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Polymer Composites for Electrical Engineering. Группа авторов
Читать онлайн.Название Polymer Composites for Electrical Engineering
Год выпуска 0
isbn 9781119719656
Автор произведения Группа авторов
Издательство John Wiley & Sons Limited
78 78 Zhao, M., Fu, Q., Hou, Y. et al. (2019). BaTiO3/MWNTs/polyvinylidene fluoride ternary dielectric composites with excellent dielectric property, high breakdown strength, and high‐energy storage density. ACS Omega 4 (1): 1000–1006.
79 79 Liu, F., Li, Q., Li, Z. et al. (2018). Ternary PVDF‐based terpolymer nanocomposites with enhanced energy density and high power density. Composites Part A: Applied Science and Manufacturing 109: 597–603.
80 80 Luo, S., Yu, J., Yu, S. et al. (2019). Significantly enhanced electrostatic energy storage performance of flexible polymer composites by introducing highly insulating‐ferroelectric microhybrids as fillers. Advanced Energy Materials 9 (5): 1803204.
81 81 Li, Y., Zhou, Y., Zhu, Y. et al. (2020). Polymer nanocomposites with high energy density and improved charge‐discharge efficiency utilizing hierarchically‐structured nanofillers. Journal of Materials Chemistry A 8 (14): 6576–6585.
82 82 Baer, E. and Zhu, L. (2017). 50th anniversary perspective: dielectric phenomena in polymers and multilayered dielectric films. Macromolecules 50 (6): 2239–2256.
83 83 Yin, K., Zhou, Z., Schuele, D.E. et al. (2016). Effects of interphase modification and biaxial orientation on dielectric properties of poly (ethylene terephthalate)/poly (vinylidene fluoride‐co‐hexafluoropropylene) multilayer films. ACS Applied Materials & Interfaces 8 (21): 13555–13566.
84 84 Yao, L., Wang, D., Hu, P. et al. (2016). Synergetic enhancement of permittivity and breakdown strength in all‐polymeric dielectrics toward flexible energy storage devices. Advanced Materials Interfaces 3 (13): 1600016.
85 85 Mackey, M., Schuele, D.E., Zhu, L. et al. (2012). Reduction of dielectric hysteresis in multilayered films via nanoconfinement. Macromolecules 45 (4): 1954–1962.
86 86 Li, Q., Liu, F., Yang, T. et al. (2016). Sandwich‐structured polymer nanocomposites with high energy density and great charge‐discharge efficiency at elevated temperatures. Proceedings of the National Academy of Sciences 113 (36): 9995–10000.
87 87 Liu, F., Li, Q., Cui, J. et al. (2017). High‐energy‐density dielectric polymer nanocomposites with trilayered architecture. Advanced Functional Materials 27 (20): 1606292.
88 88 Wang, Y., Cui, J., Yuan, Q. et al. (2015). Significantly enhanced breakdown strength and energy density in sandwich‐structured barium titanate/poly (vinylidene fluoride) nanocomposites. Advanced Materials 27 (42): 6658–6663.
89 89 Jiang, J., Shen, Z., Qian, J. et al. (2019). Synergy of micro‐/mesoscopic interfaces in multilayered polymer nanocomposites induces ultrahigh energy density for capacitive energy storage. Nano Energy 62: 220–229.
90 90 Hu, P., Wang, J., Shen, Y. et al. (2013). Highly enhanced energy density induced by hetero‐interface in sandwich‐structured polymer nanocomposites. Journal of Materials Chemistry A 1 (39): 12321–12326.
91 91 Jiang, J., Shen, Z., Cai, X. et al. (2019). Polymer nanocomposites with interpenetrating gradient structure exhibiting ultrahigh discharge efficiency and energy density. Advanced Energy Materials 9 (15): 1803411.
92 92 Zhang, X., Jiang, J., Shen, Z. et al. (2018). Polymer nanocomposites with ultrahigh energy density and high discharge efficiency by modulating their nanostructures in three dimensions. Advanced Materials 30 (16): 1707269.
93 93 Zhang, Y., Chi, Q., Liu, L. et al. (2018). PVDF‐based dielectric composite films with excellent energy storage performances by design of nanofibers composition gradient structure. ACS Applied Energy Materials 1 (11): 6320–6329.
94 94 Zhu, Y., Zhu, Y., Huang, X. et al. (2019). High energy density polymer dielectrics interlayered by assembled boron nitride nanosheets. Advanced Energy Materials 9 (36): 1901826.
95 95 Azizi, A., Gadinski, M.R., Li, Q. et al. (2017). High‐performance polymers sandwiched with chemical vapor deposited hexagonal boron nitrides as scalable high‐temperature dielectric materials. Advanced Materials 29 (35): 1701864.
96 96 Zhou, Y., Li, Q., Dang, B. et al. (2018). A scalable, high‐throughput, and environmentally benign approach to polymer dielectrics exhibiting significantly improved capacitive performance at high temperatures. Advanced Materials 30 (49): 1805672.
2 Polymer Composites for Thermal Energy Storage
Jie Yang, Chang‐Ping Feng, Lu Bai, Rui‐Ying Bao, Ming‐Bo Yang, and Wei Yang
College of Polymer Science and Engineering, Sichuan University, State Key Laboratory of Polymer Materials Engineering, Chengdu, Sichuan, P. R. China
Jie Yang and Chang‐Ping Feng contribute equally.
2.1 Introduction
It is predicted that there will be a one‐third increase in energy demand by 2035 from 2011.[1] Although fossil fuels, as limited and nonrenewable resources, can provide vast quantities of energy, the irreversible burning releases large amounts of pollutants, resulting in the deterioration of environment and global warming. The focus of the energy battlefield is also gradually shifting to green and renewable energy. However, the utilization efficiency of renewable energy sources, including solar energy, wind energy, tidal energy, geothermal energy, etc., only accounts for approximately 20% of today’s energy consumption owing to the limitations of modern technologies and geographical environments.[2] The discontinuity and regionalism seriously affect their utilization efficiency. More importantly, during the process of using various energy resources, a large amount of energy is used in the form of thermal energy or converted from thermal energy for reuse. Therefore, the development of thermal energy storage (TES) technologies and systems through sensible heat, latent heat, and thermochemical reaction is of great significance to solve the issue of spatiotemporal mismatch between energy supply and demand, improve energy utilization efficiency, alleviate energy crisis, and manage environmental pollution.[3–5] TES not only serves as an integrated buffer in energy conversion systems but also can be incorporated into thermal management technologies for electronics, human body, and buildings.
Phase change materials (PCMs), as an advanced energy storage technique, can absorb or release a lot of energy in the form of latent heat during phase transition for efficient storage and utilization of energy, while maintaining constant temperature (Figure 2.1).[6–8] The selection criteria and characteristics of ideal PCMs feasible for TES are listed in Table 2.1.[7–11] However, it is troublesome for the majorities of PCMs to fully satisfy these criteria. Recent advancements in the innovations of nanomaterials and nanotechnologies for energy‐related applications provide possibilities for PCMs with enhanced comprehensive performance.
Figure 2.1 Working principle of PCMs.
Table 2.1 The features of ideal PCMs feasible for TES.
| Aspects | Details |
|---|---|
| Thermal properties | Appropriate phase transition temperature to satisfy practical applicationsLarge phase change enthalpy to provide high latent heat storage capacityHigh thermal conductivity to achieve fast charging or discharging rateExcellent thermal stability to prolong service life |
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Kinetic
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