Raman, SJ and Kumar, U (2019) Validity of circuit-based models for air-cored helical windings at high-frequency regimes. In: IET Generation, Transmission and Distribution, 13 (9). pp. 1709-1717.
PDF
IET_gen_tra_dis_13-9_1709-1717_2019.pdf - Published Version Restricted to Registered users only Download (4MB) | Request a copy |
Abstract
Helical coils in different forms find applications in various areas of electrical engineering. While power engineers use close-pitched coils in inductors, reactors and transformer windings, communication engineers use large-pitched helical coils as antennas. In classical power engineering, coils are represented as lumped inductors for power frequency applications and switch-over to distributed circuit models while dealing with switching and lightning transients. Even for very fast rising excitations such as very fast transient overvoltages, chopped lightning waves and propagation of partial discharge pulses, multi-conductor transmission-line-based models have been employed, which appears to be an over-simplification. It would be very useful if an upper-frequency limit for the circuit-based models is quantified, which requires an extensive solution of the electromagnetic fields. After realising the inherent late-time instability of marching-on-in-time methods, a relatively new method called the marching-on-in-degree-based scheme is adopted for the solution of the associated electric field integral equation. A deeper insight is first obtained by analysing the helical antennas. Subsequently, based on the extensive simulation results for the single-layer helical coils, an empirical relation relating the upper-frequency bound for the circuit-based modelling has been deduced.
Item Type: | Journal Article |
---|---|
Publication: | IET Generation, Transmission and Distribution |
Publisher: | Institution of Engineering and Technology |
Additional Information: | The copyright for this article belongs to Institution of Engineering and Technology. |
Keywords: | Electromagnetic fields; Integral equations; Lightning; Partial discharges; Timing circuits; Transformer windings; Winding, Communication engineers; Distributed circuit model; Electric field integral equation; Extensive simulations; Marching on in degree; Multi-conductor transmission lines; Partial discharge pulse; Very fast transient overvoltages, Helical antennas |
Department/Centre: | Division of Electrical Sciences > Electrical Engineering |
Date Deposited: | 22 Nov 2022 09:13 |
Last Modified: | 22 Nov 2022 09:13 |
URI: | https://eprints.iisc.ac.in/id/eprint/77952 |
Actions (login required)
View Item |