Processable and recyclable polyurethane/<scp>HNTs</scp>@<scp>Fe<sub>3</sub>O<sub>4</sub></scp> solid–solid phase change materials with excellent thermal conductivity for thermal energy storage

Lin, Chucheng; Ying, Puyou; Huang, Min; Zhang, Ping; Yang, Tao; Liu, Gang; Wu, Jianbo; Levchenko, Vladimir

doi:10.1002/pc.26342

Cited by 12 publications

(6 citation statements)

References 38 publications

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“…The calcined β‐SiC w @SiO 2 /PVDF exhibits improved TC in comparison to raw β‐SiC w ‐0/PVDF due to the formation of hydrogen bonds between the SiO 2 shell and host PVDF, this enhances the interfacial compatibility of the β‐SiC w filler and PVDF matrix, as schematically depicted in Figure 10C. Compared to the β‐SiC w ‐0/PVDF, the long‐range migration of electron transmission in raw β‐SiC w ‐1/PVDF and β‐SiC w ‐3/PVDF is obviously restrained 48,49 . This is because the SiO 2 shell becomes increasingly dense and has a better electron‐blocking effect as the calcination temperature increases.…”

Section: Thermal Conductivitymentioning

confidence: 98%

“…Compared to the β-SiC w -0/PVDF, the long-range migration of electron transmission in raw β-SiC w -1/PVDF and β-SiC w -3/PVDF is obviously restrained. 48,49 This is because the SiO 2 shell becomes increasingly dense and has a better F I G U R E 1 0 (A) A comparison of the thermal conductivity (TC) of the composites with various fillers at various calcination temperatures, (B) describes infrared thermograms of various composites, and (C) schematic diagram of the models of heat transfer mechanism of various composites. 51…”

Section: Thermal Conductivitymentioning

confidence: 99%

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Morphological engineering of SiO₂ interlayer towards meliorative dielectric and thermal properties in β‐SiC_w@SiO₂/PVDF composites

et al. 2023

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Polymers with high thermal conductivity (TC) and dielectric constant (ε) but low dielectric loss show enormously potential applications in electrical power systems. To enhance the ε and TC while significantly suppressing the loss of β‐silicon carbide whisker (β‐SiCw)/polyvinylidene fluoride (PVDF), in this study, SiO2 shells with different morphologies were constructed on the superficies of β‐SiCw via a facile oxidation method in air atmosphere. The SiO2 shell’ morphology on the TC and dielectric performances of the β‐SiCw@SiO2/PVDF are systematically explored as a function of the frequency and filler loading. The β‐SiCw@SiO2/PVDF demonstrate astonishingly restricted loss and meliorative TC when compared to the β‐SiCw/PVDF because the SiO2 shell not only suppresses the β‐SiCw from direct contact with one another and impedes the long‐distance charges migration thereby resulting in rather low loss and leakage conductivity, but also restrains the thermal interfacial resistance via increased interfacial compatibility and interactions. The concurrent enhancement effect in the ε and TC but low loss of the composites is more evident in the crystalline SiO2 interlayer with a high TC compared with amorphous one. These results provide insight into the exploration of composite nanodielectrics with large TC and ε but low loss for applications in electrical power systems.Highlights Core@shell structured β‐SiCw@SiO2/PVDF were obtained by a facile oxidation. The great reduction in both loss and conductivity is attributed to the SiO2 shell. Crystalline SiO2 shell can improve the composites' thermal conductivity. The SiO2 shell prevents long‐range carrier migration.

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Section: Thermal Conductivitymentioning

confidence: 98%

Section: Thermal Conductivitymentioning

confidence: 99%

Morphological engineering of SiO₂ interlayer towards meliorative dielectric and thermal properties in β‐SiC_w@SiO₂/PVDF composites

et al. 2023

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“…Currently, with the increase of environmental standards and energy demand, it has great practical significance to realize the reuse and reprocessing of PCMs for thermal management applications. In fact, development of stimulus response dynamic networks has already improved novel phase change materials with excellent recyclable performance. , For example, Lei and coworkers have reported a series of PCMs with a dynamic crosslinked structure, including dynamic Diels–Alder (DA) bonds, disulfide covalent bonds, metal–ligand coordination, and oxime carbamate bonds . Wang et al ,, adopted furan/maleimide Diels–Alder (DA) and hydrogen bonds as reversible units to synthesize SSPCM composites.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Properties of Dynamic Crosslinking Polyurethane/PEG Shape-Stable Phase Change Materials Based on the Diels–Alder Reaction

Lin

Ying

et al. 2023

ACS Appl. Polym. Mater.

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Phase change materials (PCMs) can absorb and release energy while keeping the temperature constant; hence, they play a crucial role in the thermal management field. Shape-stable phase change materials (SSPCMs) were synthesized by chemical crosslinking to address the liquid leakage problem of solid−liquid phase change materials (SLPCMs) during the phase change process. However, the abandoned SSPCMs cannot be reused and recycled, which seriously restricts their practical application. Herein, a polyurethane network containing Diels−Alder bonds was used as the enclosure compound to obtain the encapsulation of polyethylene glycol (PEG), and then, the chemical structure, crystallization behavior, and phase transition ability of SSPCMs were systematically investigated. The results showed that the SSPCMs-3 sample (300 wt % PEG) had the best comprehensive performance, an enthalpy value of 171.7 J/g, and no leakage at 80 °C for 1 h. Moreover, the structure, crystallization behavior, and phase transition ability of SSPCMs could also basically remain unchanged after multiple thermal cycling and reprocessing.

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“…CANs rely on dynamic covalent bonds that can break/reform and recombine either autonomously or with appropriate stimuli (esp. light , and heat − ), endowing polymers with unprecedented properties, such as self-healing, ,, recyclability, , weldability, and reprocessabIlity. − So far, many dynamic covalent bonds, such as Diels–Alder, , transesterification, , carbamate bonds, thiol–ene click reactions, disulfide bonds, − thiocarbamate bonds, − thiol–anhydride, transimination, boronic esters, , siloxane exchange, and hindered urea bonds, have been applied to design the thermosetting polymers with various types of CANs. , …”

Section: Introductionmentioning

confidence: 99%

Fully Closed-Loop Recyclable Thermosetting Polythiourethane Microspheres and Their Application in Efficient Fabrication of Composites with Segregated Structures

Yao

Huang

et al. 2023

ACS Appl. Eng. Mater.

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Introducing dynamic covalent bonds into cross-linked polymer endows thermosetting polymers with thermoplastic properties such as reprocessability and recyclability, providing a solution to the environmental problems induced by thermosetting polymers. However, unlike thermoplastic polymers, the synthesis and molding processes of most thermosetting polymers with covalent adaptable networks still maintain together, affecting the development of industrial production. Herein, the cross-linked polythiourethane microspheres (PTUMs) with dynamic covalent bonds have been prepared by suspension polymerization. The PTUMs can be closed-loop-recycled and shows no significant performance degradation after recycling, paving an easy and efficient way for the recycling of cross-linked polymers. Furthermore, as with the thermoplastic film prepared from polymer pellets, a thermosetting polythiourethane film (PTUMF) can be obtained by simple compression molding of PTUMs. Importantly, by mixing PTUMs with fillers and then compression molding, the composites with a segregated structure and excellent electrical conductivity can be fabricated. Such composites can be used as wearable strain sensors to monitor human motions. Notably, the preparation and molding of thermosetting polymer materials in this work are separated, which may be conducive to the development of industrial production.

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Processable and recyclable polyurethane/HNTs@Fe₃O₄ solid–solid phase change materials with excellent thermal conductivity for thermal energy storage

Cited by 12 publications

References 38 publications

Morphological engineering of SiO₂ interlayer towards meliorative dielectric and thermal properties in β‐SiC_w@SiO₂/PVDF composites

Morphological engineering of SiO₂ interlayer towards meliorative dielectric and thermal properties in β‐SiC_w@SiO₂/PVDF composites

Synthesis and Properties of Dynamic Crosslinking Polyurethane/PEG Shape-Stable Phase Change Materials Based on the Diels–Alder Reaction

Fully Closed-Loop Recyclable Thermosetting Polythiourethane Microspheres and Their Application in Efficient Fabrication of Composites with Segregated Structures

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Processable and recyclable polyurethane/HNTs@Fe3O4 solid–solid phase change materials with excellent thermal conductivity for thermal energy storage

Cited by 12 publications

References 38 publications

Morphological engineering of SiO2 interlayer towards meliorative dielectric and thermal properties in β‐SiCw@SiO2/PVDF composites

Morphological engineering of SiO2 interlayer towards meliorative dielectric and thermal properties in β‐SiCw@SiO2/PVDF composites

Synthesis and Properties of Dynamic Crosslinking Polyurethane/PEG Shape-Stable Phase Change Materials Based on the Diels–Alder Reaction

Fully Closed-Loop Recyclable Thermosetting Polythiourethane Microspheres and Their Application in Efficient Fabrication of Composites with Segregated Structures

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Product

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Processable and recyclable polyurethane/HNTs@Fe₃O₄ solid–solid phase change materials with excellent thermal conductivity for thermal energy storage

Morphological engineering of SiO₂ interlayer towards meliorative dielectric and thermal properties in β‐SiC_w@SiO₂/PVDF composites

Morphological engineering of SiO₂ interlayer towards meliorative dielectric and thermal properties in β‐SiC_w@SiO₂/PVDF composites