Experimental Validation of a Novel CO<sub>2</sub> Refrigeration System for Cold Storage: Achieving Energy Efficiency and Carbon Emission Reductions

Experimental Validation of a Novel CO<sub>2</sub> Refrigeration System for Cold Storage: Achieving Energy Efficiency and Carbon Emission Reductions

To address the high energy consumption and carbon emissions associated with cold storage operations, a novel refrigeration system is proposed, which utilizes the natural refrigerant CO<sub>2</sub> and integrates an innovative control strategy. Experimental validations were conducted in C...

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Bibliographic Details
Main Authors: Yi-Zhou Wang, Yu-Wei Fan, Xiao-Long Li, Jian-Guo Yang, Xin-Rong Zhang
Format: Article
Language:English
Published: MDPI AG 2025-02-01
Series:Energies
Subjects:
cold storage
cold chain
carbon dioxide
environmental protection
energy conservation
Online Access:https://www.mdpi.com/1996-1073/18/5/1129
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Summary:To address the high energy consumption and carbon emissions associated with cold storage operations, a novel refrigeration system is proposed, which utilizes the natural refrigerant CO<sub>2</sub> and integrates an innovative control strategy. Experimental validations were conducted in Changsha (a subtropical monsoon climate) and Changchun (a continental monsoon climate), which are two regions representing typical climatic zones in China, to assess the system’s energy-saving potential, temperature stability, and environmental impacts with the total equivalent warming impact and life cycle carbon performance methods. For Changchun, the total equivalent warming impact reached 78.3 kg CO<sub>2e</sub>/kg, reflecting reductions of 99.5% in direct emissions and 58.6% in indirect emissions compared with R410A systems, as mentioned in the reference. The life cycle carbon performance was reduced by 85.1% and 72.2% compared with the two experiment cases, with indirect emissions from energy consumption comprising the largest share. The system maintained exceptional temperature stability, with vertical-layer variations remaining under 1 °C. These findings demonstrate this system’s adaptability to achieve energy and emission reductions across diverse climates, providing a sustainable framework for future cold storage design aligned with global carbon neutrality goals.
ISSN:1996-1073

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