Interdisciplinary blog

New imaging technology to design and build greener and safer aircraft

January 22, 2015
by Thomas Blumensath

The University of Southampton is helping to develop new imaging technology to be used in the design, manufacture and maintenance for current and future generations of carbon composite aircraft. Led by QinetiQ, the UK consortium of the University of Southampton and University College London (UCL) and four companies in ProjectCAN brings together world leaders from […]

The University of Southampton is helping to develop new imaging technology to be used in the design, manufacture and maintenance for current and future generations of carbon composite aircraft.

Led by QinetiQ, the UK consortium of the University of Southampton and University College London (UCL) and four companies in ProjectCAN brings together world leaders from academia, the aerospace industry and X-ray inspection equipment manufacture.

As part of the governmentā€™s Aerospace Technology Institute, Innovate UK, the UKā€™s innovation agency, has provided the team with significant funding to develop two new non-destructive testing processes for the detection of flaws in composite aerospace components.

The University of Southamptonā€™s Āµ-VIS Centre for Computed Tomography is host to one part of this three-year project. Together with Nikon Metrology UK Ltd, it aims to develop and test methods for scanning and visualising the insides of large, flat components using X-rays.Ā  The partners will develop both the system for acquiring scan data and software to reconstruct it into a 3-D volume image, allowing manipulation and visualisation using standard software.

ā€œConventional computed tomography (CT) techniques are widely used but are not well suited to image extended flat objects,ā€ said Dr Thomas Blumensath, of the University of Southampton.Ā  ā€œWe will be developing an alternative technique, which applies computed laminography (CL) techniques, to overcome the limitations of conventional CT for large, flat components. This will enhance our ability to find defects in large composite parts, such as those which are increasingly used in modern aircraft.

ā€œThis will ultimately help in the production and maintenance processes and will assist in the development of more environmentally-friendly aeroplanes, as well as enhanced overall aircraft safety.ā€

Traditional CT requires the scanned components to be fully rotated, and will yield optimal results only when the X-ray attenuation for each angle is broadly similar. It is impossible to scan very large parts due to space restrictions; when scanning smaller flat panels, the variation of attenuation across the angles can become too large for optimal imaging.Ā  CL systems use a different motion, such as linear translation or limited-angle rotation, to scan components where CT is impossible or ill-suited.

A laminography system comprises the hardware that positions the sample, source and detector to acquire 2D projection data, as well as an algorithm to reconstruct a 3D volume image from the data.Ā  ProjectCAN will develop both this hardware and software to allow laminographic imaging within the custom Nikon Metrology 225/450kV X-ray scanner already in service in the Āµ-VIS centre at Southampton.

In parallel with the work at the University of Southampton and Nikon Metrology, the team at Axi-Tek and UCL will be developing a new backscatter x-ray inspection technique to non-destructively inspect large area composite structures such as wing sections, engine cowlings and fuselage components.Ā  Sometimes referred to as ā€œone-sidedā€ x-ray inspection, backscatter uniquely allows the x-ray investigation of the structural integrity of composite materials from a single side of the component, that is, the x-rays do not have to pass through and out the other side of the component.Ā  To enhance this technique, the team also intend to combine the backscatter x-ray with more conventional optical surface inspection.

Fisheye view of the Nikon Metrology 225/450kV X-ray scanner at the University of Southampton's Āµ-VIS centre. Photograph courtesy of Sharif Ahmed, University of Southampton.

Fisheye view of the Nikon Metrology 225/450kV X-ray scanner at the University of Southampton’s Āµ-VIS centre. Photograph courtesy of Sharif Ahmed, University of Southampton.

 

Notes for editors:

  1. This work is undertaken in close collaboration with industrial and academic partners, such as Nikon Metrology UK Ltd, Axi-Tek Ltd and QinetiQ, as well as UCLā€™s Radiation Physics Group and the University of Southamptonā€™s multidisciplinary, multiscale, microtomographic Volume Imaging lab (Ī¼-VIS)
  2. The work is funded through a grant by Innovate UK, the UKā€™s innovation agency, UC Project No 101804.
  3. Through world-leading research and enterprise activities, the University of Southampton connects with businesses to create real-world solutions to global issues. Through its educational offering, it works with partners around the world to offer relevant, flexible education, which trains students for jobs not even thought of. This connectivity is what sets Southampton apart from the rest; we make connections and change the world. http://www.southampton.ac.uk/

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Categories: Uncategorized. Tags: Blog, CII, Computationally Intensive Imaging, idr, imaging, interdisciplinary research, research, Thomas Blumensath, u-vis, University of Southampton, and x-ray imaging.

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