Thermal performance of an accumulator unit using phase change material with a fixed volume of fins

Amer, Ahmed E.; Elsakka, Mohamed; Лебедев, В. А.

doi:10.1002/er.7095

Cited by 22 publications

(10 citation statements)

References 40 publications

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“…Dekhil et al 84 and Rana et al 268 found that the melting time of the shell-andtube LHS system was reduced with the incorporation of fins, and the melting and solidification rate of longitudinal fins were twice of plain tubes and 1.14 times of the radial finned tubes. Amer et al 269 and Abreha et al 270 found that the melting time and solidification of the finned shell-and-tube LHS system were reduced by up to 70.5% by increasing the HTF flow rate and HTF inlet temperature. Shaker et al 271 found that the complete melting and solidification time of cylindrical encapsulated PCM was enhanced by 41% with increasing the fin number from 4 to 12.…”

Section: Thermal Enhancementmentioning

confidence: 99%

“…Amagour et al 91 proposed an improved PCM-based coil tube heat exchanger configuration with 13 complete copper fins of 248 mm (long) × 50 mm (high) × 0.9 mm (thick) and 37 copper fins with dimensions of 248 mm × 25 mm × 0.9 mm, which can reduce the melting time by 9% compared with the original configuration. Xu et al 274 and Amer et al 269 concluded that the coupled effects of fin number, location, length, and thickness should be considered comprehensively to obtain an optimal fin structure. The critical value of total fin length was also proved to be increased with the increasing of the Rayleigh number…”

Section: Thermal Enhancementmentioning

confidence: 99%

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Recent Advances in CFD Simulations of Multiphase Flow Processes with Phase Change

Zhu

Zhang

et al. 2023

Ind. Eng. Chem. Res.

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Phase change is a phenomenon that has been extensively utilized in chemical engineering, energy, electronics, vehicle, and space exploration. From both the science and engineering perspectives, gaining a profound understanding of the intricacies of multiphase flow processes accompanied by heat and mass transfer due to phase change is of fundamental importance. Indeed, the computational fluid dynamics (CFD) has been increasingly applied as an effective tool to give an in-depth and efficient analysis of the phase change processes, thereby enhancing our understanding and capacity to control and optimize the phase change effects in these processes. This paper seeks to provide a comprehensive review of the utilization of CFD methodologies in the simulations of phase change flows across various applications, including temperature management, drying, separation and purification, and others. First, the CFD models at various scales that are developed to elucidate the phase change processes are summarized. Second, the noteworthy advances in the recent CFD simulation work on various phase change processes are presented, respectively. Finally, the challenges and potential prospects to facilitate the application of the phase change flow are discussed. The current review aims to offer insightful guidance for the CFD modeling of phase change processes in numerous engineering application scenarios.

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Section: Thermal Enhancementmentioning

confidence: 99%

Section: Thermal Enhancementmentioning

confidence: 99%

Recent Advances in CFD Simulations of Multiphase Flow Processes with Phase Change

Zhu

Zhang

et al. 2023

Ind. Eng. Chem. Res.

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“…They discovered that the staggered distribution of fins can improve the melting and heat charging rate by 37.2 and 59.1%, respectively. Amer et al [ 13 ] examined the melting process in a PCM-filled shell-and-tube (SAT) unit with a various number of circular fins. They showed that with 36, 30, 18, and 6 fins, 72, 72, 66, and 53% of melting rate enhancement can be obtained compared to the base SAT unit without fins.…”

Section: Introductionmentioning

confidence: 99%

Utilization of Carbon-Based Nanomaterials and Plate-Fin Networks in a Cold PCM Container with Application in Air Conditioning of Buildings

et al. 2022

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Cold energy storage devices are widely used for coping with the mismatch between thermal energy production and demand. These devices can store cold thermal energy and return it when required. Besides the countless advantages of these devices, their freezing rate is sluggish, therefore researchers are continuously searching for techniques to improve their operating speed. This paper tries to address this problem by simultaneously combining a network of plate fins and various types of carbon-based nanomaterials (NMs) in a series of complex computational fluid dynamics (CFD) simulations that are validated by published experimental results. Horizontal, vertical, and the combination of these two plate-fin arrangements are tested and compared to the base model. Subsequently, several carbon-based NMs, including SWCNT, MWCNT, and graphene-oxide NMs are utilized to further improve the process. The influence of these fin networks, nanoparticle types, and their volume- and mass-based concentrations within the PCM container are studied and discussed. According to the results, carbon-based NMs exhibit superior performance compared to metal-oxide NMs, so that at identical NM volume and mass fractions, MWCNT particles present a 2.77% and 17.72% faster freezing rate than the CuO particles. The combination of plate-fin network and MWCNT particles is a promising technique that can expedite the ice formation rate by up to 70.14%.

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“…Therefore, it has a broad application prospect. However, the low thermal conductivity of phase change materials (PCMs) limits the thermal energy charge/discharge rate of shell‐and‐tube LTESU 4 . For solving this problem, various methods to enhance heat transfer have been proposed by researchers, such as adding nanoparticles, 5,6 metallic foam, 7,8 and fins 9,10 .…”

Section: Introductionmentioning

confidence: 99%

“…However, the low thermal conductivity of phase change materials (PCMs) limits the thermal energy charge/discharge rate of shell-and-tube LTESU. 4 For solving this problem, various methods to enhance heat transfer have been proposed by researchers, such as adding nanoparticles, 5,6 metallic foam, 7,8 and fins. 9,10 Compared with other strengthening methods, fins have the advantages of easy manufacture, low cost, and long service life.…”

Section: Introductionmentioning

confidence: 99%

Improving the solidification performance of a shell‐and‐tube latent‐heat thermal energy storage unit using a connected‐Y ‐shaped fin

Cai

Zheng

Yang

et al. 2022

Intl J of Energy Research

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Summary In this paper, the solidification process of the phase change material (PCM) in the shell‐and‐tube latent‐heat thermal energy storage unit (LTESU) strengthened by fin is studied. For improving the strengthening effect of fins on the solidification performance of shell‐and‐tube LTESU, this paper proposes a novel connected‐Y‐shaped fin. The novel fin is inspired by the interconnection of the internal texture of the lotus leaf, and the branches of the two‐level Y‐shaped fins are connected into a whole by three metal annuluses. The numerical simulation method is applied to investigate the influence of the connected‐Y‐shaped fin on the solidification performance of PCM. The effects of annulus position and fin width on solidification performance are studied and analyzed. At the same time, the effects of the connected‐Y‐shaped fin on the solidification process under different wall temperatures and the radius ratio of outer to inner tube (γi) are investigated. The results indicated that the connected‐Y‐shaped fin can significantly enhance the discharging performance of LTESU. Compared with the traditional two‐level Y‐shaped fins, the optimized connected‐Y‐shaped fin can shorten the PCM solidification time by 53.9%. The optimum width ratio of the connected‐Y‐shaped fin should be 2. The optimum radius ratio of the outer annulus, middle annulus, and inner annulus to the outer tube should be 0.91, 0.64, and 0.41, respectively. The scope of application of the conclusion is that Ste = 0.139 − 0.496, and γi = 0.083 − 0.167. Highlight A novel connected‐Y‐shaped fin is proposed for the latent heat storage unit. The influences of fin structure parameters on the solidification process are discussed. Optimum fin parameters are recommended for maximizing the solidification rate. The novel fin can decrease the solidification time of PCM by 53.9%.

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Thermal performance of an accumulator unit using phase change material with a fixed volume of fins

Cited by 22 publications

References 40 publications

Recent Advances in CFD Simulations of Multiphase Flow Processes with Phase Change

Recent Advances in CFD Simulations of Multiphase Flow Processes with Phase Change

Utilization of Carbon-Based Nanomaterials and Plate-Fin Networks in a Cold PCM Container with Application in Air Conditioning of Buildings

Improving the solidification performance of a shell‐and‐tube latent‐heat thermal energy storage unit using a connected‐Y ‐shaped fin

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