Numerical Analysis of Shell-and-Tube Type Latent Thermal Energy Storage Performance with Different Arrangements of Circular Fins

Kuboth, Sebastian; König-Haagen, Andreas; Brüggemann, Dieter

doi:10.3390/en10030274

Cited by 41 publications

(18 citation statements)

References 27 publications

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“…This work agrees with earlier work [17,32,[93][94][95][96][97][98][99][100][101] in concluding that fins are an effective strategy for the enhancement of heat transfer within LHTSDs. However, it qualifies that conclusion by noting that the flow and melt boundary develop in similar ways in both cases despite the significant differences in geometry.…”

Section: Analysis Of Melt and Flow Behavior During Dischargingsupporting

confidence: 92%

“…However, the most common (and cost-effective) strategy to enhance heat transfer into and out of a PCM thermal storage unit is the use of high conductivity fins [17,32,93]. Previous computational and experimental work on finned heat spreaders demonstrates that they consistently enhance heat transfer within a variety of types of LHTSDs [94], including containers with flat plate fins [95,96], axial fins [97,98], and circular fins [99][100][101].…”

Section: Introductionmentioning

confidence: 99%

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Improving the performance of finned latent heat thermal storage devices using a Cartesian grid solver and machine-learning optimization techniques

Augspurger¹

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Section: Analysis Of Melt and Flow Behavior During Dischargingsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Improving the performance of finned latent heat thermal storage devices using a Cartesian grid solver and machine-learning optimization techniques

Augspurger¹

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“…SCHPs are used in the cooling of electronics, in space applications as well as in thermal energy storage systems [1]. Various studies have been carried out to investigate their performance in such applications [6][7][8][9][10][11][12]. On the other hand, RHPs are mainly used in applications such as the cooling of drill tips [13], cooling of rotating electrical machines [14][15][16] and heating/cooling of metal strips [17].…”

Section: Introductionmentioning

confidence: 99%

Transient Modelling of Rotating and Stationary Cylindrical Heat Pipes: An Engineering Model

et al. 2018

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Rotating wickless and stationary capillary cylindrical heat pipes are widely used heat transfer devices. Transient behavior of such heat pipes has been investigated numerically with computational fluid dynamics and lumped parameter models. In this paper, the advantages of both methods are combined into a novel engineering model that is low in computational cost but still accurate and rich in the details it provides. The model describes the interior dynamics of the heat pipe with a 2D representation of a cylindrical heat pipe. Liquid and vapor volumes are coarsely meshed in the axial direction. The cells are allowed to change in size in the radial direction during simulation. This allows for tracking the liquid/vapor interface without having to implement fine meshing. The model includes the equations for mass, momentum and energy and is applicable to both rotating and stationary heat pipes. The predictions of the model are validated with other experimental, numerical, and analytical works having an average deviation of less than 4%. The effects of various parameters on the system are explored. The presented model is suitable for the simulation of heat pipe systems in which both the level of detail and the computational cost are crucial factors.

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“…Most noticeable is the recent trend of the shell-and-tube LHS unit being integrated into solar thermal power systems, as seen in the applications studied by Li et al [4] and Tehrani et al [5]. Consequently, the shell-and-tube type LHS unit was the subject of a number of analytical [6][7][8][9], experimental [10][11][12][13], and numerical [14][15][16][17][18][19][20][21][22] studies, which focused mostly on performance enhancements at the charging/discharging-stage of the unit.…”

Section: Introductionmentioning

confidence: 99%

“…It was found that proper arrangements of the hierarchical inner tube design can decrease melting time. Along the same line of geometric investigations, Darzi et al [16], Tabassum et al [19], and Kuboth et al [21] explored new ideas of geometrically altering the shell-and-tube type LHS unit to enhance the heat transfer performance.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation and Optimization of the Melting Process of Phase Change Material inside Horizontal Annulus

Chen

Sun

2017

Energies

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Latent heat storage (LHS) technologies adopting phase change materials (PCMs) are increasingly being used to bridge the spatiotemporal mismatch between energy production and demand, especially in industries like solar power, where strong cyclic fluctuations exist. The shell-and-tube configuration is among the most prevalent ones in LHS and thus draws special attention from researchers. This paper presents numerical investigations on the melting of PCM, a paraffin blend RT27, inside a horizontal annulus. The volume of fluid model was adopted to permit density changes with the solidification/melting model wherein natural convection was taken into account. The eccentricity and diameter of the inner tube, sub-cooling degree of the PCM, and the heating-surface temperature were considered as variables for study. Through the evaluation of the melting time and exergy efficiency, the optimal parameters of the horizontal annulus were obtained. The results showed that the higher the heating boundary temperature, the earlier the convection appeared and the shorter the melting time. Also, the different eccentricity and diameters of the inner tube influenced the annulus tube interior temperature distribution, which in turn determined the strength and distribution of the resulting natural convection, resulting in varying melting rates.

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Numerical Analysis of Shell-and-Tube Type Latent Thermal Energy Storage Performance with Different Arrangements of Circular Fins

Cited by 41 publications

References 27 publications

Improving the performance of finned latent heat thermal storage devices using a Cartesian grid solver and machine-learning optimization techniques

Improving the performance of finned latent heat thermal storage devices using a Cartesian grid solver and machine-learning optimization techniques

Transient Modelling of Rotating and Stationary Cylindrical Heat Pipes: An Engineering Model

Numerical Simulation and Optimization of the Melting Process of Phase Change Material inside Horizontal Annulus

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