Spacecraft that must operate in cold environments at reduced heat load are at risk of radiator freezing.For a vehicle that lands at the Lunar South Pole,the design thermal environment is 215 K,but the radiator working fluid must also be kept from freezing during the 0 K sink of transit.A radiator bypass flow setpoint control design such as those used on the Space Shuttle Orbiter and ISS would require more than 30% of the design heat load to avoid radiator freezing during transit-even with a very low freezing point working fluid.By changing the traditional active thermal control system(ATCS)architecture to include a regenerating heat exchanger inboard of the radiator and using a regenerator bypass flow control valve to maintain system setpoint,the required minimum system heat load can be reduced by more than half.This gives the spacecraft much more flexibility in design and operation.The present work describes the regenerator bypass ATCS setpoint control methodology.It includes analytical results comparing the performance of this system to the traditional radiator bypass system.Finally,a summary of the advantages of the regenerator bypass system are presented.
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机译:必须在减少热量负荷下冷环境操作的航天器面临着散热器冻结的风险。对于在农历南极落地的车辆,设计热环境是215 k,但散热器工作流体也必须保持冻结0 K Transit.a散热器旁路流动设定点控制设计,如航天飞机轨道器和ISS上使用的那些需要超过30%的设计热负荷,以避免在运输过程中散热 - 即使有一个非常低的冰点工作液体。通过改变传统的主动热控制系统(ATC)架构,包括散热器的再生热交换器,并使用再生器旁路流量控制阀保持系统设定点,所需的最小系统热负荷可以减少一半以上这使得航天器更具灵活性的设计和操作。目前的工作描述了再生器旁路ATCS设定点控制方法。包括分析Al结果将该系统的性能与传统散热器旁路系统进行比较。最后,提出了再生器旁路系统的优点。
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