High voltage Bi-directional flyback converter for capacitive actuator

Thummala, Prasanth; Zhang, Zhe; Andersen, Michael A. E.

doi:10.1109/epe.2013.6634458

Cited by 17 publications

(15 citation statements)

References 15 publications

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“…Since the load is purely capacitive, the converter efficiency is defined as energy efficiency, instead of normal power efficiency. The charge and discharge energy efficiency measurement [30] results are provided in Table IV. During the charge process the output energy is the energy stored in the load capacitor, and the input energy is obtained by integrating the input charge current and multiplying it with the input voltage.…”

Section: Resultsmentioning

confidence: 99%

“…The bidirectional flyback converters are proposed in [26]- [28] to transfer the power in both directions. Prior work on the high voltage drivers for the DEAP actuators demonstrated a low voltage piezoelectric transformer based DEAP solution, and it was inserted inside a coreless DEAP actuator [29], and a bidirectional flyback converter topology to drive the PolyPower Push Inlastor DEAP actuator [30]. In [31] an efficiency optimization technique is proposed for a bidirectional flyback converter used to drive capacitive actuator.…”

Section: A Cmentioning

confidence: 99%

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Design of a high voltage bidirectional DC-DC converter for driving capacitive incremental actuators usable in electric vehicles (EVs)

Thummala

Zhang

Andersen

et al. 2014

2014 IEEE International Electric Vehicle Conference (IEVC)

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Abstract-This paper presents the design of a low input (24 V) and variable high output voltage (0-2.5 kV) bidirectional dc-dc converter for driving a capacitive actuator. The topology is a digitally controlled bidirectional flyback converter with a variable frequency control. The objective is, to design the converter for efficiently charging and discharging the capacitive actuator from 0 V to 2.5 kV and vice versa, respectively. The converter is used to drive a dielectric electro active polymer (DEAP) based capacitive incremental actuator, which has the potential to be used in automotive (e.g., EVs), space and medical industries. The design of the bidirectional flyback converter to charge and discharge a 400 nF capacitive actuator is presented, when 4 kV and 4.5 kV high voltage MOSFETs are used on the secondary high voltage side. The experimental results and efficiency measurements of the converter with the proposed design are provided. Keywords

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Section: Resultsmentioning

confidence: 99%

Section: A Cmentioning

confidence: 99%

Design of a high voltage bidirectional DC-DC converter for driving capacitive incremental actuators usable in electric vehicles (EVs)

Thummala

Zhang

Andersen

et al. 2014

2014 IEEE International Electric Vehicle Conference (IEVC)

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“…Several bidirectional flyback converter topolofies have been proposed and implemented in [25]- [29]. The conventional high voltage bidirectional flyback converter [30], [31], for driving (charging and discharging) a DEAP actuator with a certain actuation frequency, is shown in Fig. 3.…”

Section: High Voltage Drivers: Conventional and Proposedmentioning

confidence: 99%

“…Primary parallel, secondary series flyback converter with multiple transformers is proposed in [36], to reduce the equivalent selfcapacitance on the secondary HV side. The HV converter used in [9], [30], [32], [35] The 4 kV, 300 mA high voltage IXYS MOSFET [37] has the following features:…”

Section: High Voltage Drivers: Conventional and Proposedmentioning

confidence: 99%

“…The flyback converter is suitable for low power (< 150 W) and high voltage (2.5 kV) applications, due to its simple structure and low component count [16]. In [17], [30], [32]- [36], [44], [45] bidirectional flyback converters with various power stages and control techniques, for charging and discharging DEAP actuators have been proposed and implemented. The proposed converter with multiple series con- nected secondary windings is different from aforementioned converters, since it is aimed for bidirectional operation, by replacing the diode with a MOSFET on the secondary HV side.…”

Section: Introductionmentioning

confidence: 99%

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Bidirectional flyback converter with multiple series connected outputs for high voltage capacitive charge and discharge applications

Thummala

Schneider

Zhang

et al. 2015

2015 IEEE Applied Power Electronics Conference and Exposition (APEC)

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Abstract-This paper evaluates two different implementations of a bidirectional flyback converter for driving a capacitive electro active actuator, which must be charged and discharged from 0 V to 2.5 kV DC and vice versa, supplied from a 24 V battery. In one implementation, a high voltage MOSFET (4 kV) in series with a high voltage blocking diode is added, in parallel with a high voltage freewheeling diode of a conventional flyback topology, to enable bidirectional operation. Experimental result from a digitally controlled bidirectional flyback converter shows that the discharge energy efficiency is limited by the parasitics of the high voltage active components, which also prevent full utilization of valley switching during discharge process. A second implementation is therefore proposed, where the secondary of flyback transformer winding is split into multiple windings which are connected in series by lower voltage rating MOSFETs driven by a gate drive transformer. Simulation results to compare the operation of conventional and proposed converters are provided. The advantages of proposed implementation are improved energy efficiency and lower cost. Experimental results with two series connected secondary windings are provided to validate the proposed implementation.Balancing capacitor across a series combination of one of the splitted secondary winding and a secondary MOSFET.

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Design and modelling of a tubular dielectric elastomer actuator with constrained radial displacement as a cardiac assist device

Martinez¹,

Chavanne²,

Walter³

et al. 2021

Smart Mater. Struct.

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In this paper, we propose an improvement of a dielectric elastomer actuator (DEA) based augmented aorta. The actuator is a multi-layered tubular DEA subject to the internal pressure of the blood. When activated in synchronisation with the heart, the DEA supplies energy and limits the load on the left ventricle. The improvement consists in implementing a constraint on the radial displacement of the actuator. This addition allows to increase the electromechanical stability of the device by avoiding snap-through of the material leading to irreversible breakdown. By increasing the stability of the device, it allows to reach higher activation voltages and thus, a higher energy. In order to help the design of this new actuator, we have developed an analytical model of the inflation of a tubular DEA. In addition to previous works, the new model takes into account the multi-layered structure of the device as well as the constraint on the radial displacement to obtain accurate characteristics of the DEA. After validation with specially design experiments, the modelling is used to study the influence of the radial limitation value on the performances of the DEA.

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High voltage Bi-directional flyback converter for capacitive actuator

Cited by 17 publications

References 15 publications

Design of a high voltage bidirectional DC-DC converter for driving capacitive incremental actuators usable in electric vehicles (EVs)

Design of a high voltage bidirectional DC-DC converter for driving capacitive incremental actuators usable in electric vehicles (EVs)

Bidirectional flyback converter with multiple series connected outputs for high voltage capacitive charge and discharge applications

Design and modelling of a tubular dielectric elastomer actuator with constrained radial displacement as a cardiac assist device

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