不同构建方向和层宽的快速成型 CFRP 复合材料加工数值研究

IF 1.9 Q3 ENGINEERING, MANUFACTURING Manufacturing Letters Pub Date : 2024-10-01 DOI:10.1016/j.mfglet.2024.09.086
Sk Md Alimuzzaman , Jianfeng Ma , Muhammad P. Jahan
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引用次数: 0

摘要

过去二十年来,快速成型制造(AM)技术因其定制化和采用复杂几何形状的附加优势,以及相对较低的购买飞行比,在工业领域得到广泛应用。碳纤维增强聚合物(CFRP)复合材料因其高强度重量比的最大优势,已被应用于不同的高性能工业领域。CFRP 复合材料的快速成型制造(AM-CFRP)为利用不同的打印方向提高机械强度提供了可能,并能在保持可持续制造的前提下生产复杂形状的产品。然而,AM 零件的局限性在于表面不规则和尺寸精度有问题。要将 AM-CFRP 零件用于高精度装配或工业应用,通常需要进行后加工处理,以满足客户对几何公差和可接受表面光洁度的要求。本研究采用基于有限元分析(FEA)的数值模拟,评估了 AM 参数对 AM-CFRP 复合材料可加工性的影响。使用硬质合金端铣工具和 AM-CFRP 工件模拟了四种不同的打印方向(即 0°-90°、45°-135°、0°-90°-45°-135°)、两种不同的层宽(即 50 µm 和 100 µm)以及两种填充模式(即实心和穿孔结构)的槽铣操作。根据切削力、首次接触应力和最大应力产生情况,以及在不同 AM 参数下对 AM-CFRP 进行槽铣加工时界面的温度升高情况,分析了三维打印 CFRP 的可加工性。讨论了 AM-CFRP 在各种加工条件下的失效机制演变,如分层、基体破裂等,并分析了切屑和毛刺的形成机制。使用 ABAQUS/Explicit 有限元分析软件包对 AM-CFRP 工件的三维微槽铣削操作进行建模,并采用适当的损伤和构成模型,如相邻通道和层的损伤起始、发展和内聚。
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Numerical investigation on machining of additively manufactured CFRP composite with different build orientations and layer widths
Additive manufacturing (AM) is now a widely researched manufacturing technology in the past two decades to adopt in industry for its added advantage of customization and adopting complex geometries with comparatively low buy-to-fly ratio. Carbon fiber reinforced polymer (CFRP) composite has found applications in different high-performance industries for its greatest benefit of high strength-to-weight ratio. Additive manufacturing of CFRP composite (AM-CFRP) opens up the possibility of enhancing mechanical strength using different printing orientations and enables producing complex shapes maintaining sustainable manufacturing perspective. However, Limitation of AM parts of having surface irregularities and questionable dimensional accuracies. To use AM-CFRP parts in high precision assembly or industrial applications, post processing machining is often required to meet the customers’ specification of geometrical tolerances and acceptable surface finish. In this study, the influence of AM parameters on machinability of AM-CFRP composite has been evaluated using finite element analysis (FEA) based numerical simulation. The slot milling operation was simulated with a tungsten carbide end milling tool and AM-CFRP workpiece with four different printing directions, i.e., 0°-90°, 45°-135°, 0°-90°-45°-135°, two different layer widths, i.e., 50 µm and 100 µm, and two in-fill patterns, i.e., solid and perforated structures. The machinability of the 3D printed CFRP has been analyzed based on cutting forces, stress at first contact and maximum stress generation, and temperature increases at the interface during slot milling of AM-CFRP under different AM parameters. Evolution of failure mechanisms of AM-CFRPs under various machining conditions, such as, delamination, matrix rupture etc., have been discussed and chip and burr formation mechanisms have been analyzed. Finite Element analysis (FEA) package ABAQUS/Explicit was used to model 3D micro slot milling operation of AM-CFRP workpiece with appropriate damage and constitutive models, such as, damage initiation, progression and cohesion in adjacent passes and layers.
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来源期刊
Manufacturing Letters
Manufacturing Letters Engineering-Industrial and Manufacturing Engineering
CiteScore
4.20
自引率
5.10%
发文量
192
审稿时长
60 days
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