Integration of a mechanical and thermal compressor booster in combined absorption power and refrigeration cycles

This paper presents and discusses the performance improvement and operational flexibility of a Single-Stage Combined Absorption Power and Refrigeration Cycle (SSAPRC) with an integrated compression booster. The compression booster is placed between the absorber and the evaporator. A mechanical compr...

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Bibliographic Details
Published in:Energy (Oxford) 2017-09, Vol.135, p.327-341
Main Authors: Ayou, Dereje S., Bruno, Joan Carles, Coronas, Alberto
Format: Article
Language:English
Subjects:
Absorption
Absorption chiller
Adaptability
Biomass energy production
Boundary conditions
Compression
Compression ratio
Cycle ratio
Design parameters
Dual-function
Ejection
Energy consumption
Energy sources
Exergy
Flexibility
Integration
Power
Refrigeration
Renewable energy sources
Solar energy
Solar heating
Studies
Temperature
Temperature requirements
Thermal energy
Vapors
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Summary:This paper presents and discusses the performance improvement and operational flexibility of a Single-Stage Combined Absorption Power and Refrigeration Cycle (SSAPRC) with an integrated compression booster. The compression booster is placed between the absorber and the evaporator. A mechanical compressor and later a thermal compressor (vapor-ejector) are used as a compression booster. This added feature is very interesting for this type of cycle, because they generate power that could be used in the cycle itself to produce the compression needed to enhance the cycle’s performance. The energetic and exergetic performance of these new modified combined absorption cycles have been analyzed for typical thermal boundary conditions and design parameters. The integration of a mechanical compressor or a vapor ejector reduces the required driving temperature of the cycle, and when a certain split ratio is exceeded the system can work in dual-output mode producing power and cooling. The use of a vapor ejector further improved the net power output of the system. The proposed cycle configurations have an outstanding adaptability and flexibility to respond to the variation of heat source and heat rejection temperatures by adjusting the compression ratio. These cycles are therefore excellent candidates to provide simultaneous power and refrigeration, using renewable energy sources such as solar thermal energy, biomass or waste-derived fuels in polygeneration systems for remote locations or those with difficult access to the electrical grid. •Integration of a compressor booster in a combined absorption cycle.•Production of cooling and power even using a mechanical compressor.•Outstanding adaptability and flexibility to the variation of working conditions.•For the base case, the first-law and exergy efficiencies are 12.2% and 60.6%.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2017.06.148