A novel output power control ofwireless powering kitchen appliance system with free-positioning feature
Journal article
Authors/Editors
Strategic Research Themes
No matching items found.
Publication Details
Author list: Nutwong S., Sangswang A., Naetiladdanon S., Mujjalinvimut E.
Publisher: MDPI
Publication year: 2018
Journal: Energies (1996-1073)
Volume number: 11
Issue number: 7
ISSN: 1996-1073
eISSN: 1996-1073
Languages: English-Great Britain (EN-GB)
View in Web of Science | View on publisher site | View citing articles in Web of Science
Abstract
To achieve a free-positioning wireless power transfer (WPT) system, the output power must be regulated throughout the operation. This paper presents a novel output power control of a WPT system, based on the model predictive control (MPC). The output power is predicted by utilizing the system's mathematical model. The optimal duty cycle for a desired output power is obtained through the minimization of the objective function, which is simple and easy to implement, with no need for gain tuning. The proposed controller is implemented on the primary side, without any measurement or communication devices on the secondary side. This reduces the cost, size, and complexity of the WPT system. The load resistance and mutual inductance identification method is also introduced. It is based on the reflected impedance knowledge, where only the information of primary current is required. Experimental results of the output power step response show better performance compared with conventional Proportional-Integral (PI) control. The proposed controller is experimentally validated on a 200 W kettle. The output power can be kept constant at 200 W while the kettle is laterally moved. With the proposed controller, the kettle can be placed freely up to 7 cm from the align position, which is 63.64% of the primary coil's outer radius. ฉ 2018 by the authors. Licensee MDPI, Basel, Switzerland.
Keywords
free-positioning, output power regulation, parameters identification, Primary-side control, reflected impedance, wireless power transfer
Contact Information