Thermo-convective Study of a Shell and Tube Thermal Energy Storage Unit

Elmeriah, Abderrahmane; Nehari, Driss; Aichouni, Mohamed

doi:10.3311/ppme.10873

Cited by 6 publications

(9 citation statements)

References 10 publications

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“…To validate the solution method, the results of the numerical simulation are compared with the numerical results of Elmirah et al 20 and Kumar and Krishna 33 . According to Figures 5 and 6, the highest errors in the graphs of liquid fraction and the outlet temperature are equal to 5.5% and 0.8%, respectively.…”

Section: Model Description and Numerical Methodsmentioning

confidence: 99%

“…Also, tube radius is a more important parameter than thickness for better heat transfer. Elmirah et al 20 studied the heat transfer of the shell–tube thermal energy storage system considering the limited Reynolds number from 100 to 1500. They displayed that the length, diameter of the shell, and Reynolds number have a noticeable influence on the temperature of the outlet fluid, and the Reynolds number is also a highly impressive parameter that has a meaningful influence on the time and rate of freezing and melting of materials.…”

Section: Introductionmentioning

confidence: 99%

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Numerical investigation of the shell configuration effect on the melting of various phase change materials in the presence of porous medium and non‐Newtonian fluid

Azarbarzin

Javaherdeh

2023

Heat Trans

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By considering the ability of phase change materials (PCMs) in the storage of energy, the melting of four types PCMs including RT22, RT26, RT35, and RT41 in a heat exchanger is examined in this research. The impact of various shell cross‐sectional configurations on the complete melting time of materials, temperature changes, and liquid fraction throughout the melting process are presented. It is assumed that the main heat transfer fluid in the tube is non‐Newtonian and the tube is filled with a porous medium. The enthalpy porosity manner is applied for simulating the process of phase change and the heat natural convection and conduction cases are discussed. On the basis of the obtained results, the decrease in complete melting time is about 20% compared with the absence of a porous medium in the circular cross‐section configuration. The shell configuration has a noticeable impact on the reduction of the required time for melting. In the square cross‐section configuration, RT22 has the lowest melting time, as well as RT41 has the longest melting time in the inverted triangular cross‐section configuration in which the maximum time difference for RT22 is about 77% less. So, the best cross‐section for the shortest complete melting time is square.

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Section: Model Description and Numerical Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical investigation of the shell configuration effect on the melting of various phase change materials in the presence of porous medium and non‐Newtonian fluid

Azarbarzin

Javaherdeh

2023

Heat Trans

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“…In the opposite process, there is no difference between positions. The thermo-convective features between a water (HTF) and paraffin wax (PCM) result in conduction and forced convection in ESS was studied by Abderrahmane et al [23]. Enthalpy evaluation was employed to investigate the thermal characteristics during phase change processes.…”

Section: Theoretical Investigationmentioning

confidence: 99%

Review on latent thermal energy storage using phase change material

ALJABAIR

Alesbe

Ibrahim

2023

Journal of Thermal Engineering

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One of the appealing technologies that contributes to raising the energy storage density is latent heat thermal energy storage. The heat of fusion is isothermally stored at a temperature representing the temperature at which a phase-change material transitions between phases. The current research provides a review of how phase transition materials are used in melting and solidification. Generally, the range of working temperature extends from -20 °C to 200 °C for solidification and melting applications. The first range (-20 to 5 °C) is employed for commercial and domestic refrigeration. The second range (5 to 40 °C) is utilized to lower the energy requirements for air-conditioning applications. The applications includes in third range (40 to 82 °C) are solar collector and heating of water. Applications of absorption cooling, waste electricity generations, and heat recovery are operated at high temperature range (82 to180 °C). There are various types of PCMs for all the above temperature ranges. The present review paper will discuss the application field, Geometry, PCM type, heat transfer augmentation technique and their effects on the performance. The conclusions are mentioned to give more insight about the PCM behavior in various applications.

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“…Enthalpy -porosity method is used [12,13,14,15] to simulate the solidification process of the PCM due to its ability resolve explicit tracking of the solid-liquid interface position as well as ease to solve issues related to the phase change [16]. This method affords the exact simulation results and the best image of the required operations.…”

Section: Governing Equationsmentioning

confidence: 99%

“… There is no explicit requirement for the solid/liquid interface.  All researchers depend on it now [12,13,14,15]. Numerical models were used to simulate the cases of the present study, passing through four steps which are:…”

Section: Governing Equationsmentioning

confidence: 99%

Numerical Predication of Solidification Phenomena of Phase Change Material in Concentric Annulus Pipe

Abbas

Al-Hadithi

2021

IJOIR

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Two-dimensional numerical simulation is performed aiming to understand the role of buoyancy force convection during restricted solidification of phase change materials (PCMs) inside a shell and tube heat exchanger according to annulus cross section. Where the transient history of PCM solidification evolution was studied. The governing equations of mass, momentum and energy are solved to study the solidification behavior inside the annulus geometry. The fluid flow in the mushy zone was accounted for using the Darcy drag source term in momentum, and the liquid percentage in each cell was updated using the enthalpy-porosity method. Thermal conditions of the outer cylinder insulated (adiabatic) and the inner cylinder at constant temperature (isothermal). The results are presents as a temperature contour and liquid fraction distribution in the domain. The predicted result shows the capturing phenomenon: primary heat conduction in all regions, then heat convection and conduction become dominant in the top and bottom regions, respectively. The max. and min. temperature changes near the outer pipe surface during 16 hrs. are 56.25% and 42.5%, respectively.

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Thermo-convective Study of a Shell and Tube Thermal Energy Storage Unit

Cited by 6 publications

References 10 publications

Numerical investigation of the shell configuration effect on the melting of various phase change materials in the presence of porous medium and non‐Newtonian fluid

Numerical investigation of the shell configuration effect on the melting of various phase change materials in the presence of porous medium and non‐Newtonian fluid

Review on latent thermal energy storage using phase change material

Numerical Predication of Solidification Phenomena of Phase Change Material in Concentric Annulus Pipe

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