Thermodynamic analysis of a tri-generation system driven by biomass direct chemical looping combustion process

Thermodynamic analysis of a tri-generation system driven by biomass direct chemical looping combustion process

•A tri-generation system driven by biomass direct chemical looping combustion process is proposed for the first time;•Thorough thermodynamic analysis of the proposed tri-generation system is conducted;•High energy and exergy efficiencies of 90.92% and 33.82%, respectively are achieved. Chemical loop...

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Bibliographic Details
Published in:Energy conversion and management Vol. 244; p. 114517
Main Authors: Sun, Zhuang, Aziz, Muhammad
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 15-09-2021
Elsevier Science Ltd
Subjects:
Absorption
Accounting
Biomass
Biomass burning
Carbon dioxide
Carbon sequestration
Combustion
Competitiveness
Cooling
Direct chemical looping combustion
Energy efficiency
Exergy
Exergy efficiency
Fluidized bed combustion
Gas turbines
Heat exchangers
Nuclear fuels
Rankine cycle
Reactors
Sensitivity analysis
Synthesis gas
Thermodynamic analysis
Thermodynamics
Tractors
Tri-generation
Turbines
Thermodynamic analysis
Energy efficiency
Exergy efficiency
Direct chemical looping combustion
Tri-generation
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Summary:•A tri-generation system driven by biomass direct chemical looping combustion process is proposed for the first time;•Thorough thermodynamic analysis of the proposed tri-generation system is conducted;•High energy and exergy efficiencies of 90.92% and 33.82%, respectively are achieved. Chemical looping process (CLP) is a promising technology for in-situ CO2 capture without energy penalty. Direct CLP has more compact structure, favorable economic competitiveness, and larger reduction of exergy loss compared to syngas CLP. In this work, a novel biomass direct chemical looping combustion (CLC) driven tri-generation system for the production of cooling, heating, and power is proposed. The proposed system contains a direct CLC section as the prime mover, two gas turbines and an organic Rankine cycle for power generation, an absorption chiller for cooling production, and two heat exchangers to generate heat. First, a thorough thermodynamic analysis is implemented to assess the energy and exergy efficiencies of the proposed system under evaluated design conditions, as well as identify the exergy loss distribution. Second, Sensitivity analysis is conducted to investigate the effects of major operating parameters on the system performances. Third, the performances of the proposed system are compared to syngas CLC based tri-generation system. Thermodynamic analysis results show that the proposed system has high energy efficiency of 90.92% and exergy efficiency of 33.82%. The largest exergy loss takes place in the air reactor, accounting for 34.42% of total exergy loss, followed by fuel reactor and absorption chiller, which are 30.09% and 15.37%, respectively. Besides, the proposed system has better thermodynamic performances than syngas CLC driven tri-generation, whose energy and exergy efficiencies are 69% and 23.4%, respectively.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.114517