| Title: | Design of Inverter for Hand Tools Wireless Charger |
| Other Titles: | Design of Inverter for Hand Tools Wireless Charger |
| Authors: | Cassier, Quentin |
| Advisor: | Zavřel Martin, Ing. |
| Referee: | Streit Luboš, Ing. Ph.D. |
| Issue Date: | 2019 |
| Publisher: | Západočeská univerzita v Plzni |
| Document type: | diplomová práce |
| URI: | http://hdl.handle.net/11025/37347 |
| Keywords: | induction charger;single-phase full bridge inverter;resonant transformer;silicon-carbide mosfet;high frequency switching;electromagnetic compatibility;wireless power transfer. |
| Keywords in different language: | induction charger;single-phase full bridge inverter;resonant transformer;silicon-carbide mosfet;high frequency switching;electromagnetic compatibility;wireless power transfer. |
| Abstract: | This paper goes through the design of an inverter for hand held tools wireless charger. The resulting device should be compact and able to recharge devices at up to 600W with a high efficiency. Such system could be used to recharge cordless power tools but could also be applied to most other battery powered device like laptops or drones. Such charger can also be useful in case of harsh environment which prohibit the use of connectors like in explosive or medical area. The first part of this paper focus on component choices to fulfil requirements such as space constraints, heat dissipation and electromagnetic compatibility. The second part is about printed circuit board layout and the issues encountered during the design. The third part cover the possibility of control and the programming of the inverter. And finally, the last part describes the realisation and testing of the inverter. |
| Abstract in different language: | This paper goes through the design of an inverter for hand held tools wireless charger. The resulting device should be compact and able to recharge devices at up to 600W with a high efficiency. Such system could be used to recharge cordless power tools but could also be applied to most other battery powered device like laptops or drones. Such charger can also be useful in case of harsh environment which prohibit the use of connectors like in explosive or medical area. The first part of this paper focus on component choices to fulfil requirements such as space constraints, heat dissipation and electromagnetic compatibility. The second part is about printed circuit board layout and the issues encountered during the design. The third part cover the possibility of control and the programming of the inverter. And finally, the last part describes the realisation and testing of the inverter. |
| Rights: | Plný text práce je přístupný bez omezení. |
| Appears in Collections: | Diplomové práce / Theses (KAE) |
Files in This Item:
| File | Description | Size | Format | |
|---|---|---|---|---|
| Q Cassier Thesis.pdf | Plný text práce | 2,63 MB | Adobe PDF | View/Open |
| 080158_oponent.pdf | Posudek oponenta práce | 879,01 kB | Adobe PDF | View/Open |
| 080158_vedouci.pdf | Posudek vedoucího práce | 887,96 kB | Adobe PDF | View/Open |
| 080158_hodnoceni.pdf | Průběh obhajoby práce | 75,74 kB | Adobe PDF | View/Open |
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