Numerical Investigation of Thermal Energy Storage Systems for Collective Heating of Buildings

Ali, Emad; Ajbar, Abdelhamid; Lamrani, Bilal

doi:10.3390/buildings14010141

Cited by 2 publications

(1 citation statement)

References 37 publications

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“…According to the results, charging efficiency is better when the height ratio of high and low melting point PCM layers is 12.05% and 87.95%, respectively [4]. The cascade PCM arrangement offers a balanced solution, which guarantees high HTF outlet temperatures, stable and extended thermal energy generation, and enhanced energy efficiency [5]. For a commercial-scale upholstered bed, the thermal performance of durable ceramics at elevated temperatures (1000°C) is analyzed using a CFD model.…”

Section: Nomenclaturementioning

confidence: 99%

Numerical and parametric study of the thermal performance of a latent storage unit

Sebbar,

Labtira

2024

Preprint

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Latent heat storage is an advanced technology with advantages for heating and cooling systems, including load displacement, flexibility, and energy savings. By accumulating thermal energy efficiently during low-demand periods and using it during high-demand periods. This reduces environmental impact, and financial savings, and increases system reliability. This work aims to study numerically a latent heat storage system. This system consists of a tank filled with a phase-change material (PCM); the tank is crossed by a heat transfer fluid to charge the PCM with thermal energy. this process follows the evolution of the PCM temperature and the tank outlet temperature during the charging period. A thorough parametric study analyzes the thermal and dynamic performance of the system and studies the effect of several parameters, including tank height, HTF mass flow rate, PCM layer thickness, and the amount of energy stored during charge. The system was modeled using computational fluid dynamics (CFD) to simulate PCM phase change phenomena. Validation of the numerical model showed excellent agreement with experimental results. It was observed that a higher mass flow rate leads to a shorter storage time and lower stored energy, with values of 19.2563 kWh for a flow rate of 0.6 kg/s and 20.1642 kWh for a flow rate of 0.4 kg/s.

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Section: Nomenclaturementioning

confidence: 99%

Numerical and parametric study of the thermal performance of a latent storage unit

Sebbar,

Labtira

2024

Preprint

View full text Add to dashboard Cite

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Assessment of the Optimal Energy Generation and Storage Systems to Feed a Districting Heating Network

Pompei,

Nardecchia,

Miliozzi

et al. 2024

Buildings

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Employing sustainable energy systems is a must fact of the current years. Urban districts can lead the decarbonization process of cities to allow the development of decentralization energy systems such as district heating. On the other hand, the exergy analysis combined with energy evaluation can be a suitable way to investigate the efficiency and flexibility of an energy system. In this framework, this study investigates the optimal energy and storage systems to feed a district heating network. Four types of energy systems were analyzed, such as boilers, cogeneration plants, solar systems and the combination of them. The size of the thermal energy storage of the network is investigated in terms of volume and temperature. In parallel, the exergy efficiency of all the systems was calculated. The optimal heating system configuration to feed the studied district heating is the cogeneration plant with solar collectors, according to both the temperature trend fluctuation and exergy efficiency of the system. Moreover, the employment of thermal energy storage is crucial to face the renewable energy source’s variability. As a further investigation, additional exergy indicators can be studied to underline the performances of such an decentralized energy system to increase the quality of the built environment.

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Numerical Investigation of Thermal Energy Storage Systems for Collective Heating of Buildings

Cited by 2 publications

References 37 publications

Numerical and parametric study of the thermal performance of a latent storage unit

Numerical and parametric study of the thermal performance of a latent storage unit

Assessment of the Optimal Energy Generation and Storage Systems to Feed a Districting Heating Network

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