fbpx
Wikipedia

Industrial computed tomography

January 01, 1970

Industrial computed tomography (CT) scanning is any computer-aided tomographic process, usually X-ray computed tomography, that uses irradiation to produce three-dimensional internal and external representations of a scanned object. Industrial CT scanning has been used in many areas of industry for internal inspection of components. Some of the key uses for industrial CT scanning have been flaw detection, failure analysis, metrology, assembly analysis and reverse engineering applications.[1][2] Just as in medical imaging, industrial imaging includes both nontomographic radiography (industrial radiography) and computed tomographic radiography (computed tomography).

Animated set of computed tomography transmission images of a Logitech C500 webcam

Types of scanners edit

 
Line beam scanner

Line beam scanning is the traditional process of industrial CT scanning.[3] X-rays are produced and the beam is collimated to create a line. The X-ray line beam is then translated across the part and data is collected by the detector. The data is then reconstructed to create a 3-D volume rendering of the part.

In cone beam scanning, the part to be scanned is placed on a rotary table.[3] As the part rotates, the cone of X-rays produce a large number of 2D images that are collected by the detector. The 2D images are then processed to create a 3D volume rendering of the external and internal geometries of the part.

 
Cone beam scanner

History edit

Industrial CT scanning technology was introduced in 1972 with the invention of the CT scanner for medical imaging by Godfrey Hounsfield. The invention earned him a Nobel Prize in medicine, which he shared with Allan McLeod Cormack.[4][5] Many advances in CT scanning have allowed for its use in the industrial field for metrology in addition to the visual inspection primarily used in the medical field (medical CT scan).

Analysis and inspection techniques edit

Various inspection uses and techniques include part-to-CAD comparisons, part-to-part comparisons, assembly and defect analysis, void analysis, wall thickness analysis, and generation of CAD data. The CAD data can be used for reverse engineering, geometric dimensioning and tolerance analysis, and production part approval.[6]

Assembly edit

One of the most recognized forms of analysis using CT is for assembly, or visual analysis. CT scanning provides views inside components in their functioning position, without disassembly. Some software programs for industrial CT scanning allow for measurements to be taken from the CT dataset volume rendering. These measurements are useful for determining the clearances between assembled parts or the dimension of an individual feature.

 
An industrial computed tomography (CT) scan conducted on an aluminum casting to identify internal failures such as voids. All color coordinated particles within casting are voids/porosity/air pockets, which can additionally be measured and are color coordinated according to size.

Void, crack and defect detection edit

Flight through a 3D reconstruction of a disposable pepper grinder. Glass in blue.

Traditionally, determining defects, voids and cracks within an object would require destructive testing. CT scanning can detect internal features and flaws displaying this information in 3D without destroying the part. Industrial CT scanning (3D X-ray) is used to detect flaws inside a part such as porosity,[7] an inclusion, or a crack.[8] It has been also used to detect the origin and propagation of damages in concrete.[9]

Metal casting and moulded plastic components are typically prone to porosity because of cooling processes, transitions between thick and thin walls, and material properties. Void analysis can be used to locate, measure, and analyze voids inside plastic or metal components.

Geometric dimensioning and tolerancing analysis edit

Traditionally, without destructive testing, full metrology has only been performed on the exterior dimensions of components, such as with a coordinate-measuring machine (CMM) or with a vision system to map exterior surfaces. Internal inspection methods would require using a 2D X-ray of the component or the use of destructive testing. Industrial CT scanning allows for full non-destructive metrology. With unlimited geometrical complexity, 3D printing allows for complex internal features to be created with no impact on cost, such features are not accessible using traditional CMM. The first 3D printed artefact that is optimised for characterisation of form using computed tomography CT [10]

Image-based finite element methods edit

Image-based finite element method converts the 3D image data from X-ray computed tomography directly into meshes for finite element analysis. Benefits of this method include modelling complex geometries (e.g. composite materials) or accurately modelling "as manufactured" components at the micro-scale.[11]

Trends and Developments edit

The industrial computed tomography market is forecast to reach a size of USD 773.45 million to USD 1,116.5 million between 2029 and 2030. Regional trends show that strong market growth is expected, particularly in the Asia-Pacific region, but also in North America and Europe, due to strict safety regulations and preventive maintenance of industrial equipment.[12][13] Growth is being driven primarily by the ongoing development of CT devices and services that enable precise and non-destructive testing of components. Innovations such as the use of artificial intelligence for automated fault analyses and the development of mobile CT systems are expanding the possibilities.[14]

See also edit

References edit

  1. ^ Flisch, A., et al. Industrial Computer Tomography in Reverse Engineering Applications. DGZfP-Proceedings BB 67-CD Paper 8, Computerized Tomography for Industrial Applications and Image Processing in Radiology, March 15–17, 1999, Berlin, Germany.
  2. ^ Woods, Susan. , November 1, 2010.
  3. ^ a b Hofmann, J., Flisch, A., Obrist, A., Adaptive CT scanning-mesh based optimisation methods for industrial X-ray computer tomography applications. NDT&E International (37), 2004, pp. 271–278.
  4. ^ Zoofan, Bahman. "3D Micro-Tomography – A Powerful Engineering Tool" 2011-07-07 at the Wayback Machine. 3D Scanning Technologies. July 5, 2010.
  5. ^ Noel, Julien. "Advantages of CT in 3D Scanning of Industrial Parts 2011-07-07 at the Wayback Machine. August 18, 2010.
  6. ^ Micro Manufacturing Magazine for the global micro manufacturing technology industry, August 2010.
  7. ^ Lambert, J.; Chambers, A. R.; Sinclair, I.; Spearing, S. M. (2012). "3D damage characterisation and the role of voids in the fatigue of wind turbine blade materials". Composites Science and Technology. 72 (2): 337. doi:10.1016/j.compscitech.2011.11.023.
  8. ^ Bull, D. J.; Helfen, L.; Sinclair, I.; Spearing, S. M.; Baumbach, T. (2013). "A comparison of multi-scale 3D X-ray tomographic inspection techniques for assessing carbon fibre composite impact damage" (PDF). Composites Science and Technology. 75: 55–61. doi:10.1016/j.compscitech.2012.12.006.
  9. ^ Joshi, Nirmal Raj; Matsumoto, Ayumu; Asamoto, Shingo; Miura, Taito; Kawabata, Yuichiro (2022-04-01). "Investigation of the mechanical behaviour of concrete with severe delayed ettringite formation expansion focusing on internal damage propagation under various compressive loading patterns". Cement and Concrete Composites. 128: 104433. doi:10.1016/j.cemconcomp.2022.104433. ISSN 0958-9465. S2CID 246514058.
  10. ^ Shah, Paras; Racasan, Radu; Bills, Paul (2016-11-01). "Comparison of different additive manufacturing methods using computed tomography". Case Studies in Nondestructive Testing and Evaluation. 6: 69–78. doi:10.1016/j.csndt.2016.05.008. ISSN 2214-6571.
  11. ^ Evans, Ll. M.; Margetts, L.; Casalegno, V.; Lever, L. M.; Bushell, J.; Lowe, T.; Wallwork, A.; Young, P.; Lindemann, A. (2015-05-28). "Transient thermal finite element analysis of CFC–Cu ITER monoblock using X-ray tomography data". Fusion Engineering and Design. 100: 100–111. doi:10.1016/j.fusengdes.2015.04.048. hdl:10871/17772.
  12. ^ "Industrial CT Scanning Market - Computed Tomography - Size, Share & Industry Analysis". www.mordorintelligence.com. Mordor Intelligence. Retrieved 2024-04-11.
  13. ^ "Industrial Computed Tomography Market Size Report, 2030". www.grandviewresearch.com. Grand View Research, Inc. Retrieved 2024-04-11.
  14. ^ "Insights into trends, market development and technological innovations". www.microvista.de. Microvista GmbH. 2024-04-10. Retrieved 2024-04-11.

January 01, 1970
industrial, computed, tomography, scanning, computer, aided, tomographic, process, usually, computed, tomography, that, uses, irradiation, produce, three, dimensional, internal, external, representations, scanned, object, industrial, scanning, been, used, many. Industrial computed tomography CT scanning is any computer aided tomographic process usually X ray computed tomography that uses irradiation to produce three dimensional internal and external representations of a scanned object Industrial CT scanning has been used in many areas of industry for internal inspection of components Some of the key uses for industrial CT scanning have been flaw detection failure analysis metrology assembly analysis and reverse engineering applications 1 2 Just as in medical imaging industrial imaging includes both nontomographic radiography industrial radiography and computed tomographic radiography computed tomography source source source source source source source Animated set of computed tomography transmission images of a Logitech C500 webcam Contents 1 Types of scanners 2 History 3 Analysis and inspection techniques 3 1 Assembly 3 2 Void crack and defect detection 3 3 Geometric dimensioning and tolerancing analysis 3 4 Image based finite element methods 4 Trends and Developments 5 See also 6 ReferencesTypes of scanners edit nbsp Line beam scanner Line beam scanning is the traditional process of industrial CT scanning 3 X rays are produced and the beam is collimated to create a line The X ray line beam is then translated across the part and data is collected by the detector The data is then reconstructed to create a 3 D volume rendering of the part In cone beam scanning the part to be scanned is placed on a rotary table 3 As the part rotates the cone of X rays produce a large number of 2D images that are collected by the detector The 2D images are then processed to create a 3D volume rendering of the external and internal geometries of the part nbsp Cone beam scannerHistory editIndustrial CT scanning technology was introduced in 1972 with the invention of the CT scanner for medical imaging by Godfrey Hounsfield The invention earned him a Nobel Prize in medicine which he shared with Allan McLeod Cormack 4 5 Many advances in CT scanning have allowed for its use in the industrial field for metrology in addition to the visual inspection primarily used in the medical field medical CT scan Analysis and inspection techniques editVarious inspection uses and techniques include part to CAD comparisons part to part comparisons assembly and defect analysis void analysis wall thickness analysis and generation of CAD data The CAD data can be used for reverse engineering geometric dimensioning and tolerance analysis and production part approval 6 Assembly editOne of the most recognized forms of analysis using CT is for assembly or visual analysis CT scanning provides views inside components in their functioning position without disassembly Some software programs for industrial CT scanning allow for measurements to be taken from the CT dataset volume rendering These measurements are useful for determining the clearances between assembled parts or the dimension of an individual feature nbsp An industrial computed tomography CT scan conducted on an aluminum casting to identify internal failures such as voids All color coordinated particles within casting are voids porosity air pockets which can additionally be measured and are color coordinated according to size Void crack and defect detection edit source source source source source source source Flight through a 3D reconstruction of a disposable pepper grinder Glass in blue Traditionally determining defects voids and cracks within an object would require destructive testing CT scanning can detect internal features and flaws displaying this information in 3D without destroying the part Industrial CT scanning 3D X ray is used to detect flaws inside a part such as porosity 7 an inclusion or a crack 8 It has been also used to detect the origin and propagation of damages in concrete 9 Metal casting and moulded plastic components are typically prone to porosity because of cooling processes transitions between thick and thin walls and material properties Void analysis can be used to locate measure and analyze voids inside plastic or metal components Geometric dimensioning and tolerancing analysis edit Traditionally without destructive testing full metrology has only been performed on the exterior dimensions of components such as with a coordinate measuring machine CMM or with a vision system to map exterior surfaces Internal inspection methods would require using a 2D X ray of the component or the use of destructive testing Industrial CT scanning allows for full non destructive metrology With unlimited geometrical complexity 3D printing allows for complex internal features to be created with no impact on cost such features are not accessible using traditional CMM The first 3D printed artefact that is optimised for characterisation of form using computed tomography CT 10 Image based finite element methods edit Image based finite element method converts the 3D image data from X ray computed tomography directly into meshes for finite element analysis Benefits of this method include modelling complex geometries e g composite materials or accurately modelling as manufactured components at the micro scale 11 Trends and Developments editThe industrial computed tomography market is forecast to reach a size of USD 773 45 million to USD 1 116 5 million between 2029 and 2030 Regional trends show that strong market growth is expected particularly in the Asia Pacific region but also in North America and Europe due to strict safety regulations and preventive maintenance of industrial equipment 12 13 Growth is being driven primarily by the ongoing development of CT devices and services that enable precise and non destructive testing of components Innovations such as the use of artificial intelligence for automated fault analyses and the development of mobile CT systems are expanding the possibilities 14 See also editCT scan Industrial radiography Cone beam computed tomography applications in quality control and metrology PCB reverse engineering an application of industrial CT to image printed circuit boards non destructively References edit Flisch A et al Industrial Computer Tomography in Reverse Engineering Applications DGZfP Proceedings BB 67 CD Paper 8 Computerized Tomography for Industrial Applications and Image Processing in Radiology March 15 17 1999 Berlin Germany Woods Susan 3 D CT inspection offers a full view of microparts November 1 2010 a b Hofmann J Flisch A Obrist A Adaptive CT scanning mesh based optimisation methods for industrial X ray computer tomography applications NDT amp E International 37 2004 pp 271 278 Zoofan Bahman 3D Micro Tomography A Powerful Engineering Tool Archived 2011 07 07 at the Wayback Machine 3D Scanning Technologies July 5 2010 Noel Julien Advantages of CT in 3D Scanning of Industrial Parts Archived 2011 07 07 at the Wayback Machine August 18 2010 Reducing Preproduction Inspection Costs with Industrial CT Computed Tomography Micro Manufacturing Magazine for the global micro manufacturing technology industry August 2010 Lambert J Chambers A R Sinclair I Spearing S M 2012 3D damage characterisation and the role of voids in the fatigue of wind turbine blade materials Composites Science and Technology 72 2 337 doi 10 1016 j compscitech 2011 11 023 Bull D J Helfen L Sinclair I Spearing S M Baumbach T 2013 A comparison of multi scale 3D X ray tomographic inspection techniques for assessing carbon fibre composite impact damage PDF Composites Science and Technology 75 55 61 doi 10 1016 j compscitech 2012 12 006 Joshi Nirmal Raj Matsumoto Ayumu Asamoto Shingo Miura Taito Kawabata Yuichiro 2022 04 01 Investigation of the mechanical behaviour of concrete with severe delayed ettringite formation expansion focusing on internal damage propagation under various compressive loading patterns Cement and Concrete Composites 128 104433 doi 10 1016 j cemconcomp 2022 104433 ISSN 0958 9465 S2CID 246514058 Shah Paras Racasan Radu Bills Paul 2016 11 01 Comparison of different additive manufacturing methods using computed tomography Case Studies in Nondestructive Testing and Evaluation 6 69 78 doi 10 1016 j csndt 2016 05 008 ISSN 2214 6571 Evans Ll M Margetts L Casalegno V Lever L M Bushell J Lowe T Wallwork A Young P Lindemann A 2015 05 28 Transient thermal finite element analysis of CFC Cu ITER monoblock using X ray tomography data Fusion Engineering and Design 100 100 111 doi 10 1016 j fusengdes 2015 04 048 hdl 10871 17772 Industrial CT Scanning Market Computed Tomography Size Share amp Industry Analysis www mordorintelligence com Mordor Intelligence Retrieved 2024 04 11 Industrial Computed Tomography Market Size Report 2030 www grandviewresearch com Grand View Research Inc Retrieved 2024 04 11 Insights into trends market development and technological innovations www microvista de Microvista GmbH 2024 04 10 Retrieved 2024 04 11 Retrieved from https en wikipedia org w index php title Industrial computed tomography amp oldid 1223707592, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.