• DocumentCode
    646425
  • Title

    Suspension control strategy for a fully electrified vehicle

  • Author

    Tudon-Martinez, Juan C. ; Varrier, S. ; Morales-Menendez, Ruben ; Ramirez-Mendoza, Ricardo

  • Author_Institution
    Tecnol. de Monterrey, Monterrey, Mexico
  • fYear
    2013
  • fDate
    17-19 July 2013
  • Firstpage
    1469
  • Lastpage
    1474
  • Abstract
    The design of chassis for a truck considers a wide set of conditions in which load and unload are the most typical variety. For years, flat ride rules have been applied to achieve comfort, by providing tuning rules in the suspension as today. For an electric vehicle however, the weight distribution is different as a result of power train and batteries. A suspension control strategy is proposed in a full size pick-up truck using magneto-rheological dampers. As a first principle, the estimation of the frequency of the road profile allows the control of comfort and road holding in normal driving situations (straight roads). This strategy includes the coupling joints among the four-wheel stations of the truck and it allows the control of vertical forces in order to minimize the chassis vertical acceleration. A second principle, it uses the continuous measurement of the steering wheel to configure the four semi-active damping forces in order to reduce the wheel tramp, wheel hop, front-end dive, and other causes of vehicle instability under risk driving conditions. Simulation results in CarSim™ of a full prototype show that the suspension performance of the new fully electrified truck is better in comfort (reduction up to 60% in the chassis vertical acceleration) and handling (reduction around 5% in the vehicle slip angle) than the original truck (before its modification).
  • Keywords
    couplings; damping; electric vehicles; force control; magnetorheology; mechanical stability; power transmission (mechanical); road vehicles; shock absorbers; steering systems; suspensions (mechanical components); vehicle dynamics; vibration control; wheels; CarSim; batteries; chassis design; chassis vertical acceleration minimization; comfort control; continuous measurement; coupling joints; electric vehicle; four-wheel stations; frequency estimation; front-end dive; full size pick-up truck; fully electrified truck; magnetorheological dampers; normal driving situations; power train; risk driving conditions; road holding; road profile; semiactive damping forces; steering wheel; suspension control strategy; vehicle instability; vertical force control; weight distribution; wheel hop; wheel tramp; Damping; Monitoring; Roads; Shock absorbers; Stability analysis; Vehicles;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Control Conference (ECC), 2013 European
  • Conference_Location
    Zurich
  • Type

    conf

  • Filename
    6669835