Increasing the SOFIA Secondary Mirror Mechanism’s Fast Steering Capability by Identification of a Structural Resonance and Its Subsequent Elimination Through Mass Re-Distribution

IF 1.5 Q3 ASTRONOMY & ASTROPHYSICS
Y. Lammen, Andreas Reinacher, Benjamin Greiner, Jörg F. Wagner, A. Krabbe
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引用次数: 8

Abstract

The Stratospheric Observatory for Infrared Astronomy (SOFIA) consists of a 2.7[Formula: see text]m infrared telescope integrated into a Boeing 747 SP. One of the most complex subsystems of the observatory is the secondary mirror assembly (SMA). This active steering mechanism is used for image stabilization and infrared chopping. Since its integration in 2002, the performance of the mechanism is limited by a structural resonance. Based on Finite Element (FE) simulations and experimental modal surveys, a ring shaped reaction mass was identified to be the causing element of this structural mode. Attenuating the resonance on the hardware level would result in a larger actuation bandwidth for faster chopping and image stabilization. Concentrating mass at the suspension points while keeping the inertia of the ring structure is expected to take strain energy out of the mode. An end-to-end simulation, including a FE model of the mechanism and a controller model was set up to predict the in-flight performance of this concept. A segmented ring made from tungsten and AlSiC (i.e. strong mass redistribution) mounted on the original suspension was selected for the design of a prototype. The prototype was manufactured and thoroughly tested on a full-scale mockup of the mechanism confirming the predicted performance. An actuation bandwidth improvement of 80% was achieved. The settling time for infrared chopping was reduced from 10 to 7[Formula: see text]ms providing about 3.3% higher efficiency for observations with 5[Formula: see text]Hz chopping.
通过识别结构共振并通过质量重分配消除结构共振,提高SOFIA副镜机构的快速转向能力
平流层红外天文观测站(SOFIA)由一台2.7米的红外望远镜组成,该望远镜集成在一架波音747 SP中。天文台最复杂的子系统之一是次反射镜组件(SMA)。这种主动转向机构用于图像稳定和红外斩波。自2002年整合以来,该机制的性能受到结构共振的限制。基于有限元(FE)模拟和实验模态调查,环形反应质量被确定为这种结构模式的原因。在硬件层面上衰减谐振将导致更大的致动带宽,用于更快的斩波和图像稳定。将质量集中在悬挂点,同时保持环形结构的惯性,预计会使应变能脱离模式。建立了端到端仿真,包括机构的有限元模型和控制器模型,以预测该概念的飞行性能。原型的设计选择了安装在原始悬架上的由钨和AlSiC(即强质量再分配)制成的分段环。原型被制造出来,并在全尺寸的机构模型上进行了彻底的测试,确认了预测的性能。实现了80%的驱动带宽改进。红外斩波的稳定时间从10毫秒减少到7毫秒[公式:见正文]ms,为5赫兹斩波的观测提供了约3.3%的高效率。
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来源期刊
Journal of Astronomical Instrumentation
Journal of Astronomical Instrumentation ASTRONOMY & ASTROPHYSICS-
CiteScore
2.30
自引率
7.70%
发文量
19
期刊介绍: The Journal of Astronomical Instrumentation (JAI) publishes papers describing instruments and components being proposed, developed, under construction and in use. JAI also publishes papers that describe facility operations, lessons learned in design, construction, and operation, algorithms and their implementations, and techniques, including calibration, that are fundamental elements of instrumentation. The journal focuses on astronomical instrumentation topics in all wavebands (Radio to Gamma-Ray) and includes the disciplines of Heliophysics, Space Weather, Lunar and Planetary Science, Exoplanet Exploration, and Astroparticle Observation (cosmic rays, cosmic neutrinos, etc.). Concepts, designs, components, algorithms, integrated systems, operations, data archiving techniques and lessons learned applicable but not limited to the following platforms are pertinent to this journal. Example topics are listed below each platform, and it is recognized that many of these topics are relevant to multiple platforms. Relevant platforms include: Ground-based observatories[...] Stratospheric aircraft[...] Balloons and suborbital rockets[...] Space-based observatories and systems[...] Landers and rovers, and other planetary-based instrument concepts[...]
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