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Mount and Coudé Lab Thermal Control 25 August 2003 ATST CoDR Dr. Nathan Dalrymple Air Force Research Laboratory Space Vehicles Directorate.

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Presentation on theme: "Mount and Coudé Lab Thermal Control 25 August 2003 ATST CoDR Dr. Nathan Dalrymple Air Force Research Laboratory Space Vehicles Directorate."— Presentation transcript:

1 Mount and Coudé Lab Thermal Control 25 August 2003 ATST CoDR Dr. Nathan Dalrymple Air Force Research Laboratory Space Vehicles Directorate

2 Coudé Lab Thermal Control Coudé lab will be held at a constant, uniform temperature –Instruments always immersed in same environment –“Shirt-sleeve” environment for investigators in lab Subjective, but probably in the range 15 < T coudé < 25 ˚C Telescope assembly will track ambient temperature –Varies by ~15 ˚C over day, ~20 ˚C over year Over much of the year, there will be a large volume of warm air beneath much cooler air—unstable situation

3 Coudé Lab Thermal Control warm cool Need some kind of “window” system Hole in deck

4 “Window” Requirements 1.Allow no more than error budget of seeing a.Diffraction limited: 10 nm rms wavefront b.Seeing limited: 0.03 arcsec, 50% enc. energy c.Coronal: 0.03 arcsec, 50% enc. energy 2.Pass entire wavelength range of telescope visible  thermal IR a.Truly simultaneous visible/IR observations require air “window” b.Visible and near-IR observations could use fused silica or similar window

5 Coudé Lab Thermal Control

6 Coudé Window Concept Ventilation reduces “chimney effect” Air knives act to contain separate air volumes Several possible windows: 1.Open (no window) 2.Fused silica 3.IR window

7 Mount Thermal Control Mount is shaded by enclosure Wind passes over mount Mount temperature will lag ambient (thermal inertia) Provision for drawing air through structural members to assist thermal equilibration

8 Higher wind = shorter time constant Lumped Capacity Mount Model

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