Fabrication, Structure, and Thermal Properties of Mg–Cu Alloys as High Temperature PCM for Thermal Energy Storage

Sun, Zhenzhen; Zou, Liyi; Cheng, Xiaomin; Zhu, Jiaoqun; Li, Yuanyuan; Zhou, Weibing

doi:10.3390/ma14154246

Cited by 3 publications

(3 citation statements)

References 26 publications

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“…The density of the composite was increased by almost 75% to 1.05 g cm −3 , indicating that different composite filler materials and synthesis methods have different effects on the bulk energy storage density and thermal power capacity. Sun et al [ 88 ] investigated the thermophysical properties of Mg‐24%Cu, Mg‐31%Cu, and Mg‐45%Cu alloys, including their microstructure, phase composition, phase transition temperature, and enthalpy. The test results show that the Mg‐24%Cu, Mg‐31%Cu, and Mg‐45%Cu alloys have starting melting temperatures of 485, 486, and 485 °C and melting enthalpies of 152, 21, 5, and 91 J g −1 .…”

Section: Overview Of the Pcmmentioning

confidence: 99%

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Liu,

Zhang,

Hua

et al. 2024

Energy Tech

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Photovoltaic technology plays a crucial role in harnessing renewable energy. While photovoltaic panels directly convert solar energy into electricity, more than 50% of solar radiation is lost as waste heat, diminishing the overall efficiency of the panels. This study reviews various cooling technologies for photovoltaic systems, focusing on the use of phase change materials for cooling in photovoltaic systems. Phase change materials, known for their high latent heat capacity, are extensively used in thermal energy storage applications. Incorporating phase change materials in photovoltaic systems can increase thermal storage potential by 30–50% compared to conventional systems, leading to a 70% extension in heat storage duration and various levels of enhanced power output. The main purpose of the article is to review the advantages and disadvantages of various technologies, determine the research direction of phase change materials for cooling systems in photovoltaics, and ensure the reliability of this technology.

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Section: Overview Of the Pcmmentioning

confidence: 99%

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Liu,

Zhang,

Hua

et al. 2024

Energy Tech

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“…Researchers have shown significant interest in developing energy storage alloys suitable for high-temperature environments in recent years. The Mg-Cu systems [3] and Mg-Al systems are commonly studied [4]. Mg-Cu--based alloys often have relatively small phase change enthalpy, resulting in higher energy consumption in practical applications.…”

Section: Introductionmentioning

confidence: 99%

Thermal properties and container compatibility of (Al0.8Si0.2)100−xBix phase change energy storage alloys

Sun,

Chang,

et al. 2024

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“…In comparison to microcapsules (with a PCM sphere diameter of <1 mm), the macrocapsules (with a PCM sphere diameter of >1 mm) present a higher ratio of core to shell, resulting in a higher thermal energy density of the TES systems . However, due to the large volume expansion of Cu-based PCMs at high temperatures, the shells of the capsules may crack during the phase-change transition, resulting in the leakage of the liquid metals. − To overcome this issue, the sacrificial layer method can smartly create a buffer cavity inside the macrocapsules. Mathur et al coated the sacrificial layer and shell on the core for inorganic salt mixture PCMs by the fluid bed method.…”

Section: Introductionmentioning

confidence: 99%

Copper–Alumina Capsules for High-Temperature Thermal Energy Storage

Zhao

Liu

Sheng

et al. 2023

ACS Appl. Eng. Mater.

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High corrosivity, leakage, and oxidation of metallic phase-change materials (PCMs) have limited their applications in high-temperature thermal energy storage (TES) systems, regardless of their favorable benefits for high-temperature TES applications of over 1000 °C. To overcome these major challenges, this work presents a facile paraffin sacrificial layer approach for directly encapsulating copper (Cu) sphere PCMs with the alumina (Al 2 O 3 ) shell, considering a buffer inner cavity. The cavity is formed by the decomposition of the paraffin layer through a pre-sintered process. It plays a key role in accommodating the volume expansion of the Cu core, thereby preventing the breakage of the shell and the leakage of the liquid PCM. A series of macrocapsules with different sizes (9.5−21 mm) containing the Cu core, cavity, and Al 2 O 3 shell are successfully produced using the paraffin sacrificial layer method and deploying a two-step heat treatment. The experimental results show that the Al 2 O 3 shell possesses a good structure, which can prevent the leakage of the Cu core. The Al 2 O 3 shell also has strong compatibility with the Cu core without any chemical reaction between two materials. In a temperature range of 1000−1100 °C, the calculated mass and volume energy storage densities of the PCM macrocapsule with 21 mm outer diameter are found to be 222 kJ/kg and 745 J/cm 3 , which are 1.83 and 1.76 times, respectively, higher than those for the Al 2 O 3 ceramic. After thermal cycle tests, the encapsulated Cu PCM shows superior shape stability, chemical stability, and thermal durability, which can be applied in long-term thermal storage systems for high-temperature TES systems.

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Fabrication, Structure, and Thermal Properties of Mg–Cu Alloys as High Temperature PCM for Thermal Energy Storage

Cited by 3 publications

References 26 publications

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Thermal properties and container compatibility of (Al0.8Si0.2)100−xBix phase change energy storage alloys

Copper–Alumina Capsules for High-Temperature Thermal Energy Storage

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