纺织学报 ›› 2024, Vol. 45 ›› Issue (03): 65-73.doi: 10.13475/j.fzxb.20221004001

• 纺织工程 • 上一篇    下一篇

血管支架预制件的六角形三维虚拟编织

丁彩红(), 顾馨, 卢晨雨   

  1. 东华大学 机械工程学院, 上海 201620
  • 收稿日期:2023-03-29 修回日期:2023-08-01 出版日期:2024-03-15 发布日期:2024-04-15
  • 作者简介:丁彩红(1973—),女,副教授,博士。主要研究方向为纺织机械机电一体化技术及机械设计和故障诊断技术。E-mail:dingch@dhu.edu.cn

Hexagonal three-dimensional virtual braiding of vascular stent preforms

DING Caihong(), GU Xin, LU Chenyu   

  1. College of Mechanical Engineering, Donghua University, Shanghai 201620, China
  • Received:2023-03-29 Revised:2023-08-01 Published:2024-03-15 Online:2024-04-15

摘要:

为解决六角形三维编织血管支架的编织工艺复杂、开发周期长的问题,提出了基于MatLab编程的支架三维虚拟编织方法,以快速完成编织工艺开发。首先,基于六角形编织机底盘的结构特点,对底盘单元进行坐标数值化,从而可将支架编织的工艺和工序转换为不同时刻下携纱器在底盘上的XY平面坐标和运动信息以及纱线在芯棒上的高度坐标z值,并应用数值计算方法进行连接和拟合,建立纱线空间轨迹的数学模型,得到虚拟支架的三维基本形态。然后,将编织支架的三维形态展开为二维形态,分析二维平铺形态下单向支架沿螺旋方向缠绕的特点,应用线性方程组求解纱线的交织点坐标,并通过层内和层间的纱线交织关系判断得到各交织点的交织类型。最后,通过方程修正得到具有六角形编织特征的纱线波动方程,进一步建立了具有纱线立体交织特征的虚拟支架实体化数学模型。经不同编织工艺的支架虚拟仿真实验,将虚拟支架与其实物进行比较发现,虚拟支架均能准确直观地表达实物的几何特征和交织特征。由此验证了虚拟仿真建模的正确性,有利于六角形三维编织工艺的快速开发。

关键词: 六角形三维编织, 血管支架, 虚拟编织, 单向管状织物, 交织判断

Abstract:

Objective The braiding process for braided vascular stent preforms is relatively straightforward and fixed, with drawbacks including weak mechanical qualities and singular applications that cannot satisfy the genuine market needs. Complex correspondence between fabrics and processes, as well as long development cycles, are issues of developing a process by hexagonal three-dimensional (3-D) braider with a variety of braiding processes. Therefore, it is suggested that a simulation technique considers the connection between the hexagonal braiding process and the fabric structure, so as to create a 3-D virtual model of the stents under particular hexagonal braiding processes and to speed up the development of braiding processes.

Method Firstly, the units were mathematically coordinated by building the geometric relationships of the hexagonal braider chassis, so that the yarn movements could be transformed from the braiding process and recorded in matrices. By using matrix operations, the spatial coordinate sets of the yarns were produced, and the related formulas for the yarn trajectory and the fundamental 3-D shape of the stent were then created. The 3-D form of the stent was expanded, and by analyzing the characteristics of the unidirectional fabric, a system of linear equations was applied to solve for the yarns' interweaving points and identify the type of interweaving in conjunction with the yarn movement. Finally, the yarn fluctuation equation was modified to generate formulas for the trajectory with interweaving properties, and the solid model of the holder was constructed and tested against the actual object to verify the correctness of the model.

Results In detail, matrixes were applied to record the information transformed by the hexagonal braiding process, and in combination with the mathematical model of the carrier-suspender-mandrel established, the tangent points of the yarn wound on the mandrel, i.e., the set of coordinates of the spatial trajectory of the yarn, were calculated by matrix operations. The discrete points in the coordinate sets were connected and fitted to create a model of the spatial trajectory of the yarn, which was compared with the trajectory obtained by the numerical calculation, suggesting that the spatial spiral curve could be used to simplify and more accurately show the spatial trajectory of the yarn, and the model obtained by this method was used as the 3-D basic form of the stent. In order to further demonstrate the interwoven form of the stent, the 3-D basic form of the stent was expanded along the z-axis direction, enabling the interweave points to be solved in reduced dimensions. On this basis, calculation of yarn winding tangent point was created to calculate the 2-D coordinates of the yarn interweaving points and to find the 3-D coordinates by means of the z-values. In addition, the z-values enabled information relating to the interweaving of the yarns in the braiding process to be found, which was used to determine the carrier interaction of the inter-weaving yarns, and in turn to apply interweaving principle to determine the change in position of the yarns in the fabric to obtain the fabric in-terweaving type (UV) defined. Based on the above, the modified yarn fluctuation equations were applied to obtain the mathematical formulas for left- and right-handed yarns reflecting the type of interweaving of the hexagonal braiding, thus creating a solid numerical model of a virtual fabric with 3-D interweaving characteristics. In order to validate the method above, 3-D virtual braiding experiments were carried out on stents with different hexagonal braiding processes, comparing the type of interweaving and related dimensions of the virtual fabric and the real one, and it was discovered that both were almost identical in terms of morphology and values. By inputting the hexagonal braiding process and dimensional parameters, the method was able to produce a corresponding 3-D model of the virtual vascular stent.

Conclusion The viability and accuracy of the virtual braiding approach for the hexagonal 3-D braiding process of the stent preforms were confirmed through modelling of forms, interwoven manipulation, and solidification of the hexagonal braided stent preforms. This would offer technical assistance for the quick advancement of the hexagonal braiding process and the evaluation of the stent's mechanical characteristics. It was important to note that many companies had concentrated on the structure of stents with variable yarn rotation and superimposed inter-weaving layers and their braiding process in addition to the widely used unidirectional structure of hexagonal 3-D braided stents. As a result, the virtual modelling needs of braided stents had been further broadened and the 3-D virtual braiding algorithm of the stent would also become more complex.

Key words: hexagonal three-dimensional braiding, vascular stent, virtual braiding, unidirectional tubular fabric, interwoven judgment

中图分类号: 

  • TH789

图1

六角形编织机及所编织物示例"

图2

六角形编织机底盘的数值化表达"

图3

纱线缠绕切点的计算"

图4

纱线缠绕切点的判断示意图"

图5

单根纱线轨迹的比较"

图6

编织支架三维基本形态"

图7

编织支架交织类型"

图8

编织支架平铺状态"

图9

编织支架的交织成因"

图10

编织支架交织示意图"

图11

编织支架实物"

图12

编织支架的实体化模型"

图13

支架实物与三维虚拟模型的对比示例"

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