Evaporation enhancement for evaporative cooling systems

蒸发冷却系统的蒸发强化

• 批准号: RGPIN-2014-04197
• 负责人: MacDonald, Brendan
• 金额: $ 1.68万
• 依托单位: University of Ontario Institute of Technology
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=658223
• 关键词: Evaporation; enhancement; evaporative; cooling; systems

Cooling is of critical importance for a wide range of fields. Presently, there are two fields where cooling is essential for realizing performance and growth potential: (1) microelectronic devices, which have components that are continually decreasing in size while facing an increase in power demands and corresponding need for heat removal, and (2) air conditioning for residential and commercial spaces, which is correlated with productivity and energy demand. There are relatively limited methods for cooling, most of which require refrigerants that can damage the environment. Current technology is not keeping pace with the rising cooling demands so there is a need for efficient and environmentally friendly technology.**We take our inspiration for efficient cooling from nature, where human perspiration serves as an example of using evaporating droplets for cooling. Evaporation can provide very efficient cooling by exploiting the large amount of energy dissipated during a liquid to vapour phase change. Sessile droplets offer advantages over film and pool boiling due to their high surface area to volume ratios, which are beneficial for interfacial processes such as evaporation. There is great potential for evaporative cooling technology using sessile droplets; however, there is still an inadequate understanding of the evaporation process and the role of interfacial effects. Better understanding of the influence of interfacial effects on evaporation will lead to improved performance and efficiency, which is especially crucial as technology decreases in size to the micro- and nano-scales where interfacial effects become more important.**This research program investigates an interfacial effect known as Marangoni convection, which is caused by an imbalance of surface tension forces at a liquid-vapour interface, and results in fluid flow within a droplet. In certain circumstances Marangoni convection has been shown to substantially increase evaporation rates and a majority of the energy required for evaporation is transported by Marangoni convection along the surface of a droplet. The enhanced evaporation rates can be used to improve cooling technology performance; however, this behaviour is still poorly understood and fluctuates based on the properties of the droplet (size, chemical mixture) and the substrate material. The objectives of this research are to: (1) quantify the influence of Marangoni convection on evaporation rates using experimental techniques for various sessile droplet sizes, fluid mixtures, and substrate materials, (2) develop and validate mathematical and numerical models of the evaporation process, which include the effects of Marangoni convection as a method for increasing the evaporation rates, and (3) apply the findings to develop energy efficient evaporative cooling technology by generating designs and performing simulations with our models.**This research program aims to develop energy efficient, high capacity, and environmentally friendly evaporative cooling technology. Cooling living and working spaces using current technology places high demands on energy requirements, particularly in developing countries, but also in warm and humid Canadian summers. Cooling in electronic devices presents an opportunity for new technology to enter the market since power density and performance are limited by the overheating of components. We will generate an understanding and quantification of the influence of Marangoni convection on evaporation rates in sessile droplets, which will be valuable for a broad range of applications. This research will produce highly qualified personnel who are proficient in the thermal management and energy fields, which are significant for many expanding Canadian industries.

冷却在很多领域都是至关重要的。目前，冷却对于实现性能和增长潜力是必不可少的两个领域：(1)微电子设备，其部件尺寸不断减小，同时面临功率需求和相应的散热需求的增加，以及(2)住宅和商业空间的空调，这与生产率和能源需求相关。冷却的方法相对有限，其中大多数方法需要的制冷剂可能会破坏环境。目前的技术跟不上日益增长的冷却需求，因此需要高效和环保的技术。**我们从自然中获得高效降温的灵感，人类的汗水就是使用蒸发液滴进行降温的例子。蒸发可以通过利用液体到汽相转变过程中耗散的大量能量来提供非常有效的冷却。与膜沸腾和池沸腾相比，固着液滴具有优势，因为它们的表面积与体积比高，这有利于界面过程，如蒸发。利用固着液滴的蒸发冷却技术具有很大的潜力，但对蒸发过程和界面效应的作用仍缺乏足够的了解。更好地了解界面效应对蒸发的影响将导致性能和效率的提高，这一点尤其关键，因为技术的尺寸减小到微米和纳米尺度，其中界面效应变得更加重要。**本研究计划研究一种被称为Marangoni对流的界面效应，它是由液-汽界面上表面张力的不平衡引起的，并导致液滴内的流体流动。在某些情况下，Marangoni对流已被证明可大大增加蒸发速率，蒸发所需的大部分能量是通过Marangoni对流沿液滴表面输送的。提高的蒸发速率可用于改善冷却技术性能；然而，人们对这种行为仍然知之甚少，并根据液滴(大小、化学混合物)和基材的性质而波动。本研究的目标是：(1)利用实验技术，针对不同的固液滴大小、流体混合物和衬底材料，量化Marangoni对流对蒸发速率的影响；(2)开发和验证蒸发过程的数学和数值模型，其中包括Marangoni对流作为一种提高蒸发速率的方法的影响；(3)应用研究结果，通过生成设计和使用我们的模型进行模拟，开发高效节能的蒸发冷却技术。**本研究计划旨在开发高效、高容量和环境友好的蒸发冷却技术。使用当前技术冷却生活和工作空间对能源需求提出了很高的要求，特别是在发展中国家，但在加拿大温暖潮湿的夏季也是如此。电子设备的冷却为新技术进入市场提供了机会，因为功率密度和性能受到元件过热的限制。我们将对Marangoni对流对固着液滴中蒸发速率的影响进行了解和量化，这将对广泛的应用具有价值。这项研究将培养出精通热管理和能源领域的高素质人才，这对加拿大许多正在扩张的行业具有重要意义。