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Achieving low‐thermal conductivity and high β phase in <scp>PVDF</scp>/<scp>PMMA</scp> blend foams via low‐pressure microcellular foaming

Zhengsheng Weng, Minghui Wu, Qian Ren, Wanwan Li, Xiuyu Zhu, Long Wang, Hui Li, Wenge Zheng

2022Journal of Applied Polymer Science17 citationsDOI

Abstract

Abstract Polyvinylidene fluoride (PVDF) foam exhibits wider applications than traditional foams such as polyethylene and polystyrene foams due to its good corrosion resistance, flame retardant and wide operating temperature range. However, PVDF is difficult to foam and rigorous operating conditions including high pressure and high temperature were unavoidably adopted to prepare PVDF foams. Herein, microcellular PVDF foam was successfully fabricated with the combination of adding polymethylmethacrylate (PMMA) and batch foaming at mild processing condition. Compared to the pure PVDF foam with a low‐expansion‐ratio of 1.1 times, the PVDF/PMMA (70/30) blend foam showed an expansion ratio as high as 20 times together with a small cell size of approximately 5 μm. Additionally, the prepared PVDF/PMMA blend foam exhibited a low‐thermal conductivity (0.039 w m −1 k −1 ) and high content of β‐phase crystal (95%), which shows promising application in areas like electronic devices, thermal insulation and packaging materials.

Topics & Concepts

Materials sciencePolyvinylidene fluorideComposite materialPolystyreneThermal conductivityPolyethyleneThermal insulationFoaming agentPhase (matter)PolypropylenePolymerPorosityOrganic chemistryChemistryLayer (electronics)Polymer Foaming and CompositesAdvanced Sensor and Energy Harvesting MaterialsDielectric materials and actuators
Achieving low‐thermal conductivity and high β phase in <scp>PVDF</scp>/<scp>PMMA</scp> blend foams via low‐pressure microcellular foaming | Litcius