三维编织技术的创新及其应用

C. Emonts, N. Grigat, F. Merkord, B. Vollbrecht, Akram Idrissi, J. Sackmann, T. Gries
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引用次数: 8

摘要

编发一般分为二维编发和三维编发。二维编发包括平面编发和圆形编发。圆形辫子代表三维纺织品,因为它们包围了一个体积,但由二维纱线结构组成。三维编织是由三维纱线结构定义的。从历史上看,三维编织物是在带有笛卡尔或径向床身的行式和柱式编织机上通过绕镶嵌纱线的线轴运动来生产的。三维旋转编织机允许更灵活的编织过程,因为线轴是通过单独控制的喇叭齿轮和开关移动的。德国亚琛工业大学纺织技术研究所(ITA)的两台编织机都是基于3D旋转机的原理。这台完全数字化的3D编织机符合工业4.0标准,可为轻量化应用提供近净形状的三维编织纺织品预制件生产。预制体可根据应用在所有三个空间方向上进行具体加固。由于高度的设计自由度,复杂的3D结构可以在一个过程步骤中产生。三维六边形编织技术应用于医用纺织品领域。喇叭齿轮的特殊形状及其六角形排列为机床上的线轴提供了最密集的填料。此外,花边编织机构允许两个线轴占据两个喇叭齿轮之间的位置,最大限度地增加了线轴的数量。其中一个主要应用是管状结构的近净形状生产,如复杂的支架结构。与二维编织相比,三维编织提供了许多优势,例如,在一个工艺步骤中生产复杂的三维几何形状,编织层的连接,生产横截面变化和分支,以及无需额外工艺步骤即可对技术纺织品进行局部加固。本文介绍了三维编织技术的最新进展、三维编织机的研制以及三维编织软件和仿真技术的发展。此外,还介绍了其在轻量化建筑和医用纺织品领域的各种应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Innovation in 3D Braiding Technology and Its Applications
Braids are generally divided into 2D braids and 3D braids. Two-dimensional braids include flat braids and circular braids. Circular braids represent three-dimensional textiles, as they enclose a volume, but consist of a two-dimensional yarn architecture. Three-dimensional braids are defined by a three-dimensional yarn architecture. Historically, 3D braids were produced on row and column braiding machines with Cartesian or radial machine beds, by bobbin movements around inlay yarns. Three-dimensional rotary braiding machines allow a more flexible braiding process, as the bobbins are moved via individually controlled horn gears and switches. Both braiding machines at the Institut für Textiltechnik (ITA) of RWTH Aachen University, Germany, are based on the principal of 3D rotary machines. The fully digitized 3D braiding machine with an Industry 4.0 standard enables the near-net-shape production of three-dimensionally braided textile preforms for lightweight applications. The preforms can be specifically reinforced in all three spatial directions according to the application. Complex 3D structures can be produced in just one process step due to the high degree of design freedom. The 3D hexagonal braiding technology is used in the field of medical textiles. The special shape of the horn gears and their hexagonal arrangement provides the densest packing of the bobbins on the machine bed. In addition, the lace braiding mechanism allows two bobbins to occupy the position between two horn gears, maximizing the number of bobbins. One of the main applications is the near-net-shape production of tubular structures, such as complex stent structures. Three-dimensional braiding offers many advantages compared to 2D braiding, e.g., production of complex three-dimensional geometries in one process step, connection of braided layers, production of cross-section changes and ramifications, and local reinforcement of technical textiles without additional process steps. In the following review, the latest developments in 3D braiding, the machine development of 3D braiding machines, as well as software and simulation developments are presented. In addition, various applications in the fields of lightweight construction and medical textiles are introduced.
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