Based on prior successful fabrication and demonstration testing of a carbon-carbon heat pipe radiator element with integral fins this paper examines the hypothetical extension of the technology via substitution of high thermal conductivity composites which would permit increasing fin length while still maintaining high fin effectiveness. As a result the specific radiator mass could approach an ultimate asymptotic minimum value near 1.0 kg/m2, which is less than one fourth the value of present day satellite radiators. The implied mass savings would be even greater for high capacity space and planetary surface power systems, which may require radiator areas ranging from hundreds to thousands of square meters, depending on system power level.
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机译:基于先前成功制造并带有一体式翅片的碳-碳热管散热器元件的示范性测试,本文通过替代高导热率复合材料来检验该技术的假想扩展,该复合物将允许增加翅片长度,同时仍保持高翅片效率。结果,特定的散热器质量可能接近1.0 kg / m2的最终渐近最小值,该最小值小于当今卫星散热器的值的四分之一。对于大容量空间和行星表面电源系统,隐含的质量节省将更大,这可能取决于系统功率水平而需要数百到数千平方米的散热器面积。
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