Computed laminography of CFRP using an X-ray cone beam and robotic sample manipulator systems
Computed laminography of CFRP using an X-ray cone beam and robotic sample manipulator systems
Carbon fibre reinforced polymers (CFRPs) are of interest to the aerospace sector for meeting future CO2 emission targets due to their weight reduction potential. However, the detection of structural and matrix defects is crucial for determining the performance and suitability of CFRPs in current and future generations of aircraft. Computed laminography (CL), a well-established non-destructive testing method, is well-suited to the scanning of CFRP components with large aspect ratios, for which conventional computed tomography is less suitable. Utilising an existing Nikon Metrology custom build X-ray CT scanner, two lift-in lift-out robotic sample manipulator systems are used to extend the capability of the system and allow the exploration of atypical scanning geometries. Implementing raster and limited angle trajectories, reconstructions using the ASTRA Tomography Toolbox and the SIRT algorithm are able to show structural defects in CFRPs, despite the reduced information inherent with CL systems. This paper reports on the system design and initial experiments that demonstrate benefits and drawbacks of different design options and scanning trajectory choices.
Computed laminography, X-ray cone-beam, robot arm, hexapod, CFRP
655-663
Wood, Charles
45eae1e9-e6f2-4656-96eb-a055f4d68aec
O'Brien, Neil
2e05fb57-6800-4a98-b20a-f7775efd011e
Denysov, Andriy
2d4a43d6-d109-468b-a2ad-0120a78f7bbf
Blumensath, Thomas
470d9055-0373-457e-bf80-4389f8ec4ead
March 2019
Wood, Charles
45eae1e9-e6f2-4656-96eb-a055f4d68aec
O'Brien, Neil
2e05fb57-6800-4a98-b20a-f7775efd011e
Denysov, Andriy
2d4a43d6-d109-468b-a2ad-0120a78f7bbf
Blumensath, Thomas
470d9055-0373-457e-bf80-4389f8ec4ead
Wood, Charles, O'Brien, Neil, Denysov, Andriy and Blumensath, Thomas
(2019)
Computed laminography of CFRP using an X-ray cone beam and robotic sample manipulator systems.
IEEE Transactions on Nuclear Science, 66 (3), , [8629274].
(doi:10.1109/TNS.2019.2895910).
Abstract
Carbon fibre reinforced polymers (CFRPs) are of interest to the aerospace sector for meeting future CO2 emission targets due to their weight reduction potential. However, the detection of structural and matrix defects is crucial for determining the performance and suitability of CFRPs in current and future generations of aircraft. Computed laminography (CL), a well-established non-destructive testing method, is well-suited to the scanning of CFRP components with large aspect ratios, for which conventional computed tomography is less suitable. Utilising an existing Nikon Metrology custom build X-ray CT scanner, two lift-in lift-out robotic sample manipulator systems are used to extend the capability of the system and allow the exploration of atypical scanning geometries. Implementing raster and limited angle trajectories, reconstructions using the ASTRA Tomography Toolbox and the SIRT algorithm are able to show structural defects in CFRPs, despite the reduced information inherent with CL systems. This paper reports on the system design and initial experiments that demonstrate benefits and drawbacks of different design options and scanning trajectory choices.
Text
Computed Laminography
- Author's Original
Text
Laminography (revised)
- Accepted Manuscript
More information
Submitted date: 13 November 2017
Accepted/In Press date: 2 August 2018
e-pub ahead of print date: 29 January 2019
Published date: March 2019
Keywords:
Computed laminography, X-ray cone-beam, robot arm, hexapod, CFRP
Identifiers
Local EPrints ID: 415613
URI: http://eprints.soton.ac.uk/id/eprint/415613
ISSN: 0018-9499
PURE UUID: 9576c43f-37d8-4f06-80af-db87faa7ba9d
Catalogue record
Date deposited: 16 Nov 2017 17:30
Last modified: 16 Mar 2024 04:02
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Contributors
Author:
Charles Wood
Author:
Neil O'Brien
Author:
Andriy Denysov
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