Three-phases bubble column to polyethylene terephthalate depolymerization for cement mortar composites improvement

Q3 Engineering

Journal of Achievements in Materials and Manufacturing Engineering Pub Date : 2022-05-01 DOI:10.5604/01.3001.0016.0284

A. Hameed, M. Alzuhairi, S. Ibrahim

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引用次数: 0

Abstract

This paper aims to prepare depolymerized polyethylene terephthalate (DPET) powder from recycled plastic water bottles. Adding this DPET powder to the cement mortar was also studied. The adopted PET depolymerization process includes the usage of both ethylene glycol (EG) as solvent and nano-MgO as a catalyst. A bubble column reactor was designed for this process. Five different mortar groups were made; each has different DPET content of 0%, 1%, 3%, 6% and 9% as a sand replacement. The flexural strength test and the water absorption measurement are done after two curing periods: 7 and 28 days. The research finding demonstrated that the flexural strength of mortar was reduced by increasing the DPET powder percentage and the maximum dropping was 15% when 9% of DPET was added. The ability of the mortar to absorb the water was reduced by 14.5% when DPET powder was 9%. The mortar microstructure is featured with fewer cavities and porosity. This work’s employed bubble column technique is limited only to the laboratory environment and needs to be scaled up within industrial mass production. For future research, it is suggested to decrease depolymerization time by using smaller pieces of plastic water bottle waste and trying other types of nanocatalyst. The modified mortar can be utilized in areas where moisture, rainfalls, and sanitation systems exist. The article claims that depolymerized waste PET improves chemical process efficiency by lowering reaction time and improving mass and heat transfer rates. Besides, this approach saves money. It is found out that the depolymerized plastic waste is much more functional due to its high cohesion capability than being used as small PET pieces.

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三相泡柱以聚对苯二甲酸乙二醇酯解聚用于水泥砂浆复合材料的改进

以回收塑料水瓶为原料制备聚对苯二甲酸乙二醇酯(DPET)粉末。并对该DPET粉体在水泥砂浆中的添加进行了研究。所采用的PET解聚工艺包括使用乙二醇(EG)作为溶剂和纳米氧化镁作为催化剂。为此设计了气泡塔反应器。五个不同的迫击炮组;每种砂的DPET含量分别为0%、1%、3%、6%和9%。抗弯强度试验和吸水率测定分别在7天和28天后进行。研究结果表明，增加DPET粉的掺量会降低砂浆的抗折强度，当DPET粉掺量为9%时，砂浆的抗折强度最大下降15%。当DPET粉含量为9%时，砂浆的吸水能力降低了14.5%。砂浆微观结构具有孔洞少、孔隙率低的特点。这项工作所采用的气泡柱技术仅限于实验室环境，需要在工业批量生产中扩大规模。在未来的研究中，建议通过使用更小的塑料水瓶废料和尝试其他类型的纳米催化剂来缩短解聚时间。改性砂浆可用于潮湿，降雨和卫生系统存在的地区。文章声称，解聚废PET通过降低反应时间和提高质量和传热率来提高化学过程效率。此外，这种方法节省了资金。研究发现，与PET小片相比，解聚后的废塑料具有较强的内聚能力，具有更大的功能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Achievements in Materials and Manufacturing Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

2.10

自引率

0.00%

发文量

期刊介绍： The Journal of Achievements in Materials and Manufacturing Engineering has been published by the Association for Computational Materials Science and Surface Engineering in collaboration with the World Academy of Materials and Manufacturing Engineering WAMME and the Section Metallic Materials of the Committee of Materials Science of the Polish Academy of Sciences as a monthly. It has 12 points which was received during the evaluation by the Ministry of Science and Higher Education journals and ICV 2017:100 on the ICI Journals Master list announced by the Index Copernicus. It is a continuation of "Proceedings on Achievements in Mechanical and Materials Engineering" published in 1992-2005. Scope: Materials[...] Properties[...] Methodology of Research[...] Analysis and Modelling[...] Manufacturing and Processingv Biomedical and Dental Engineering and Materials[...] Cleaner Production[...] Industrial Mangement and Organisation [...] Education and Research Trends[...]