Thermochemical Valorization of Plastic Waste Containing Low Density Polyethylene, Polyvinyl Chloride and Polyvinyl Butyral into Thermal and Fuel Energy

Energies Pub Date : 2024-07-13 DOI:10.3390/en17143458
Beata Jabłońska, Gabriela Poznańska, Paweł Jabłoński, Joanna Zwolińska
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Abstract

Pyrolysis is a promising technology for transforming waste plastics (WPs) into high-value products. In the near future it will play a key role in the circular economy, as a sustainable and environmentally friendly method of managing this waste. Although the literature reports on the pyrolysis of plastics, it is focused on pure polymers. On the other hand, the state-of-the-art knowledge about the pyrolysis of mixed and contaminated WPs is still scarce. Industrial waste processing usually uses polymer mixtures containing various impurities that influence the pyrolysis process during chemical WPs recycling. In the paper the pyrolysis of three types of WPs: low density polyethylene (LDPE), polyvinyl chloride (PVC) and polyvinyl butyral (PVB) from repeated mechanical recycling of plastics, as well as their binary and ternary mixtures, is considered. The influence of particular components on the pyrolysis process is analyzed. The aim is to determine synergistic behavior of the mixtures during the pyrolysis process, which is important for increasing the efficiency and quality of the obtained bioproducts. Methods such as thermogravimetric (TG/DTG) analysis coupled with Fourier transform infrared spectroscopy (FTIR) and mass spectroscopy (MS) are used. The variations in the initial and final temperature of pyrolysis, mass loss and mass loss rate are determined. The content of PVC significantly lowers the initial temperature and mass loss and increases the final temperature. The pyrolysis of the considered mixtures shows a noticeable synergism—in the initial stage of pyrolysis up to a temperature around 450 °C, the mass loss is accelerated compared to what is predicted by simple superposition. The inhomogeneity of the mixtures as well as the waste origin causes a significant variation in the activation energy. Three main conclusions are obtained: (i) if the waste does not contain PVC, the pyrolysis is nearly complete at a temperature around 500 °C at a heating rate of 10 °C/min, whereas PVC is not fully processed even at 995 °C; (ii) the synergistic effects affect significantly the pyrolysis process by accelerating some steps and lowering the activation energy; and (iii) the presence of PVC noticeably lowers the temperature of the first stage of PVB pyrolysis. The investigation results prove that chemical recycling of mixed LDPE, PVC and PVB waste can be an effective method of plastic waste management.
将含低密度聚乙烯、聚氯乙烯和聚乙烯醇缩丁醛的塑料废弃物转化为热能和燃料的热化学增值技术
热解是将废塑料(WPs)转化为高价值产品的一项前景广阔的技术。在不久的将来,它将在循环经济中发挥关键作用,成为一种可持续和环保的废物管理方法。尽管有文献对塑料热解进行了报道,但主要集中在纯聚合物方面。另一方面,有关混合和受污染可湿性粉剂热解的最新知识仍然很少。工业废物处理通常使用含有各种杂质的聚合物混合物,这些杂质会影响化学可湿性粉末回收过程中的热解过程。本文研究了三种可湿性粉末(低密度聚乙烯 (LDPE)、聚氯乙烯 (PVC) 和聚乙烯醇缩丁醛 (PVB))以及它们的二元和三元混合物的热解。分析了特定成分对热解过程的影响。目的是确定混合物在热解过程中的协同行为,这对提高所获生物产品的效率和质量非常重要。研究采用了热重(TG/DTG)分析、傅立叶变换红外光谱(FTIR)和质谱(MS)等方法。测定了热解初始温度和最终温度的变化、质量损失和质量损失率。聚氯乙烯的含量大大降低了初始温度和质量损失,提高了最终温度。与简单叠加法预测的结果相比,所考虑的混合物在热解的初始阶段到 450 ℃ 左右的温度期间,质量损失会加快。混合物的不均匀性和废物来源导致活化能的显著变化。研究得出了三个主要结论:(i) 如果废料中不含聚氯乙烯,在加热速度为 10 °C/min 时,热解过程在 500 °C 左右的温度下基本完成,而聚氯乙烯即使在 995 °C 的温度下也不能完全处理;(ii) 协同效应通过加速某些步骤和降低活化能而对热解过程产生重大影响;(iii) 聚氯乙烯的存在明显降低了 PVB 热解第一阶段的温度。研究结果证明,对 LDPE、PVC 和 PVB 混合废料进行化学回收是一种有效的塑料废料管理方法。
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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