Evaluation of Mechanical Properties of Composites Manufactured from Recycled Tetra Pak® Containers

Tecnura Pub Date : 2020-10-01 DOI:10.14483/22487638.16296

Sebastián Macías Gallego, Álvaro Guzmán Aponte, Robison Buitrago Sierra, Juan Felipe Santa Marín

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引用次数: 2

Abstract

Context: Tetra Pak® is a common material used for the production of food containers. Currently, those containers are recycled by physical separation of the cellulose fibers through a hydro pulped process, but sometimes separating the individual components is not economically viable. This work evaluates an alternative process to obtain composites from recycled Tetra Pak®. Methodology: Tetra Pak® used containers were collected and cut into small pieces at the laboratory. Then, the containers were hot-pressed to obtain sheets in a manual hydraulic press by using different configurations. Samples were cut, and their tensile strength was evaluated (ASTM D3039). Failure analysis of samples was carried out by FE-SEM to identify issues related to processing and to understand the differences in mechanical properties. Results: The results showed that the lowest tensile strength was 9.5 MPa (type I sample) and the highest tensile strength was 37.4 MPa (type III sample). Conclusions: The results of mechanical tests show that this material can be used for non-structural purposes in the building industry. Failure analysis shows that fiber pull-out and delamination are the most important failure mechanisms in type I samples. For type III sample, failure was produced by a sequence of intralaminar fractures

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回收利乐®容器制造的复合材料的机械性能评估

背景：利乐®是一种用于生产食品容器的常见材料。目前，这些容器是通过水力制浆工艺对纤维素纤维进行物理分离来回收的，但有时分离单个成分在经济上是不可行的。这项工作评估了从回收的利乐®中获得复合材料的替代工艺。方法：在实验室收集利乐®使用过的容器并切成小块。然后，通过使用不同的配置，在手动液压机中对容器进行热压以获得片材。切割样品，并评估其拉伸强度（ASTM D3039）。通过FE-SEM对样品进行失效分析，以确定与加工相关的问题，并了解机械性能的差异。结果：拉伸强度最低为9.5MPa（I型试样），最高为37.4MPa（III型试样）。结论：力学试验结果表明，该材料可用于建筑行业的非结构用途。失效分析表明，纤维拔出和分层是I型样品中最重要的失效机制。对于III型样本，故障是由一系列层内骨折引起的

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Tecnura

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审稿时长

40 weeks