Your search keyword '"Changfeng Ke"' showing total 2 results

1. Resistance to intense electron beam bombardment of TiC/Graphite: Numerical modeling and experimental investigation

Author

Changfeng Ke, Huo Yankun, Jun Cheng, Jianzhong Ni, Tang Yunsheng, Ping Wu, Changhua Chen, and Wenyuan Liu

Subjects

010302 applied physics, Materials science, Process Chemistry and Technology, Numerical modeling, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, Acceleration voltage, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Coating, 0103 physical sciences, Materials Chemistry, Ceramics and Composites, Graphite substrate, Cathode ray, engineering, Graphite, Surface layer, Composite material, 0210 nano-technology, Deposition (law)

Abstract

Resistance to intense electron beam bombardment of TiC/Graphite was investigated numerically and experimentally. The results indicate that the decreasing of initial electron energy and the increasing of TiC coating thickness could both enhance the electron energy deposition inside the surface layer of the TiC/Graphite, and finally cause the increasement of the temperature differences at the interface between TiC coating and graphite substrate. The graphite substrate is well coated with TiC in all the TiC/graphite targets, and the morphology of the TiC coatings could be controlled by adjusting its thickness. Under electron beam with accelerating voltage of 850 keV, current of 11 kA, pulsewidth of 40 ns and pulse number of 30 times, TiC/Graphite target with TiC coating thickness of 1 μm shows more excellent electron beam bombardment resistance, agreeing with the results of the numerical modeling.

Published

2021

2. Significantly improved surface flashover characteristics of insulators in vacuum by direct fluorination

Author

Chen Changhua, Li Duan, Changfeng Ke, Li Lin, and Wenyuan Liu

Subjects

High surface, Colloid and Surface Chemistry, Materials science, Electric field, Arc flash, Breakdown voltage, Insulator (electricity), High voltage, Dielectric, High-density polyethylene, Composite material

Abstract

Seeking an insulator supporting high voltage and short pulsed-power electric field in vacuum is an important topic especially for some sophisticated equipments. The voltage breakdown along the surface of insulator in vacuum (i.e. surface flashover) is one of the most serious problems for insulators, and it greatly limits the overall performance of a vacuum-dielectric system. The improvement of surface flashover characteristics of insulators in vacuum become a significant challenge for the development of high voltage pulsed-power devices. Herein, we report a simple and convenient avenue to achieve the high surface flashover performance of high density polyethylene (HDPE) in vacuum based on direct fluorination technique. The physicochemical properties of the fluorinated HDPE (i.e., surface morphology, the chemical component, structure and dielectric capability) were comparatively investigated with the untreated HDPE. The surface flashover characteristics of HDPE in vacuum were mainly discussed. The performance of HDPE at different fluorination temperature was also investigated. The results demonstrated that the direct fluorination strategy developed in this work is an effective means to improve the surface dielectric capability of insulators in vacuum. It is believed to provide a novel possibility for the common insulators applied in high electric field vacuum environments.

Published

2014