Lichten Award Paper: Variational Tolerance Analysis (VTA) - Design and Manufacturing Optimization Using Statistical Simulation

Andrew Lavoie
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引用次数: 0

Abstract

Appropriate consideration of tolerances is critical to the design and manufacture of products that meet customer requirements and defined cost targets. Tolerance analysis is most commonly conducted at the individual part or sub-assembly level utilizing basic stack-up methods (worst-case analysis) to ensure the producibility of the assembled product. A worst-case analysis assumes that each dimension in the stack-up will be manufactured on the extreme end or limit of its assigned tolerance (max or min) in such a way that all tolerances become additive. This usually results in tighter than required drawing tolerances being assigned to guarantee the product can be assembled. Modern day manufacturing processes focus on targeting the nominal dimensional value, so it is safe to assume that a higher number of parts will be produced closer to the nominal value than parts produced at the extreme end of the tolerance range. When evaluating the tolerance stack-up of a larger assembly with many parts additional tolerance analysis methods apply (Root Sum Squared, RSS), and a worst-case analysis becomes more costly and less meaningful. The RSS method of tolerance analysis takes into consideration manufacturing targets and applies normal distribution methods to assess more likely tolerance results, allowing relaxed drawing tolerances to be assigned while still maintaining a high level of confidence in a successful assembly. For analysis of complex systems or installations, tolerance studies using more sophisticated approaches to deal with variation such as Monte Carlo statistical analysis is required. Variational Tolerance Analysis (VTA) tools available today allow a typical Monte Carlo tolerance simulation to be visualized by the designer through 3-dimensional real time manufacturing simulations and sensitivity analysis. This in turn simplifies the development process and allows better identification of tolerance drivers within a large system installation; analysis of the geometric effect of tolerances within the installation; and the ability to quickly iterate the analysis to optimize designs for producibility and lower cost. In this paper, the use of VTA is assessed and quantified to form a business case for further investment by Lockheed Martin. In the course of this work, VTA has been evaluated both before and after final designs were released to manufacturing. Before final designs are released VTA can be used for design optimization (i.e. build before you build simulations), part sequencing studies, or to gain insight into the assembly/installation process enabling advanced planning to take place up front. VTA can also address challenges discovered after final designs have been released to manufacturing and parts are on hand (i.e. during the build) such as: assembly issues, out of spec part disposition, and to inform manufacturing of any special tooling or part rework considerations aiding in corrective action or risk mitigation plans. Cost savings to the business due to the implementation of VTA has been demonstrated in 4 distinct ways: 1.Reduced design revisions – Design optimization up front reduces future revisions caused by producibility and tolerance related discoveries. 2.Manufacturing – Through tolerance optimization, nonimpactful tolerances can be relaxed while still ensuring a successful assembly. 3.Reduced build schedule – Increased assembly awareness and advanced planning allows a streamlined production process with risk mitigation strategies in place. 4.Reduced scrap, rework, repair (SRR) – Engineering labor to disposition out of spec parts is reduced by entering as-measured tolerances into the simulation model to assess the overall impact to installation success. The conclusion is VTA simulations provide measurable benefits to the business through robust design optimization, and multi-layered cost and risk reductions.
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Lichten奖论文:变分公差分析(VTA) -利用统计模拟进行设计和制造优化
适当考虑公差对于设计和制造满足客户要求和确定成本目标的产品至关重要。公差分析通常在单个零件或子装配级进行,利用基本的叠加方法(最坏情况分析)来确保装配产品的可生产性。最坏情况分析假设堆叠中的每个尺寸将在其指定公差(最大或最小)的极端端或极限上制造,从而使所有公差都成为可加性。这通常会导致比要求的图纸公差更严格,以保证产品可以组装。现代制造工艺的重点是瞄准标称尺寸值,因此可以肯定的是,在接近标称尺寸值的地方生产的零件数量比在公差范围的极端末端生产的零件数量要多。当评估包含许多部件的大型装配的公差叠加时,需要应用额外的公差分析方法(根和平方和,RSS),而最坏情况分析变得更加昂贵且没有意义。公差分析的RSS方法考虑了制造目标,并应用正态分布方法来评估更可能的公差结果,允许轻松地分配图纸公差,同时仍然保持对成功装配的高水平信心。对于复杂系统或装置的分析,需要使用更复杂的方法来处理变化的公差研究,例如蒙特卡罗统计分析。目前可用的变分公差分析(VTA)工具允许设计师通过三维实时制造模拟和灵敏度分析将典型的蒙特卡罗公差模拟可视化。这反过来又简化了开发过程,并允许在大型系统安装中更好地识别公差驱动程序;安装过程中公差的几何效应分析以及快速迭代分析的能力,以优化设计的可生产性和降低成本。在本文中,对VTA的使用进行了评估和量化,以形成洛克希德·马丁公司进一步投资的商业案例。在这项工作的过程中,VTA在最终设计发布到制造之前和之后都进行了评估。在最终设计发布之前,VTA可用于设计优化(即在构建模拟之前进行构建),零件排序研究,或深入了解装配/安装过程,从而提前进行高级规划。VTA还可以解决在最终设计发布给制造部门和现有零件(即在制造过程中)之后发现的挑战,例如:装配问题、不符合规格的零件处置,并通知制造部门任何特殊工具或零件返工事项,以帮助采取纠正措施或降低风险计划。由于VTA的实施,为业务节省了成本,这在4个不同的方面得到了证明:减少设计修订-预先设计优化减少了由于可生产性和公差相关发现而导致的未来修订。2.制造-通过公差优化,可以在确保装配成功的同时放松非影响公差。3.减少生产进度-提高装配意识和先进的计划,使生产过程具有降低风险的策略。4.减少报废、返工、修理(SRR) -通过在仿真模型中输入测量公差来评估对安装成功的总体影响,减少了处理不合规格零件的工程劳动。结论是,VTA模拟通过稳健的设计优化以及多层的成本和风险降低,为业务提供了可衡量的好处。
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