Design, manufacture and metrology of additively manufactured, metal and ceramic lightweight circular mirror prototypes

TL;DR

This paper presents the design, manufacturing, and metrology of lightweight metal and ceramic mirror prototypes for space applications, utilizing additive manufacturing to achieve complex geometries and significant weight reduction.

Contribution

It introduces novel AM mirror designs with integrated features and lattice structures, demonstrating successful fabrication and surface characterization for space-based telescopes.

Findings

Achieved 50-70% weight reduction in mirror prototypes.

Successfully printed aluminium and fused silica mirror components.

Surface roughness measurements confirmed quality suitable for optical use.

Abstract

Spaced-based mirrors are a developing use-case for Additive Manufacturing (AM), the process that builds a part layer-by-layer. The increased geometric freedom results in novel and advantageous designs previously unachievable. Conventionally, mirror fabrication uses subtractive (milling & turning), formative (casting) and fabricative (bonding) manufacturing methods; however, an additive method can simplify an assembly by consolidating individual components into one, and incorporating lattice structures and function optimised geometries to reduce the mass of components, which are beneficial to space-based instrumentation as mass and volume are constrained. Attention must be given to the printability of the design - build orientation and powder/resin removal from lattices and internal cavities are challenges when designing for AM. This paper will describe the design, manufacture and metrology of mirror prototypes from the Active Deployable Optical Telescope (ADOT) 6U CubeSat project. The AM mirror is 52mm in diameter, 10mm deep, with a convex 100mm radius of curvature reflective surface and deploys telescopically on three booms. The objectives of the designs were to combine the boom mounting features into the mirror and to lightweight both prototypes by 50% and 70% using internal, thin-walled lattices. Four final lattice designs were downselected through simulation and prototype validation. Prototypes were printed in the aluminium alloy AlSi10Mg using powder bed fusion and fused silica using stereolithography. Aluminium mirrors were single point diamond turned and had surface roughness measurements taken. Fused silica designs were adapted from the aluminium designs and have completed printing.