Capacitive effects on windings in magnetic components

Host

KU Leuven

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Client & task

Seven Games Company

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Objectives

As power electronics move toward ever higher switching frequencies, the capacitive behaviour of windings becomes a critical factor in the design and reliability of magnetic components. Parasitic capacitances, whether between turns, layers, or windings, can strongly influence high-frequency behaviour, causing increased losses, resonances, electromagnetic interference, and in extreme cases partial discharge or insulation breakdown. These effects are further amplified by the growing variety of winding technologies, including round-wire, foil, Litz wire, PCB-integrated windings, and emerging superconducting conductors.

Understanding and modelling these capacitive effects is essential to ensure robust operation of high-frequency transformers and inductors in advanced power electronic systems. This project investigates these phenomena across multiple winding technologies, with a particular emphasis on defect sensitivity, reliability, and performance optimisation for high-frequency converter applications.

Objectives 1

Investigate the impact of HF capacitive effects on various winding types in magnetic components, including round, flat, Litz, PCB windings, foil, and superconductive materials.

Objectives 2

Explore these HF effects, focusing on aspects such as defect effects and partial discharge phenomena.

Objectives 3

Assess the implications of these capacitive effects on the performance and reliability of magnetic components in HF PE applications.

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Expected Results

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19.7%

Thoroughly comprehend and document HF capacitive effects on various winding types in magnetic components, enhancing the field knowledge.

67%

Conduct in-depth analysis of defect effects and partial discharge phenomena in different windings, contributing to the optimization of magnetic component designs.

260%

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- Brian Green, CEO of Seven Games

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