Simulation of critical interface phenomena in advanced steel processing

先进钢铁加工中关键界面现象的模拟

• 批准号: RGPIN-2015-04259
• 负责人: Militzer, Matthias
• 金额: $ 2.55万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=686013
• 关键词: Simulation; critical; interface; phenomena; advanced

State-of-the-art models for steel processing are based on the concept of microstructure engineering where the operational parameters of the industrial process are linked to the final properties of the steel product by accurately modelling the microstructure evolution. For most steels the austenite-ferrite transformation is a key metallurgical tool to tailor the properties. A multi-scale approach including atomistic and phase field simulations has shown promise to advance phase transformation models in steels. Phase field modelling is a powerful methodology to describe the evolution of microstructures with complex morphologies that are common in advanced steels. Thus, phase field models are proposed as a promising computational tool for developing next generation process models from casting to final heat treatments. The proposed discovery project will seek to further explore and develop the fundamentals of the phase field methodology as a simulation tool for advanced steel processing. In particular, advanced computational approaches will be developed for incorporation of atomistic simulation results into phase field models for grain growth and the austenite-ferrite transformation. Here, the interaction of migrating interfaces with alloying elements plays a central role and atomistic simulations can provide new insight into these interaction mechanisms. For high performance hot-rolled steels accelerated cooling has become a key technology to control the phase transformation and resulting properties. The Leidenfrost temperature is a critical cooling parameter where the transition from film boiling to more efficient cooling mechanisms including nucleate boiling occurs. The Leidenfrost temperature depends significantly on surface roughness. This is another interface phenomenon where phase field models may provide a powerful simulation technique.****An exciting component of the proposed research is to use the same modelling framework for both microstructure and temperature evolution. The proposed research offers opportunities for training of three PhD students. The first two PhD projects will seek to incorporate atomistic simulation results for solute-interface interactions into phase field models. The third project will deal with the development of a phase field model to account for the effect of surface roughness on cooling of steel.******************

最先进的钢加工模型基于微观结构工程的概念，其中通过精确地模拟微观结构演变，将工业过程的操作参数与钢产品的最终性能联系起来。对于大多数钢来说，铁素体-铁素体转变是调整性能的关键冶金工具。包括原子和相场模拟在内的多尺度方法已显示出推进钢中相变模型的希望。相场模型是描述先进钢中常见的具有复杂形貌的微观结构演变的一种强有力的方法。因此，相场模型被提出作为一个有前途的计算工具，用于开发下一代工艺模型，从铸造到最终的热处理。拟议的发现项目将寻求进一步探索和发展相场方法的基本原理，作为先进钢铁加工的模拟工具。特别是，先进的计算方法将被开发用于将原子模拟结果纳入相场模型的晶粒生长和铁素体-铁素体转变。 在这里，迁移界面与合金元素的相互作用起着核心作用，原子模拟可以提供这些相互作用机制的新见解。对于高性能热轧钢，加速冷却已成为控制相变和性能的关键技术。莱顿弗罗斯特温度是一个关键的冷却参数，其中从膜沸腾过渡到更有效的冷却机制，包括核沸腾发生。莱顿弗罗斯特温度在很大程度上取决于表面粗糙度。这是另一种界面现象，其中相场模型可以提供强大的模拟技术。拟议研究的一个令人兴奋的组成部分是使用相同的建模框架进行微观结构和温度演变。拟议的研究提供了三个博士生的培训机会。前两个博士项目将寻求将溶质界面相互作用的原子模拟结果纳入相场模型。第三个项目将处理相场模型的开发，以说明表面粗糙度对钢冷却的影响。**