Search results for "SiC devices"

showing 3 items of 3 documents

Power losses comparison between Silicon Carbide and Silicon devices for an isolated DC-DC converter

2021

In recent years, new efficient power devices have been implemented. Silicon Carbide has replaced silicon as regards the production and the utilization of many devices, such as MOSFETs, diodes, IGBTs and many others. SiC devices are characterized by a low reverse recovery charge, high carrier saturation velocity, by which it is possible to work at high frequency, and high breakdown voltage. Thanks to the great thermal conductivity and the wide bandgap, these devices can operate at high temperature and reach high voltages and currents. What is important to stress is the fact that power losses in SiC devices are lower than the silicon ones. These are the reasons why these devices are utilized …

Materials scienceSiliconSiC devicesbusiness.industryDC-DC converterschemistry.chemical_elementSaturation velocityHardware_PERFORMANCEANDRELIABILITYSettore ING-IND/32 - Convertitori Macchine E Azionamenti ElettriciSettore ING-INF/01 - ElettronicaIsolated power converterschemistry.chemical_compoundchemistryPower electronicsMOSFETHardware_INTEGRATEDCIRCUITSSilicon carbideOptoelectronicsBreakdown voltagePower semiconductor devicePower lossesbusinessDiode
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A Configuration of 3-phase Traction Inverter Employing {SiC} Devices

2022

In the scenario of a more and more sustainable society, an increasing electrification in different fields, such as mobility and industrial applications, is foreseen in the next decades. As far as power electronics is concerned, a challenging perspective is represented by achieving higher and higher switching frequencies while maintaining high voltage and low power losses. To do that, emerging semiconductor technologies are supposed to be increasingly employed, as well as innovative topologies of connections among switching devices. Among them, the cascode configuration can notably contribute to achieve high levels of dV/dt without losing efficiency. In this paper, a 3-phase Pulse Width Modu…

SiC devicesCascode connectiontraction inverter2022 IEEE 16th International Conference on Compatibility, Power Electronics, and Power Engineering (CPE-POWERENG)
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Simulation of parasitic effects on Silicon Carbide devices for automotive electric traction

2020

Wide Band Gap (WBG) semiconductors are increasingly addressed towards Electric Vehicle (EV) applications, due to their significant advantages in terms of high-voltage and low-losses performances, suitable for high power applications. Nevertheless, the packaging in WBG devices represents a challenge for designers due to the notable impact that inductive and capacitive parasitic components can bring in high switching frequency regime in terms of noise and power losses. In this paper, a comparison between conventional Silicon (Si) and emerging Silicon-Carbide (SiC) power switching devices is presented. The effects of inductive parasitic effects and switching frequency are investigated in simul…

business.product_categoryMaterials scienceElectric vehicles020209 energyCapacitive sensingHardware_PERFORMANCEANDRELIABILITY02 engineering and technologySettore ING-IND/32 - Convertitori Macchine E Azionamenti Elettrici7. Clean energyNoise (electronics)Settore ING-INF/01 - ElettronicaParasitic effects modelinglaw.inventionchemistry.chemical_compoundPrinted circuit boardlawElectric vehicleMOSFETHardware_INTEGRATEDCIRCUITS0202 electrical engineering electronic engineering information engineeringSilicon carbideSiC devicesDC-DC converters020208 electrical & electronic engineeringWide-bandgap semiconductorEngineering physicsCapacitorchemistrybusiness
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