• DocumentCode
    2385544
  • Title

    Incremental step reference governor for load conditioning of hybrid Fuel Cell and Gas Turbine power plants

  • Author

    Tsourapas, Vasilis ; Sun, Jing ; Stefanopoulou, Anna

  • Author_Institution
    Innovation Center, Eaton Corp., Southfield, MI
  • fYear
    2008
  • fDate
    11-13 June 2008
  • Firstpage
    2184
  • Lastpage
    2189
  • Abstract
    A hybrid solid oxide fuel cell and gas turbine (SOFC/GT) system exploits the complementary features of the two power plants, where the GT recuperates the energy in the SOFC exhaust stream and thereby boosting the overall system efficiency. Through model based transient analysis, however, it is shown that the intricate coupling dynamics make the transient load following very challenging. Power shutdown has been observed when the load is changed abruptly. In this work, a novel closed-loop reference governor controller is proposed to mitigate the shutdown phenomenon. The reference governor utilizes the region of attraction of a reduced order SOFC/GT model to determine the feasibility of applying an incremental step change, subject to the constraint of no system shutdown. It is shown that with a moderate computational cost, the speed of the hybrid power system response can be improved significantly compared to the fastest conventional load filter.
  • Keywords
    closed loop systems; fuel cell power plants; gas turbine power stations; hybrid power systems; load regulation; power station control; power system transients; solid oxide fuel cells; transient analysis; closed-loop reference governor controller; coupling dynamics; gas turbine power plant; hybrid power system response; hybrid solid oxide fuel cell system; incremental step reference governor controller; load conditioning; model based transient analysis; power shutdown mitigation; Boosting; Computational efficiency; Fuel cells; Hybrid power systems; Power generation; Power system modeling; Power system transients; Solids; Transient analysis; Turbines; SOFC; dynamics; feedback control; fuel cells; hybrid; modeling;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    American Control Conference, 2008
  • Conference_Location
    Seattle, WA
  • ISSN
    0743-1619
  • Print_ISBN
    978-1-4244-2078-0
  • Electronic_ISBN
    0743-1619
  • Type

    conf

  • DOI
    10.1109/ACC.2008.4586816
  • Filename
    4586816