Thermal management is critical to a number of technologies used in a microgravity environment and in Earth-based systems. Examples include electronic cooling, power generation systems, metal forming and extrusion, and HVAC (heating, venting, and air conditioning) systems. One technique that can deliver the large heat fluxes required for many of these technologies is two-phase heat transfer. This type of heat transfer is seen in the boiling or evaporation of a liquid and in the condensation of a vapor. Such processes provide very large heat fluxes with small temperature differences. Our research program is directed toward the development of a new, two-phase heat transfer cell for use in a microgravity environment. In this paper, we consider the main technology used in this cell, a novel technique for the atomization of a liquid called vibration-induced droplet atomization. In this process, a small liquid droplet is placed on a thin metal diaphragm that is made to vibrate by an attached piezoelectric transducer. The vibration induces capillary waves on the free surface of the droplet that grow in amplitude and then begin to eject small secondary droplets from the wave crests. In some situations, this ejection process develops so rapidly that the entire droplet seems to burst into a small cloud of atomized droplets that move away from the diaphragm at speeds of up to 50 cm/s. By incorporating this process into a heat transfer cell, the active atomization and transport of the small liquid droplets could provide a large heat flux capability for the device. Experimental results are presented that document the behavior of the diaphragm and the droplet during the course of a typical bursting event. In addition, a simple mathematical model is presented that qualitatively reproduces all of the essential features we have seen in a burst event. From these two investigations, we have shown that delayed droplet bursting results when the system passes through a resonance condition. This occurs when the initial acceleration of the diaphragm is higher than the critical acceleration and the driving frequency is larger than the initial resonance frequency of the diaphragm-droplet system. We have incorporated this droplet atomization device into a design for a new heat transfer cell for use in a microgravity environment. The cell is essentially a cylindrical container with a hot surface on one end and a cold surface on the other. The vibrating diaphragm is mounted in the center of the cold surface. Heat transfer occurs through droplet evaporation and condensation on the hot and cold ends of the cell. A prototype of this heat transfer cell has been built and tested. It can operate continuously and provides a modest level of heat transfer, about 20 W/sq cm. Our work during the next few years will be to optimize the design of this cell to see if we can produce a device that has significantly better performance than conventional heat exchangers and heat pipes.
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机译:热管理对于微重力环境和地基系统中使用的许多技术至关重要。示例包括电子冷却,发电系统,金属成型和挤压以及HVAC(加热,通风和空调)系统。可以提供许多这些技术所需的大热通量的一种技术是两相传热。在液体的沸腾或蒸发以及蒸气的冷凝中可以看到这种类型的热传递。这样的过程提供了很小的温差的非常大的热通量。我们的研究计划旨在开发一种用于微重力环境的新型两相传热单元。在本文中,我们考虑了该电池中使用的主要技术,这是一种用于液体雾化的新技术,称为振动感应液滴雾化。在此过程中,将一小滴液滴放在薄的金属膜片上,该膜片通过连接的压电传感器振动。振动在液滴的自由表面上引起毛细波,该毛细波的振幅增大,然后开始从波峰喷射出小的次级液滴。在某些情况下,这种喷射过程发展得如此之快,以至于整个液滴似乎破裂成一团雾化的雾状液滴,这些雾状液滴以高达50 cm / s的速度离开隔膜。通过将此过程合并到传热池中,小液滴的主动雾化和传输可以为设备提供大的热通量。提出了实验结果,这些结果记录了典型爆裂事件过程中隔膜和液滴的行为。此外,还提供了一个简单的数学模型,该模型定性地再现了我们在突发事件中看到的所有基本特征。从这两个研究中,我们已经表明,当系统经过共振条件时,会导致液滴的爆裂延迟。当膜片的初始加速度高于临界加速度并且驱动频率大于膜片-液滴系统的初始共振频率时,会发生这种情况。我们已将此液滴雾化设备整合到用于微重力环境的新型传热池的设计中。该电池本质上是圆柱形容器,其一端具有热表面,而另一端具有冷表面。振动膜片安装在冷表面的中央。热量通过液滴的蒸发和在电池的热端和冷端凝结而发生。该传热单元的原型已构建并经过测试。它可以连续运行,并提供适度的热传递,大约20 W / sq cm。在接下来的几年中,我们的工作将是优化该电池的设计,以查看我们是否能够生产出一种性能比传统热交换器和热管明显更好的设备。
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