Metallurgical Chemistry of Liquid Alloys and Molten Slags

液态合金和熔渣的冶金化学

• 批准号: RGPIN-2015-05459
• 负责人: McLean, Alexander
• 金额: $ 2.55万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=613563
• 关键词: Metallurgical; Chemistry; Liquid; Alloys; Molten

The following research activities have been designed with three objectives in mind: 1) Development of new fundamental knowledge that relates to the processing of liquid metal alloys and oxide melts; 2) Thematic topics that will fulfill the requirements for graduate and undergraduate thesis projects; and 3) Research that will provide students with hands-on training experience in experimental techniques and materials characterization procedures involving high temperature furnaces, advanced electron-optic facilities, XRD equipment and modern analytical systems. To achieve these objectives, research will be conducted based on two distinct themes: nitrogen dissolution in molten oxides, and solute interactions within iron alloys. 1. The processes involved in iron and steelmaking are based directly or indirectly on the control of slag chemistry, which in turn has a profound influence on slag structure, and therefore slag properties and performance. In view of the importance of slag control there is an increasing need to generate information pertaining to the characterization, properties and performance of oxide melts and synthetic fluxes. The increasing demand for low nitrogen steel has prompted interest in the possibility of using custom-designed fluxes to remove nitrogen from steel melts. Nitrogen can dissolve in slags in two distinct forms, free nitride where the nitrogen replaces free oxygen ions; and incorporated nitride where the nitrogen replaces oxygen ions involved in the network of polymerized anions. The objective of the proposed research will be to conduct thermodynamic and kinetic studies using a thermo-gravimetric technique and a selective analytical method to quantify the different species of nitrides present in different oxide melts and synthetic fluxes and thus develop an improved understanding of how slag chemistry influences slag performance. 2. In recent years the need for alloy irons for critical applications within the automotive sector have required the production of materials with very low contents of non-metallic inclusions and carefully controlled amounts of the residual elements oxygen, sulphur and nitrogen. The nodularization and high temperature properties of these ductile irons are strongly influenced by silicon, aluminum, cerium and other rare earths. The objective of this project is to use levitated droplets to determine the effect of these alloying additives on the activity coefficients of oxygen, sulphur and nitrogen with iron-carbon alloys, rather than pure iron, as the solvent. Falling droplet experiments will also be conducted in order to determine the reoxidation behaviour and nitrogen absorption encountered when these alloy irons are allowed to fall for fractions of a second through air and potentially protective atmospheres such as argon and nitrogen.

以下研究活动的设计有三个目标：1）发展与液态金属合金和氧化物熔体加工有关的新的基础知识; 2）满足研究生和本科生论文项目要求的主题; 3）研究，将提供学生的手-在实验技术和材料表征程序方面的培训经验，涉及高温炉、先进的电子光学设施、XRD设备和现代分析系统。为了实现这些目标，研究将基于两个不同的主题进行：氮在熔融氧化物中的溶解，以及铁合金中的溶质相互作用。 1.炼铁和炼钢过程直接或间接地基于对炉渣化学的控制，而炉渣化学又对炉渣结构产生深远影响，从而影响炉渣的性质和性能。鉴于炉渣控制的重要性，越来越需要生成与氧化物熔体和合成焊剂的表征、性质和性能有关的信息。对低氮钢的需求不断增加，促使人们对使用定制设计的熔剂从钢熔体中去除氮的可能性产生了兴趣。氮可以以两种不同的形式溶解在炉渣中：游离氮化物，其中氮取代游离氧离子;以及结合的氮化物，其中氮取代参与聚合阴离子网络的氧离子。拟议的研究的目的将是进行热力学和动力学研究，使用热重技术和选择性的分析方法来量化不同氧化物熔体和合成熔剂中存在的不同种类的氮化物，从而提高对炉渣化学如何影响炉渣性能的理解。 2.近年来，汽车行业对关键应用的合金铁的需求要求生产具有非常低的非金属夹杂物含量和仔细控制的残余元素氧、硫和氮的量的材料。硅、铝、铈等稀土元素对球铁的球化和高温性能有很大影响。该项目的目的是使用悬浮液滴来确定这些合金添加剂对铁碳合金而不是纯铁作为溶剂的氧、硫和氮的活度系数的影响。还将进行落滴实验，以确定当这些合金铁通过空气和潜在的保护气氛（如氩气和氮气）下落几分之一秒时遇到的再氧化行为和氮气吸收。