A Feedback Linearization Control Scheme for the Integration of Wind Energy Conversion Systems Into Distribution Grids

This paper focuses on the development of a control strategy for integration of wind energy conversion systems (WECS) into the electrical distribution networks with particular attention to the combined provision of energy and ancillary services. Typically, a WECS is composed by a variable speed wind turbine coupled with a direct driven permanent magnet (DDPM) synchronous generator. This configuration offers a considerable flexibility in design and operation of the power unit, as its output is delivered to the grid through a fully controlled frequency converter. Here, a new control scheme to regulate electrical and mechanical quantities of such generation unit is proposed, aimed both at reaching optimal performances in terms of power delivered to the grid and at providing the voltage support ancillary service at the point of common coupling. The control scheme is derived resorting to the feedback linearization (FBL) technique, which allows both decoupling and linearization of a non linear multiple input multiple output system. Several numerical simulations are then performed in order to show how the flexibility of the DDPM wind generator can be fully exploited, thanks to the use of the FBL approach, which assures independent control of each variable and significant simplifications in controller synthesis and system operation, thus making it easier to integrate WECS into modern day smart grids.

[1]  Weiping Li,et al.  Applied Nonlinear Control , 1991 .

[2]  K. Tan,et al.  Optimum control strategies in energy conversion of PMSG wind turbine system without mechanical sensors , 2004, IEEE Transactions on Energy Conversion.

[3]  Tzann-Shin Lee,et al.  Input-output linearization and zero-dynamics control of three-phase AC/DC voltage-source converters , 2003 .

[4]  D. Kline,et al.  Benefits to the United States of Increasing Global Uptake of Clean Energy Technologies , 2010 .

[5]  Federico Delfino,et al.  Integration of large-size photovoltaic systems into the distribution grids: a p-q chart approach to assess reactive support capability , 2010 .

[6]  F. M. Hughes,et al.  Fault ride through of fully rated converter wind turbines with AC and DC transmission systems , 2009 .

[7]  M. Kleimaier Grid Integration of Wind Generation , 2009, 2009 CIGRE/IEEE PES Joint Symposium Integration of Wide-Scale Renewable Resources Into the Power Delivery System.

[8]  Anjan Bose,et al.  Stability Simulation Of Wind Turbine Systems , 1983, IEEE Transactions on Power Apparatus and Systems.

[9]  G. Joos Wind turbine generator low voltage ride through requirements and solutions , 2008, 2008 IEEE Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century.

[10]  Sistema politico,et al.  Office of Energy Efficiency and Renewable Energy , 2020, Federal Regulatory Guide.

[11]  M. G. Molina,et al.  Dynamic modeling of wind farms with variable-speed direct-driven PMSG wind turbines , 2010, 2010 IEEE/PES Transmission and Distribution Conference and Exposition: Latin America (T&D-LA).