Utilising the microstructure of chemically and thermally activated waste textiles for noise attenuation in an urban Australian context

IF 11.2 1区环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL

Resources Conservation and Recycling Pub Date : 2023-10-01 DOI:10.1016/j.resconrec.2023.107112

Charlotte Wesley , Chaoyang Jiang , Farshid Pahlevani , Con Doolan , Heriyanto , Veena Sahajwalla

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Abstract

This study considers the suitability of end-of-life cotton textiles as a precursor for activated carbon fibre (ACF) cloth for noise attenuation. The study presents a materials transformation and valorisation technique to increase circularity of waste textiles, which is supported by strong end markets and increasing demand.

Thermal and chemical parameters were modified to identify the preferable settings for maximising the surface area of the activated carbon fibre cloth. The surface area was tested using Brunauer-Emmett-Teller (BET) Analysis. The least amount of phosphoric acid (H₃PO₄) on the sample yielded the highest surface area when comparing textile to acid dosage ratios of 1-1, 1-2, 1-3 and 1-4. Varying the water content in the 1-1 ratio had little effect on the surface area but did affect the structure. The textile - acid - water ratio of 1-1-4 was preferable to 1-1-2, as more of the textile structure remained intact under the naked eye and under the Scanning Electron Microscopy (SEM). Samples transformed under a temperature of 850 °C had a higher surface area than samples transformed at 650 °C and 950 °C, which were 1900 m²/g, 1500 m²/g. and 1600 m²/g respectively.

To maximise noise attenuation, multi-layer activated carbon fibres were created by layering the textiles prior to chemical and thermal transformation processes. By increasing the scale of production, the surface area was reduced. However, the multi-layer ACF yielded promising results even with a modest surface area of approximately 1300 m²/g. The analysis showed that the ACFs were superior to broad spectrum acoustic foams for higher frequency sound desipite being one fifth of the corresponding thickness. The findings from this study are promising for applications requiring a very thin noise attenuating barrier. This advanced material could increase circularity of waste textiles in Australia and reduce the impact of noise pollution in urban environments.

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利用化学和热活化废纺织品的微观结构在澳大利亚城市环境中衰减噪音

本研究考虑了报废棉纺织品作为活性碳纤维（ACF）布降噪前体的适用性。该研究提出了一种材料转化和定价技术，以提高废弃纺织品的循环性，这得到了强大的终端市场和不断增长的需求的支持。修改了热和化学参数，以确定最大化活性碳纤维布表面积的优选设置。使用Brunauer-Emmett-Teller（BET）分析测试表面积。当比较1-1、1-2、1-3和1-4的织物与酸的剂量比时，样品上最少量的磷酸（H3PO4）产生最高的表面积。以1-1的比例改变含水量对表面积几乎没有影响，但确实影响了结构。1-1-4的织物酸水比比1-1-2更好，因为在肉眼和扫描电子显微镜（SEM）下，更多的织物结构保持完整。在850°C的温度下转化的样品比在650°C和950°C下转化的1900 m2/g和1500 m2/g的样品具有更高的表面积。和1600m2/g。为了最大限度地降低噪音，在化学和热转化过程之前，通过对纺织品进行分层来制造多层活性碳纤维。通过增加生产规模，减少了表面积。然而，即使具有约1300m2/g的适度表面积，多层ACF也产生了有希望的结果。分析表明，ACFs比广谱声学泡沫具有更高的频率，其声音密度为相应厚度的五分之一。这项研究的发现对于需要非常薄的噪声衰减屏障的应用是有希望的。这种先进的材料可以增加澳大利亚废弃纺织品的循环性，并减少城市环境中噪音污染的影响。

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来源期刊

Resources Conservation and Recycling 环境科学-工程：环境

CiteScore

22.90

自引率

6.10%

发文量

625

审稿时长

23 days

期刊介绍： The journal Resources, Conservation & Recycling welcomes contributions from research, which consider sustainable management and conservation of resources. The journal prioritizes understanding the transformation processes crucial for transitioning toward more sustainable production and consumption systems. It highlights technological, economic, institutional, and policy aspects related to specific resource management practices such as conservation, recycling, and resource substitution, as well as broader strategies like improving resource productivity and restructuring production and consumption patterns. Contributions may address regional, national, or international scales and can range from individual resources or technologies to entire sectors or systems. Authors are encouraged to explore scientific and methodological issues alongside practical, environmental, and economic implications. However, manuscripts focusing solely on laboratory experiments without discussing their broader implications will not be considered for publication in the journal.