Thermal insulation material produced from recycled materials for building applications: cellulose and rice husk-based material

IF 2.2 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Frontiers in Built Environment Pub Date : 2023-11-30 DOI:10.3389/fbuil.2023.1271317
N. Marín-Calvo, Sergio González-Serrud, Arthur James-Rivas
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Abstract

Construction materials derived from agro-industrial waste are increasingly attractive in the building sector, due to their sustainability and lower environmental impact. Hence, in recent years worldwide the amount of research and publications tending to the development of materials that take advantage of residues from agro-industrial activities has increased. The role of thermal insultation materials in the building envelope is significant, especially in hot-humid region. This study presents the manufacturing and evaluation of a cellulose and rice husk-based insulation material, as a proposal for the reuse of materials considered as value-added waste, such as recycled paper and rice husks. Boards and test specimens were elaborated, as well as mechanical and thermal tests. The material was evaluated by means of thermal tests, in accordance with ASTM C177, to measure the thermal conductivity. Tensile and compressive strength tests were performed, based on ASTM C209 and ASTM C39 Standard, respectively. According to the results obtained, the material shows a thermal coefficient of 0.04 W/m∙K which corresponds to a material with the potential to thermally insulate an enclosure. Maximum stresses were obtained for the 3 compositions in average for a range between 1.31 and 1.76 MPa. Ultimate compressive strength obtained was between 20.19 and 21.23 MPa. The proposed material is presented as a sustainable alternative, which can be used in the field of environmentally friendly buildings, which contribute to reducing the carbon footprint, by energy savings.
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用回收材料生产的建筑用隔热材料:纤维素和稻壳基材料
从农用工业废料中提取的建筑材料,由于其可持续性和对环境的影响较小,在建筑领域越来越具有吸引力。因此,近年来全球范围内利用农用工业废料开发材料的研究和出版物数量不断增加。保温材料在建筑围护结构中发挥着重要作用,尤其是在湿热地区。本研究介绍了纤维素和稻壳基隔热材料的生产和评估情况,这是对回收纸和稻壳等被视为高附加值废物的材料进行再利用的一项建议。我们制作了板材和测试样本,并进行了机械和热测试。根据 ASTM C177 标准,通过热测试评估了材料的导热性。拉伸和压缩强度测试分别根据 ASTM C209 和 ASTM C39 标准进行。根据测试结果,这种材料的热系数为 0.04 W/m∙K,具有隔热保温的潜力。3 种成分平均获得的最大应力在 1.31 至 1.76 兆帕之间。最终抗压强度在 20.19 至 21.23 兆帕之间。所提议的材料是一种可持续的替代材料,可用于环保建筑领域,通过节约能源减少碳足迹。
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来源期刊
Frontiers in Built Environment
Frontiers in Built Environment Social Sciences-Urban Studies
CiteScore
4.80
自引率
6.70%
发文量
266
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