Treatment of polypropylene microfibers by atmospheric and low-pressure plasma – application to a reinforced cement composite containing recycled concrete

Acta Polytechnica CTU Proceedings Pub Date : 2023-07-24 DOI:10.14311/app.2023.40.0022

J. Ďureje, Z. Prošek, J. Trejbal, Š. Potocký, R. Hlůžek

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Abstract

The effect of atmospheric and low-pressure plasma modification on polypropylene (PP) microfibers was examined. Mechanical changes on the microfiber surfaces were observed using scanning electron microscopy (SEM). Next, wettability was measured using the packed-cell method. The fibers were applied into a cement matrix containing micro-milled recycled concrete. Test specimens were made and then the dynamic modulus of elasticity was continuously measured. After 28 days were made in the test specimens central notches to a depth of 14 mm. Finally, bending tests were performed. From the results, the fracture energy of the composite material was calculated. It was proven that low-pressure plasma modification as well as atmospheric plasma modification increases the wettability of PP fibers with water. Furthermore, it was found that samples containing plasma-modified microfibers have a higher fracture energy compared to the same samples with fibers without plasma modification. Conversely, plasma modification had no effect on the dynamic modulus of elasticity.

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常压和低压等离子体处理聚丙烯微纤维——在含再生混凝土的增强水泥复合材料中的应用

研究了常压和低压等离子体改性对聚丙烯(PP)超细纤维的影响。利用扫描电镜(SEM)观察了微纤维表面的力学变化。接下来，使用填充细胞法测量润湿性。将纤维应用到含有微磨再生混凝土的水泥基体中。制作试件，连续测量动弹性模量。28天后，在试件中央做了14毫米深的缺口。最后进行了弯曲试验。根据实验结果，计算了复合材料的断裂能。实验证明，低压等离子体改性和常压等离子体改性均能提高PP纤维的润湿性。此外，我们发现含有等离子体修饰的微纤维的样品比没有等离子体修饰的纤维具有更高的断裂能。相反，等离子体改性对动态弹性模量没有影响。

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Acta Polytechnica CTU Proceedings

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0.40

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