Recent progress in the preparation, structure, and application of thermal insulation materials

doi:10.11949/0438-1157.20250329

Abstract

Abstract:

As global energy consumption and greenhouse gas emissions become increasingly severe, the development of efficient and environmentally friendly thermal insulation materials has become a significant topic in the field of materials science and engineering. Thermal insulation materials are widely used in construction, industry, aerospace and other fields, especially in reducing energy loss and improving energy efficiency. This paper summarizes the recent progress in the preparation and structural research of thermal insulation materials, with a focus on the structural characteristics and thermal insulation performance of organic, inorganic, and their composite aerogels and foams. By comparing and analyzing the thermal conductivity and temperature resistance of different materials, the review systematically outlines the applicable scenarios and current applications of various material systems. Finally, the future development trends of thermal insulation materials are discussed, suggesting that the integration of multi-scale structural design, biomimetic structures, and sustainable materials will be the key path to enhancing thermal insulation performance.

Key words: thermal insulation materials, aerogels, thermal conductivity, porosity, composites, preparation, foam

摘要：

随着全球能源消耗和温室气体排放问题日益严峻，开发高效、环保的隔热材料已成为材料科学与工程领域的重要课题。隔热材料在建筑、工业、航空航天等领域应用广泛，尤其在减少能量损失和提高能源效率方面起着关键作用。综述了近年来隔热材料的制备、结构研究进展，重点介绍了有机、无机及其复合气凝胶和泡沫的结构特性及其隔热性能，通过对比分析各类材料的热导率及耐温性能，系统梳理了不同材料体系的适用场景与应用现状。最后，展望了隔热材料未来的发展趋势，认为多尺度结构设计、仿生结构和可持续材料的结合将成为提高隔热性能的关键路径。

关键词: 隔热材料, 气凝胶, 热导率, 孔隙率, 复合材料, 制备, 泡沫

CLC Number:

TB 34

Xinyan CHEN, Yiling CHEN, Xinbo PENG, Jingjie HU, Xueliang JIANG, Feng YOU. Recent progress in the preparation, structure, and application of thermal insulation materials[J]. CIESC Journal, 2025, 76(12): 6179-6195.

陈欣妍, 陈依玲, 彭馨博, 胡靖杰, 江学良, 游峰. 隔热材料的制备、结构及应用研究进展[J]. 化工学报, 2025, 76(12): 6179-6195.

Figures/Tables 9

References 76

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分类	典型材料	形态	热导率/ (W/(m·K))	性能特点	制备方法	文献
有机高分子材料	聚苯乙烯泡沫板（EPS）	泡沫	40.0	轻质易切割，吸水性较高，需阻燃处理；广泛用于建筑墙体保温	挤出法、泡沫塑料加工法	—
	聚苯乙烯泡沫挤塑板（XPS）	泡沫	30.0	闭孔结构，抗压强度高，防潮性好；适用于地暖、冷库	挤出成型法	—
	聚氨酯泡沫（PUR）	泡沫	20.0~30.0	高黏结性，无缝填充，阻燃性优于EPS；用于冷链、管道保温	发泡法、喷涂法	[7]
	聚酰亚胺	泡沫	100.0~50.0	耐温性较好，低烟无毒，脆性较高	热固化法、发泡法	[8]
生物质材料	纤维素	颗粒	40.0~60.0	天然可再生，弹性好，但易受潮霉变；用于红酒塞、装饰保温	—	[9]
	壳聚糖	松散填充	50.0~200.0	高孔隙率，吸声性强，防虫蛀；适用于热带地区建筑隔热	—	[10]
	木质素	板材	50.0~70.0	农业废弃物再生利用，成本低，但耐火性差；用于临时建筑夹层	—	[11]
无机材料	硅酸铝纤维	纤维棉	30.0~40.0	耐高温，抗热震，但对皮肤有刺激性；用于窑炉内衬	纤维化法、吹气法	[12]
	碳纳米线圈	—	20.0~40.0	超弹性，电磁屏蔽效能高，表面活性位点多；用于催化载体，柔性传感器	—	[13]
	石墨烯	—	10.0~20.0	超高导电性，超轻，力学强度可调；应用于超级电容器电极，高效散热片	—	[14]
	二氧化硅	气凝胶	10.0~20.0	超轻，憎水性强，柔性可裁剪；用于航天服、管道包裹	超临界干燥法、溶胶-凝胶法	[15]
	碳	气凝胶	10.0~20.0	导电性可控，耐高温，纳米多孔结构；用于电池隔热、电子器件	—	[16]
	玻璃棉	纤维卷材	30.0~40.0	成本低，吸声性能好，但易碎裂；广泛用于建筑吊顶、管道保温	纤维化法、吹气法	[17]
有机-无机杂化材料	二氧化硅气凝胶/聚酰亚胺泡沫	泡沫	24.0	高温稳定性强，良好的隔热性能	液氮气化法	[18]
	聚酰亚胺气凝胶/二氧化硅复合材料	气凝胶	7.4	卓越的低热导率和结构稳定性	3D打印与氢键网络调控	[19]
	间位芳纶纤维/氟化空心玻璃微球	气凝胶	21.6	高的隔热性能及耐热性	溶胶-凝胶法	[20]

分类	典型材料	形态	热导率/ (W/(m·K))	性能特点	制备方法	文献
有机高分子材料	聚苯乙烯泡沫板（EPS）	泡沫	40.0	轻质易切割，吸水性较高，需阻燃处理；广泛用于建筑墙体保温	挤出法、泡沫塑料加工法	—
	聚苯乙烯泡沫挤塑板（XPS）	泡沫	30.0	闭孔结构，抗压强度高，防潮性好；适用于地暖、冷库	挤出成型法	—
	聚氨酯泡沫（PUR）	泡沫	20.0~30.0	高黏结性，无缝填充，阻燃性优于EPS；用于冷链、管道保温	发泡法、喷涂法	[7]
	聚酰亚胺	泡沫	100.0~50.0	耐温性较好，低烟无毒，脆性较高	热固化法、发泡法	[8]
生物质材料	纤维素	颗粒	40.0~60.0	天然可再生，弹性好，但易受潮霉变；用于红酒塞、装饰保温	—	[9]
	壳聚糖	松散填充	50.0~200.0	高孔隙率，吸声性强，防虫蛀；适用于热带地区建筑隔热	—	[10]
	木质素	板材	50.0~70.0	农业废弃物再生利用，成本低，但耐火性差；用于临时建筑夹层	—	[11]
无机材料	硅酸铝纤维	纤维棉	30.0~40.0	耐高温，抗热震，但对皮肤有刺激性；用于窑炉内衬	纤维化法、吹气法	[12]
	碳纳米线圈	—	20.0~40.0	超弹性，电磁屏蔽效能高，表面活性位点多；用于催化载体，柔性传感器	—	[13]
	石墨烯	—	10.0~20.0	超高导电性，超轻，力学强度可调；应用于超级电容器电极，高效散热片	—	[14]
	二氧化硅	气凝胶	10.0~20.0	超轻，憎水性强，柔性可裁剪；用于航天服、管道包裹	超临界干燥法、溶胶-凝胶法	[15]
	碳	气凝胶	10.0~20.0	导电性可控，耐高温，纳米多孔结构；用于电池隔热、电子器件	—	[16]
	玻璃棉	纤维卷材	30.0~40.0	成本低，吸声性能好，但易碎裂；广泛用于建筑吊顶、管道保温	纤维化法、吹气法	[17]
有机-无机杂化材料	二氧化硅气凝胶/聚酰亚胺泡沫	泡沫	24.0	高温稳定性强，良好的隔热性能	液氮气化法	[18]
	聚酰亚胺气凝胶/二氧化硅复合材料	气凝胶	7.4	卓越的低热导率和结构稳定性	3D打印与氢键网络调控	[19]
	间位芳纶纤维/氟化空心玻璃微球	气凝胶	21.6	高的隔热性能及耐热性	溶胶-凝胶法	[20]