Numerical simulation into influence of airflow channel quantities on melt-blowing airflow field in processing of polymer fiber

IF 3.2 3区 化学 Q2 POLYMER SCIENCE
e-Polymers Pub Date : 2023-12-26 DOI:10.1515/epoly-2023-0126
Dongjun Guo, Zhisong Zhu, Jie Yuan
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引用次数: 0

Abstract

To obtain better airflow field characteristics of melt-blowing and acquire slender melt-blowing fiber, a new die with multi-channel of melt-blowing airflow was designed. The airflow field under the spinneret hole of the melt-blowing die was simulated and analyzed using computational fluid dynamics method, and distribution rules of the ordinary die and the new die on the airflow field along the spinning centerline were compared and discussed. The melt-blowing fiber diameter distribution for the ordinary die and the new die was numerically calculated using a stretching model of the melt-blowing fiber. In contrast with an ordinary die, the new melt-blowing die enhances the average speed in main stretching zone by 89.8% and increases the peak speed by 50.4%. The higher airflow temperature of new die improves the softening degree and melting fluidity of the polymer. Meanwhile, the smaller turbulence intensity and the reverse speed of the new die make airflow more stable and reduce disturbance and adhesion of the fiber, and a larger pressure difference and a peak pressure can accelerate the refinement and attenuation of the fiber. The new melt-blowing die with airflow multi-channel is conducive to extension, which is a better choice in the manufacturing process of nonwoven melt-blowing fibers.
聚合物纤维加工过程中气流通道数量对熔喷气流场影响的数值模拟
为了获得更好的熔喷气流场特性和更细长的熔喷纤维,设计了一种多通道熔喷气流的新模具。采用计算流体力学方法对熔喷模具喷丝板孔下的气流场进行了模拟分析,并比较讨论了普通模具和新型模具的气流场在纺丝中心线上的分布规律。利用熔喷纤维的拉伸模型对普通模头和新型模头的熔喷纤维直径分布进行了数值计算。与普通模头相比,新型熔喷模头在主拉伸区的平均速度提高了 89.8%,峰值速度提高了 50.4%。新模具较高的气流温度提高了聚合物的软化程度和熔融流动性。同时,新模具较小的湍流强度和反向速度使气流更加稳定,减少了对纤维的扰动和粘附,较大的压差和峰值压力可加速纤维的细化和衰减。气流多通道的新型熔喷模有利于延伸,是无纺布熔喷纤维制造工艺的较佳选择。
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
e-Polymers
e-Polymers 化学-高分子科学
CiteScore
5.90
自引率
10.80%
发文量
64
审稿时长
6.4 months
期刊介绍: e-Polymers is a strictly peer-reviewed scientific journal. The aim of e-Polymers is to publish pure and applied polymer-science-related original research articles, reviews, and feature articles. It includes synthetic methodologies, characterization, and processing techniques for polymer materials. Reports on interdisciplinary polymer science and on applications of polymers in all areas are welcome. The present Editors-in-Chief would like to thank the authors, the reviewers, the editorial staff, the advisory board, and the supporting organization that made e-Polymers a successful and sustainable scientific journal of the polymer community. The Editors of e-Polymers feel very much engaged to provide best publishing services at the highest possible level.
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