Investigate the Processability of Biobased Thermoplastics Used in Nonwoven Fabrics

Aravin Prince Periyasamy*, Enni Luoma, Tim Höhnemann, Simon Ringger and Pirjo Heikkilä, 
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Abstract

The Covid-19 pandemic increased enormously the manufacturing and usage of face masks and other personal protective equipment (PPE), resulting in accumulation of plastic waste and, thus, causing universal environmental concerns. In addressing the issue of waste reduction and finding alternatives for fossil-based products, investigation of different biobased and biodegradable polymers plays a crucial role. This study examines the processability characteristics of three commonly used biobased polymers available in the market: biobased poly(lactic acid) (PLA), partly biobased and biodegradable poly(butylene succinate) (PBS), and biobased high-density poly(ethylene) (BioHDPE). The investigation combines substantial polymer analysis with subsequent processability trials in two different spunmelt processes, namely, meltblow (MB) and the Nanoval technology, aiming to reveal the differences and difficulties in the processing behavior and pointing out advantages and/or disadvantages of the respective polymer/technology combination. In general, the observed processability behavior and outcomes indicate that within the used processes PLA exhibits superior processability compared to PBS and BioHDPE. Both the meltblow and Nanoval processing of PLA demonstrated a consistent production of fibers and efficient uptake without any compromise on the throughput. In contrast, the processing of PBS using Nanoval required the utilization of significantly elevated temperatures, as indicated by a rheological study. Furthermore, the rheological evaluation revealed that the viscosity of BioHDPE was excessively elevated, rendering it unsuitable for effective processing by the Nanoval method. The microfibers in the PLA-based meltblown fabric had a higher surface area, explaining why the PLA fibers were able to function as a barrier and, thus, contribute to the mitigation of air permeability adjustable between 500 and 1000 l·s–1·m–2 and thus competitive or even superior to PP nonwovens of the same fiber diameter and base weight (1480 l·s–1·m–2). Overall, these results showed that PLA can be an alternative raw material for fossil-based nonwovens of PPE applying, especially, the meltblown technique.

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调查无纺布中使用的生物基热塑性塑料的可加工性
Covid-19 大流行极大地增加了口罩和其他个人防护设备(PPE)的生产和使用,导致塑料废物的积累,从而引起了普遍的环境问题。在解决减少废物和寻找化石基产品替代品的过程中,对不同生物基和生物可降解聚合物的研究起到了至关重要的作用。本研究考察了市场上三种常用生物基聚合物的加工性特征:生物基聚乳酸(PLA)、部分生物基和生物可降解聚丁二酸丁二醇酯(PBS)以及生物基高密度聚乙烯(BioHDPE)。调查结合了大量的聚合物分析和随后在两种不同纺熔工艺(即熔喷(MB)和 Nanoval 技术)中进行的加工性试验,旨在揭示加工行为中的差异和困难,并指出相应聚合物/技术组合的优势和/或劣势。总体而言,观察到的加工性能和结果表明,在所使用的工艺中,聚乳酸的加工性能优于聚苯乙烯和生物高密度聚乙烯。聚乳酸的熔喷法和纳诺瓦法都能稳定地生产纤维,并在不影响产量的情况下实现高效吸收。相比之下,正如流变学研究表明的那样,使用 Nanoval 处理 PBS 需要显著升高温度。此外,流变学评估显示,生物高密度聚乙烯的粘度过高,不适合使用 Nanoval 方法进行有效加工。基于聚乳酸的熔喷织物中的微纤维具有更大的表面积,这就解释了为什么聚乳酸纤维能够起到阻隔作用,从而有助于降低可调的透气性(500 至 1000 l-s-1-m-2),因此与具有相同纤维直径和基重(1480 l-s-1-m-2)的聚丙烯无纺布相比,聚乳酸纤维具有竞争力,甚至更胜一筹。总之,这些结果表明,聚乳酸可以作为化石基非织造布的替代原料,用于生产个人防护设备,特别是熔喷技术。
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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