Effects of Geometric Parameters and Heat-Transfer Fluid Injection Direction on Enhanced Phase-Change Energy Storage in Vertical Shell-and-Tube System

Guo, Zhanjun; Zhou, Wu; Liu, Sen; Kang, Zhangyang; Tan, Rufei

doi:10.3390/su151713062

Cited by 4 publications

(2 citation statements)

References 24 publications

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“…The observed trend closely aligns with a study by Zhanjun et al, 21 indicating that an increase in tube length results in reduced PCM thickness, facilitating natural convection within the PCM and increasing its melting point in relation to tube length, thus demonstrating a positive correlation.. Additionally, in another study conducted by Cáceres et al, 22 the melting time of the EPCM would increase exponentially over an increasing radius. This follows closely to what was obtained in Fig.…”

Section: Resultssupporting

confidence: 89%

Analysis of Melting Dynamics and Parametric Optimization in Encapsulated Phase Change Materials for Thermal Energy Storage

Sharif,

Walvekar,

Khalid

et al. 2024

ECS J. Solid State Sci. Technol.

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Phase change materials (PCMs) enable efficient thermal energy storage via latent heat absorption during phase transformation. Encapsulating PCMs enhances heat transfer while preventing material leakage. This study utilizes computational fluid dynamics (CFD) to numerically investigate melting dynamics in encapsulated PCMs, elucidating key design parameters influencing performance. Spherical encapsulations containing paraffin wax and hydrated salt PCMs were simulated using CFD. By systematically varying the encapsulation radius from 16-58 mm and shell thickness from 18-72 mm, we found that increasing radius exponentially raises melting time due to declining surface area to volume ratios. This indicates subdividing PCM volumes into smaller capsules can accelerate heat transfer. Furthermore, an optimal 54-55 mm stainless steel shell thickness was identified, beyond which efficiency diminishes due to reducing surface area effects. Comparing PCM types revealed the salt hydrate doubled latent heat storage density to 9.032 $/kWh versus paraffin, showcasing the importance of PCM selection. These CFD simulations deliver crucial insights into tailoring size, encapsulation, and PCM parameters to optimize encapsulated systems for sustainable thermal energy storage.

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Section: Resultssupporting

confidence: 89%

Analysis of Melting Dynamics and Parametric Optimization in Encapsulated Phase Change Materials for Thermal Energy Storage

Sharif,

Walvekar,

Khalid

et al. 2024

ECS J. Solid State Sci. Technol.

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show abstract

“…Thermal energy storage technology [7] involves changing the storage medium temperature through heating or cooling, and releasing its internal thermal energy when needed for building heating/cooling and industrial operations. Latent heat storage utilizes phase change materials (PCM) as the heat storage medium [8]. This technology has gained attention in recent years because of its advantages of high latent heat capacity, temperature stability, and minimal volume change [9,10].…”

Section: Introductionmentioning

confidence: 99%

Design and Research of Heat Storage Enhancement by Innovative Wave Fin in a Hot Water–Oil-Displacement System

Ning,

Huang,

et al. 2023

Sustainability

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Energy storage technology provides a new direction for the utilization of renewable and sustainability energy. The objective of this study is to introduce a novel, wavy, longitudinal fin design, which aims to improve heat transfer in the melting process of a Latent Heat Thermal Energy Storage (LHTES) unit. The main goal is to mitigate the negative effects caused by the refractory zone at the end of the melting phase. A two-dimensional numerical model of LHTES unit is established by using the enthalpy porosity method and verified by experimental data. Through the quantitative comparison between the traditional rectangular fin and the innovative wave fin, the influence of wave fin on the heat transfer mechanism in the heat storage process is revealed. The results show that the average heat storage rate of five and six wave fins is 3.70% and 12.98% higher than that of conventional rectangular fins, respectively, and the average temperature response of six wave fins is 17.78% higher than that of conventional rectangular fins. The addition of the wave fin weakens the negative effect of the refractory zone, but prolongs the heating time of the initial melting point.

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Application of microencapsulated phase change materials for controlling exothermic reactions

Shaddel Khalifelu,

Hamid,

Rahimi-Ahar

et al. 2024

Reviews in Chemical Engineering

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Thermal runaway is a frequent source of process safety issues, and the uncontrolled release of chemical energy puts reactors at risk. The design of the exothermic reactor faces challenges due to the selective sensitivity of the product to high temperatures and the need to increase the lifetime of the catalyst, optimize the product distribution, and improve the thermodynamic properties. Phase change material (PCM) encapsulation is recommended to reduce leakage, phase separation, and volume change problems. This work introduces encapsulated PCMs to improve reactor temperature control and minimize thermal runaway in exothermic processes. The warning temperature value setting effectively inhibits fugitive exothermic reactions and enhances heat transfer. When a sufficient quantity of encapsulated PCMs is input, the response speed will automatically accelerate. Spontaneous acceleration of the reaction rate due to thermal runaway of the reaction may be completely avoided by adding a sufficient amount of encapsulated PCM. Microencapsulation is used to control volume changes and inhibit thermal reactions. Preventive strategies include cooling, depressurization, safety release, emergency resources, and reaction containment. Encapsulated PCMs improve mechanical and thermal properties, surface-to-volume ratio, heat transfer surface, thermal capacity, and efficiency.

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Effects of Geometric Parameters and Heat-Transfer Fluid Injection Direction on Enhanced Phase-Change Energy Storage in Vertical Shell-and-Tube System

Cited by 4 publications

References 24 publications

Analysis of Melting Dynamics and Parametric Optimization in Encapsulated Phase Change Materials for Thermal Energy Storage

Analysis of Melting Dynamics and Parametric Optimization in Encapsulated Phase Change Materials for Thermal Energy Storage

Design and Research of Heat Storage Enhancement by Innovative Wave Fin in a Hot Water–Oil-Displacement System

Application of microencapsulated phase change materials for controlling exothermic reactions

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