials Enhanced by Thermal Conductivity of Graphene[J]. New Carbon Mater, 2018,33(3):262-267.
3. [3]
  TONG Cang, LI Xiangli, DUANMU Lin. Preparation and Properties of Polyethylene Glycol/Silica/Expanded Graphite Phase Change Energy Storage Materials[J]. District Heat Supply, 2018(3):100-104.
4. [4]
  Deng Y, Li J H, Qian T T. Thermal Conductivity Enhancement of Polyethylene Glycol/Expanded Vermiculite Shape-Stabilized Composite Phase Change Materials with Silver Nanowire for Thermal Energy Storage[J]. Chem Eng J, 2016,295:427-435.
5. [5]
  Wang W T, Tang B T, Ju B Z. Fe₃O₄-Functionalized Graphene Nanosheet Embedded Phase Change Material Composites:Efficient Magnetic-and Sunlight-Driven Energy Conversion and Storage[J]. J Mater Chem A, 2017,5(3):958-968.
6. [6]
  YAN Pinping, LUO Fubin, HUANG Baoquan. Properties of Thermal Conductivity Enhanced Polyethylene Glycol-Based Phase Change Composites[J]. Chinese J Appl Chem, 2020,37(1):46-53.
7. [7]
  Luo F B, Yan P P, Qian Q R. Highly Thermally Conductive Phase Change Composites for Thermal Energy Storage Featuring Shape Memory[J]. Compos Part A, 2020,129105706.
8. [8]
  Yang J, Tang L S, Bao R Y. Largely Enhanced Thermal Conductivity of Poly(Ethylene Glycol)/Boron Nitride Composite Phase Change Materials for Solar-Thermal-Electric Energy Conversion and Storage with Very Low Content of Graphene Nanoplatelets[J]. Chem Eng J, 2017,315:481-490.
9. [9]
  Li C C, Xie B S, Chen D L. Ultrathin Graphite Sheets Stabilized Stearic Acid as a Composite Phase Change Material for Thermal Energy Storage[J]. Energy, 2019,166:246-255.
10. [10]
  Dong W L, Liu H L, Behera J K. Wide Bandgap Phase Change Material Tuned Visible Photonics[J]. Adv Funct Mater, 2018,291806181.
11. [11]
  Zhao Y J, Min X, Huang Z H. Honeycomb-Like Structured Biological Porous Carbon Encapsulating PEG:A Shape-Stable Phase Change Material with Enhanced Thermal Conductivity for Thermal Energy Storage[J]. Energy Build, 2018,158:1049-1062.
12. [12]
  Zhou Y, Sheng D K, Liu X D. Synthesis and Properties of Crosslinking Halloysite Nanotubes/Polyurethane-Based Solid-Solid Phase Change Materials[J]. Sol Energy Mater Sol Cells, 2018,174:84-93.
13. [13]
  Wang J J, Yang M, Lu Y F. Surface Functionalization Engineering Driven Crystallization Behavior of Polyethylene Glycol Confined in Mesoporous Silica for Shape-Stabilized Phase Change Materials[J]. Nano Energy, 2016,19:78-87.
14. [14]
  Min X, Fang M H, Huang Z H. Enhanced Thermal Properties of Novel Shape-Stabilized PEG Composite Phase Change Materials with Radial Mesoporous Silica Sphere for Thermal Energy Storage[J]. Sci Rep, 2015,512964.
15. [15]
  Zhao Y J, Sun B, Du P P. Hierarchically Channel-Guided Porous Wood-Derived Shape-Stabilized Thermal Regulated Materials with Enhanced Thermal Conductivity for Thermal Energy Storage[J]. Mater Res Express, 2019,6115515.
16. [16]
  Yang J, Zhang E W, Li X F. Cellulose/Graphene Aerogel Supported Phase Change Composites with High Thermal Conductivity and Good Shape Stability for Thermal Energy Storage[J]. Carbon, 2016,98:50-57.
17. [17]
  Yang J, Tang L S, Bao R Y. Hybrid Network Structure of Boron Nitride and Graphene Oxide in Shape-Stabilized Composite Phase Change Materials with Enhanced Thermal Conductivity and Light-to-Electric Energy Conversion Capability[J]. Sol Energy Mater Sol Cells, 2018,174:56-64.
18. [18]
  Bahraseman H G, Languri E M, East J. Fast Charging of Thermal Energy Storage Systems Enabled by Phase Change Materials Mixed with Expanded Graphite[J]. Int J Heat Mass Tran, 2017,109:1052-1058.
19. [19]
  Xue F, Jin X Z, Xie X. Constructing Reduced Graphene Oxide/Boron Nitride Frameworks in Melamine Foam Towards Synthesizing Phase Change Materials Applied in Thermal Management of Microelectronic Devices[J]. Nanoscale, 2019,11(40):18691-18701.
20. [20]
  MO Zhishen. A Method to Studying the Non-isothermal Crystallization Kinetics of Polymer[J]. Acta Polym Sin, 2008(7):656-667.
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