SBIR Phase I: Modeling and Simulation Tools for Vacuum Science Technologies

SBIR 第一阶段：真空科学技术的建模和仿真工具

• 批准号: 1215014
• 负责人: Timothy Deschenes
• 金额: $ 14.99万
• 依托单位: Spectral Sciences Inc
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-07-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1215014&HistoricalAwards=false
• 关键词: SBIR; Phase; Modeling; Simulation; Tools

This Small Business Innovation Research Phase I project will develop a software suite to simulate the large range of pressures and complex moving parts geometry of high vacuum pumps, critical for many manufacturing processes. The approach is new and leverages the direct simulation Monte Carlo (DSMC) method, a particle based gas-flow approach used mainly for aerospace applications. Our approach seamlessly spans high to low pressure regimes and includes innovative ideas for flows over complex moving parts, both substantial advances over existing methods. Currently, there are no commercial tools available to simulate the rarefied to transition gas flow in high vacuum pumps and high vacuum environments. Instead, engineers have relied on costly trial and error and often settle on a non-optimal, compromise design. There is a clear need for predictive software for the simulation and modeling of high vacuum pumps and high vacuum environments. The objective of this Phase I is to demonstrate the feasibility of an innovative software suite based on the DSMC method to simulate gas flows in high vacuum pumps for real-world manufacturing processes. The software suite will include advanced, automated procedures to produce high fidelity simulations with few user inputs and modest computational resources.The broader impact/commercial potential of this project is to develop an innovative simulation package that will satisfy current and future needs of customers. The proposed software suite will impact high vacuum pump manufacturing (a multi-billion dollar industry) and facilities which maintain high vacuum environments for manufacturing and research (multi-million dollars in annual operating costs). The proposed software suite would significantly expand current simulation capabilities to predict high vacuum pump performance and would enable the development of the next generation of low cost, high performance vacuum pumps. A reduction in cost to create high vacuum environments will have a direct impact on the manufacturing of photovoltaic panels, glass coatings used on flat panel displays, water soluble pharmaceuticals, mass spectrometers and semi-conductors, which all require high vacuum pump systems. The significant reduction in fabrication energy through improved pump designs will reduce costs and CO2 emissions for the production of many consumer products. The predictive simulation results of the proposed software suite will also enhance current scientific understanding of rarefied gas flows which can be applied to other engineering development areas, including micro- and nano-fluidics and micro-satellites designed for advanced space launch systems.

这个小型企业创新研究第一阶段项目将开发一个软件套件，用于模拟高真空泵的大范围压力和复杂的运动部件几何形状，这对许多制造过程至关重要。 该方法是新的，并利用直接模拟蒙特卡罗（DSMC）方法，基于粒子的气体流动的方法主要用于航空航天应用。 我们的方法无缝地跨越高压到低压区域，并包括复杂运动部件上的流动的创新想法，这两种方法都比现有方法有实质性的进步。 目前，没有商业工具可用于模拟高真空泵和高真空环境中的稀薄过渡气体流动。 相反，工程师们依赖于昂贵的试验和错误，往往解决了一个非最佳的，妥协的设计。 对于高真空泵和高真空环境的模拟和建模，显然需要预测软件。 第一阶段的目标是证明基于DSMC方法的创新软件套件的可行性，以模拟真实世界制造过程中高真空泵中的气体流动。 该软件套件将包括先进的自动化程序，以产生高保真度的模拟与用户输入和适度的计算资源。更广泛的影响/商业潜力，这个项目是开发一个创新的模拟包，将满足客户当前和未来的需求。 拟议的软件套件将影响高真空泵制造（数十亿美元的行业）和维持高真空环境的制造和研究设施（每年数百万美元的运营成本）。所提出的软件套件将大大扩展当前的模拟能力，以预测高真空泵的性能，并将使下一代低成本，高性能真空泵的开发成为可能。 降低产生高真空环境的成本将对光伏面板、平板显示器上使用的玻璃涂层、水溶性药物、质谱仪和半导体的制造产生直接影响，这些都需要高真空泵系统。通过改进泵设计，制造能源的显著减少将降低许多消费品生产的成本和二氧化碳排放。 拟议软件套件的预测模拟结果还将提高目前对稀薄气体流动的科学认识，可应用于其他工程开发领域，包括为先进空间发射系统设计的微型和纳米流体和微型卫星。