Journal of Theoretical and Applied Mechanics

Journal of Theoretical
and Applied Mechanics
0, 0, pp. , Warsaw 0

The multivariate calculations of the electrodynamic accelerator with permanent magnet support and a ferromagnetic core were presented in the paper. The calculations were made with using the Magnetostatic module of a Maxwell/ANSYS software. The purpose of these calculations was to determine the size and location of the permanent magnets in terms of maximizing the force acting on the projectile. In the presented paper three cases have been analyzed. In order to perform a comparative analysis of the obtained results of calculations, the dimensions of the rails, projectile and outer dimensions of the core were keep constant.

Chung S.S.M., 2016, Parametric Study of Possible Railgun Radiation in Postfire Stage, IEEE Transactions on Plasma Science, 44, 6, 980-990

Domin J., Kluszczyński K., 2015, Two module electromagnetic launcher with pneumatic assist Modelling, computer simulations and laboratory investigations, COMPEL, 34, 3, 691-709

Engel T.G., Surls D., Nunnally W.C., 2001, All-Electric Rifle-Caliber Launcher With Permanent Magnet Augmentation, IEEE Transactions on Magnetics, 37, 6, 3934-3940

Gieras J.F., Piech Z.J., Tomczuk B., 2011, Linear synchronous motors, CRC Press, Taylor & Francis Group, New York

Gosiewski Z., Kłosowski P., 2008, Support of work of electromagnetic gun by using permanent magnets, Bulletin of the Military University of Technology, 57, 3, 87-95

Hric III G.R., Odendaal W.G., 2016, Improving Start-Up Contact Distribution Between Railgun Armature and Rails, IEEE Transactions on Plasma Science, 44, 7, 1202-1207

Jin L., Lei B., Zhang Q., Zhu R., 2015, Electromechanical Performance of Rails With Different Cross-Sectional Shapes in Railgun, IEEE Transactions on Plasma Science, 43, 5, 1220-1224

McNab I.R., 1999, The STAR Railgun Concept, IEEE Transactions on Magnetics, 35, 1, 432-436

Vincent G., Hundertmark S., 2013, Using the Hexagonal Segmented Railgun in Multishot Mode With Three Projectiles, IEEE Transactions on Plasma Science, 41, 5, 1431-1435

Waindok A., 2013, Modeling and measurement verification of characteristics for the permanent magnet tubular linear actuators, Oficyna Wydawnicza Politechniki Opolskiej, Opole

Waindok A., Piekielny P., 2016, Calculation models of the electrodynamic accelerator (railgun), Przegląd Elektrotechniczny, 92, 9, 246-249

Waindok A., Piekielny P., 2017, Transient Analysis of A Railgun with Permanent Magnets Support, Acta Mechanica et Automatica, 11, 4, 302-307

Waindok A., Tomczuk B., 2017, Reluctance Network Model of a Permanent Magnet Tubular Motor, Acta Mechanica et Automatica, 11, 3, 194-198

Wajnert D., 2013, Comparison of Magnetic Field Parameters Obtained from 2D and 3D Finite Element Analysis for an Active Magnetic Bearing, Proceedings of International Symposium on Electrodynamic and Mechatronic Systems, 73-74

Wang G.H., Xie L., He Y., Song S.Y., Gao J.J., 2016, Moving Mesh FE/BE Hybrid Simulation of Electromagnetic Field Evolution for Railgun, IEEE Transactions on Plasma Science, 44, 8, 1424-1428.

Wu S., Wang X., Cui S., Zhao W., 2015, Risk Evaluation for Hybrid Excitation Compulsator, IEEE Transactions on Plasma Science, 43, 5, 1410-1414.

Yamori A., Ono Y., Kubo H., Kono M., Kawashima N., 2001, Development of an Induction Type Railgun, IEEE Transactions on Magnetics, 37, 1, 470-472

Zakrzewski K., Tomczuk B., Koteras D., 2009, Amorphous modular transformers and their 3D magnetic fields calculation with FEM, COMPEL, 28, 3, 583-592