Complex Study of the Composite Building Material Based on Flax Straw Organic Waste: Hygrothermal and Physicochemical Properties

IF 2.6 4区 环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES
Pavel Cerny, Maryna Babenko, Petr Bartos, Yevhen Kononets, Pavel Kriz, Roman Rabenseifer, Frantisek Spalek
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Abstract

Abstract The focus of this study is on the hygrothermal and mechanical properties of the elaborated insulating composite based on flax straw. Flax straw is considered as an agricultural waste of organic origin, which has a high sorption capacity and a low thermal conductivity potential due to its natural porosity. Investigations on sorption moisture, thermal conductivity and mechanical properties under laboratory conditions have allowed us to develop a perspective building material suitable for use in ‘green’ construction, especially in rural areas, due to the relative accessibility of the base component. Liquid glass is proposed as a binder. The optimal composition of the filler and binder, sorption moisture, thermal conductivity and surface mapping of the proposed material were investigated. The thermal conductivity reached a minimum value of 0.0728 W m −1 K −1 at relative humidity of 50% during desorption, which is highly competitive to the values for conventional insulation materials on an organic basis. The binder was visually distributed evenly over the surface according to the SEM analysis. Corresponding to the spectral analysis by chemical elements, Na and SiO 2 in total showed 17.69% quantity volume on the composite surface of 2–5 μm in depth. Graphical Abstract
亚麻秸秆有机废弃物复合建筑材料的复合研究:湿热及理化性能
摘要研究了亚麻秸秆复合保温材料的热湿性能和力学性能。亚麻秸秆被认为是一种有机来源的农业废弃物,由于其天然多孔性,具有高吸附能力和低导热潜力。在实验室条件下对吸湿性、导热性和机械性能的研究使我们能够开发出一种适合“绿色”建筑的建筑材料,特别是在农村地区,因为基础成分相对容易接近。建议用液态玻璃作为粘合剂。研究了填料和粘结剂的最佳配比、吸湿率、导热系数和表面映射。在解吸过程中,相对湿度为50%时,导热系数达到了0.0728 W m−1 K−1的最低值,与传统的有机绝缘材料相比具有很强的竞争力。根据SEM分析,粘结剂在表面上均匀分布。与化学元素光谱分析相对应的是,在2 - 5 μm深度的复合材料表面,Na和sio2的总含量为17.69%。图形抽象
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来源期刊
Waste and Biomass Valorization
Waste and Biomass Valorization ENVIRONMENTAL SCIENCES-
CiteScore
7.90
自引率
3.10%
发文量
311
审稿时长
4 months
期刊介绍: Until the 1990s, technology was the main driver when dealing with waste and residues, the objective being the treatment of waste for (landfill) disposal, storage, and in some cases sorting. In the 1990s, depletion of raw materials and socio-economical concerns supported the direct recycling of waste and residues. However, the direct recycling approach is limited when waste/residues contain significant amounts of pollutants such as heavy metals and organics (VOC, PAH), and when the treatment process to remove/stabilize or destruct the pollutant generates emissions. Due to depletion of natural resources, increasing greenhouse emissions, and awareness of the need for sustainable development in terms of safely reusing waste and biomass, the transformation of waste/biomass to valuable materials and energy (i.e. valorization) is emerging as a strong trend
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