Laboratory testing on cracking characteristics and improvement mechanism of coral mud

Huaqiang Fang, Xuanming Ding, Yifu Li, Hong Wang, Junyu Ren
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Abstract

In recent years, the development and construction of island reefs have been flourishing. Due to the remoteness of island reefs from the mainland, the scarcity of building materials, and the high transportation costs, it is imperative to use local marine resources, and the potential value and status of coral mud on island reefs, which is formed by the remains of corals and other biological entities, is becoming increasingly prominent. Utilization and optimization of natural resources on island reefs have become a brand-new research direction and challenge. This article mainly focuses on the development of a new type of green engineering material, coral mud, for use in building surface layers. Thickness effects, PVA fiber (vinylon staple fiber) modification, and HPMC (Hydroxypropyl Methyl Cellulose) adhesive modification are taken into consideration. Through laboratory tests and image processing technology, fractal theory, and electron microscopy experiments, the macro-meso-microscopic multi-scale cracking rules of the coral mud surface layer and the optimization modification rules of PVA fibers and HPMC adhesives are revealed. The results demonstrate that the performance of the coral mud surface layer is superior to that of the kaolin surface layer, and the 10 mm thickness performs better than the 5 mm and 20 mm thicknesses. As the thickness of the coral mud surface layer increases, the contact between coral mud particles becomes denser, the scale of surface micro-cracks decreases, and the number of micro-pores decreases. PVA fibers can effectively inhibit the further development of macro and micro cracks and play a good bridging role. There is a bonding and adhesion relationship between coral mud and PVA fibers, and they have a good synergistic effect in inhibiting macro and mesoscopic cracks. With the increase in HPMC adhesive content, the number of micro-cracks and the scale of micro-cracks decrease accordingly, and the structure and performance of the coral mud surface layer are further improved. Overall, PVA fibers are more effective than HPMC adhesives in inhibiting the cracking of the coral mud surface layer. This provides valuable guidance for the development and application of coral mud in wall surface materials.

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珊瑚泥开裂特性和改善机理的实验室测试
近年来,岛礁开发建设方兴未艾。由于岛礁远离大陆、建筑材料匮乏、运输成本高等原因,利用当地海洋资源势在必行,由珊瑚等生物实体遗骸形成的岛礁珊瑚泥的潜在价值和地位日益凸显。岛礁自然资源的利用和优化成为一个全新的研究方向和挑战。本文主要介绍一种新型绿色工程材料--珊瑚泥在建筑表层中的应用。研究考虑了厚度效应、PVA 纤维(维纶短纤维)改性和 HPMC(羟丙基甲基纤维素)粘合剂改性。通过实验室测试和图像处理技术、分形理论和电子显微镜实验,揭示了珊瑚泥表层的宏观-机理-微观多尺度开裂规律以及 PVA 纤维和 HPMC 粘合剂的优化改性规律。结果表明,珊瑚泥表层的性能优于高岭土表层,10 毫米厚度的珊瑚泥表层的性能优于 5 毫米和 20 毫米厚度的珊瑚泥表层。随着珊瑚泥表层厚度的增加,珊瑚泥颗粒之间的接触变得更加致密,表面微裂纹的尺度减小,微孔数量减少。PVA 纤维能有效抑制宏观和微观裂缝的进一步发展,起到良好的桥接作用。珊瑚泥和 PVA 纤维之间存在着粘结和附着关系,它们在抑制宏观和中观裂缝方面具有良好的协同作用。随着 HPMC 粘合剂含量的增加,微裂纹的数量和尺度也相应减少,珊瑚泥表层的结构和性能得到进一步改善。总体而言,在抑制珊瑚泥表层开裂方面,PVA 纤维比 HPMC 粘合剂更有效。这为珊瑚泥在墙面材料中的开发和应用提供了宝贵的指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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