Novel Controllable High Performance Thermal Storage and Heat Transfer Systems

新型可控高性能热存储和传热系统

• 批准号: 355844-2013
• 负责人: Cotton, James
• 金额: $ 2.7万
• 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: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=638411
• 关键词: Novel; Controllable; Performance; Thermal; Storage

Canada's abundant energy supply has led to a significant reliance on energy to sustain our quality of life and to power our key industrial sectors. Given the rising cost and demand for energy worldwide as well as the growing concern over the role that fossil fuels play in both climate change and health risks, there is an urgent need to develop cleaner and sustainable alternatives as part of Canada's energy strategy. Thermal energy conversion and management is a core technology that can be applied to numerous applications, including the capture of waste heat from energy systems, vehicles and commercial or industrial processes. These systems hold enormous potential to augment conventional energy sources in the short term and to revolutionize the way we produce energy in the future. This research is motivated by a critical need for novel devices and systems to capture this "lost" energy. Combining scientific expertise, exploratory research and enabling technologies, the objective of this research program is to develop solutions that are urgently required to overcome the technological barriers that are preventing advanced concepts from being translated into systems that can meet society's needs. This includes the development of expertise in two-phase thermal management systems, new heat exchanger designs and advanced thermal storage solutions by establishing electrohydrodynamics (EHD) as the mechanism of enhancement and intelligent control. The EHD principle involves interaction of an applied electric field with a fluid medium to induce electric body forces on the fluid, and set the fluid in motion. This impact then provides the ability to significantly enhance heat transfer as well as the ability to control it. The long term research goal will be to establish analytical methods and design guidelines to facilitate the wide scale employment of these novel systems in order to maximize the potential of the EHD effect. The resulting knowledge will provide HQP with the methods and tools to integrate existing thermal management and conversion systems with these critically needed novel technologies, turning waste heat into useable energy.

加拿大丰富的能源供应导致我们严重依赖能源来维持我们的生活质量并为我们的关键工业部门提供动力。鉴于全球能源成本和需求不断上升，以及人们日益关注化石燃料在气候变化和健康风险中所扮演的角色，迫切需要开发更清洁和可持续的替代品，作为加拿大能源战略的一部分。热能转换和管理是一项核心技术，可应用于多种应用，包括从能源系统、车辆和商业或工业过程中捕获废热。这些系统具有在短期内增强传统能源并彻底改变未来能源生产方式的巨大潜力。这项研究的动机是迫切需要新颖的设备和系统来捕获这种“丢失”的能量。该研究计划结合科学专业知识、探索性研究和使能技术，旨在开发迫切需要的解决方案，以克服阻碍先进概念转化为满足社会需求的系统的技术障碍。这包括通过建立电流体动力学（EHD）作为增强和智能控制机制，开发两相热管理系统、新热交换器设计和先进蓄热解决方案方面的专业知识。 EHD 原理涉及施加的电场与流体介质的相互作用，以在流体上感应电动体力，并使流体运动。这种影响提供了显着增强传热的能力以及控制传热的能力。长期研究目标将是建立分析方法和设计指南，以促进这些新颖系统的广泛使用，从而最大限度地发挥 EHD 效应的潜力。由此产生的知识将为总部提供方法和工具，将现有的热管理和转换系统与这些急需的新技术相结合，将废热转化为可用能源。