Effects of water soaking-drying cycles on thermally modified spruce wood-plastic composites

IF 0.8 4区 工程技术 Q3 FORESTRY
Susanna Källbom, K. Lillqvist, S. Spoljaric, J. Seppälä, K. Segerholm, L. Rautkari, M. Hughes, M. Wålinder
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引用次数: 7

Abstract

The overall aim of this work was to gain more insight on the potential of modified wood (TMW) components for use in wood–thermoplastic composites (WPCs). Laboratory-scale TMWPCs were produced, and the effects of severe water soaking–drying cycles on the samples were studied. Water sorption behavior and resulting dimensional and micromorphological changes were also studied, and the results were compared with those of unmodified wood–plastic composites (UWPCs) used as control. The TMW was prepared by cutting a spruce board into half and subjecting one-half to an atmosphere of superheated steam at atmospheric pressure with a peak temperature of 210°C, with the other unmodified wood (UW) half as a control. The TMW and UW components were then prepared by a Wiley mill and thereafter sifted into smaller (mesh 0.20-0.40 mm) and larger (mesh 0.40-0.63 mm) size fractions. A portion of the wood components were also subjected to thermal extraction (HE). Composite samples with these different wood components, polypropylene (PP) matrix, and maleated PP (MAPP) as coupling agent (50/48/2 wood/PP/MAPP ratio by weight) were then prepared by using a Brabender mixer followed by hot pressing. The matching micromorphology of the composites before and after the soaking–drying cycles was analyzed using a surface preparation technique based on ultraviolet-laser ablation combined with scanning electron microscopy. The results of the water absorption tests showed, as hypothesized, a significantly reduced water absorption and resulting thickness swelling at the end of a soaking cycle for the TMWPCs compared with the controls (UWPCs). The water absorption was reduced with about 50-70% for TMWPC and 60-75% for HE-TMWPC. The thickness swelling for TMWPCs was reduced with about 40-70% compared with the controls. Similarly, the WPCs with HE-UW components absorbed about 20-45% less moisture and showed a reduced thickness swelling of about 25-40% compared with the controls. These observations also were in agreement with the micromorphology analysis of the composites before and after the moisture cycling which showed a more pronounced wood–plastic interfacial cracking (de-bonding) as well as other microstructure changes in the controls compared with those prepared with TMW and HE-UW components. Based on these observations, it is suggested that these potential bio-based building materials show increased potential durability for applications in harsh outdoor environments, in particular TMWPCs with a well-defined and comparably small size fractions of TMW components.
水浸泡-干燥循环对热改性云杉木塑复合材料的影响
这项工作的总体目标是深入了解改性木材(TMW)组件在木材热塑性复合材料(wpc)中的应用潜力。制作了实验室规模的TMWPCs,并研究了剧烈的水浸-干燥循环对样品的影响。研究了改性木塑复合材料的吸水行为和微观形貌变化,并与未改性木塑复合材料(UWPCs)作对照。TMW是通过将云杉板切成两半,并将一半置于大气压下的过热蒸汽中,峰值温度为210°C,另一半未改性木材(UW)作为对照来制备的。然后通过Wiley磨机制备TMW和UW组分,然后筛选成较小(目数0.20-0.40 mm)和较大(目数0.40-0.63 mm)的组分。一部分木材部件也进行了热萃取(HE)。然后使用Brabender混合机进行热压制备,将这些不同的木材成分,聚丙烯(PP)基体和马来化PP (MAPP)作为偶联剂(木材/PP/MAPP的重量比为50/48/2)制备复合样品。采用基于紫外激光烧蚀结合扫描电镜的表面制备技术,分析了复合材料在浸泡-干燥循环前后的匹配微观形貌。吸水试验结果表明,与对照组(UWPCs)相比,在浸泡周期结束时,TMWPCs的吸水率显著降低,从而导致厚度膨胀。TMWPC的吸水率降低了50-70%,HE-TMWPC的吸水率降低了60-75%。与对照组相比,TMWPCs的厚度肿胀减少了约40-70%。同样,与对照组相比,含有HE-UW成分的wpc吸收水分减少约20-45%,厚度膨胀减少约25-40%。这些观察结果也与湿循环前后复合材料的微观形貌分析相一致,表明与用TMW和HE-UW组分制备的复合材料相比,对照组的木塑界面开裂(脱键)和其他微观结构变化更为明显。基于这些观察,建议这些潜在的生物基建筑材料在恶劣的室外环境中表现出更高的耐久性,特别是具有明确定义和相对较小尺寸的TMW组分的tmwpc。
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
Wood and Fiber Science
Wood and Fiber Science 工程技术-材料科学:纺织
CiteScore
7.50
自引率
0.00%
发文量
23
审稿时长
>12 weeks
期刊介绍: W&FS SCIENTIFIC ARTICLES INCLUDE THESE TOPIC AREAS: -Wood and Lignocellulosic Materials- Biomaterials- Timber Structures and Engineering- Biology- Nano-technology- Natural Fiber Composites- Timber Treatment and Harvesting- Botany- Mycology- Adhesives and Bioresins- Business Management and Marketing- Operations Research. SWST members have access to all full-text electronic versions of current and past Wood and Fiber Science issues.
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