Litcius/Paper detail

Energy, exergy, and economic analysis of indirect solar dryer integrated phase change material cans

Mohammed Alktranee, Qudama Al-Yasiri, Karrar Saeed Mohammed, Müslüm Arıcı, Márta Szabó, Péter Bencs

2025Energy Conversion and Management X12 citationsDOIOpen Access PDF

Abstract

• A solar dryer enhanced using PCM cans is investigated experimentally. • The energy, exergy, and economic aspects of the systems is analysed for 1 and 2 kg of PCM to dry melon slices. • Useful heat gain and thermal efficiency were maximized by up to 9.5% and 6.8%, respectively. • Exergy analysis indicated maximum exergy efficiency, and sustainability index of 20% and 46%, respectively. • Integrating PCM has reduced the dryer’s energy payback period by 33.7% to 35.1%. The efficiency of solar dryers fluctuates as the solar radiation declines, influencing the removed water content from products. Therefore, continuous heat delivery with a stable temperature range for a longer time using energy storage materials is an efficient way to enhance the drying process from energy and exergy prospects. To this aim, a solar dryer integrated with phase change material (PCM) was designed and examined in harsh weather conditions. The solar dryer performance with 1 and 2 kg of PCM (equipped in 6 and 12 cans, respectively) was analyzed against an identical reference dryer assessing numerous energy, exergy, and economic parameters. Research outcomes revealed that PCM cans have sustained the drying process, stabilized drying temperature and functioned as an extra heat source during the daytime. Furthermore, the modified solar dryer achieved an average moisture content removal of 86.5 % and 89.7 % by employing 6 and 12 PCM cans, compared to 82.5 % in the reference dryer. Energy analysis displayed that the useful heat gain was maximized by up to 3.9 % and 9.5 % integrating 6 and 12 PCM cans, respectively. Moreover, the thermal efficiency achieved by the modified dryers was about 2.5 % and 6.8 %, respectively. Exergy analysis indicated remarkable exergy gain, exergy efficiency, and sustainability index for the solar dryer modified with 12 PCM cans, achieving a maximum of 593 W, 20 %, and 46 %. Economic analysis exhibited that the solar dryer energy payback period with 6 and 12 PCM cans was shorter than that of the reference dryer by 33.7 % and 35.1 %, respectively.

Topics & Concepts

ExergyPhase changeSolar dryerEconomic analysisPhase-change materialSolar energyEnergy analysisEnvironmental scienceProcess engineeringThermodynamicsEnergy (signal processing)Architectural engineeringEngineering physicsEconomicsEngineeringPhysicsMathematicsAgricultural economicsStatisticsElectrical engineeringPhase Change Materials ResearchRadiative Heat Transfer StudiesSolar Thermal and Photovoltaic Systems