The Application of Composite Materials in Pulsed Inductor Design

J. Novickij; N. Višniakov

doi:10.4028/www.scientific.net/SSP.113.545

Paper Titles

Some Aspects of Sound Propagation in Porous Medium
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Dispersion and Absorption in Media with Stretch Exponential and Fractional Power Relaxation
p.531

Phase Investigations of Copper Based CuZn38Al2MnFe Alloy
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Mechanical Properties of Winding Conductors Affected by Cyclic Thermal Overloads
p.541

The Application of Composite Materials in Pulsed Inductor Design
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Investigation of Possibilities for Ceramic Coating of Biological Polyethylene Implants
p.549

Experimental Industrial Carbon Nanomaterial Production
p.555

Development of High-Speed Steels for Cast Metal-Cutting Tools
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Stress and Strain Analysis of Three-Layer Composites with Interlayer Slip under Hygrothermal Loads
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HomeSolid State PhenomenaSolid State Phenomena Vol. 113The Application of Composite Materials in Pulsed...

The Application of Composite Materials in Pulsed Inductor Design

Abstract:

The multilayer construction of metal-matrix Cu-Nb microcomposite wire wound Zylon-epoxy composite reinforced inductor is analyzed. Inductor geometry was verified analytically to find the maximal available value of a magnetic field. For comparison, the soft copper wire wound inductor was made by the same geometry and technology and both inductors were investigated at room and liquid nitrogen temperatures. Experimental results were compared with calculated data. The acceptable agreement of calculated and measured data for soft copper wire wound inductor and the significant decrease of amplitude and distortions of sinus shape pulse due to weak heat dissipation of metal-matrix Cu-Nb wire wound inductor took place.

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Periodical:

Solid State Phenomena (Volume 113)

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545-548

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https://doi.org/10.4028/www.scientific.net/SSP.113.545

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Online since:

June 2006

Authors:

J. Novickij, N. Višniakov

Keywords:

Cu-Nb, High Magnetic Field, Macrocomposite, Microcomposite, Pulsed Magnet, Zylon

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