Large-Signal Characterization of Power Inductors in EV Bidirectional DC–DC Converters Focused on Core Size Optimization

Perdigão, M. S.; Trovão, João P.; Alonso, J.M.; Saraiva, E. S.

doi:10.1109/tie.2015.2402632

Cited by 64 publications

(50 citation statements)

References 31 publications

(23 reference statements)

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“…The converter used in this study is a half-bridge IGBT topology, or two-quadrant class D chopper, operating in continuous conduction mode (CCM) as shown in Figure-3. The half-bridge converter has the advantage that the number of components that are subjected to high currents and/or voltages is reduced in comparison to the other configurations [12]. The number of power components increases losses in the converter as well as producing costs.…”

Section: Bi-directional Converter Topologymentioning

confidence: 99%

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Battery energy storage for variable speed photovoltaic water pumping system

Moubarak¹,

El-Saady²,

Ibrahim³

2019

Preprint

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The photovoltaic (PV) solar electricity is no longer doubtful in its effectiveness in the process of rural communities’ livelihood transformation with solar water pumping system being regarded as the most important PV application. To overcome the intermittent and uncertain nature of solar power output, the highly fluctuating load demands and to supply loads at night time, a battery storage system is optimally sized, designed and implemented. The bi-directional Buck-Boost converter use and control are essential for energy management between the batteries and the pumping system. Domestic loads power calculation is also demonstrated and varied. Additionally, various inverter control schemes are examined and employed depending on the nature of the load connected. Finally, simulation results using Matlab/Simulink are presented for two cases: when the battery system is connected with the PV array to feed the pump motor to achieve the required varying hydraulic performance (flow rate and pumping head) under different weather conditions, and when the battery system feeds the loads while the PV array is disconnected at night.

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Section: Bi-directional Converter Topologymentioning

confidence: 99%

“…These variations can be neglected for the inductor design due to their occasional nature. The largest obtained inductance value will serve as reference for the power inductor prototype [12].…”

Section: Calculation Of the Power Inductor Valuementioning

confidence: 99%

Battery energy storage for variable speed photovoltaic water pumping system

Moubarak¹,

El-Saady²,

Ibrahim³

2019

Preprint

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“…Moreover, it is postulated that regarding the closed loop control of the converter under disturbance rejection, the adaptive inductor adds an extra control parameter and thus can be employed to assist the main control scheme in riding through the transient event. It is worth to notice that replacing the fixed power transfer inductance by a variable one can allow for core size optimization and achieving higher power density at the cost of additional power electronic devices needed for controlling the device saturation [5]. In all cases, it is necessary to investigate the overall PEC incorporating the variable magnetic device.…”

Section: Introductionmentioning

confidence: 99%

Extended Operational Range of Dual-Active-Bridge Converters by using Variable Magnetic Devices

Saeed

Garcia

2019

2019 IEEE Applied Power Electronics Conference and Exposition (APEC)

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This paper explores the use of a variable inductor as an energy transfer reactive element in a Dual-Active-Bridge (DAB) converter. By using a controlled variable inductor, the optimal switching region in the operation of the phase-shift DAB can be extended, and thus high efficiencies can be achieved over wide-load ranges. Moreover, the combination of the variable inductance with the phase shift as two independent control parameters allows for the linearization of the DAB converter transfer function, which gives significant merit to the implementation of the control function. And finally, it is feasible to reduce the magnetic core size, due to the controlled saturation of the device. To study those proposed improvements, a circuitbased model is developed to simulate the converter system. Furthermore, a prototype is constructed for the DAB converter including a controlled variable inductor and preliminary experimental results are presented which validate the studies carried out.

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“…In order to increase the inductance density, increase the saturation current and reduce the core loss of a power inductor, magnetic materials with larger permeability, higher saturation magnetization, larger resistivity and smaller coercivity (such as ferrite materials) are desired [12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

“…This supports the size reduction of power converters through power inductor miniaturization. For this purpose, different methods, such as the utilization of new magnetic materials as power inductor cores and designing new power inductor structures, have been proposed in the literature [12][13][14][15][16][17]. One of the methods used to increase the saturation current (or effectively reduce the size and weight) of the power inductor utilizes one or more permanent magnet(s) (PM) to partially cancel the magnetic fluxes generated by the power inductor winding [18][19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Evaluation of High-Current Toroid Power Inductor With NdFeB Magnet for DC–DC Power Converters

Dang

Qahouq

2015

IEEE Trans. Ind. Electron.

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This paper presents an experimental evaluation of a high current toroid power inductor (TPI) with NdFeB permanent magnet (PMTPI). By adding a small piece of fabricated NdFeB-N35EH magnet (magnet volume is ~0.36% of the PMTPI ferrite core volume) in the air gap of the TPI, the saturation current of the PMTPI is doubled with the same size and inductance value. The desired dimensions of the NdFeB-N35EH PM are calculated before fabrication and then the fabricated PM is characterized. The ~6.8 μH PMTPI is tested in a 5V to 2V buck power converter. Results show that compared to a TPI with the same size and inductance (~6.8μH) without the PM, the saturation current of the PMTPI is doubled (from 7A to 14A). Compared to another TPI with a larger size needed to double the saturation current, the ferrite core weight of the PMTPI is reduced to 53.6% and the core volume is reduced to 59.2%. Experimental results also show that the addition of the NdFeB-N35EH PM does not introduce additional power losses and increase of temperature for the PMTPI and does not affect the power converter efficiency.

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Large-Signal Characterization of Power Inductors in EV Bidirectional DC–DC Converters Focused on Core Size Optimization

Cited by 64 publications

References 31 publications

Battery energy storage for variable speed photovoltaic water pumping system

Battery energy storage for variable speed photovoltaic water pumping system

Extended Operational Range of Dual-Active-Bridge Converters by using Variable Magnetic Devices

Evaluation of High-Current Toroid Power Inductor With NdFeB Magnet for DC–DC Power Converters

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