Nonlinear three-port magnetic-circuit elements for simulating bending

© Emerald Publishing Limited. Purpose - The purpose of this paper is to show that constructing magnetic equivalent circuits (MECs) for simulating accelerator magnets is possible by defining a three-port magnetic element for modelling the T-shape field distribution, where the flux leaves the yoke and enters the aperture. Design/methodology/approach - A linear three-port magnetic element is extracted from an analytical field solution and can be represented by a number of two-port elements. Its nonlinear counterpart is obtained as a combination of the corresponding nonlinear two-port elements. An improved nonlinear three-port element is developed on the basis of an embedded nonlinear one-dimensional finite element model. Findings - The T-shaped field distribution comes together with a complicated interplay between the saturation of the ferromagnetic yoke parts and flux leaking to the aperture. This is more accurately modelled by the improved nonlinear three-port magnetic element. Research limitations/implications - MECs have a limited validity range, especially for configurations where a high saturation level and fringing flux effects coexist. Practical implications - The results of the paper appeal to be careful with applying nonlinear MECs for simulating bending magnets. Originality/value - A new nonlinear three-port magnetic element for ferromagnetic yoke parts with Tshaped flux distribution has been developed.

Jaar van publicatie:2018

BOF-keylabel:ja

IOF-keylabel:ja

BOF-publication weight:0.1

CSS-citation score:1

Auteurs:International

Authors from:Higher Education

Toegankelijkheid:Closed