Title :
Controlling inrush currents in inductively coupled power systems
Author :
Boys, J.T. ; Chen, C.I. ; Covic, G.A.
Author_Institution :
Dept. of Electr. & Comput. Eng., Auckland Univ.
fDate :
Nov. 29 2005-Dec. 2 2005
Abstract :
In an inductively coupled power transfer (ICPT) system, a multiplicity of (moving) loads take power from an elongated conductive loop (track) excited by a current in the range of 15-125 A by magnetic induction at a VLF frequency of between 5-50 kHz. In this application, the track performs the same function as a distribution line in a power system. However, frequency deviations cannot be tolerated in ICPT systems and therefore there are difficulties with inrush power surges as loads switch on. In severe cases, the inrush surge may compromise the security of the whole system. This paper proposes a solution to this problem using an ICPT pickup controller with input shaping where the poles that can cause an inrush are not excited. The paper is supported by theoretical analysis and experimental measurements and is applicable across a wide range of ICPT sizes and applications. The solution reduces the inrush effects to 10% of an uncontrolled system
Keywords :
distribution networks; electric current control; electromagnetic induction; surges; 15 to 125 A; distribution line; frequency deviations; inductively coupled power transfer systems; inrush current control; inrush power surges; magnetic induction; pickup controller; Control systems; Couplings; Frequency; Power system security; Power systems; Shape control; Size measurement; Surges; Switches; Tracking loops; inductively coupled power transfer (ICPT); input shaping; inrush current; power electronics; power system transients; rate limiting;
Conference_Titel :
Power Engineering Conference, 2005. IPEC 2005. The 7th International
Conference_Location :
Singapore
Print_ISBN :
981-05-5702-7
DOI :
10.1109/IPEC.2005.207062
