Performance investigation of linear control and nonlinear control based-on flatness approach for a DC link stabilized fuel cell/supercapacitor hybrid power plant

2011 International Conference on Clean Electrical Power (ICCEP) Pub Date : 2011-06-14 DOI:10.1109/ICCEP.2011.6036354

P. Thounthong, S. Sikkabut, P. Sethakul, M. Hinaje, S. Rael, B. Davat

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引用次数: 1

Abstract

In this paper, the control approaches of linear proportional-integral (PI) and nonlinear flatness-based estimation for dc link stabilization for fuel cell/supercapacitor hybrid power plants are compared. For high power applications, 4-phase parallel boost converters are implemented with a switching interleaving technique for a fuel cell (FC) converter, and 4-phase parallel bidirectional converters are implemented with a switching interleaving technique for a supercapacitor converter in the laboratory. As controls, mathematical models (reduced-order models) of the FC converter and the supercapacitor converter are given. The prototype small-scale power plant studied is composed of a PEMFC system (the Nexa Ballard FC power generator: 1.2 kW, 46 A) and a supercapacitor module (100 F, 32 V, based on Maxwell Technologies Company). Simulation (by Matlab/Simulink) and experimental results demonstrate that the nonlinear differential flatness-based control provides improved dc bus stabilization relative to a classical linear PI control method.

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基于平坦度方法的直流链路稳定燃料电池/超级电容器混合电厂线性控制和非线性控制性能研究

本文比较了基于线性比例积分(PI)和非线性平坦度估计的燃料电池/超级电容器混合电厂直流链路稳定控制方法。对于高功率应用，采用燃料电池(FC)转换器的开关交错技术实现了4相并联升压转换器，并且在实验室中采用超级电容器转换器的开关交错技术实现了4相并联双向转换器。作为控制，给出了FC变换器和超级电容变换器的数学模型(降阶模型)。所研究的原型小型发电厂由PEMFC系统(Nexa Ballard FC发电机:1.2 kW, 46 a)和超级电容器模块(100 F, 32 V，基于Maxwell Technologies Company)组成。仿真(Matlab/Simulink)和实验结果表明，与经典线性PI控制方法相比，基于非线性差分平坦度的控制具有更好的直流母线稳定性。

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2011 International Conference on Clean Electrical Power (ICCEP)

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