Flat heat pipe performance thresholds at ultra-thin form factors

Yashwanth Yadavalli, J. Weibel, S. Garimella
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引用次数: 6

Abstract

Improved-efficiency heat spreaders must address ergonomic- and performance-driven thermal management demands of electronic devices of increasingly thin form factor. Heat pipes offer a potential high-conductance solution, but performance limitations unique to sub-millimeter thickness devices must be characterized. Using a reduced-order, one-dimensional resistance network and a two-dimensional numerical model, the thermal resistance of a flat heat pipe is benchmarked against a solid heat spreader as a function of geometry and power input. The reduced-order model enables a broad parametric study and analytical formulation of performance limitations, while the higher fidelity numerical approach is used to assess the accuracy of the thermal resistance network near these limits. The form factors and operating conditions for which a heat pipe is more effective than a solid heater spreader are identified. Two of the bounding performance limits have been commonly discussed in prior analyses - a capillary wicking limit and an increase in the heat pipe thermal resistance relative to the solid heat spreader at very large thicknesses. A third vapor-phase threshold is observed when the thickness is reduced below a critical limit. At this threshold, the vapor-phase thermal resistance imposed by the saturation pressure/temperature gradient in the heat pipe causes a crossover in the thermal resistance relative to a solid heat spreader. Devices are susceptible to this performance threshold at very low power inputs that would not otherwise induce a capillary limitation. Accurate prediction of this threshold is an important consideration in the selection and design of ultra-thin heat pipes.
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平板热管的性能阈值在超薄的外形因素
提高效率的散热器必须满足人体工程学和性能驱动的热管理需求的电子设备越来越薄的形式因素。热管提供了一种潜在的高导解决方案,但必须对亚毫米厚度设备的性能限制进行表征。利用降阶的一维电阻网络和二维数值模型,将平面热管的热阻作为几何形状和功率输入的函数与固体散热器进行基准测试。降阶模型能够进行广泛的参数研究和性能限制的分析公式,而更高保真度的数值方法用于评估这些限制附近的热阻网络的准确性。确定了热管比固体加热器扩展器更有效的形式因素和操作条件。在先前的分析中,通常讨论了两个边界性能限制-毛细管吸湿限制和在非常大的厚度下相对于固体散热器的热管热阻的增加。当厚度减小到临界极限以下时,观察到第三个气相阈值。在这个阈值下,由热管中的饱和压力/温度梯度施加的气相热阻导致相对于固体散热器的热阻发生交叉。在非常低的功率输入下,器件容易受到此性能阈值的影响,否则不会引起毛细管限制。该阈值的准确预测是超薄热管选型和设计的重要考虑因素。
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