3D Printing Complex Unitized Instrument Optical Benches and Metering Structures

Metadata Updated: February 28, 2019

Additive machining technologies have advanced to a point where they can be utilized effectively for lowering mission costs. However, special design engineering approaches must be understood and demonstrated before additive machining can be used by flight project teams to reduce cost/risk at significant scales. We propose to manufacture an entire complex instrument structure, including optics, using additive machining to drastically reduce parts count and integration time, and demonstrate the non-standard design approaches required. The printed instrument will be subjected to environmental testing to qualify it for spaceflight, validating the manufacturing approach and reducing risk for future use of Direct Metal Laser Sintering (DMLS) components in flight programs.  This project will design and manufacture a small, cube-sat class imaging telescope using 3D printed components and traditional glass optics. The number of total parts will be reduced as 3D printing allows consolidation of traditionally separate components into complex unitary structures. 3D printed metal optics will also be manufactured to evaluate the stability and polishability of metal 3D printed mirrors. The resulting telescope will be subjected to environmental testing to increase the TRL of 3D printed metallic instrument components. The environmental testing will consist of subjecting the small telescope to vibration and thermal-vacuum to typical flight qualification levels to verify that the instrument will remain in focus. The flat mirrors are being printed out of aluminum and evaluated for single point diamond tool polishing, and will be subjected to thermal vacuum temperature cycling to evaluate figure stability.The technique employed is a commercial additive manufacturing process called "Direct Metal Laser Sintering" (DMLS) that has potential applications to reduce costs for spaceflight instruments. It is a powder bed form additive machining that has been used extensively in the biomedical industry for inplants, and it has not yet been readily adopted by the aerospace industry. This research effort demonstrates how DMLS can be applied to imaging instruments to save time and cost through the reduction in parts count and improved part performance.

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Public: This dataset is intended for public access and use. License: U.S. Government Work

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Metadata Created Date August 1, 2018
Metadata Updated Date February 28, 2019

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Harvested from NASA Data.json

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Resource Type Dataset
Metadata Created Date August 1, 2018
Metadata Updated Date February 28, 2019
Publisher Space Technology Mission Directorate
Unique Identifier TECHPORT_14531
Maintainer
TECHPORT SUPPORT
Maintainer Email
Public Access Level public
Bureau Code 026:00
Metadata Context https://project-open-data.cio.gov/v1.1/schema/catalog.jsonld
Metadata Catalog ID https://data.nasa.gov/data.json
Schema Version https://project-open-data.cio.gov/v1.1/schema
Catalog Describedby https://project-open-data.cio.gov/v1.1/schema/catalog.json
Harvest Object Id 5ea252d6-f14f-49d9-acb9-7f46e7bc220b
Harvest Source Id 39e4ad2a-47ca-4507-8258-852babd0fd99
Harvest Source Title NASA Data.json
Data First Published 2015-09-01
Homepage URL https://techport.nasa.gov/view/14531
License http://www.usa.gov/publicdomain/label/1.0/
Data Last Modified 2018-07-19
Program Code 026:027
Source Datajson Identifier True
Source Hash 46e79ee69b130025cb011a670a9c8ed876ac87c6
Source Schema Version 1.1

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