Investigation on Charge Transport in Polypropylene Film under High Electric Field by Experiments and Simulation

The charge transport in polypropylene was studied under DC electric fields at different temperatures. By the experimental measurement and simulation of the BCT model, we studied conduction currents, breakdown strength, and space charge distribution. In particular, the conduction characteristics under high temperature and high field, especially the conduction characteristics before the breakdown, were studied by systematic experiments, and the conduction characteristics and the breakdown mechanism were further studied by simulation. The results show that in the process of measuring conduction currents until breakdown, both high temperature and high electric field will promote charge transport. However, the free volume will increase at high temperature, which will easily lead to faster charge transport and breakdown. In the breakdown process at different temperatures, there are different breakdown mechanisms. At 20–60 °C, the electric breakdown process has mainly occurred in polypropylene film, and the breakdown strength is almost unchanged. At 80 °C, electric breakdown and thermal breakdown act together, and the charge transport is faster, and the breakdown field becomes smaller. Finally, we conclude that thermal stress plays a very important role in charge transport. In a high-temperature environment, the volume expansion of polypropylene will promote charge transport, and the insulation of polypropylene capacitor films will be damaged.

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Investigation of Electrical Properties of BiFeO3/LDPE Nanocomposite Dielectrics with Magnetization Treatments

Polymers ◽

10.3390/polym13162622 ◽

2021 ◽

Vol 13 (16) ◽

pp. 2622

Author(s):

Wei Song ◽

Yu Sun ◽

Tian-Jiao Yu ◽

Yu-Zhang Fan ◽

Zhi Sun ◽

...

Keyword(s):

High Temperature ◽

Electrical Properties ◽

Room Temperature ◽

Breakdown Strength ◽

Bismuth Ferrite ◽

Breakdown Field ◽

Melt Blending ◽

Blending Method ◽

Different Temperatures ◽

Breakdown Field Strength

The purpose of this paper is to study the effect of nano-bismuth ferrite (BiFeO3) on the electrical properties of low-density polyethylene (LDPE) under magnetic-field treatment at different temperatures. BiFeO3/LDPE nanocomposites with 2% mass fraction were prepared by the melt-blending method, and their electrical properties were studied. The results showed that compared with LDPE alone, nanocomposites increased the crystal concentration of LDPE and the spherulites of LDPE. Filamentous flake aggregates could be observed. The spherulite change was more obvious under high-temperature magnetization. An agglomerate phenomenon appeared in the composite, and the particle distribution was clear. Under high-temperature magnetization, BiFeO3 particles were increased and showed a certain order, but the change for room-temperature magnetization was not obvious. The addition of BiFeO3 increased the crystallinity of LDPE. Although the crystallinity decreased after magnetization, it was higher than that of LDPE. An AC test showed that the breakdown strength of the composite was higher than that of LDPE. The breakdown strength increased after magnetization. The increase of breakdown strength at high temperature was less, but the breakdown field strength of the composite was higher than that of LDPE. Compared with LDPE, the conductive current of the composite was lower. So, adding BiFeO3 could improve the dielectric properties of LDPE. The current of the composite decayed faster with time. The current decayed slowly after magnetization.

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Space charge performance of epoxy composites with improved thermal property at high temperature under high electric field

Journal of Applied Polymer Science ◽

10.1002/app.51877 ◽

2021 ◽

pp. 51877

Author(s):

Chao Dai ◽

Guangyu Zhu ◽

Yasuhiro Tanaka ◽

Hiroaki Miyake ◽

Kosuke Sato ◽

...

Keyword(s):

High Temperature ◽

Electric Field ◽

Thermal Property ◽

Space Charge ◽

High Electric Field ◽

Epoxy Composites

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Characterization of Polyimide Dielectric Layer for the Passivation of High Electric Field and High Temperature Silicon Carbide Power Devices

Materials Science Forum - Silicon Carbide and Related Materials 2004 ◽

10.4028/0-87849-963-6.717 ◽

2005 ◽

pp. 717-720

Author(s):

Samir Zelmat ◽

Marie-Laure Locatelli ◽

Thierry Lebey

Keyword(s):

Silicon Carbide ◽

High Temperature ◽

Electric Field ◽

Dielectric Layer ◽

High Electric Field ◽

Power Devices

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The Effects of Coupling Agents on the Electrical Properties of Polyimide/TiO2 Hybrid Films

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.556-562.371 ◽

2014 ◽

Vol 556-562 ◽

pp. 371-374

Author(s):

Kai Yan ◽

Xiao Xu Liu

Keyword(s):

Composite Film ◽

Breakdown Strength ◽

In Situ Polymerization ◽

Composite Films ◽

Electric Breakdown ◽

Future Application ◽

Breakdown Field ◽

Coupling Agents ◽

Hybrid Films ◽

Simple Method

Polyamides (PI)-matrix composite films with inorganic nanoTiO2 have been fabricated by employing in situ polymerization. Before addition, TiO2 particles were firstly modified with coupling agents (KH550). The electric breakdown strength and micromorphology of hybrid films were characterized and investigated. Results indicated that nanoTiO2 particles were homogeneously dispersed in the PI matrix for the addition of coupling agents and the electric breakdown strength of PI/TiO2 composite films with KH550 were better than unmodified PI composite film. The breakdown field strength and tensile modulus of PI composite film with the inorganic content of 5 wt% were 200.1 (KV/mm). So the using coupling agent can effectively improve the compatibility and the homogenous dispersion of nanoTiO2 particles in PI matrix. Meanwhile, the procedure described here offers an effective and simple method to produce PI/TiO2 with excellent electrical needed for future application in electrical engineering field.

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High electric field approximation to charge transport in semiconductor devices

Applied Mathematics Letters ◽

10.1016/0893-9659(92)90049-f ◽

1992 ◽

Vol 5 (3) ◽

pp. 99-102 ◽

Cited By ~ 27

Author(s):

Pablo Dmitruk ◽

Andrés Saúl ◽

Luis G. Reyna

Keyword(s):

Electric Field ◽

Charge Transport ◽

Semiconductor Devices ◽

Field Approximation ◽

High Electric Field

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Carrier Transport and Molecular Displacement Modulated dc Electrical Breakdown of Polypropylene Nanocomposites

Polymers ◽

10.3390/polym10111207 ◽

2018 ◽

Vol 10 (11) ◽

pp. 1207 ◽

Cited By ~ 12

Author(s):

Daomin Min ◽

Chenyu Yan ◽

Rui Mi ◽

Chao Ma ◽

Yin Huang ◽

...

Keyword(s):

Energy Storage ◽

Charge Transport ◽

Carrier Mobility ◽

Breakdown Strength ◽

Electrical Breakdown ◽

Dielectric Materials ◽

Breakdown Field ◽

Smart Power ◽

Electrical Breakdown Strength ◽

Effective Carrier

Dielectric energy storage capacitors have advantages such as ultra-high power density, extremely fast charge and discharge speed, long service lifespan and are significant for pulsed power system, smart power grid, and power electronics. Polypropylene (PP) is one of the most widely used dielectric materials for dielectric energy storage capacitors. It is of interest to investigate how to improve its electrical breakdown strength by nanodoping and the influencing mechanism of nanodoping on the electrical breakdown properties of polymer nanocomposites. PP/Al2O3 nanocomposite dielectric materials with various weight fraction of nanoparticles are fabricated by melt-blending and hot-pressing methods. Thermally stimulated current, surface potential decay, and dc electrical breakdown experiments show that deep trap properties and associated molecular chain motion are changed by incorporating nanofillers into polymer matrix, resulting in the variations in conductivity and dc electrical breakdown field of nanocomposite dielectrics. Then, a charge transport and molecular displacement modulated electrical breakdown model is utilized to simulate the dc electrical breakdown behavior. It is found that isolated interfacial regions formed in nanocomposite dielectrics at relatively low loadings reduce the effective carrier mobility and strengthen the interaction between molecular chains, hindering the transport of charges and the displacement of molecular chains with occupied deep traps. Accordingly, the electrical breakdown strength is enhanced at relatively low loadings. Interfacial regions may overlap in nanocomposite dielectrics at relatively high loadings so that the effective carrier mobility decreases and the interaction between molecular chains may be weakened. Consequently, the molecular motion is accelerated by electric force, leading to the decrease in electrical breakdown strength. The experiments and simulations reveals that the influence of nanodoping on dc electrical breakdown properties may origin from the changes in the charge transport and molecular displacement characteristics caused by interfacial regions in nanocomposite dielectrics.

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Numerical Simulation on Charge Transport and DC Breakdown in Polyethylene-Based Micro-h-BN/Nano-SiO2 with Filler Orientation Dependent Trap Energy

Energies ◽

10.3390/en14154645 ◽

2021 ◽

Vol 14 (15) ◽

pp. 4645

Author(s):

Xuri Xu ◽

Yu Gao ◽

Jing Li ◽

Zheng Song ◽

Huicun Zhao ◽

...

Keyword(s):

Numerical Simulation ◽

Electric Field ◽

Charge Transport ◽

Breakdown Strength ◽

Hexagonal Boron Nitride ◽

Charge Trapping ◽

Sample Surface ◽

Normal Sample ◽

Normal Vector ◽

Inorganic Particles

In order to improve the thermal conductivity and the insulation properties of polyethylene (PE) used as cable insulation under DC stress, hexagonal boron nitride (h-BN) and inorganic particles have been considered as micro-filler and nano-filler, respectively. As a 2D material, the orientation of h-BN possibly affects the insulation properties of the polymer. It is important to understand the influence of the filler orientation on the insulation performance of the polymer. In this work, a numerical simulation has been performed to investigate the effect of orientation of micro-h-BN on charge transport and DC breakdown of PE-based micro/nano-composites and a comparison between the simulation result and previous literature data has been conducted. The h-BN was designated to be parallel, perpendicular to the normal sample surface vector (the direction of electric field in this work) or randomly distributed in the matrix, and the charge transport behavior and DC breakdown strength in the samples were discussed by using the bipolar charge transport (BCT) model. The results indicated that when the h-BN was perpendicular to the normal vector, the density of trapped charge was the largest and the DC breakdown strength was the highest among the three cases studied. It is suggested that the charge trapping/de-trapping processes and the electric field in the sample vary with the orientation of h-BN through tailoring the trap characteristics of the material.

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