A 3D rigid assembly modeling technique is developed for stream of variation analysis (SOVA) in multi-station processes. An assembly process is modeled as a spatial indexed state transition dynamic system. The model takes into account product and process factors such as: part-to-fixture, part-to-part, and inter-station interactions, which represent the influences coming from both tooling errors and part errors. The incorporation of the virtual fixture concept (Huang et al., Proc. of 2006 ASME MSEC) and inter-station interaction leads to the generic, unified SOVA model formulation. An automatic model generation technique is also developed for surmounting difficulties in modeling based on first principles. It enhances the applicability in modeling complex assemblies. The developed SOVA methodology outperforms the current simulation based techniques in computation efficiency, not only in forward analysis of complex assembly systems (tolerance analysis, sensitivity analysis), but it is also more powerful in backward analysis (tolerance synthesis and dimensional fault diagnosis). The model is validated using industrial case studies and series of simulations conducted using standardized industrial software (3DCS Analyst).
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机译:开发了3D刚性装配建模技术,用于多工位过程中的变化分析(SOVA)。组装过程被建模为空间索引状态转换动态系统。该模型考虑了产品和过程因素,例如:零件到夹具,零件到零件以及站间交互作用,这些因素代表了来自工具错误和零件错误的影响。虚拟夹具概念(Huang et al。,Proc。of 2006 ASME MSEC)和站间交互作用的结合导致了通用的,统一的SOVA模型制定。还开发了一种自动模型生成技术,以克服基于第一原理的建模难题。它增强了对复杂装配体进行建模的适用性。发达的SOVA方法不仅在复杂装配系统的前向分析(公差分析,灵敏度分析)方面,在计算效率方面优于当前基于仿真的技术,而且在后向分析(公差综合和尺寸故障诊断)方面更强大。使用工业案例研究和使用标准化工业软件(3DCS Analyst)进行的一系列模拟对模型进行验证。
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