Recent Progress in Battery Models for Hybrid Wind Power Systems

    Research output: Contribution to conferencePaper

    Abstract

    This paper summarizes the latest University of Massachusetts work on the analytical modeling and experimental testing of battery component models for hybrid power systems. An extension of the Kinetic Battery Model (KiBaM), developed at the University of Massachusetts is presented. The original model was based on a combination of phenomenological and physical considerations. As described in thispaper, the modified KiBaM can now model the sharp increase in voltage near the end of charging, and the sharp drop in voltage when the battery is nearly empty. This model may readily be coupled with a DC load or charging source (such as a DC wind turbine or photovoltaic panels) to determine the corresponding DC bus voltage. For example, it is now an integral part of the DC bus section of theUniversity of Massachusetts' HYBRID simulation models. The paper describes the development of the extensions to the KiBaM model and the method of determining the constants from test data. On the experimental/applications side, it includes an illustration of how the constants are obtained from representative data (using a specially developed testing apparatus), and an example of how the model canbe used.
    Original languageAmerican English
    Pages415-424
    Number of pages10
    StatePublished - 1995
    EventWindpower '95: Annual Conference and Exhibition of the American Wind Energy Association - Washington, D.C.
    Duration: 26 Mar 199530 Mar 1995

    Conference

    ConferenceWindpower '95: Annual Conference and Exhibition of the American Wind Energy Association
    CityWashington, D.C.
    Period26/03/9530/03/95

    Bibliographical note

    Work performed by the University of Massachusetts, Amherst, Massachusetts

    NREL Publication Number

    • NREL/CP-21801

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