Search results for "Printed circuit board"

showing 8 items of 28 documents

ZnO Nanowires catalytic solution growth for piezotronic and bio-applications

2016

ZnO Nanowires Gold nanoclusters Printed circuit boardSettore CHIM/01 - Chimica Analitica
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HIGH-DENSITY ZnO NANOWIRES ON PRINTED CIRCUIT BOARDS FOR WEARABLE SENSORS AND HEATERS

2019

ZnO Nanowires Printed Circuit Boards heartbear sensor microheatersSettore CHIM/01 - Chimica Analitica
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A prototypal PCB board for the EMI characterization of SiC-based innovative switching devices

2020

In this paper, a preliminary PCB board for the electromagnetic interference (EMI) characterization of innovative silicon-carbide (SiC) based switching devices is presented. Packaging technological issues can determine hurdles in the high-frequency switching and high power regime where wide band gap semiconductors are intended today for Electric Vehicle (EV) applications. In particular, the parasitic inductances that emerge in such devices, must be assessed, by using e.g. EMI techniques. In this specific case, the EMI characterization is supposed to be carried out in a semi-anechoic chamber, available at the University of Palermo (UNIPA), to assess the electromagnetic disturbances according …

business.product_categoryComputer science020209 energy02 engineering and technologySettore ING-IND/32 - Convertitori Macchine E Azionamenti Elettricicomputer.software_genreSettore ING-INF/01 - Elettronica7. Clean energyElectromagnetic interferencePrinted circuit boardEMIElectric vehicle0202 electrical engineering electronic engineering information engineeringelectromagnetic compatibilityelectric vehiclesPage layoutbusiness.industry020208 electrical & electronic engineeringElectrical engineeringElectromagnetic compatibilitySiC deviceElectromagnetic interferencePower (physics)Settore ING-IND/31 - ElettrotecnicabusinesscomputerVoltage
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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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Selective Disintegration–Milling to Obtain Metal-Rich Particle Fractions from E-Waste

2022

This research was supported by ERDF project no. 1.1.1.1/20/A/139 “Development of sustainable recycling technology of electronic scrap for precious and non-ferrous metals extraction”. The project was co-financed by REACT-EU funding to mitigate the effects of the pandemic crisis. The article was published with the financial support from the Riga Technical University Research Support Fund. This research was also supported by the Institute of Solid State Physics, University of Latvia as the Center of Excellence has received funding from the European Union’s Horizon 2020 Framework Program H2020-WIDESPREAD-01-2016-2017-TeamingPhase2 under grant agreement No. 739508, project CAMART2. The authors w…

disintegratione-wasteMetals and Alloysprecious metalsprinted circuit boards:NATURAL SCIENCES::Physics [Research Subject Categories]e-waste millingGeneral Materials Sciencedisintegration; e-waste; e-waste mechanical pretreatment; e-waste milling; precious metals; printed circuit boardse-waste mechanical pretreatmentMetals
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An Energy-Autonomous Wireless Sensor with Simultaneous Energy Harvesting and Ambient Light Sensing

2021

Wireless sensor nodes (WSNs) are generally powered by batteries, which results in a substantial limitation to the places where the nodes can be installed, to the maximum number of deployable devices, and to the node lifetime. To meet the demand for Internet-of-Things (IoT) applications that require a large number of maintenance-free, low cost, wireless sensor nodes, this paper proposes a wireless sensor platform with a single photovoltaic transducer that performs the dual role of harvesting energy and sensing ambient light. This dual use allows even smaller and cheaper nodes that do not require any form of supporting external power, with a reduced component count. The device implements off-…

energy harvestingComputer sciencetime measurementsensors01 natural sciencesSettore ING-INF/01 - Elettronicaphase measurementpowerPrinted circuit boardwireless sensor networkbluetooth low energyWirelessBluetooth Low Energy Energy harvesting Internet of Things (IoT) light sensors low power Microcontroller Wireless Sensor Network Wireless Sensor Node Home AutomationElectrical and Electronic Engineeringwireless sensor networksInstrumentationlow powerbusiness.industry010401 analytical chemistryPhotovoltaic systemElectrical engineeringlight sensorswireless communication0104 chemical sciencesMicrocontrollerinternet of things (iot)Transducermicrocontrollerphotovoltaic systemswireless sensor nodehome automationNode (circuits)businessEnergy harvestingWireless sensor network
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Effective Recovery Process of Copper from Waste Printed Circuit Boards Utilizing Recycling of Leachate

2020

AbstractThis study presents an optimized leaching and electrowinning process for the recovery of copper from waste printed circuit boards including studies of chemical consumption and recirculation of leachate. Optimization of leaching was performed using response surface methodology in diluted sulfuric acid and hydrogen peroxide media. Optimum leaching conditions for copper were found by using 3.6 mol L−1 sulfuric acid, 6 vol.% hydrogen peroxide, pulp density of 75 g L−1 with 186 min leaching time at 20°C resulting in complete leaching of copper followed by over 92% recovery and purity of 99.9% in the electrowinning. Study of chemical consumption showed total decomposition of hydrogen pero…

inorganic chemicalsrikkihappopiirilevyt0211 other engineering and technologieschemistry.chemical_elementkupari02 engineering and technology010501 environmental sciences01 natural sciencescomplex mixtureschemistry.chemical_compoundPrinted circuit boardvetyperoksidiGeneral Materials ScienceLeachateResponse surface methodologyHydrogen peroxide0105 earth and related environmental sciences021110 strategic defence & security studiesGeneral Engineeringtechnology industry and agricultureSulfuric acidPulp and paper industryCopperchemistrytalteenottoliuotussähkö- ja elektroniikkaromuLeaching (metallurgy)Electrowinning
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Automated PCB Inspection System

2017

TEM Journal; Vol 6, No 2, 2017. ISSN 2217-8309

lcsh:TComputer VisionPrinted Circuit BoardAutomated Visual Inspectionlcsh:LQuality AssuranceQuality Assurance.lcsh:Technologylcsh:Education
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