Use of diffusion bonded Cu strap and Integrated MLI for thermal control of 100K IR detector on L'Ralph instrument
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Passive cooling of cryogenic instruments is one of the most challenging aspects of spaceflight thermal control systems (TCS). They are highly sensitive to parasitic heat leaks from their warmer environment, especially the spacecraft components. The L'Ralph instrument on the Lucy mission is an example of such a system, with its LEISA detector requiring passive cooling to temperatures below 112 K. MLI performance can be measured in terms of estar, and analysts apply bias between a high and low estar value. This approach works well for conventional MLI at room temperature, however, it can be dangerous when a mission goes through a wide range of temperatures during its lifetime, with estar values increasing exponentially as temperatures get colder. Various estar correlations are presented as well as how L'Ralph is approaching the MLI problem with the use of IMLI. IMLI uses discrete spacers to isolate each layer, and doesn't require intermediate layers such as dacron netting. This results in estar performance that can be more precisely estimated, and yields values around 0.004 at the 112K operating temperature. L'Ralph is using IMLI on the backside of the radiator, which permits a more effective use of increased radiator area, by minimizing the area dependent heat leak impact from the instrument backloading. The detector is thermally coupled to the radiator via a diffusion bonded Cu strap. The diffusion bonding process chemically bonds the Cu foil ends in order to maximize heat transfer effectiveness across the multiple foils used. Employing a pressure compensation design via the use of Ti blocks and a clamp at the strap ends ensures that as temperatures go colder, pre-load is maintained in order to minimize resistance at the strap ends. The use of both of these technologies, and how they work together are crucial to the success of the L'Ralph TCS.
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Daniel Bae, NASA, US
ICES101: Spacecraft and Instrument Thermal Systems
The 51st International Conference on Environmental Systems was held in Saint Paul, Minnesota, US, on 10 July 2022 through 14 July 2022.