Collaborative Research: Understanding Laser-Assisted Surface Cooling Enhancement (LASCE)

合作研究：了解激光辅助表面冷却增强 (LASCE)

• 批准号: 1402587
• 负责人: Mario Trujillo
• 金额: $ 14.97万
• 依托单位: University of Wisconsin-Madison
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-07-01 至 2018-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1402587&HistoricalAwards=false
• 关键词: Collaborative; Research; Understanding; Laser; Assisted

CBET-1403508/1402587Aguilar/TrujilloThis grant provides funding for studying and developing a non-intrusive method to enhance local heat transfer between a target surface and a cooling fluid. The approach takes advantage of thermocavitation bubbles, which are formed when continuous wave (CW) laser light is properly focused within highly absorbing liquid thin films. These bubbles form and collapse within microseconds, vigorously agitating the liquid and enhancing heat transfer. This phenomenon is called Laser-Assisted Surface Cooling Enhancement (LASCE). The PIs preliminary estimates show that heat transfer enhancement is as great as that of phase change (evaporation/boiling), which is the current upper limit to liquid-based cooling systems. LASCE may also match or exceed the performance obtained using micro-modified structures, but without implementing any type of surface modification. Also, CW lasers are often less complex lasing media, cheaper and simpler than pulse lasers, and can control the frequency of bubble formation simply by modulating their output power. The potential impact of this project, therefore, is in novel ways of controlling surface heat. This has implications for systems ranging from laser surgery to combustion engine devices.This study encompasses collaborative experimental and computational research between University of California-Riverside and University of Wisconsin-Madison aimed at studying and quantifying the: 1) balance between the heat input to induce thermal cavitation and the cooling produced by enhanced convection; 2) sensitivity of the resulting fluid flow to the operating parameters of the laser and; 3) physics of interaction between multiple cavitation events and its effect on enhanced convective cooling. Based on highly accurate numerical simulations and detailed measurement techniques, a thorough examination of the physics underpinning the most desirable heat transfer conditions will be sought, which is essential in optimizing the operation of LASCE. This will be followed by an equally important objective, which aims to explore LACSE's suitability for applications where surface modification is impossible, such as skin (scalp) cooling during laser therapy across a novel transparent cranial implant ("Window to the Brain") developed at UCR. The success of this project will open the door to many transformative applications of optical thermocavitation aimed at low-temperature combustion strategies for mitigating the levels of NOx and particulate matter emissions to improve engine efficiency as well as transdermal drug delivery for diverse biomedical applications.

CBET-1403508/1402587 Aguilar/Trujillo该赠款为研究和开发一种非侵入性方法提供资金，以增强目标表面和冷却液之间的局部传热。该方法利用热空化气泡，这是形成连续波（CW）激光适当地集中在高吸收液体薄膜。这些气泡在微秒内形成并破裂，强烈搅动液体并增强传热。这种现象被称为激光辅助表面冷却增强（LASCE）。PI的初步估计表明，传热增强与相变（蒸发/沸腾）一样大，这是目前液体冷却系统的上限。LASCE还可以匹配或超过使用微改性结构获得的性能，但不实施任何类型的表面改性。此外，CW激光器通常是不太复杂的激光介质，比脉冲激光器更便宜和更简单，并且可以简单地通过调制它们的输出功率来控制气泡形成的频率。因此，该项目的潜在影响是控制表面热量的新方法。这项研究包括加州大学河滨分校和威斯康星大学麦迪逊分校之间的合作实验和计算研究，旨在研究和量化：1）热输入诱导热空化和增强对流产生的冷却之间的平衡; 2）所产生的流体流动对激光器的操作参数的敏感性;以及3）多个空化事件之间的相互作用的物理学及其对增强的对流冷却的影响。基于高度精确的数值模拟和详细的测量技术，将寻求对支撑最理想的传热条件的物理学进行彻底的检查，这对于优化LASCE的操作至关重要。接下来是一个同样重要的目标，旨在探索LACSE在表面改性不可能的应用中的适用性，例如在UCR开发的新型透明颅骨植入物（“大脑之窗”）的激光治疗期间冷却皮肤（头皮）。该项目的成功将为光学热空化的许多变革性应用打开大门，这些应用旨在降低NOx和颗粒物排放水平的低温燃烧策略，以提高发动机效率以及用于各种生物医学应用的透皮药物输送。

项目成果

An improved categorization of vapor bubble collapse: Explaining the coupled nature of hydrodynamic and thermal mechanisms

• DOI: 10.1016/j.ijheatmasstransfer.2019.118754
• 发表时间: 2019-12
• 期刊: International Journal of Heat and Mass Transfer
• 影响因子: 5.2
• 作者: Raunak Bardia;M. Trujillo

Assessing the physical validity of highly-resolved simulation benchmark tests for flows undergoing phase change

• DOI: 10.1016/j.ijmultiphaseflow.2018.11.018
• 发表时间: 2019-03
• 期刊: International Journal of Multiphase Flow
• 影响因子: 3.8
• 作者: Raunak Bardia;M. Trujillo