Analysis of an optimal resorption cogeneration using mass and heat recovery processes

Yiji Lu*, Yaodong Wang, Huashan Bao, Ye Yuan, Liwei Wang, Anthony Paul Roskilly

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

38 Citations (Scopus)


This paper presents an optimised resorption cogeneration using mass and heat recovery to improve the performance of a novel resorption cogeneration fist proposed by Wang et al. This system combines ammonia-resorption technology and expansion machine into one loop, which is able to generate refrigeration and electricity from low-grade heat sources such as solar energy and industrial waste heat. Two sets of resorption cycle are designed to overcome the intermittent performance of the chemisorption and produce continuous/simultaneous refrigeration and electricity. In this paper, twelve resorption working pairs of salt complex candidates are analysed by the first law analysis using Engineering Equation Solver (EES). The optimal resorption working pairs from the twelve candidates under the driven temperature from 100°C to 300°C are identified. By applying heat/mass recovery, the coefficient of performance (COP) improvement is increased by 38% when the high temperature salt (HTS) is NiCl2 and by 35% when the HTS is MnCl2. On the other hand, the energy efficiency of electricity has also been improved from 8% to 12% with the help of heat/mass recovery. The second law analysis has also been applied to investigate the exergy utilisation and identify the key components/processes. The highest second law efficiency is achieved as high as 41% by the resorption working pair BaCl2-MnCl2 under the heat source temperature at 110°C.

Original languageEnglish
Pages (from-to)892-901
Number of pages10
JournalApplied Energy
Publication statusPublished - 15 Dec 2015


  • First law analysis
  • Heat and mass recovery
  • Refrigeration and electricity
  • Resorption cogeneration
  • Resorption working pair
  • Second law analysis

ASJC Scopus subject areas

  • Building and Construction
  • Energy(all)
  • Mechanical Engineering
  • Management, Monitoring, Policy and Law


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