Performance analysis and exergo-economic optimization of a solar-driven adjustable tri-generation system

[Display omitted] •Solar-driven adjustable tri-generation system for building heating and cooling.•Energy, exergy, and adjustable performance in variable conditions is explored.•Energy levels and investment recovery are considered in exergo-economic optimization.•Optimal solar heat allocation ratio...

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Bibliographic Details
Published in:Energy conversion and management 2021-04, Vol.233, p.113873, Article 113873
Main Authors: Chen, Yuzhu, Zhao, Dandan, Xu, Jinzhao, Wang, Jun, Lund, Peter D.
Format: Article
Language:English
Subjects:
Adjustable heat to electricity ratio
Air conditioning
Combined cooling heating and power
Cooling
Cost recovery
Economic analysis
Electricity
Energy
Energy conversion efficiency
Energy efficiency
Energy levels
Exergy
Heat
Heat recovery
Hybrid systems
Investment recovery coefficient
Irradiance
Modified exergo-economic method
Optimization
Rankine cycle
Sensitivity analysis
Service life
Solar collectors
Solar energy
Solar heating
System effectiveness
Thermal analysis
Thermal energy
Thermal simulation
Thermodynamic performance
Thermodynamics
Working conditions
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Summary:[Display omitted] •Solar-driven adjustable tri-generation system for building heating and cooling.•Energy, exergy, and adjustable performance in variable conditions is explored.•Energy levels and investment recovery are considered in exergo-economic optimization.•Optimal solar heat allocation ratio is 0.86 with a minimum exergy cost of 0.83 $/kWh. Solar-driven trigeneration system producing cooling, heating and power (CCHP) is an effective way to increase the utilization rate of solar energy. Here, a novel adjustable CCHP system is proposed by employing parabolic trough collectors (PTC), Organic Rankine Cycle (ORC), absorption chiller (AC) and electrical chiller/heater (EC/H) to meet building cooling and heating demand. A full thermal simulation model of the system is constructed and validated. The thermal and adjustable performance of a hybrid system with variable solar irradiance and solar thermal allocation ratio is explored by carrying out energy, exergy and heat to electricity ratio. Considering the energy levels of products and investment recovery coefficient of units at the end of service life, a modified exergo-economic method is utilized to optimize the thermal allocation ratio among the system components based on a specific working condition converted from yearly building parameters. The thermal analysis shows that except for the energy efficiency with increasing allocation ratio, the irradiance and allocation ratio have positive impacts on energy, and exergy performance, and the proposed system has a higher adjustable performance with a higher heat to electricity ratio than other studies. The exergo-economic optimization shows that 86% of the solar heat is fed to the ORC-unit at optimum point with an unit exergy cost of 0.826 $/kWh. Compared to conventional exergo-economic method, the specific costs of the products are lower owing to the function of cost recovery coefficient. This research illustrates a new way to effectively utilize solar thermal energy for district energy systems.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.113873