Litcius/Paper detail

Achieving off-grid refrigeration in remote areas: A solar-powered vapor compression refrigerator prototype with PCM integration

Angelo Maiorino, Fabio Petruzziello, Grilletto Arcangelo, Cilenti Claudio, Aprea Ciro

2024International Journal of Refrigeration15 citationsDOIOpen Access PDF

Abstract

• The refrigerator works in an off-grid configuration, and its indirect emissions are null. • Laboratory tests showed complete autonomy for several set-point temperatures for 24 h. • Implementing phase change Materials, outdoor tests showed autonomy for more days. • The use of PCMs can significantly reduce battery size and weight, improving the system's compactness. • The system is particularly suitable for areas with electrification deficiencies. The availability of vaccines, medicines, and perishable goods in remote or off-grid areas remains a formidable challenge. Integrating solar photovoltaic (PV) systems with refrigeration technology has emerged as a promising solution to address this critical need. This paper presents an autonomous solar-powered refrigerator prototype for off-grid refrigeration in remote areas utilising renewable energy. The system comprises a 160 W photovoltaic module, a 12/24 V DC compressor refrigerator, a lead-acid battery, and a Maximum Power Point Tracking (MPPT) controller. Its main feature is complete autonomy from the electricity grid, thanks to its standalone configuration. An experimental campaign evaluated the system's behaviour in the laboratory for 24 h at different set-point temperatures. A water-based Phase Change Material (PCM) was implemented to improve its autonomy in severe outdoor conditions. A further experimental campaign emulated the functioning of the prototype while managing the temperature of a sample solution whose melting temperature was equal to – 21 °C to ensure its liquid state during the tests. The target range for preserving the sample was defined at ± 1 °C. Several real conditions have been considered, such as higher cooling loads realised through 21 litres of additional thermal mass in the refrigerator and pick and place conditions for simulating the opening and closing of the door. The results demonstrate that the solar refrigerator prototype achieves complete autonomy from the electricity grid, paving the way for solutions for preserving perishable goods such as medicines and food in unelectrified areas.

Topics & Concepts

Refrigerator carRefrigerationVapor-compression refrigerationGridProcess engineeringCompression (physics)Environmental scienceComputer scienceRefrigerantMaterials scienceMechanical engineeringEngineeringGeologyGas compressorComposite materialGeodesyRefrigeration and Air Conditioning TechnologiesThermodynamic and Exergetic Analyses of Power and Cooling SystemsSmart Grid Energy Management