Demagnetizing Experiment of Magnetism-Concealed Tank Based on Smart Materials

Ying Huang

doi:10.4028/www.scientific.net/AMM.484-485.151

Paper Titles

Microwave Technology Based Polymer Process
p.132

Synthesize Phosphomolybdic Acid-Doped Polyaniline Microspheres for Catalytic Applications
p.137

Water-Filter Ratio on Heat Resistance of Condensate Polishing Filter Material in Water
p.141

Analysis of the Metal Cell Board’s Design and Production of the High-Speed Rail Way
p.146

Demagnetizing Experiment of Magnetism-Concealed Tank Based on Smart Materials
p.151

Highly-Efficient Preparation of Key Intermediate of Huperzine A
p.157

Analysis of Organic Low-Carbon Solar Material
p.161

Study on the Collaboration between Advanced Manufacturing Technology and Production Process
p.169

Machinery Manufacturing Based on Computer Control
p.173

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 484-485Demagnetizing Experiment of Magnetism-Concealed...

Demagnetizing Experiment of Magnetism-Concealed Tank Based on Smart Materials

Abstract:

The core component -----a set of coaxial densely winded degaussing loops of a magnetism-concealed tank is designed and made by experiment method. From the data, it can be concluded that the coaxial densely winded degaussing loops can eliminate the tanks magnetic field signs which are engendered by magnetization in the earth magnetic field, specially, the demagnetizing effect near the axis is more obvious. It should be paid attention to the direction of the demagnetizing electric current in experimentation, another important factor to get optimal demagnetizing effect is to seize the right time of demagnetizing electric current. If a demagnetizing electric current is kept too long, as can be seen from the table, the tanks magnetic field signs will be strengthened owing to the counter-rotational magnetization, which accords with the electromagnetic theories. In addition, the degaussing loops work characteristics are given in our auxiliary experiment. In conclusion this experiment design method provides a sustain for magnetism protection theory of equips, and a train of thought is offered for both the magnetism-concealed tanks designing and researching through the experiment process.

You might also be interested in these eBooks

Green Power, Materials and Manufacturing Technology and Applications III

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 484-485)

Pages:

151-156

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.484-485.151

Citation:

Cite this paper

Online since:

January 2014

Authors:

Ying Huang

Keywords:

Demagnetizing Effects, Experiment Design, Magnetism-Concealed, Tank

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] LIU Shang (2005) Electromagnetic Environmental Effects of weaponry and its development trend Journal of the Academy of Equipment Command & Technology 1(8): 112-115.

Google Scholar

[2] Huang Ying, Li Hua, Qi Yinghua (2009) coaxial uniform degaussing coil tanks magnetic field effect of the numerical simulation. Armored Force Engineering University 2(8): 90-94.

Google Scholar

[3] Huang Ying, Li Hua, Fei Bao Chun (2009) uniform density around the spherical shell-type equipment, numerical calculation and simulation of the internal and external magnetic field . Central China Normal University (Natural Science) 3(2): 76-79.

Google Scholar

[4] The Rao Feibiao (2010) ARMORED FORCE, Bear He in, the basic combat unit as a whole digitized armored equipment performance testing requirements analysis. Armored Force Engineering University 4(1): 14-18.

Google Scholar

[5] Rakou VA, Uman MA (1998) Review and Evaluation of Lighting Return Stroke Models Including Some Aspects of Their Application,. IEEE Trans. Electromagnet. Compact. 5(4): 403-426.

DOI: 10.1109/15.736202

Google Scholar

[6] Huang Ying (2009).

Google Scholar

[7] Fei Bao Jun, Wang Xiuting (2002) Tanks external magnetic field of a computational model. Armored Force Engineering University 7(2): 8-13.

Google Scholar