• Title of article

    A unified model of combined energy systems with different cycle modes and its optimum performance characteristics

  • Author/Authors

    Yue Zhang، نويسنده , , Weiqiang Hu، نويسنده , , Congjie Ou، نويسنده , , Jincan Chen، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2009
  • Pages
    7
  • From page
    1766
  • To page
    1772
  • Abstract
    A unified model is presented for a class of combined energy systems, in which the systems mainly consist of a heat engine, a combustor and a counter-flow heat exchanger and the heat engine in the systems may have different thermodynamic cycle modes such as the Brayton cycle, Carnot cycle, Stirling cycle, Ericsson cycle, and so on. Not only the irreversibilities of the heat leak and finite-rate heat transfer but also the different cycle modes of the heat engine are considered in the model. On the basis of Newton’s law, expressions for the overall efficiency and power output of the combined energy system with an irreversible Brayton cycle are derived. The maximum overall efficiency and power output and other relevant parameters are calculated. The general characteristic curves of the system are presented for some given parameters. Several interesting cases are discussed in detail. The results obtained here are very general and significant and can be used to discuss the optimal performance characteristics of a class of combined energy systems with different cycle modes. Moreover, it is significant to point out that not only the important conclusions obtained in Bejan’s first combustor model and Peterson’s general combustion driven model but also the optimal performance of a class of solar-driven heat engine systems can be directly derived from the present paper under some limit conditions.
  • Keywords
    Performance characteristic , Optimal analysis , Combined energy system , Irreversible loss
  • Journal title
    Applied Thermal Engineering
  • Serial Year
    2009
  • Journal title
    Applied Thermal Engineering
  • Record number

    1041979