TY - GEN
T1 - Design and analysis of a two-phase two-Axis-compensated compulsator
AU - Zhao, Weiduo
AU - Song, Liwei
AU - Cui, Shumei
N1 - Publisher Copyright:
© 2014 IEEE.
PY - 2014/10/10
Y1 - 2014/10/10
N2 - As power supplies, compulsators are popular choices for electromagnetic railguns. In this paper, a two-phase two-Axis-compensated compulsator (2P2AC compulsator) with lower internal inductance and higher power density was designed and analyzed. Two-phase armature windings are allocated on the stator, and discharge pulse currents to the load via a rectifier. This arrangement decouples the machine speed from the pulse width, thus enables a higher tip speed. Two sets of windings with electrical orthogonal displacement are allocated on the rotor. The bigger one is the field winding, which freewheels via a diode and provides the direct-Axis compensation during the discharge process. While the smaller one is the short-circuit compensating winding providing the quadrature-Axis compensation. The effect of the composition of the d- and q-Axis compensation is equivalent to a passive compensation by using a continuous conductive shield, which compresses the flux for all rotor positions. Compared to the passive compensation, this arrangement has no conductive path to couple with the field winding due to the orthogonal displacement, thus speeding up the charging process. This paper presents the design methodology of the 2P2AC compulsator, along with its system performance of driving railgun load.
AB - As power supplies, compulsators are popular choices for electromagnetic railguns. In this paper, a two-phase two-Axis-compensated compulsator (2P2AC compulsator) with lower internal inductance and higher power density was designed and analyzed. Two-phase armature windings are allocated on the stator, and discharge pulse currents to the load via a rectifier. This arrangement decouples the machine speed from the pulse width, thus enables a higher tip speed. Two sets of windings with electrical orthogonal displacement are allocated on the rotor. The bigger one is the field winding, which freewheels via a diode and provides the direct-Axis compensation during the discharge process. While the smaller one is the short-circuit compensating winding providing the quadrature-Axis compensation. The effect of the composition of the d- and q-Axis compensation is equivalent to a passive compensation by using a continuous conductive shield, which compresses the flux for all rotor positions. Compared to the passive compensation, this arrangement has no conductive path to couple with the field winding due to the orthogonal displacement, thus speeding up the charging process. This paper presents the design methodology of the 2P2AC compulsator, along with its system performance of driving railgun load.
KW - Electromagnetic launch
KW - compensation
KW - compulsator
KW - pulsed power supply
KW - railgun
UR - http://www.scopus.com/inward/record.url?scp=84909952624&partnerID=8YFLogxK
U2 - 10.1109/EML.2014.6920617
DO - 10.1109/EML.2014.6920617
M3 - Conference contribution
AN - SCOPUS:84909952624
T3 - Conference Proceedings - EML 2014 17th International Symposium on Electromagnetic Launch Technology
BT - Conference Proceedings - EML 2014 17th International Symposium on Electromagnetic Launch Technology
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2014 17th International Symposium on Electromagnetic Launch Technology, EML 2014
Y2 - 7 July 2014 through 11 July 2014
ER -