Title :
Flatness based control of a dual active bridge converter for a fuel cell application
Author :
Phattanasak, M. ; Kaewmanee, W. ; Thounthong, P. ; Sethakul, P. ; Martin, Jean-Philippe ; Pierfederici, S. ; Davat, B.
Author_Institution :
Dept. of TE, KMUTNB, Bangkok, Thailand
Abstract :
Based on the properties of flatness system, this paper proposes a nonlinear control for a dual active bridge converter for fuel cell applications. This converter is connected to fuel cell via a diode and an LC low-pass filter. The constraint of fuel cell like the maximum power and current slope are taken into account by means of the control of the energy stored in the filter capacitor corresponding to the fuel cell voltage obtained from its static characteristic. The diode and parasitic resistances are modeled as a series resistance connected to the fuel cell and its value is estimated and is used in the control algorithm. The effectiveness of the proposed system is demonstrated via experimental results.
Keywords :
bridge circuits; power capacitors; power convertors; power generation control; power semiconductor diodes; proton exchange membrane fuel cells; voltage control; LC low-pass filter; PEMFC; current slope; diode; dual active bridge converter; energy control; filter capacitor; flatness based control; flatness system; fuel cell voltage; maximum power; nonlinear control; parasitic resistances; proton exchange membrane fuel cell application; series resistance; static characteristic; Bridge circuits; Capacitors; Fuel cells; Inductance; Resistance; Trajectory; Voltage control; dual active bridge; flatness system; fuel cell;
Conference_Titel :
Industrial Electronics Society, IECON 2013 - 39th Annual Conference of the IEEE
Conference_Location :
Vienna
DOI :
10.1109/IECON.2013.6699233
