Energetic, exergetic and exergoeconomic assessment of transcritical CO2 reversible system combined with dedicated mechanical subcooling (DMS) for residential heating and cooling

•Transcritical CO2 reversible system with DMS is proposed for annual heating and cooling.•System performance is assessed from the perspective of energetic, exergetic and exergoeconomic.•Influences of terminal type, climate condition, and energy-saving potential are evaluated.•APF, AEE and exergoecon...

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Bibliographic Details
Published in:Energy conversion and management 2020-04, Vol.209, p.112594, Article 112594
Main Authors: Dai, Baomin, Zhao, Xiaoxuan, Liu, Shengchun, Yang, Qianru, Zhong, Dan, Hao, Yunying, Hao, Ying
Format: Article
Language:English
Subjects:
Air conditioning
Annual heating and cooling
Carbon dioxide
Climatic conditions
CO2
Coils
Cold regions
Cooling
Dedicated mechanical subcooling
Energetic and exergetic analysis
Energy conservation
Exergoeconomic analysis
Exergy
Heat exchangers
Heat pumps
Heating
Residential buildings
Reversible heat pump-air conditioning
Subsidies
Temperature gradients
Thermal insulation
Thermodynamics
Throttling
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Summary:•Transcritical CO2 reversible system with DMS is proposed for annual heating and cooling.•System performance is assessed from the perspective of energetic, exergetic and exergoeconomic.•Influences of terminal type, climate condition, and energy-saving potential are evaluated.•APF, AEE and exergoeconomic performance of CO2 system is significantly enhanced with DMS.•Effects of compressor price reduction and building thermal insulation on exergoeconomic performance are discussed. A transcritical CO2 reversible heat pump-air conditioning system combined with dedicated mechanical subcooling (DMS) is proposed as an annual heating and cooling solution. A common residential building is selected as a scenario to assess the system annual performance from the viewpoint of energetic, exergetic, and exergoeconomic, and compare with traditional CO2 system (BASE). The influences of terminal type, climate condition, and energy-saving potential are discussed. The results indicate the annual performance factor (APF) of CO2 system is significantly improved by up to 6.23 ~ 22.90%. APF generally increases with the latitude, and it achieves the highest value of 3.41 by using small temperature difference fan-coil unit (STD-FCU) as terminal. The annual exergy efficiency (AEE) is promoted by 7.25 ~ 24.79%, and the throttling irreversibility can be significantly reduced by adopting DMS. From the perspective of thermoeconomic, introducing DMS to CO2 system is cost effective. The total cost, including non-exergy-related investment and cost of exergy destruction, is reduced by 16.96% for heating and 4.52% for cooling. The annual exergoeconomic factor increases with the improvement of building energy-saving potential while decreases with the compressor price reduction. To widen the application of CO2 system, it is suggested that the price of CO2 compressor should be reduced, such as with the help of government subsidies. Furthermore, the thermal insulation performance of the residential building should also be improved, especially for the severe cold and cold regions.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2020.112594