Absorption power and cooling combined cycle with an aqueous salt solution as a working fluid and a technically feasible configuration

Vaclav Novotny, David J. Szucs, Jan Špale, Hung Yin Tsai, Michal Kolovratnik

Research output: Contribution to journalArticlepeer-review

8 Scopus citations

Abstract

Combined systems for power production and thermally activated cooling have a high potential for improving the efficiency and utilisation of thermal systems. In this regard, various configurations have been proposed and are comprehensively reviewed. They are primarily based on absorption systems and the implementation of multiple levels of complexity and flexibility. The configuration of the absorption power and cooling combined cycle proposed herein has wide commercial applicability owing to its simplicity. The configuration of the components is not new. However, the utilisation of aqueous salt solutions, the comparison with ammonia chiller and with absorption power cycles, the focus on parameters that are important for real-life applications, and the comparison of the performances for constant heat input and waste heat recovery are novel. The proposed cycle is also compared with a system based on the organic Rankine cycle and vapour compression cycle. An investigation of its performance proves that the system is suitable for a given range of boundary conditions from a thermodynamic standpoint, as well as in terms of system complexity and technical feasibility. New possibilities with regard to added power production have the potential to improve the economics and promote the use of absorption chiller systems.

Original languageEnglish
Article number3715
JournalEnergies
Volume14
Issue number12
DOIs
StatePublished - Jun 2 2021
Externally publishedYes

Keywords

  • Absorption cooling
  • Absorption cycle
  • Absorption power cycle
  • Combined power and cooling
  • Kalina cycle
  • LiBr
  • Salt solution

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