Prasanth Thummala scite author profile

Transformer parasitics such as leakage inductance and self-capacitance are rarely calculated in advance during the design phase, because of the complexity and huge analytical error margins caused by practical winding implementation issues. Thus, choosing one transformer architecture over another for a given design is usually based on experience, or a trial and error approach. This paper presents analytical expressions for calculating leakage inductance, self-capacitance and ac resistance in transformer winding architectures (TWAs), ranging from the common non-interleaved primary/secondary winding architecture, to an interleaved, sectionalized, and bank winded architecture. The calculated results are evaluated experimentally, and through finite element (FEM) simulations, for a RM8 transformer with a turns ratio of 10. The four TWAs such as, noninterleaved and non-sectioned, non-interleaved and sectioned, interleaved and non-sectioned, and interleaved and sectioned, for an EF25 transformer with a turns ratio of 20, are investigated and practically implemented. The best TWA for a RM8 transformer in a high-voltage (HV) bidirectional flyback converter, used to drive an electro active polymer based incremental actuator, is identified based on the losses caused by the transformer parasitics. For an EF25 transformer, the best TWA is chosen according to whether electromagnetic interference (EMI) due to the transformer interwinding capacitance, is a major problem or not.

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Digital Control of a High-Voltage (2.5 kV) Bidirectional DC--DC Flyback Converter for Driving a Capacitive Incremental Actuator

Thummala

Maksimović

Zhang

et al. 2016

IEEE Trans. Power Electron.

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Efficiency Optimization by Considering the High-Voltage Flyback Transformer Parasitics Using an Automatic Winding Layout Technique

Thummala

Schneider

Zhang

et al. 2015

IEEE Trans. Power Electron.

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Abstract-This paper presents an efficiency optimization approach for a high voltage bidirectional flyback dc-dc converter. The main goal is to optimize the converter for driving a capacitive actuator, which must be charged and discharged from 0 V to 2.5 kV dc and vice versa, supplied from a 24 V dc supply. The energy efficiency is optimized using a proposed new automatic winding layout ( Magnitude of negative flux density at the beginning of a switching cycle during charge process (T) ΔB Peak-to-peak flux density of the current excitation (T) Manusctipt

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Dielectric electro active polymer incremental actuator driven by multiple high-voltage bi-directional DC-DC converters

Thummala

Zhang

Andersen

et al. 2013

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High voltage Bi-directional flyback converter for capacitive actuator

Thummala

Zhang

Andersen

2013

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Keywords«High voltage power converters», «Switched-mode power supply », «Energy efficiency», «Actuator», «Electroactive materials». AbstractThis paper presents a high voltage DC-DC converter topology for bi-directional energy transfer between a low voltage DC source and a high voltage capacitive load. The topology is a bi-directional flyback converter with variable switching frequency control during the charge mode, and constant switching frequency control during the discharge mode. The converter is capable of charging the capacitive load from 24 V DC source to 2.5 kV, and discharges it to 0 V. The flyback converter has been analyzed in detail during both charge and discharge modes, by considering all the parasitic elements in the converter, including the most dominating parameters of the high voltage transformer viz., self-capacitance and leakage inductance. The specific capacitive load for this converter is a dielectric electro active polymer (DEAP) actuator, which can be used as an effective replacement for conventional actuators in a number of applications. In this paper, the discharging energy efficiency definition is introduced. The proposed converter has been experimentally tested with the film capacitive load and the DEAP actuator, and the experimental results are shown together with the efficiency measurements.

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