Phase Change Energy Storage For Solar Dynamic Power Systems F. P. CHIARAMONTE AND J. D. TAYLOR + SUMMARY This paper presents the results of a transient computer simulation that was developed to study phase change energy storage techniques for Space Station Freedom (SSF) solar dynamic (SD) power systems. Such SD systems may be used in future growth SSF configurations. Two solar dynamic options are considered in this paper: Brayton and Rankine. Model elements consist of a single node receiver and concentrator, and takes into account overall heat engine efficiency and power distribution characteristics. The simulation not only computes the energy stored in the receiver phase change material (PCM), but also the amount of the PCM required for various combinations of load demands and power system mission constraints. For a solar dynamic power system in low earth orbit, the amount of stored PCM energy is calculated by balancing the solar energy input and the energy consumed by the loads corrected by an overall system efficiency. The model assumes an average 75 kW SD power system load profile which is connected to user loads via dedicated power distribution channels. The model then calculates the stored energy in the receiver and subsequently estimates the quantity of PCM necessary to meet peaking and contingency requirements. The model can also be used to conduct trade studies on the performance of SD power systems using different storage materials. Nomenclature Cs specific heat of the solid kWe kilowatt, electric m mass of the phase change material N number of some parameter Q energy power T temperature t time At time interval u specific internal energy X liquid fraction AX change in the liquid fraction r] efficiency k latent heat of fusion + NASA Lewis Research Center, 21000 Brookpark Rd., Cleveland, OH 44135 USA.
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