Search results for "Maximum power transfer theorem"

showing 10 items of 32 documents

An efficient wireless power transfer prototype for electrical vehicles

2017

Based on the inductive power transfer (IPT), the contactless approach allows safe and comfortable operations of battery charging for Electric Vehicles (EVs). In this paper, a contactless system particularly suitable for E-bike battery charging is proposed. A practical realization of the system has been carried out, aiming at the system evaluation in terms of working and efficiency. Through a phase shift modulation, a power regulation has been implemented. The target power level is 100 W.

Battery (electricity)Renewable Energy Sustainability and the EnvironmentComputer sciencebusiness.industry020209 energy020208 electrical & electronic engineeringElectrical engineeringVehicle-to-gridEnergy Engineering and Power TechnologyVehicle-to-grid02 engineering and technologyElectric vehicleInductive power transferRenewable energyModulationPower electronics0202 electrical engineering electronic engineering information engineeringMaximum power transfer theoremComputerSystemsOrganization_SPECIAL-PURPOSEANDAPPLICATION-BASEDSYSTEMSWireless power transferbusinessContactless chargingRealization (systems)2017 IEEE 6th International Conference on Renewable Energy Research and Applications (ICRERA)
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Power tracking with maximum efficiency for wireless charging of E-bikes

2014

Wireless charging techniques, based on Inductive Power Transfer (IPT), are attractive for Electric Vehicles (EV), due to benefits such as convenience and safety. An accurate valuation of the maximum achievable efficiency in an IPT system is extremely unlikely due to the high sensitivity to parasitic elements variations. Therefore, an “on site” procedure of power efficiency characterization is useful to get a precise description of the efficiency curve and obtain the actual maximum efficiency. In this paper, a power tracking algorithm aiming at efficiency maximization is proposed for a Wireless Charging system. The algorithm aims at finding the maximum power transfer efficiency with respect …

Engineeringbusiness.industryInductive power transfer wireless battery charging power flow control power tracking maximum efficiencyControl variableMaximizationSettore ING-IND/32 - Convertitori Macchine E Azionamenti ElettriciSettore ING-INF/01 - ElettronicaMaximum power point trackingMaximum efficiencyElectronic engineeringMaximum power transfer theoremWirelessbusinessElectrical efficiencyPower control2014 IEEE International Electric Vehicle Conference (IEVC)
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Physiological compatibility of wireless chargers for electric bicycles

2015

The Inductive Power Transfer represents a viable solution of wireless battery charging for all users of electric mobility. This method brings some benefits to the electric vehicles, being a convenient technique, compared to the conventional wire-based battery charging. Among the electric vehicles, the electric bicycles particularly fit with this innovative method of battery charging. Nevertheless, the physiological effects of the produced magnetic fields need to be taken into account. In this paper, the design of an Inductive Power Transfer system for E-bike wireless battery charging is presented and the measurements concerning the surrounding magnetic field are provided in order to validat…

Engineeringbusiness.industryElectrical engineeringwireless chargingelectric bicycleSettore ING-IND/32 - Convertitori Macchine E Azionamenti ElettriciMagnetic fieldSettore ING-IND/31 - ElettrotecnicaHardware_GENERALCompatibility (mechanics)Maximum power transfer theoremWirelessphysiological compatibilityinductive power transferbusinesselectric mobility
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Optimal matching between optical rectennas and harvester circuits

2017

This paper deals with optimal coupling issues between rectennas and harvesting circuits. An optical rectenna consists of a nanoantenna usually coupled with an ultra-high speed rectifier. These devices aim to receive and convert solar and thermal radiation in a DC voltage, while a harvester circuit provides the energy to be stored. The rectenna impedance is influenced both by its structure and by the rectifying diode, the harvester circuit impedance has to be matched to optimize the power transfer. The purpose of this contribution is to discuss the best impedance conditions by taking into account the constraints that are due to the individual devices the conversion system consist of. Finally…

energy harvestingEngineeringEnvironmental EngineeringrectennaEnergy Engineering and Power Technology02 engineering and technologyHardware_PERFORMANCEANDRELIABILITYSettore ING-INF/01 - Elettronica01 natural sciencesIndustrial and Manufacturing EngineeringRectifier0103 physical sciencesElectronic engineeringHardware_INTEGRATEDCIRCUITSMaximum power transfer theoremElectrical and Electronic Engineering010306 general physicsElectrical impedanceElectronic circuitDiodeimpedance matchingbusiness.industryElectrical engineering021001 nanoscience & nanotechnologyRectennaImpedance and Voltage matchingnanoantenna0210 nano-technologybusinessEnergy harvestingEnergy (signal processing)
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Design, implementation and experimental results of a wireless charger for E-bikes

2019

Based on the Inductive Power Transfer (IPT), the wireless energy transmission is increasingly representing an attractive solution for vehicle battery charging. Due to its high smartness, the wireless solution may be considered an interesting battery charging method for electric bicycles, as they represent light-weight and flexible means of transportation. According to the Vehicle-To-Grid (V2G) concept, the wireless power flow can occur in both the alternative directions: from the grid to the battery or in the opposite way. A Bi-Directional Inductive Power Transfer (BDIPT) system is therefore particularly convenient in the scenario of a multi-parking area. For the E-bike application, a bicyc…

Battery (electricity)Computer sciencebusiness.industry020209 energy020208 electrical & electronic engineeringElectrical engineeringelectric bicycle02 engineering and technologySettore ING-IND/32 - Convertitori Macchine E Azionamenti ElettriciGridSettore ING-INF/01 - Elettronicalaw.inventionBi-directional power converterCapacitorBattery chargerElectric power transmissionlaw0202 electrical engineering electronic engineering information engineeringMaximum power transfer theoremWirelesswireless battery charginginductive power transferResistorbusiness
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Contactless power transfer application for devices identification

2019

This paper deals with the problem of non-contact power transfer systems to identify components based on infrared signatures reading. This approach enables the distinction of a larger number of different devices situated in a relatively small area, compared to RFID technology. Moreover, the presented infrared contactless identification is resilient to natural environmental infrared perturbations. The advantages of this approach are demonstrated in a simple use-case: continuously identifying low consumption chess pieces on a custom chessboard. This approach can be further instantiated for high consumption devices such as electrically charging small autonomous guided vehicles.

Identification (information)Computer sciencelcsh:TA1-2040Electronic engineeringMaximum power transfer theoremlcsh:Engineering (General). Civil engineering (General)MATEC Web of Conferences
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Achieving maximum power transfer in a multi-source renewable system

2014

In this paper, a multi-source DC-DC power system is proposed for renewable applications. A multi-input, single inductor power converter controlled by two interacting control loops is designed. The steady-state and small-signal analysis of the designed system is carried out. A battery-photovoltaic system is designed as an application example. Both the output voltage and maximum power point of solar panels are properly controlled to achieve high performances of the whole system. Experimental results on a 48 V laboratory prototype are presented to discuss system performances.

EngineeringMulti-input converterMaximum power principlebusiness.industryRenewable energy sourcePower converterInductorPower (physics)Renewable energyRenewable energy systemsElectric power systemElectronic engineeringMaximum power transfer theoremPoint (geometry)businessVoltagePower system
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Design of a solar-battery-thermoelectric power converter prototype

2015

In this paper a multisource renewable energy system for high-current applications is proposed. The power architecture is based on a multi-input power converter including control and reconfiguration subsystems. Independently of the type of connected renewable sources, a proper control of the output DC voltage bus is provided as well as a proper control on the operating point of each renewable source to achieve the maximum power transfer. A 48V thermoelectric-photovoltaic-battery system in a three input configuration is designed. Three interacting feedback networks are implemented: the outer loop which controls the output voltage and as many inner loops as connected renewable sources to achie…

Power optimizerEngineeringSwitched-mode power supplyBuck converterbusiness.industryPower moduleBoost converterElectronic engineeringElectrical engineeringMaximum power transfer theoremPower factorbusinessMaximum power point tracking
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Novel Isolated Multiple-Input Buck-Boost DC-DC Converter for Renewable Energy Sources

2021

An isolated multiple input dc-dc converter (MIC) with unidirectional buck-boost characteristics and simultaneous power transfer is proposed for multi-sources in renewable energy systems in this paper. When compared to existing isolated MICs, the proposed MIC significantly reduces the component count and control complexity since it requires a fixed coupled inductor with only one primary and secondary winding each for any number of inputs and does not require any phase-shifted pulse-width modulation. The operation of the proposed converter for simultaneous power transfer from multiple sources with varying voltages is numerically verified in simulation and validated on OPAL-RT’s OP5700 hardwar…

Modulationbusiness.industryElectromagnetic coilControl theoryComputer scienceBuck–boost converterMaximum power transfer theorembusinessInductorPhase modulationRenewable energyVoltageIECON 2021 – 47th Annual Conference of the IEEE Industrial Electronics Society
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Optimal Operating Point Calculation for Medium Voltage Distribution Systems

2007

The paper deals with the calculation of the optimal working point of a distribution system, equipped with several distributed generators, able to operate also autonomously, i.e. disconnected from the main grid. When connected to the main grid, it appears in general convenient to assign the slack bus role to the bus that represents such a connection. The problem becomes more complex when maximum power transfer constraints through the connection must be taken into account. The adequate slack bus treatment is even more important when the optimal operating condition must refer to the condition subsequent to an intentional or unintentional disconnection from the main grid. The paper presents an …

Electric power distributionOperating pointEngineeringPower flow calculationElectric power distributionbusiness.industrySlack bus treatmentDistributed parameter networksLocal area networksLocal area networkControl engineeringGridMulti-objective optimizationChlorine compoundsMulti-objective optimizationSlack busGenetic algorithmDistributed generationepfl-smartgridsMaximum power transfer theoremDistributed generationDistribution of goodsbusinessComputer networks2007 IEEE Lausanne Power Tech
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