The Impact of Heat Exchangers’ Constructions on the Melting and Solidification Time of Phase Change Materials

Radomska, Ewelina; Mika, Łukasz; Sztekler, Karol; Lis, Łukasz

doi:10.3390/en13184840

Cited by 10 publications

(5 citation statements)

References 157 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…On the contrary, a more rapid charging/discharging period would enhance its adaptability to a wider variety of process integration, increasing the replication in other EII sectors and the overall system flexibility. The combustion air speed and the HX transference area should be maximised, hence increasing the convection and the heat transfer coefficient [22]. In this regard, the discharging period can be reduced without compromising the great ranges reached at the combustion air outlet.…”

Section: Pcm Databasementioning

confidence: 99%

Decision Support System of Innovative High-Temperature Latent Heat Storage for Waste Heat Recovery in the Energy-Intensive Industry

et al. 2021

View full text Add to dashboard Cite

Reductions in energy consumption, carbon footprint, equipment size, and cost are key objectives for the forthcoming energy-intensive industries roadmaps. In this sense, solutions such as waste heat recovery, which can be replicated into different sectors (e.g., ceramics, concrete, glass, steel, aluminium, pulp, and paper) are highly promoted. In this line, latent heat thermal energy storage (TES) contributes as an innovative technology solution to improve the overall system efficiency by recovering and storing industrial waste heat. To this end, phase-change material (PCM) selection is assisted through a decision-support system (DSS). A simplified tool based on the MATLAB® model, based on correlations among the most relevant system parameters, was developed to prove the feasibility of a cross-sectorial approach. The research work conducted a parametric analysis to assess the techno-economic performance of the PCM-TES solution under different working conditions and sectors. Additionally, a multicriteria assessment was performed comparing the tool outputs from metal alloys and inorganic hydrated PCM salts. Overall, the inorganic PCMs presented higher net economic and energy savings (up to 25,000 €/yr; 480 MWh/yr), while metal alloys involved promising results, shorter cycles, and competitive economic ratios; its commercial development is still limited.

show abstract

Section: Pcm Databasementioning

confidence: 99%

Decision Support System of Innovative High-Temperature Latent Heat Storage for Waste Heat Recovery in the Energy-Intensive Industry

et al. 2021

View full text Add to dashboard Cite

show abstract

“…This review presents a summary of the recent advancements in enhancing heat exchange measures in phase change heat storage devices from dual perspectives. Additionally, it offers relevant references for further research on phase change heat storage heat exchangers Table provides an overview of heat exchanger types along with the corresponding enhanced heat exchange measures applicable to various heat storage equipment configurations.…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, it offers relevant references for further research on phase change heat storage heat exchangers. 8 Table 1 provides an overview of heat exchanger types along with the corresponding enhanced heat exchange measures applicable to various heat storage equipment configurations. Within each figure, the yellow region represents PCMs, while the changing shades of red and blue depict heat transfer fluid (HTF).…”

Section: Introductionmentioning

confidence: 99%

Progress in the Study of Enhanced Heat Exchange in Phase Change Heat Storage Devices

et al. 2023

View full text Add to dashboard Cite

In comparison with sensible heat storage devices, phase change thermal storage devices have advantages such as high heat storage density, low heat dissipation loss, and good cyclic performance, which have great potential for solving the problem of temporal and spatial imbalances in the transfer and utilization of heat energy. However, there are also issues such as the small thermal conductivity of phase change materials (PCMs) and poor efficiency in heat storage and release, and in recent years, enhanced heat transfer in phase change thermal storage devices has become one of the research hotspots for optimizing thermal storage devices. Although there have been reviews of enhanced heat transfer technology for phase change thermal storage devices in the literature, there is still insufficient research on the summarization of the enhanced heat transfer mechanism, structural optimization, and applications of phase change thermal storage devices. This Review provides a review of enhanced heat transfer in phase change thermal storage devices from two aspects: internal structure enhanced heat transfer and heat exchange medium flow channel enhanced heat transfer. It summarizes the enhanced heat transfer measures of various types of phase change thermal storage devices and discusses the role of structural parameters in enhanced heat transfer. It is hoped that this Review will provide some references for scholars engaged in research on phase change thermal storage heat exchangers.

show abstract

“…28 Phase change materials (PCMs) are innovative materials that efficiently absorb and release a significant amount of energy during phase transformation, serving for temperature regulation and energy storage. [29][30][31] Polyethylene glycol (PEG) is a well-known kind of PCMs, which emerges as a highly promising solid-liquid PCM due to its exceptional qualities, such as low vapor pressure, excellent chemical and thermal stability, appropriate phase transition temperature, lack of supercooling, and nontoxic nature. [32][33][34] PEG also exhibits some drawbacks which would limits its practical applications.…”

Section: Introductionmentioning

confidence: 99%

Preparation of a thermally conductive phase‐change coating with good anti‐corrosion

Hu,

Li,

et al. 2023

Polymer Composites

View full text Add to dashboard Cite

Polyethylene glycol (PEG) is a widely available and environmentally friendly phase change material known for its high energy storage capacity. However, its application in various industries is limited due to slow heat absorption and release, poor mechanical properties, and inadequate weather resistance. PEG was blended with waterborne epoxy resin (WER) to improve its mechanical properties and weather resistance. Furthermore, graphene nanoplatelets (GNPs) and boron nitride (BN) were incorporated into the WER/PEG resin substrate to prepare WER/PEG/BN@GNP coatings, resulting in enhanced thermal conductivity. When the GNP content was 0.5 wt%, the WER/PEG/BN@GNP coatings performed excellent anti‐corrosion. Otherwise, the leakage of PEG under heat‐cool cycling was addressed by the preparation of WER/PEG/BN@GNP coatings, as well as the low rates of heat absorption and release. In this work, the preparation method successfully combines the phase‐change characteristics of PEG, the outstanding mechanical properties of WER, and the high thermal conductivity of BN and GNP. The WER/PEG/BN@GNP coatings present significant potential for practical applications.Highlights A new coating is prepared by incorporation of BN/GNP into PEG/WER matrix. The prepared coating performs phase change and good heat conduction efficiency. The phase‐transition leakage of PEG is resolved by the combination with WER. The synergy of BN and GNP fillers can enhance thermal conductivity effectively. The prepared coating exhibits insulation and anti‐corrosion at low GNP content.

show abstract

The Impact of Heat Exchangers’ Constructions on the Melting and Solidification Time of Phase Change Materials

Cited by 10 publications

References 157 publications

Decision Support System of Innovative High-Temperature Latent Heat Storage for Waste Heat Recovery in the Energy-Intensive Industry

Decision Support System of Innovative High-Temperature Latent Heat Storage for Waste Heat Recovery in the Energy-Intensive Industry

Progress in the Study of Enhanced Heat Exchange in Phase Change Heat Storage Devices

Preparation of a thermally conductive phase‐change coating with good anti‐corrosion

Contact Info

Product

Resources

About