利用农业废弃物制成的无化学物质隔热板,实现可持续建筑材料的可持续发展

Siwat Lawanwadeekul , Nipa Jun-On , Panisara Kongthavorn , Teerawat Sangkas , Suphaporn Daothong
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引用次数: 0

摘要

为了满足对可持续建筑材料的迫切需求,本研究采用了一种创新的生态友好型方法,利用农业废料稻草作为主要材料来制造隔热板。纸浆(PP)和PK(Persea kurzii)作为非化学粘合剂的比例分别为 50:50、60:40、70:30 和 80:20。混合后,所有样品均在 5 巴的无热液压条件下进行压缩,以评估其物理、机械、热和声学特性。增加粘合剂的比例会直接影响板材密度和抗折强度,同时也会对孔隙率产生反向影响。PK 粘合剂的热导率值较低,仅为 0.040 W/mK,这证明它是一种良好的热绝缘体,同时具有较高的吸音系数,尤其是在较高频率下。RSPP-4 嵌板的降噪系数最高(0.51),可吸收低频噪音,表明其具有降噪潜力。显微分析进一步揭示了面板的表面特性。聚丙烯表面光滑,纤维编织连续,没有遮盖毛孔,而 PK 则由颗粒组成。表面特征与声学性能之间的相关性,尤其是在高频率下的相关性,凸显了材料特性之间错综复杂的平衡关系。研究成果可应用于建筑行业,以开发具有卓越热学和声学性能的可持续建筑材料。这些热声学板材可有效利用农业废弃物,并显示出作为环保建筑材料的潜力,从而提高各种建筑环境中的室内舒适度和声学性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chemical-free thermal-acoustic panels from agricultural waste for sustainable building materials

To address the pressing need for sustainable building materials, this study introduced an innovative and eco-friendly approach to manufacturing thermal-acoustic panels, utilizing agricultural waste with rice straw as the primary material. Paper pulp (PP) and Persea kurzii (PK) were used as non-chemical binders at ratios of 50:50, 60:40, 70:30, and 80:20. After mixing, all the samples were subjected to heat-free hydraulic compression at 5 bars to evaluate their physical, mechanical, thermal, and acoustic properties. Increasing the proportion of the binder directly impacted panel density and flexural strength while also inversely affecting porosity. The PK binder had a low thermal conductivity value of 0.040 W/mK, proving it was a good thermal insulator with a high sound absorption coefficient, especially at higher frequencies. The RSPP-4 panel had the highest noise reduction coefficient (0.51) and absorbed low frequencies, suggesting its potential for noise reduction. Microscopic analysis provided further insight into panel surface characteristics. PP exhibited a smooth surface with a continuous fiber weave that did not obscure the pores, while PK consisted of particles. The correlation between surface characteristics and acoustic performance, especially at high frequencies, underscored the intricate balance between material properties. Research results can be applied in the construction industry to develop sustainable building materials that offer superior thermal and acoustic properties. These thermal-acoustic panels can effectively utilize agricultural waste and show potential as environmentally friendly construction materials to enhance indoor comfort and acoustics in various building environments.

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CiteScore
9.20
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