半结晶聚合物纤维熔融纺丝的粘弹性模型层次

IF 2.7 2区工程技术 Q2 MECHANICS

Journal of Non-Newtonian Fluid Mechanics Pub Date : 2024-11-16 DOI:10.1016/j.jnnfm.2024.105349

Manuel Ettmüller , Walter Arne , Nicole Marheineke , Raimund Wegener

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引用次数: 0

摘要

在半结晶聚合物的纤维熔融纺丝中，纤维截面上的结晶程度可能是不均匀的，从而影响最终产品的性能。对于基于仿真的工艺设计，问题是必须在径向上解决哪些纤维数量和模型方程，以捕获所有实际相关的影响，同时暗示一个可以通过合理的努力计算的模型。在本文中，我们提出了粘弹性两相纤维模型的层次结构，从复杂的，完全分解的和非常昂贵的三维描述到横截面平均的，便宜的评估一维模型。特别是，我们提出了一种新的应力平均二维纤维模型，它绕过了Doufas等人（2001）建立的应力分解纤维模型中对进口剖面的额外假设。仿真结果验证了该降维模型的性能和应用范围。新的应力平均变体提供了快速和可靠的结果，特别是在低流动增强结晶的情况下。

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Viscoelastic model hierarchy for fiber melt spinning of semi-crystalline polymers

In the fiber melt spinning of semi-crystalline polymers, the degree of crystallization can be non-homogeneous over the cross-section of the fiber, affecting the properties of the end product. For simulation-based process design, the question arises as to which fiber quantities and hence model equations must be resolved in radial direction to capture all practically relevant effects and at the same time imply a model that can be computed with reasonable effort. In this paper, we present a hierarchy of viscoelastic two-phase fiber models ranging from a complex, fully resolved and highly expensive three-dimensional description to a cross-sectionally averaged, cheap-to-evaluate one-dimensional model. In particular, we propose a novel stress-averaged one-two-dimensional fiber model, which circumvents additional assumptions on the inlet profiles needed in the established stress-resolved fiber model by Doufas et al. (2001). Simulation results demonstrate the performance and application regime of the dimensionally reduced models. The novel stress-averaged variant provides fast and reliable results, especially in the regime of low flow-enhanced crystallization.

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来源期刊

Journal of Non-Newtonian Fluid Mechanics 物理-力学

CiteScore

5.00

自引率

19.40%

发文量

109

审稿时长

61 days

期刊介绍： The Journal of Non-Newtonian Fluid Mechanics publishes research on flowing soft matter systems. Submissions in all areas of flowing complex fluids are welcomed, including polymer melts and solutions, suspensions, colloids, surfactant solutions, biological fluids, gels, liquid crystals and granular materials. Flow problems relevant to microfluidics, lab-on-a-chip, nanofluidics, biological flows, geophysical flows, industrial processes and other applications are of interest. Subjects considered suitable for the journal include the following (not necessarily in order of importance): Theoretical, computational and experimental studies of naturally or technologically relevant flow problems where the non-Newtonian nature of the fluid is important in determining the character of the flow. We seek in particular studies that lend mechanistic insight into flow behavior in complex fluids or highlight flow phenomena unique to complex fluids. Examples include Instabilities, unsteady and turbulent or chaotic flow characteristics in non-Newtonian fluids, Multiphase flows involving complex fluids, Problems involving transport phenomena such as heat and mass transfer and mixing, to the extent that the non-Newtonian flow behavior is central to the transport phenomena, Novel flow situations that suggest the need for further theoretical study, Practical situations of flow that are in need of systematic theoretical and experimental research. Such issues and developments commonly arise, for example, in the polymer processing, petroleum, pharmaceutical, biomedical and consumer product industries.