Fabrication of Hydroxyl Modified Hollow Glass Microsphere Composite Isocyanate-Based Polyimide Foam and Optimization Strategy Based on Different Bonding Mechanisms

IF 503.1 1区 医学 Q1 ONCOLOGY CA: A Cancer Journal for Clinicians Pub Date : 2024-11-13 DOI:10.1002/pol.20240796
Yifei Jin, Gaohui Sun, Guocheng Zhou, Rongrong Chen, Jun Wang, Zailin Yang, Shihui Han
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Abstract

In this study, the hydroxyl modified hollow glass microsphere (HM-HGM) is added to different foaming slurries of isocyanate-based polyimide foam (IBPIF) at varying ratios, and different bonding effects are formed to optimize the dispersion behavior. Then, the novel HGM composited IBPIF (IBPIF/HGM) is prepared. Hydroxyl groups on HM-HGM establish hydrogen bonding effect with pyromellitic acid dimethyl ester and dimethyl formamide in the white slurry and react with isocyanate groups in the black slurry. The cell structure of IBPIF is altered to improve its sound absorption performance and mechanical behaviors. Compared with IBPIF/HGM-0, the average cell size of IBPIF/HGM-1 and BPIF/HGM-5 decreases significantly. The sound absorption performance and mechanical behaviors of them are improved to some extent. Compared with samples in which the HM-HGM is added alone to a single slurry, when the dosage ratio of HM-HGM in black and white slurries is 1:1, IBPIF/HGM-3 has more uniform cell structure. The change of IBPIF cell structure by the introduction of HM-HGM and the unique structure of HM-HGM can enhance the sound absorption performance and mechanical behaviors of IBPIF. The design idea of different bonding mechanisms significantly provides technical assistance to enhance the acoustic performance of polymeric foam materials.

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羟基改性中空玻璃微球复合异氰酸酯基聚酰亚胺泡沫的制备及基于不同粘合机制的优化策略
本研究将羟基改性中空玻璃微球(HM-HGM)以不同比例添加到异氰酸酯基聚酰亚胺泡沫(IBPIF)的不同发泡浆料中,并形成不同的粘结效果,以优化分散行为。然后,制备出新型 HGM 复合 IBPIF(IBPIF/HGM)。HM-HGM 上的羟基与白色浆料中的吡咯烷酮酸二甲酯和二甲基甲酰胺形成氢键效应,并与黑色浆料中的异氰酸酯基团发生反应。改变 IBPIF 的细胞结构可改善其吸音性能和机械性能。与 IBPIF/HGM-0 相比,IBPIF/HGM-1 和 BPIF/HGM-5 的平均细胞尺寸明显减小。它们的吸音性能和机械性能都得到了一定程度的改善。与在单一浆料中单独添加 HM-HGM 的样品相比,当黑白浆料中 HM-HGM 的用量比为 1:1 时,IBPIF/HGM-3 的细胞结构更加均匀。引入 HM-HGM 改变了 IBPIF 的细胞结构,HM-HGM 的独特结构可提高 IBPIF 的吸声性能和力学行为。不同粘合机制的设计思想为提高聚合泡沫材料的声学性能提供了重要的技术帮助。
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来源期刊
CiteScore
873.20
自引率
0.10%
发文量
51
审稿时长
1 months
期刊介绍: CA: A Cancer Journal for Clinicians" has been published by the American Cancer Society since 1950, making it one of the oldest peer-reviewed journals in oncology. It maintains the highest impact factor among all ISI-ranked journals. The journal effectively reaches a broad and diverse audience of health professionals, offering a unique platform to disseminate information on cancer prevention, early detection, various treatment modalities, palliative care, advocacy matters, quality-of-life topics, and more. As the premier journal of the American Cancer Society, it publishes mission-driven content that significantly influences patient care.
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