Abstract
The thin iron plate is needed to be transported without the degradation of the quality of surface, and magnetic levitation technology is one of the solutions to satisfy these requirements. Magnetic saturation in the objective, however, is a severe problem for the levitation of the thin iron plate. Design and evaluation method of the electromagnet is studied to avoid the saturation. In this paper, the shape of the electromagnet is studied to obtain the maximum attractive force without the saturation in the thin iron plate. The magnetic saturation position is investigated first, and it is proved that the saturation occurs in the iron plate especially when it is very thin. Therefore, the preferable shape of electromagnet should be investigated to secure the large cross sectional area of flux path in the plate. The authors propose the Multipolar electromagnet to solve this problem. The relationship between the electromagnet shape and the cross sectional area of flux path in the plate is studied. (orig.)
Osabe, H;
[1]
Watada, M;
[1]
Torii, S;
[1]
Ebihara, D
[1]
- Dept. of Electrical and Electronic Engineering, Musashi Inst. of Technology, Tokyo (Japan)
Citation Formats
Osabe, H, Watada, M, Torii, S, and Ebihara, D.
The effect on the multipolar electromagnet for the levitation of thin iron plate.
Germany: N. p.,
1995.
Web.
Osabe, H, Watada, M, Torii, S, & Ebihara, D.
The effect on the multipolar electromagnet for the levitation of thin iron plate.
Germany.
Osabe, H, Watada, M, Torii, S, and Ebihara, D.
1995.
"The effect on the multipolar electromagnet for the levitation of thin iron plate."
Germany.
@misc{etde_412488,
title = {The effect on the multipolar electromagnet for the levitation of thin iron plate}
author = {Osabe, H, Watada, M, Torii, S, and Ebihara, D}
abstractNote = {The thin iron plate is needed to be transported without the degradation of the quality of surface, and magnetic levitation technology is one of the solutions to satisfy these requirements. Magnetic saturation in the objective, however, is a severe problem for the levitation of the thin iron plate. Design and evaluation method of the electromagnet is studied to avoid the saturation. In this paper, the shape of the electromagnet is studied to obtain the maximum attractive force without the saturation in the thin iron plate. The magnetic saturation position is investigated first, and it is proved that the saturation occurs in the iron plate especially when it is very thin. Therefore, the preferable shape of electromagnet should be investigated to secure the large cross sectional area of flux path in the plate. The authors propose the Multipolar electromagnet to solve this problem. The relationship between the electromagnet shape and the cross sectional area of flux path in the plate is studied. (orig.)}
place = {Germany}
year = {1995}
month = {Dec}
}
title = {The effect on the multipolar electromagnet for the levitation of thin iron plate}
author = {Osabe, H, Watada, M, Torii, S, and Ebihara, D}
abstractNote = {The thin iron plate is needed to be transported without the degradation of the quality of surface, and magnetic levitation technology is one of the solutions to satisfy these requirements. Magnetic saturation in the objective, however, is a severe problem for the levitation of the thin iron plate. Design and evaluation method of the electromagnet is studied to avoid the saturation. In this paper, the shape of the electromagnet is studied to obtain the maximum attractive force without the saturation in the thin iron plate. The magnetic saturation position is investigated first, and it is proved that the saturation occurs in the iron plate especially when it is very thin. Therefore, the preferable shape of electromagnet should be investigated to secure the large cross sectional area of flux path in the plate. The authors propose the Multipolar electromagnet to solve this problem. The relationship between the electromagnet shape and the cross sectional area of flux path in the plate is studied. (orig.)}
place = {Germany}
year = {1995}
month = {Dec}
}