Characteristic Analysis of Eddy Current Braking System with AC Excitation and Auxiliary Capacitor.

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Bibliographic Details
Title: Characteristic Analysis of Eddy Current Braking System with AC Excitation and Auxiliary Capacitor.
Authors: Niu, Xu1 (AUTHOR), Kou, Baoquan1 (AUTHOR), Zhang, Lu1 (AUTHOR) zhanglu24@hit.edu.cn
Source: Energies (19961073). May2026, Vol. 19 Issue 9, p2118. 20p.
Subject Terms: *Eddy currents (Electric), *Alternating currents, *Capacitors, *Electric power management, *Energy harvesting, *Magnetic flux density, *High speed trains
Abstract: The eddy current braking system (ECBS) is a crucial non-contact technology for high-speed railway. Conventional DC-excited systems face significant challenges such as excessive rail heating and high-capacity power supply requirements. This paper proposes a novel ECBS with AC excitation and auxiliary capacitor to achieve integrated energy recovery and power supply optimization. To evaluate its performance, a rigorous analytical framework is developed. First, a 2D subdomain model is established by incorporating the longitudinal end effect to solve the magnetic field distribution. Subsequently, an equivalent circuit is derived from the subdomain results to investigate steady-state braking characteristics and power flow. Analysis results demonstrate that the proposed system not only generates controllable braking force but also converts a portion of kinetic energy into storable electrical energy, effectively mitigating secondary rail heating. Most significantly, the implementation of an optimal auxiliary capacitor (134 μF) is found to reduce the required inverter capacity compared to inverter-only conditions. These findings provide a theoretical foundation and a practical design tool for developing high-performance, energy-efficient braking systems in high-speed transportation. [ABSTRACT FROM AUTHOR]
Database: Energy & Power Source
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Abstract:The eddy current braking system (ECBS) is a crucial non-contact technology for high-speed railway. Conventional DC-excited systems face significant challenges such as excessive rail heating and high-capacity power supply requirements. This paper proposes a novel ECBS with AC excitation and auxiliary capacitor to achieve integrated energy recovery and power supply optimization. To evaluate its performance, a rigorous analytical framework is developed. First, a 2D subdomain model is established by incorporating the longitudinal end effect to solve the magnetic field distribution. Subsequently, an equivalent circuit is derived from the subdomain results to investigate steady-state braking characteristics and power flow. Analysis results demonstrate that the proposed system not only generates controllable braking force but also converts a portion of kinetic energy into storable electrical energy, effectively mitigating secondary rail heating. Most significantly, the implementation of an optimal auxiliary capacitor (134 μF) is found to reduce the required inverter capacity compared to inverter-only conditions. These findings provide a theoretical foundation and a practical design tool for developing high-performance, energy-efficient braking systems in high-speed transportation. [ABSTRACT FROM AUTHOR]
ISSN:19961073
DOI:10.3390/en19092118