Analysis of boiling phenomena associated with liquid jet impingement

与液体射流冲击相关的沸腾现象分析

• 批准号: 261633-2011
• 负责人: Hamed, Mohamed
• 金额: $ 2.33万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=571103
• 关键词: Analysis; boiling; phenomena; associated; liquid

Many manufacturing operations such as for continuous casting, hot and cold rolling of slabs and strips, hardening, extrusion and forging, employ liquid jet impingement boiling because they require intensive cooling rates at specific temperatures, i.e., "Controlled Intensive Cooling" rates. However, the need for precise controlled intensive cooling rates poses a significant technological challenge because of the lack of predictive tools that can be used to design and operate proper controlled intensive cooling systems. Current industrial practices rely on trial and error and on accumulated field knowledge. Consequently, hundreds of millions of dollars are wasted every year; millions of tons of harmful emissions are released into the environment due to reprocessing and scraping of metal parts that did not meet production specifications due to distortion, cracking, or lack of proper mechanical properties caused by improper controlled intensive cooling. The lack of proper mechanical properties caused by improper controlled intensive cooling prevents our metal processing industry from opening new markets. In fact, controlled intensive cooling is not only important for the metal processing industry, but also for other industries. For example, in electronics thermal management, the lack of proper controlled intensive cooling systems is currently the major obstacle for offering the next generation of high-speed processors. The proposed experimental research in this application is concerned with the development of comprehensive models that our Canadian industry can use to better design the next generation of controlled intensive cooling systems using water and nanofluid jets

许多制造操作，例如用于连续铸造、板坯和带材的热轧和冷轧、硬化、挤压和锻造，采用液体射流冲击沸腾，因为它们需要在特定温度下的强烈冷却速率，即，“受控强化冷却”率。然而，由于缺乏可用于设计和操作适当的受控强化冷却系统的预测工具，对精确受控强化冷却速率的需求构成了重大的技术挑战。 目前的工业实践依赖于试错和积累的领域知识。因此，每年浪费数亿美元;数百万吨的有害排放物被释放到环境中，这是由于对不符合生产规格的金属零件进行再加工和报废，这些零件由于变形、开裂或由于不适当的控制强化冷却而缺乏适当的机械性能。 由于不适当的控制强化冷却导致的机械性能的缺乏，阻碍了我们的金属加工行业开拓新的市场。事实上，受控强化冷却不仅对金属加工行业很重要，对其他行业也很重要。例如，在电子热管理中，缺乏适当的受控强化冷却系统目前是提供下一代高速处理器的主要障碍。在这项申请中提出的实验研究涉及开发综合模型，我们的加拿大工业可以使用该模型来更好地设计下一代使用水和纳米流体射流的受控强化冷却系统。