An innovative composite elbow manufacturing method with 6-axis robotic additive manufacturing for fabrication of complex composite structures

IF 3.6 4区 材料科学 Q2 MATERIALS SCIENCE, COMPOSITES Journal of Thermoplastic Composite Materials Pub Date : 2023-10-31 DOI:10.1177/08927057221109153
Ahmet İpekçi, Bülent Ekici
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Abstract

Filament winding method is the most commonly used method to produce profiles with different cross sections as composite product manufacturing. In this method, fiber material is wound with resin at different angles on a mold that has a suitable cross section shape. As a winding strategy, angled and helical winding can be done. Motion planning for this process is done with geodesic and nongeodesic theories. Requirement to use mold in the filament winding method increases the cost. Also, there is an obligation to helical windings. In winding of different layers, 90° angle cannot be given between the layers. To overcome all these constraints, UV curing can be achieved using photopolymer resin and continuous fiber glass fiber with the help of robotic additive manufacturing technology. Toolpath strategies for production has a key role in this work. As a tool path strategy, nonplanar slicing can be done and manufactured composite elbow in angular layers without mold. Then, under favour of 6-axis mobility of the industrial robot arm, layers can be obtained at exactly 90° angle. In addition, in this method, unlike other winding methods, internal voids, i.e. a filling rate, can be given within the cylindrical encircled layers. In order to verify whether the elbows produced with this method meet the requirements of the desired applications in the industry in terms of mechanical properties, at different filling rates (50%, 75%, 100%), winding turns (0 and 1/8), and different fiber densities (45%, 55% and 65%) 90° curved composite elbows were produced and their internal pressure strength tests were tested. Afterwards, an optimization study was carried out with the Taguchi method for the production parameters that will maximize the internal pressure strength. According to the results of the optimization study, it is seen that it is appropriate to choose the printing parameters that will obtain the highest internal pressure strength values for production with this method, 100% fill rate, 65% fiber density and 0° winding angle. The products made of this process have the advantage of easy-shaping, reasonable ratio of axial strength and encircled strength, specification easy-unifying, stable product quality.
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一种创新的六轴机器人增材制造复合材料弯头制造方法,用于复杂复合材料结构的制造
长丝缠绕法是复合材料制品制造中最常用的生产不同截面型材的方法。在这种方法中,纤维材料以不同角度与树脂缠绕在具有合适横截面形状的模具上。作为一种缠绕策略,可以进行角度缠绕和螺旋缠绕。这个过程的运动规划是用测地线和非测地线理论完成的。在长丝缠绕法中使用模具的要求增加了成本。此外,还有螺旋绕组的义务。在不同层的缠绕中,层与层之间不能有90°的夹角。为了克服所有这些限制,在机器人增材制造技术的帮助下,可以使用光聚合物树脂和连续纤维玻璃纤维实现UV固化。用于生产的工具路径策略在这项工作中起着关键作用。作为一种刀具路径策略,可以在不需要模具的情况下,在有角度的层上进行非平面切片加工。然后,利用工业机械臂的六轴可动性,可以精确地获得90°角的层。此外,在该方法中,与其他缠绕方法不同,可以在圆柱形包围层内给定内部空隙,即填充率。为了验证用该方法生产的弯头在力学性能方面是否满足工业应用的要求,在不同填充率(50%、75%、100%)、缠绕匝数(0和1/8)、不同纤维密度(45%、55%和65%)下生产了90°弯曲的复合材料弯头,并进行了内压强度试验。随后,采用田口法对最大内压强度的生产参数进行了优化研究。优化研究结果表明,采用该方法生产时,可获得最高内压强度值的印刷参数为:100%填充率、65%纤维密度、0°缠绕角。该工艺生产的产品具有成型方便、轴向强度与围向强度比合理、规格易于统一、产品质量稳定等优点。
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来源期刊
Journal of Thermoplastic Composite Materials
Journal of Thermoplastic Composite Materials 工程技术-材料科学:复合
CiteScore
8.00
自引率
18.20%
发文量
104
审稿时长
5.9 months
期刊介绍: The Journal of Thermoplastic Composite Materials is a fully peer-reviewed international journal that publishes original research and review articles on polymers, nanocomposites, and particulate-, discontinuous-, and continuous-fiber-reinforced materials in the areas of processing, materials science, mechanics, durability, design, non destructive evaluation and manufacturing science. This journal is a member of the Committee on Publication Ethics (COPE).
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