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Analysis of Heating Rates on the Conical Surface of Apollo Command Module Flying AS-202 Flight

机译：阿波罗指挥舱飞行as-202飞行锥面加热速率分析

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The aerodynamic and aerothermal heating at the leeward surfaces of the Apollo capsule flying high angle of attack were found difficult to simulate using conventional tools. Due to the large subsonic region in the proximity of the shoulder of the base shield, correlation-based tools were found to be inadequate. CFD tools are too time consuming for conceptual design purposes, and cannot account for the transient effects of material response such as wall temperature and blowing. An accurate and timely simulation is essential to effectively size the thermal protection system (TPS), to enhance its performance, and to ensure the safety of the crew. Northrop Grumman Corporation applied a modified version of the MASCC/ATAC program, an inviscid flowfield code with boundary layer solver to simulate this scenario. The MASCC/ATAC code is believed to be the only non-CFD code that can rigorously perform the simulations on the windward surface. The predictions on the windward side of the conical surface were found to be in good agreement with flight data over a wide range of environments. The results are presented in the paper.

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Wong, J. L.;
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年度 2005
页码 1-6
总页数 6
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Aerodynamic heating ; Inviscid flow ; Thermal protection ; Computational fluid dynamics ; Boundary layers ; Transient response ; Flow distribution ; Safety ; Simulation ; Wall temperature;

机译：空气动力学加热; Inviscid流动;热保护;计算流体动力学;边界层;瞬态响应;流量分布;安全性;模拟;壁温;

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专利

1. Analysis of Apollo Command Module Afterbody Heating Part Ⅰ: AS-202 [J] . Michael J. Wright, Dinesh K. Prabhu, Edward R. Martinez Journal of Thermophysics and Heat Transfer . 2006,第1期

机译：阿波罗指令模块车身后加热分析：第一部分：AS-202
2. Base flow investigation of the Apollo AS-202 Command Module [J] . Louis M.G. Walpot, Michael J. Wright, Peter Noeding, Progress in Aerospace Sciences . 2012,第JanaaFeba期

机译：Apollo AS-202命令模块的基本流程调查
3. Radiative Gasdynamics of the Nose Surface of the Apollo-4 Command Module at its Superobrital Reentry [J] . Surzhikov S. T. Fluid Dynamics . 2017,第6期

机译：Apolo-4命令模块的辐射气体动力学在其过度重新进入
4. Analysis of Afterbody Heating Rates on the Apollo Command Modulels, Part I: AS- 202 [C] . M. Wright, D. Prabhu, E. Martinez AIAA Fluid Dynamics Conference;AIAA Flow Control Conference;AIAA Thermophysics Conference;AIAA Plasmadynamics and Lasers Conference . 2004

机译：在Apollo指令模块上分析后车身加热速率，第一部分：AS-202
5. Integrated flight/propulsion control with variable rotor speed command for rotorcraft. [D] . Iwata, Takanori. 1996

机译：旋翼航空器具有可变旋翼速度指令的集成飞行/推进控制。
6. Evolution and Ecology of Silent Flight in Owls and Other Flying Vertebrates [O] . Christopher J Clark, Krista LePiane, Lori Liu 2020

机译：猫头鹰与其他飞脊椎动物沉默飞行的演变与生态
7. Endothermy of dynastine scarab beetles (Cyclocephala colasi) associated with pollination biology of a thermogenic arum lily (Philodendron solimoesense) : Cyclocephala colasi beetles are facultative endotherms that spend most of their adult lives inside the inflorescences of Philodendron solimoesense, where ambient temperature (Ta) averages about 28°C due to floral thermogenesis. Measurements of respiration within a range of Ta showed that active beetles became spontaneously endothermic at Ta below 28°C but were rarely endothermic above it. There was no evidence of endothermy within the inflorescences, indicating that activities in the floral chamber can occur without the high energy expense of endothermy. Bouts of endothermy occurred at lower Ta in respirometer chambers mainly in the evening, when the insects normally fly from one inflorescence to another, and during the night, when they normally eat and mate within the inflorescence. Patterns of endothermy in individual episodes were studied in non-flying beetles with respirometry and infrared thermal imaging. Heat was generated in the thorax by oscillatory waves of respiration that were coupled with thoracic temperature (Tth) increases. Stationary beetles could regulate Tth at about 33°C independently of Ta between 16 and 29°C. At Ta20°C, this represents a 116-fold increase in metabolic rate over resting, ectothermic values. Endothermy was clearly a requirement for flight, and beetles departing inflorescences warmed to about 30°C before take-off. During flight, Tth was dependent on Ta, decreasing from 37 to 28°C at Ta of 37 to 20°C, respectively. The lowest Ta at which flight could occur was about 20°C. Thermal conductance of stationary, endothermic beetles increased at higher metabolic rates, probably because of increased ventilatory heat loss. [O] . Seymour, R.S., White, C.R., Gibernau, Marc 2009

机译：与产热香芋百合（Philodendron solimoesense）授粉生物学相关的动态圣甲虫（Cyclocephala colasi）吸热：Cyclocephala colasi甲虫是兼性吸热体，它们大部分成年生活都在Philodendron solimoesense的花序中，其平均温度（Ta）由于花的生热作用，温度约为28°C。在Ta范围内的呼吸测量表明，活跃的甲虫在Ta低于28°C时会自发吸热，而在Ta高于28°C时很少吸热。在花序中没有吸热的迹象，表明花室中的活动可以在没有高的吸热能量消耗的情况下发生。吸热的爆发主要发生在晚上，当昆虫通常从一个花序飞到另一个花序时，以及在晚上，它们通常在花序中进食并交配时，在呼吸计室的较低Ta处发生。在非飞行甲虫中通过呼吸测定法和红外热成像研究了单个发作中的吸热模式。伴随着胸温（Tth）升高的呼吸振荡波在胸腔中产生热量。固定甲虫可以在约33°C的温度下调节Tth，而与Ta在16至29°C之间的温度无关。在Ta20°C下，这表示其代谢速率比静止的，等温的升高116倍。吸热显然是飞行的要求，离开花序的甲虫在起飞前会升温到约30°C。在飞行过程中，Tth取决于Ta，在Ta从37降至20°C时，Tth分别从37°C降至28°C。可能发生飞行的最低Ta约为20°C。固定的，吸热的甲虫的热导率以较高的代谢率增加，这可能是由于通风热损失增加所致。

Analysis of Heating Rates on the Conical Surface of Apollo Command Module Flying AS-202 Flight

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