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Maximizing Additive Manufacturing Potential with Design Optimization in Aerospace
技术
- 传感器 - 红外传感器
适用行业
- 航天
- 生命科学
适用功能
- 产品研发
- 质量保证
用例
- 添加剂制造
- 快速原型制作
挑战
欧洲航空航天制造商 Thales Alenia Space 热衷于探索增材制造 (AM) 在其空间卫星开发项目中的潜力。该公司希望研究增材制造与设计优化技术相结合的减重潜力。面临的挑战是找到一种将这些技术与新制造技术结合使用的方法。泰雷兹阿莱尼亚宇航公司选择卫星的铝制过滤器支架作为该研究的测试用例。该支架需要其支撑部件的结构载荷、通过过滤器的气流的热载荷以及太空旅行的极端温度的独特组合。该研究的主要目标是使用设计优化技术来降低支架的热合规性,同时优化组件的重量并为增材制造工艺的最终设计做好准备。
关于客户
泰雷兹阿莱尼亚宇航公司是欧洲领先的航空航天制造商,在法国、意大利、西班牙、比利时、英国、德国和波兰开展业务。该公司为国防、地球观测、通信、导航和安全市场设计、集成、测试、运营和提供空间系统。泰雷兹阿莱尼亚航天公司在全球拥有约 7,500 名员工,处于航空航天业增材制造开发、实施和工业化的前沿。公司不断探索新技术和制造工艺,以改进其产品和服务。
解决方案
Thales Alenia Space 与 Altair ProductDesign 合作,是因为 Altair 在开发设计优化技术并将其应用于航空航天业方面拥有专业知识。 Altair ProductDesign 的第一步是将支架的现有模型转换为可与 HyperWorks 的 OptiStruct 结构分析求解器一起使用的格式,并将两个模型组合在一起以创建独特的热结构模型。这使得可以并行探索两组约束的影响。一旦确认新模型能够准确代表物理支架,团队就进入设计优化阶段。使用 OptiStruct,该团队建立了模型并指定了该技术必须遵守的众多约束条件,以便提供令人满意的解决方案。支架被分为“可设计”和“不可设计”空间部分。 OptiStruct 使用拓扑优化技术提出了一种新的材料高效设计,该设计满足性能标准,同时去除对设计没有积极影响的区域的材料。然后将建议的几何形状解释为更适合增材制造工艺的布局,并转换为可制造的 CAD 模型。
运营影响
数量效益
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