Characteristics and dispersity of a two gap capillary discharge applied for long spark gap ignition in air

In this paper, the characteristics and dispersity of a two gap capillary (TGC) discharge applied for long spark gap ignition are studied. Under the same discharge condition, 30 repetitive discharges are done to get a certain number of data samples. Accordingly, the change trend of the characteristic...

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Bibliographic Details
Published in:Physics of plasmas 2017-07, Vol.24 (7)
Main Authors: Huang, Dong, Yang, Lanjun, Guo, Haishan, Zhang, Zhiyuan, Jiang, Hongqiu, Xu, Haipeng
Format: Article
Language:English
Subjects:
Automotive parts
Capillary pressure
Charging
Delay
Discharge
Electric arcs
Electric potential
Electrical resistivity
Energy consumption
Ignition
Magnetic cores
Maintenance management
Neon
Plasma physics
Statistical analysis
Statistical methods
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Summary:In this paper, the characteristics and dispersity of a two gap capillary (TGC) discharge applied for long spark gap ignition are studied. Under the same discharge condition, 30 repetitive discharges are done to get a certain number of data samples. Accordingly, the change trend of the characteristics and the dispersity with the charging voltage of C 1 are analyzed statistically. The delay of soft capillary discharge is determined by the saturation rate of the magnetic core of the pulse transformer and decreases with the increase in the charging voltage. The main discharge delay decreases from 1.0 kV to 2.0 kV and stops the decreasing trend when the charging voltage increases to 2.5 kV. In contrast, the current amplitude of soft capillary discharge and main discharge increases with charging voltage. Long tail extinction is witnessed at the charging voltage of 1.0 kV and the major cause is the insufficient pressure in the post discharge. The waveform of the capillary arc resistivity is U-like shape and the minimum resistivity decreases with the increase in the charging voltage. Meanwhile, the arc resistivity in the ascending stage is much higher than that in the descending stage with the same value of the discharge current. The energy consumption of the TGC discharge can be mainly divided into four parts and more than 70% of the energy is consumed in main discharge.
ISSN:1070-664X
1089-7674
DOI:10.1063/1.4989714