Abstract
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.
Highlights
A metallized film capacitor, insulated with biaxial-orientated polypropylene (BOPP), is widely used as the filter capacitor for electric energy converter circuits, and is one of the key pieces of equipment in the inverter station in high-voltage direct current (HVDC)transmission systems [1]
Compared with the insulation materials in other electrical equipment, such as XLPE in power cables, polyimide film in motors, and Nomex insulation paper in power transformers, in which the operating electric fields are normally less than 50 kV/mm, the dielectric behavior and aging process are expected to be substantially different in BOPP film regularly operating under an electric filed more than 200 kV/mm and temperatures up to 80 ◦ C
The pulsed electric acoustic (PEA) method is powerful in measuring space charge distribution in thick insulating films, while it cannot be used to study the BOPP film with a thickness of less than μm, due to the space resolution limitation [3]
Summary
A metallized film capacitor, insulated with biaxial-orientated polypropylene (BOPP), is widely used as the filter capacitor for electric energy converter circuits, and is one of the key pieces of equipment in the inverter station in high-voltage direct current (HVDC)transmission systems [1]. A metallized film capacitor, insulated with biaxial-orientated polypropylene (BOPP), is widely used as the filter capacitor for electric energy converter circuits, and is one of the key pieces of equipment in the inverter station in high-voltage direct current (HVDC). In the process of its service in the HVDC inverter station, its insulation sustains the combined effects of high DC electric field and high temperature over the life, leading to early failure, and even breakdown of the BOPP film [2]. Extra high-field dielectric behavior, and the corresponding mechanism of insulating materials, are closely related to the microscopic physical process of charge transport. There are few studies on the charge transport characteristics of BOPP film under an extra high electric field (200 kV/mm to breakdown electric field), due to the limitation of the experimental conditions. The pulsed electric acoustic (PEA) method is powerful in measuring space charge distribution in thick insulating films
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