Measurement of liquid metal and alloy properties

液态金属和合金性能的测量

• 批准号: 576698-2022
• 负责人: Henein, HaniH
• 金额: $ 1.46万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Idea to Innovation
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=746822
• 关键词: Measurement; liquid; metal; alloy; properties

Knowing the values of the thermophysical properties of metallic liquids, namely the density, the viscosity and the surface tension, but also how they evolve with temperature and under different gas atmospheres is critical for industrial proceeses. They enable the optimizization of high temperature metallurgical processes. There would be a great benefit to the industry if a complete database of these properties existed, but these values are typically difficult and time consuming to measure. Numerous methods have been developed to measure each of these properties but they are difficult to adapt for metallic liquids due to the high temperature and reactivity. Commercialized options are limited, researchers must invest significant resources to build their own measurement devices. The mostly used alternative relies on an electromagnetic levitation method which requires zero gravity conditions. The experiments are then costly as the samples must be sent to the international space station (ISS) or parabolic flights to make these measurements. Overall, there is a need for researchers and industry to have access to a robust, convenient, and cost-effective instrument to measure simultaneously the density, surface tension and viscosity of metallic liquids. The Discharge Crucible (DC) method comes as a ground-based alternative to measure simultaneously the density, surface tension and viscosity of metallic liquids. The technique relies on a robust mathematical formulation describing how the velocity of a fluid draining by gravity from a container depends on the thermophysical properties of interest. The anticipated product would consist of a compact device including all the necessary sensors, heating and cooling elements which could be connected to a user-friendly interface for data analysis of the properties. The device would also allow the user to easily change the atmosphere in which to conduct the experiment and adjust the temperature. This method was developed at the University of Alberta in the early 2000s. It can be used anywhere and allow those in research and industry to make the necessary measurements of the three properties simultaneously in a cost and time effective manner.

了解金属液体的热物理性质的值，即密度、粘度和表面张力，以及它们如何随温度和在不同气体气氛下演变，对于工业过程至关重要。它们能够优化高温冶金工艺。如果存在这些属性的完整数据库，将会给行业带来巨大的好处，但这些值通常难以测量且耗时。人们已经开发了许多方法来测量这些特性，但由于金属液体的高温和反应性，它们很难适用。商业化的选择有限，研究人员必须投入大量资源来构建自己的测量设备。最常用的替代方案依赖于电磁悬浮方法，该方法需要零重力条件。实验成本高昂，因为样本必须发送到国际空间站（ISS）或抛物线飞行才能进行这些测量。总体而言，研究人员和工业界需要一种强大、方便且经济高效的仪器来同时测量金属液体的密度、表面张力和粘度。放电坩埚 (DC) 方法是一种基于地面的替代方法，可同时测量金属液体的密度、表面张力和粘度。该技术依赖于一个强大的数学公式，描述了通过重力从容器中排出的流体的速度如何取决于感兴趣的热物理性质。预期的产品将由一个紧凑的设备组成，包括所有必要的传感器、加热和冷却元件，这些元件可以连接到用户友好的界面以进行性能数据分析。该设备还允许用户轻松改变进行实验的气氛并调节温度。这种方法是阿尔伯塔大学在 2000 年代初开发的。它可以在任何地方使用，并允许研究和工业人员以成本和时间有效的方式同时对这三种属性进行必要的测量。