Metal additive manufacturing has transformed the product design process by enabling the fabrication of components with complex geometries that cannot be manufactured using conventional methods. Initial designs can be further enhanced by employing topology optimization software and Design for Metal Additive Manufacturing (DFMAM) guidelines. In this study, a commercially available bicycle spider-crank was optimized for three-dimensional (3D) metal manufacturing. The 3D surface geometry of the original spider-crank was acquired using a white light scanner and used to generate a 3D solid model of the part. Boundary conditions were obtained from cycling loads found in published literature and applied to an ANSYS Finite Element Analysis (FEA) model. The FEA model was analyzed to determine the von Mises stress throughout the part. ANSYS Topology Optimization software was applied to the model. The software uses an iterative process to remove low stress material and recalculate stress within the part until no more material can be removed without exceeding a target maximum stress value. Following topology optimization. DFMAM principles were applied to enable the part to be 3D printed. Results from the FEA showed the DFMAM optimized design to be 41.5% lighter than the original design. The maximum stress increased from 41.2% of the material yield strength to 61.5% in the DFMAM optimized design, which exceeded the target optimization value of 50% yield strength. Analysis results were verified experimentally. The original design and DFMAM optimized design were printed using an EOS M 290 metal additive manufacturing machine. Parts were separated from the support structure and tested on a universal testing machine. A custom testing apparatus was designed and built to conduct the testing. Testing was performed at 15 degrees intervals throughout the range of motion. Strain gages attached to the arm of the crank were used to obtain stress values at specific locations and dial indicators were used to measure the deflection of the crank arm under load. Experimental results closely matched results obtained from the FEA, validating the model. With the model validated at specific locations, it was assumed that the stress calculated by the FEA at the critical points were also accurate. The results showed the topology optimization software to be an effective and useful tool for optimizing the design of 3D metal printed parts. However, topology optimization alone was not enough to finalize a design prior to printing. The application of DFMAM principles were needed to ensure that the overhanging structures would not collapse during printing. Because the determination of what constitutes an overhang is determined by the part orientation when printed, some modification will generally be required prior to printing. In conclusion, using a bicycle spider-crank as an example, this research has shown that the use of topology optimization software and Design for Metal Additive Manufacturing principles is able to reduce the weight of a 3D metal printed part while simultaneously achieving a maximum stress near a target value.
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机译:金属增材制造通过制造具有复杂几何形状的部件而无法使用常规方法制造,从而改变了产品设计过程。通过采用拓扑优化软件和金属增材制造设计(DFMAM)指南,可以进一步增强初始设计。在这项研究中,针对三维(3D)金属制造对市售的自行车曲柄进行了优化。使用白光扫描仪获取原始蜘蛛曲柄的3D表面几何形状,并用于生成零件的3D实体模型。边界条件是从已发表文献中发现的循环载荷中获得的,并已应用于ANSYS有限元分析(FEA)模型。分析FEA模型以确定整个零件的von Mises应力。将ANSYS拓扑优化软件应用于该模型。该软件使用迭代过程来去除低应力材料并重新计算零件内的应力,直到在不超过目标最大应力值的情况下不能去除更多材料为止。以下拓扑优化。应用DFMAM原理使零件可以3D打印。 FEA的结果表明DFMAM优化的设计比原始设计轻41.5%。在DFMAM优化设计中,最大应力从材料屈服强度的41.2%增加到61.5%,超过了50%屈服强度的目标优化值。分析结果经过实验验证。原始设计和DFMAM优化设计是使用EOS M 290金属增材制造机印刷的。将零件与支撑结构分开,并在通用测试机上进行测试。设计并构建了定制的测试设备来进行测试。在整个运动范围内,以15度间隔进行测试。使用附接到曲柄臂上的应变仪获得特定位置的应力值,并使用百分表测量载荷下曲柄臂的挠度。实验结果与从FEA获得的结果非常匹配,从而验证了模型。通过在特定位置验证模型,可以假定FEA在临界点计算出的应力也是准确的。结果表明,拓扑优化软件是优化3D金属印刷零件设计的有效工具。但是,仅拓扑优化不足以在打印之前完成设计。需要使用DFMAM原理来确保悬垂结构在打印过程中不会崩溃。由于确定什么构成突出部分是由打印时的零件方向决定的,因此在打印之前通常需要进行一些修改。总而言之,以自行车的曲柄为例,该研究表明,使用拓扑优化软件和金属增材制造原理设计可以减轻3D金属印刷件的重量,同时在接近3D的情况下获得最大应力。目标值。
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