避免旋转打褶中的局部化不稳定性

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
Tian Yu , J.A. Hanna
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引用次数: 1

摘要

旋转打褶是一种广泛使用的由非织造布制成过滤器的工艺。这包括通过将材料连续注入手风琴形状的包装中,对预先弱化的折痕进行间接的弹塑性弯曲。这一步骤可能会因定位不稳定性而失败,定位不稳定性会在褶皱面而不是所需的折痕位置产生扭结。在本工作中,我们考虑了几何参数和材料参数对旋转打褶过程的影响。我们将该过程公式化为具有铰链连接的平面不可伸展杆的多点变弧长边值问题。刻面(杆)和折痕(铰链)都服从非线性矩-曲率或矩-角本构定律。注意到在材料注入点的套筒边界条件的一些意想不到的方面,这是许多连续片材工艺中常见的。这一过程被建模为准静态,具有多重平衡的特点,我们通过数值延拓进行了探索。可能稳定的扭结平衡的存在被视为潜在褶皱失效的保守迹象。故障也可能由于注射点的定位而发生。因此,我们可以获得将参数空间划分为机械打褶成功或失败的区域的“可打褶表面”。打褶的成功主要取决于注射点和打褶包装之间的距离。其他因素,如相对于刻面的折痕刚度和强度,也会产生影响。我们的方法可以适用于研究其他褶皱和成型过程、折叠结构的展开和折叠,或柔顺结构的多重稳定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Avoiding localization instabilities in rotary pleating

Rotary pleating is a widely used process for making filters out of nonwoven fabric sheets. This involves indirect elastic–plastic bending of pre-weakened creases by continuously injecting material into an accordion-shaped pack. This step can fail through a localization instability that creates a kink in a pleat facet instead of in the desired crease location. In the present work, we consider the effects of geometric and material parameters on the rotary pleating process. We formulate the process as a multi-point variable-arc-length boundary value problem for planar inextensible rods, with hinge connections. Both the facets (rods) and creases (hinges) obey nonlinear moment–curvature or moment–angle constitutive laws. Some unexpected aspects of the sleeve boundary condition at the point of material injection, common to many continuous sheet processes, are noted. The process, modeled as quasistatic, features multiple equilibria which we explore by numerical continuation. The presence of, presumably stable, kinked equilibria is taken as a conservative sign of potential pleating failure. Failure may also occur due to localization at the injection point. We may thus obtain “pleatability surfaces” that separate the parameter space into regions where mechanical pleating will succeed or fail. Successful pleating depends primarily on the distance between the injection point and the pleated pack. Other factors, such as the crease stiffness and strength relative to that of the facets, also have an influence. Our approach can be adapted to study other pleating and forming processes, the deployment and collapse of folded structures, or multi-stability in compliant structures.

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来源期刊
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
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68 days
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