Performance Assessment of Three Latent Heat Storage Designs for a Solar Hot Water Tank

Zakri, Waleed; Mellouli, Sofiene; Fageehi, Yahya Ali

doi:10.3390/su15010640

Cited by 3 publications

(1 citation statement)

References 22 publications

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“…Several numerical and experimental studies dealt with the analysis of latent heat storage systems for various solar thermal applications. The great portion of published studies were conducted for residential hot water end-use, such as the work of Zakri et al [32], Bazri et al [33], Yari et al [34], and Chopra et al [35]. Also, some existing works focused on the applicability of latent heat storage in greenhouses [36] and solar power plants for electricity generation [37].…”

Section: Introductionmentioning

confidence: 99%

Latent Thermal Energy Storage for Solar Industrial Drying Applications

Allouhi

2023

Sustainability

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Solar heat is an attractive alternative in industrial processes. However, the intermittent and stochastic nature of solar energy necessitates the use of heat storage systems to bridge the gap between heat production and demand. This study introduces a validated numerical analysis approach to investigate the performance of latent storage tanks filled with spherical phase-change materials. A 1D thermal model is developed to describe the charging processes of adipic acid as PCM. The study examines the performance characteristics of latent heat storage in terms of stored energy and duration through parametric investigations. For mass flow rates ranging from 600 to 1000 kg/h, storage durations were found to vary from 440 to 582 min. The storage duration decreased significantly from approximately 1150 min at a charging temperature of 160 °C to 470 min at a charging temperature of 240 °C. The bed porosity affected the storage process, with a porosity of 0.5 achieving a thermal energy storage of around 344 MJ but requiring a longer charging time of about 610 min. Higher heating rates allowed for lower storage durations, with storage durations of approximately 460 min for a heating rate of 3 °C/min, compared to 660 min, for a heating rate of 0.5 °C/min.

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Section: Introductionmentioning

confidence: 99%

Latent Thermal Energy Storage for Solar Industrial Drying Applications

Allouhi

2023

Sustainability

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Thermodynamic analysis of Powell-Eyring-blood hybrid nanofluid through vertical stretching sheet with interface slip and melting heat

Hahim,

Bouzgarrou,

Rehman

et al. 2023

Results in Engineering

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Integrating Solar Heaters with Building Energy Systems : A Simulation Study

Dr. Vipul M Goti

2023

IJSRCSEIT

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This paper looks at the topic of high-tech solar water heating systems being incorporated into existing building energy infrastructure. Hybrid systems that use solar water heating in conjunction with other renewable energy sources are also discussed, as are technical developments in collector designs, the use of cutting-edge control and monitoring systems, and the like. Reduced carbon emissions and optimized resource utilization are only two of the environmental advantages highlighted in the report. It also emphasizes the need of precise system sizing and regional life cycle assessments (LCAs) in achieving maximum energy efficiency. The paper highlights knowledge gaps in the areas of performance analysis, localized environmental impact studies, integration difficulties, and economic assessments. By filling up these spaces, it hopes to promote more eco-friendly and economical construction methods. Sustainable construction, energy savings, less of an influence on the environment, and new innovations in solar water heating are some of the terms that come to mind.

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Performance Assessment of Three Latent Heat Storage Designs for a Solar Hot Water Tank

Cited by 3 publications

References 22 publications

Latent Thermal Energy Storage for Solar Industrial Drying Applications

Latent Thermal Energy Storage for Solar Industrial Drying Applications

Thermodynamic analysis of Powell-Eyring-blood hybrid nanofluid through vertical stretching sheet with interface slip and melting heat

Integrating Solar Heaters with Building Energy Systems : A Simulation Study

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