Simulation Model of a 2-kW IPT Charger with Phase-Shift Control: Validation through the Tuning of the Coupling Factor

Simulation Model of a 2-kW IPT Charger with Phase-Shift Control: Validation through the Tuning of the Coupling Factor

When applied to road vehicle electrification, inductive power transfer (IPT) technology has the potential to boost the transition from combustion engines to electric motors powered by a battery pack. This work focuses on the validation of a PSpice circuit model developed as a replica of a 2-kW IPT p...

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Veröffentlicht in:Electronics (Basel) 2018-10, Vol.7 (10), p.255
Hauptverfasser: Vázquez, Javier, Roncero-Sánchez, Pedro, Parreño Torres, Alfonso
Format: Artikel
Sprache:eng
Schlagworte:
Batteries
Circuits
Coiling
Coils
Computer simulation
Control algorithms
Efficiency
Electric motors
Electric vehicles
Electrification
Inductive coupling
Inverters
Phase shift
Power supply
Power transfer
Receivers & amplifiers
Technology transfer
Transmitters
Tuning
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container_issue 10
container_start_page 255
container_title Electronics (Basel)
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creator Vázquez, Javier
Roncero-Sánchez, Pedro
Parreño Torres, Alfonso
description When applied to road vehicle electrification, inductive power transfer (IPT) technology has the potential to boost the transition from combustion engines to electric motors powered by a battery pack. This work focuses on the validation of a PSpice circuit model developed as a replica of a 2-kW IPT prototype with series-series compensation operating at 18.65 kHz. The laboratory prototype has the three stages commonly found in an IPT system: an inverter, controlled by the phase-shift technique, a coil coupling and a load. Simulations were run with the circuit model for three different distances between the two coils of the inductive coupling, all of which are of interest for practical chargers: 125, 150 and 175 mm. The validation approach was based on tuning the magnetic coupling factor for each distance and a set of ten load resistances, until the best match between the simulated and the experimental peak currents supplied by the inverter was found in each case. The coupling factors obtained from the simulation work are in good agreement with their experimental counterparts for the three distances, provided the duty cycle of the inverter output voltage is not too small. The circuit model developed is, therefore, able to reproduce the behavior of the laboratory prototype with sufficient accuracy over a wide range of distances between coils and loading conditions.
doi_str_mv 10.3390/electronics7100255
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source MDPI - Multidisciplinary Digital Publishing Institute; EZB-FREE-00999 freely available EZB journals
subjects Batteries
Circuits
Coiling
Coils
Computer simulation
Control algorithms
Efficiency
Electric motors
Electric vehicles
Electrification
Inductive coupling
Inverters
Phase shift
Power supply
Power transfer
Receivers & amplifiers
Technology transfer
Transmitters
Tuning
title Simulation Model of a 2-kW IPT Charger with Phase-Shift Control: Validation through the Tuning of the Coupling Factor
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