Advanced techniques for robotic polishing of aluminum mirrors

Aluminum (pure or alloy) mirrors attract increasing interest, having Young’s Modulus and density similar to glasses. Advantage of high diffusivity offsets disadvantage of high thermal expansion coefficient and means that the mirror reaches thermal equilibrium rapidly. High ductility supports extreme light-weighting and complex machining, including fluid-cooling channels in high-energy applications, and integral interface components. Aluminum mirrors are also tolerant to vibrations and shock loads. The material is amenable to single point diamond turning (SPDT) and does not require optical coating. However, SPDT tends to produce mid-spatial frequency artefacts, which are difficult to remove, especially for aspheres and free-forms. These introduce diffraction effects and compromise stray light performance. In our previous research, we have demonstrated the potential of industrial robots to automate manual interventions with CNC polishing machines, and to provide surface-processing capabilities in their own right. We have also presented research concerning the mismatch between rigid and semi-rigid tools (including non-Newtonian tools), and aspheric surfaces. In this paper, we report on polishing of spherical and aspheric aluminum mirrors using an industrial robot. This includes tool-design, tool-path generation, texture control and removal of the mid-spatial frequency artefacts. We have investigated removal-rates and textures achieved, using different specialized slurries, polishing pads and special tool-paths. An effective process has been established, achieving Sa of 5nm on a 400mm square witness sample and a 490mm elliptical off-axis parabolic mirror.

[1]  Ramón Navarro,et al.  Directly Polished Light Weight Aluminum Mirror , 2008 .

[2]  David D. Walker,et al.  Development of swinging part profilometer for optics , 2016, Optical Angular Momentum.

[3]  Kevin Moeggenborg,et al.  Low-scatter bare aluminum optics via chemical mechanical polishing , 2008, Optical Engineering + Applications.

[4]  Keith G. Carrigan Manufacturing status of Tinsley visible quality bare aluminum and an example of snap together assembly , 2012, Defense + Commercial Sensing.

[5]  Dae Wook Kim,et al.  Rigid conformal polishing tool using non-linear visco-elastic effect. , 2010, Optics express.

[6]  David D. Walker,et al.  Recent developments of Precessions polishing for larger components and free-form surfaces , 2004, SPIE Optics + Photonics.

[7]  Daniel Vukobratovich,et al.  Large stable aluminum optics for aerospace applications , 2011, Optical Engineering + Applications.

[8]  Hongyu Li,et al.  The role of robotics in computer controlled polishing of large and small optics , 2015, SPIE Optical Engineering + Applications.

[9]  T. Newswander,et al.  Aluminum alloy AA-6061 and RSA-6061 heat treatment for large mirror applications , 2013, Optics & Photonics - Optical Engineering + Applications.

[10]  Brian D. Ramsey,et al.  Development of a direct fabrication technique for full-shell x-ray optics , 2016, Astronomical Telescopes + Instrumentation.

[11]  David D. Walker,et al.  Insight into aspheric misfit with hard tools: mapping the island of low mid-spatial frequencies , 2017 .

[12]  Andreas Tünnermann,et al.  Thermal expansion coefficient analyses of electroless nickel with varying phosphorous concentrations , 2014 .

[13]  Steven L. Folkman,et al.  Characterization of electroless nickel plating on aluminum mirrors , 2002, SPIE Optics + Photonics.

[14]  Keith G. Carrigan Visible quality aluminum and nickel superpolish polishing technology enabling new missions , 2011, Defense + Commercial Sensing.

[15]  Anthony Beaucamp,et al.  Use of the 'Precessions' process for prepolishing and correcting 2D & 2(1/2)D form. , 2006, Optics express.

[16]  G. C. Wood,et al.  On the nature of the mechanically polished aluminium surface , 1995 .