Research on the Ignition Performances of the Titanium Composite SCB

Xin Jia; Wei Shun Pei; Fang Zhou; Yong Li; Bin Zhou

doi:10.4028/www.scientific.net/AMR.893.320

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Research on Application of Fractal Theory for SiO₂/UPR Granular Composites
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The Effect of the Die Temperature on the Solidification Behaviour of the Al/SiC_p Metal Matrix Composite: A Comparative Study of Experimental and Finite Element Analysis
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Research on the Ignition Performances of the Titanium Composite SCB
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Effects of Milling Techniques and Calcinations Temperature on the Composite Cathode Powder LSCF-SDC Carbonate
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Hybrid Fluorescent-Magnetic Polymeric Particles for Biomedical Applications
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Synthesis and Characterization of an Experimental Light-Curing Dental Resinous Monomer
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Performance Evaluation of Liquid Nitrogen as Coolant in Turning of Al/SiC Metal Matrix Composites (AMMC)
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 893Research on the Ignition Performances of the...

Research on the Ignition Performances of the Titanium Composite SCB

Abstract:

In this paper, the ignition performances of the titanium composite Semiconductor bridge (Ti SCB) and the polysilicon semiconductor bridge (PSCB) were studied, which include electrical explosion characteristics, temperature of theplasma generated by those two SCBs, and ignition ability with B/KNO₃. The experiment results indicated that the explosion time of the two kinds of SCB both decreases with increasing input energy. The temperature of the plasma generated by the two kinds of SCB both increases with the increasing input energy, and there is no significant difference in the highest temperature under the same condition. And the ignition experiment indicated that the output energy of Ti SCB is lower than PSCB.

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Periodical:

Advanced Materials Research (Volume 893)

Pages:

320-324

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.893.320

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Online since:

February 2014

Authors:

Xin Jia, Wei Shun Pei, Fang Zhou, Yong Li, Bin Zhou*

Keywords:

Ignition Performances, Initiators, Semiconductor bridge, Titanium

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