Iron Loss Calculation of AC Filter Inductor for Three‐Phase PWM Inverters

Matsumori, Hiroaki; Shimizu, Toshihisa; Takano, Koushi; Ishii, Hitoshi

doi:10.1002/eej.22688

Cited by 4 publications

(1 citation statement)

References 8 publications

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“…When deriving the adjusting coefficient m, the effectin (11) must be solved. Nevertheless, the equation of P V1 for H dc , which is introduced in (2), is too complex to solve the integral in (11). The method to derive the adjusting coefficient corresponding to H dc will be the focus of future work.…”

Section: Experimental Verificationmentioning

confidence: 99%

Iron-loss Calculation of Inductors Considering Non-uniform Flux Density Conditions

et al. 2019

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Owing to the significant advances made in the field of power semiconductor devices, such as SiC and GaN, the switching frequency of power converters has been increased. Thus, the volume of passive components such as filter inductors and transformers can be reduced. However, the reduction in the heat-dissipation surface area of inductors results in a considerable increase in temperature, which is a constraint for increasing the power density of power converters. To prevent these problems, the iron-loss evaluation of inductors is one of the most important issues in realizing high-power-density converters. This paper presents an accurate iron-loss calculation method for inductors considering the non-uniformity of the flux-density distribution in the magnetic core. First, it is verified that the non-uniformity of the flux-density distribution in the core results in the deviation of the iron-loss measurement even when the same magnetic material is used in the core and when the inductor is excited under the same excitation condition. Next, the procedure to obtain the iron-loss data, which describes the relationship between the iron loss and excitation condition more precisely, is introduced. Finally, a method to accurately calculate the iron loss in an inductor using electromagnetic simulation and more precise iron-loss data is introduced. method is verified using a toroidal core and a UU core under sine voltage condition and rectangular voltage condition.

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Section: Experimental Verificationmentioning

confidence: 99%

Iron-loss Calculation of Inductors Considering Non-uniform Flux Density Conditions

et al. 2019

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Iron loss evaluation of three-phase inductor for three-phase PWM inverter

Matsumori

Shimizu

Takano

et al. 2016

2016 IEEE Applied Power Electronics Conference and Exposition (APEC)

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The iron losses of three-phase inductor used in a three-phase pulse-width modulation (PWM) inverter are evaluated. First we clarify three-phase inductor design in order to make same inductance value between the each phase. Then based on the design, iron losses for various structure of inductor are simulated. Simulation result shows the iron loss can be reduced about 5% by changing structure from conventional structure. Finally, we create conventional type and newly designed inductor and measure iron loss on a real PWM inverter. In the experiment, iron loss can be reduced about 10% compared with conventional type. Furthermore the calculated agree with measured losses within 10%. The iron loss reduction is verified by simulation and experiment.

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Loss comparison of core materials used for the inductor of a buck-chopper circuit

Miwa

Shimizu

2015

2015 IEEE Energy Conversion Congress and Exposition (ECCE)

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Iron Loss Calculation of AC Filter Inductor for Three‐Phase PWM Inverters

Cited by 4 publications

References 8 publications

Iron-loss Calculation of Inductors Considering Non-uniform Flux Density Conditions

Iron-loss Calculation of Inductors Considering Non-uniform Flux Density Conditions

Iron loss evaluation of three-phase inductor for three-phase PWM inverter

Loss comparison of core materials used for the inductor of a buck-chopper circuit

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