High-Strength Organic–Inorganic Composites with Superior Thermal Insulation and Acoustic Attenuation

IF 4.7 Q1 POLYMER SCIENCE
Divya Iyer, Mohammad Galadari, Fernaldy Wirawan, Vanessa Huaco, Ricardo Martinez, Michael T. Gallagher, Laurent Pilon, Kanji Ono, Dante A. Simonetti, Gaurav N. Sant and Samanvaya Srivastava*, 
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引用次数: 0

Abstract

We demonstrate facile fabrication of highly filled, lightweight organic–inorganic composites comprising polyurethanes covalently linked with naturally occurring clinoptilolite microparticles. These polyurethane/clinoptilolite (PUC) composites are shown to mitigate particle aggregation usually observed in composites with high particle loadings and possess enhanced thermal insulation and acoustic attenuation compared with conventionally employed materials (e.g., drywall and gypsum). In addition to these functional properties, the PUC composites also possess flexural strengths and strain capacities comparable to and higher than ordinary Portland cement (OPC), respectively, while being ∼1.5× lighter than OPC. The porosity, density, and mechanical and functional properties of these composites are tuned by systematically varying their composition (diisocyanate, polyurethane, and inorganic contents) and the nature of the organic (reactivity and source of polyol) components. The fabrication process involves mild curing conditions and uses commonly available reagents (naturally occurring aluminosilicate particles, polyols, and diisocyanate), thereby making the process scalable. Finally, the composite properties are shown to be independent of the polyol source (virgin or recycled), underlining the generality of this approach for the scalable utilization of recycled polyols.

Abstract Image

Abstract Image

具有优异隔热和隔音性能的高强度有机-无机复合材料
我们展示了高填充、轻质有机-无机复合材料的简便制造方法,这种复合材料由聚氨酯与天然clinoptilolite微颗粒共价连接而成。研究表明,这些聚氨酯/clinoptilolite(PUC)复合材料可减轻高颗粒负载复合材料中通常会出现的颗粒聚集现象,并且与传统材料(如干墙和石膏)相比,具有更强的隔热性和隔音性。除了这些功能特性外,PUC 复合材料的抗折强度和应变能力也分别与普通波特兰水泥(OPC)相当或更高,同时比 OPC 轻 1.5 倍。通过系统地改变复合材料的成分(二异氰酸酯、聚氨酯和无机成分)和有机成分的性质(多元醇的反应性和来源),可以调整这些复合材料的孔隙率、密度、机械和功能特性。制造过程涉及温和的固化条件,并使用常见的试剂(天然存在的硅酸铝颗粒、多元醇和二异氰酸酯),从而使该过程具有可扩展性。最后,复合材料的特性不受多元醇来源(原生或回收)的影响,从而强调了这种方法在可扩展利用回收多元醇方面的通用性。
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CiteScore
2.50
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