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Tytuł artykułu

Study of degradation and granular flow processes using X-ray imaging

Treść / Zawartość
Identyfikatory
Warianty tytułu
PL
Analiza procesów degradacji i przepływu granulatu z wykorzystaniem obrazowania metodą promieni X
Języki publikacji
EN
Abstrakty
EN
This paper reviews the work that has been done in the past 10 years at the Lodz University of technology about the visualization and the quantification of phenomena related to degradation processes (i.e. stress corrosion cracking in stainless steel, fatigue crack in titanium alloys) in engineering materials as well as granular flow in silos using X-ray imaging (i.e. radiography and (micro)tomography). Besides presenting the experimental protocols, the paper also presents the image processing strategies that have been applied to enable the extraction of characteristic parameters from the volumetric images.
PL
Artykuł przedstawia przegląd prac badawczych przeprowadzonych w ostatnich 10 latach w Politechnice Łódzkiej, dotyczących wizualizacji oraz analizy ilościowej zjawisk mających miejsce w procesie degradacji materiałów (tj. korozji naprężeniowej stali nierdzewnej, pęknięcia stopów tytanu) oraz przepływu materiałów sypkich w silosach z wykorzystaniem obrazowania metodami opartymi na promieniowaniu X (tzn. radiografii oraz (micro)tomografii). Oprócz przedstawienia metodologii pomiaru, zostały również opisane metody przetwarzania obrazów, pozwalające na wyznaczenie charakterystycznych parametrów badanych procesów z obrazów wolumetrycznych.
Rocznik
Strony
5--10
Opis fizyczny
Bibliogr. 31 poz., rys.
Twórcy
autor
  • Institute of Applied Computer Science, Lodz University of Technology
autor
  • Institute of Applied Computer Science, Lodz University of Technology
  • Institute of Applied Computer Science, Lodz University of Technology
  • Formerly at the Institute of Applied Computer Science
autor
  • Institute of Applied Computer Science, Lodz University of Technology
  • Formerly at the Institute of Applied Computer Science
Bibliografia
  • [1] Aktouf Z., Bertrand G., Perroton L.: A three-dimensional holes closing algorithm. Pattern Recognition Letters, 23/2002, 523–531.
  • [2] Appleton B., Talbot H.: Globally minimal surfaces by continuous maximal flows. IEEE Transactions on Pattern Analysis and Machine Intelligence, 28/2006, 106–118.
  • [3] Babout L., Jopek L., Janaszewski M.: A New Directional Filter Bank for 3D Texture Segmentation: Application to Lamellar Microstructure in Titanium Alloy, in 13th IAPR International Conference on Machine Vision Applications, 2013, 419–422.
  • [4] Babout L., Jopek L., Janaszewski M.: Extraction of complex microstructural patterns in X-ray microtomography images: application to lamellar titanium alloy, in 7th World Congress on Industrial Process Tomography (WCIPT7), 2013, 703–712.
  • [5] Babout L., Janaszewski M., Marrow T.J., Withers P.J.: A method for the 3-D quantification of bridging ligaments during crack propagation. Scripta Materialia, 65/2011, 131–134.
  • [6] Babout L., Marrow T.J., Engelberg D., Withers P.J.: X-ray microtomographic observation of intergranular stress corrosion cracking in sensitised austenitic stainless steel. Materials Science and Technology, 22/2006, 1068–1075.
  • [7] Babout L., Grudzien K., Maire E., Withers P.J.. Influence of wall roughness and packing density on stagnant zone formation during funnel flow discharge from a silo: An X-ray imaging study. Chemical Engineering Science, 97/2013, 210–224.
  • [8] Babout L., Jopek Ł., Preuss M.. 3D characterization of trans- and interlamellar fatigue crack in (α+β) Ti alloy. Materials Characterization, 98/2014, 130–139.
  • [9] Bieberle MBarthel., F., Menz H.-J., Mayer H.-G., Hampel U.: Ultrafast threedimensional x-ray computed tomography. Applied Physics Letters, 98/2011, 034101.
  • [10] Birosca S., Buffiere J.-Y., Garcia-Pastor F.A., Karadge M., Babout L., Preuss M.: Three-dimensional characterization of fatigue cracks in Ti-6246 using Xray tomography and electron backscatter diffraction. Acta Materialia, 57/2009, 5834–5847.
  • [11] Cloetens P., Pateyron-Salome M., Buffiere J.Y., Peix G., Baruchel J., Peyrin F., Schlenker M.: Observation of microstructure and damage in materials by phase sensitive radiography and tomography. Journal of Applied Physics, 81/1997, 5878–5886.
  • [12] Couprie M., Coeurjolly D., Zrour R.: Discrete bisector function and Euclidean skeleton in 2D and 3D. Image Vision Comput., 25/2007, 1543.
  • [13] Fischer F., Hoppe D., Schleicher E., Mattausch G., Flaske H., Bartel R., Hampel U.: An ultra fast electron beam x-ray tomography scanner. Measurement Science & Technology, 19/2008.
  • [14] Grudzien K., Niedostatkiewicz M., Adrien J., Maire E., Babout L.: Analysis of the bulk solid flow during gravitational silo emptying using X-ray and ECT tomography. Powder Technology, 224/2012, 196–208.
  • [15] Grudzien K., Romanowski A., Chaniecki Z., Niedostatkiewicz M., Sankowski D.: Description of the silo flow and bulk solid pulsation detection using ECT. Flow Measurement and Instrumentation, 21/2010, 198–206.
  • [16] Grudzien K., Romanowski A., Williams R.A.: Application of a Bayesian approach to the tomographic analysis of hopper fow. Particle and Particle Systems Characterization, 22/2006, 246.
  • [17] Janaszewski M., Couprie M., Babout L.. Hole filling in 3D volumetric objects. Pattern Recognition, 43/2010, 3548–3559.
  • [18] Janaszewski M., Postolski M., Babout L.. Robust algorithm for tunnel closing in 3D volumetric objects based on topological characteristics of points. Pattern Recognition Letters, 32/2011, 2231–2238.
  • [19] Johnson G., King A., Honnicke M.G., Marrow J., Ludwig W.: X-ray diffraction contrast tomography: A novel technique for three-dimensional grain mapping of polycrystals. II. The combined case. Journal of Applied Crystallography, 41/2008, 310–318.
  • [20] Kak A.C., Slaney M.. Principles of computerized tomographic imaging. New York, 1987.
  • [21] King A., Johnson G., Engelberg D., Ludwig W., Marrow J.. Observations of intergranular stress corrosion cracking in a grain-mapped polycrystal. Science, 321/2008, 382–385.
  • [22] Kornev A., Babout L., Janaszewski M., Talbot H.: Outer Surface Reconstruction for 3d Fractured Objects, in Computer Vision and Graphics, Pts 1 and 2, 6374, L. Bolc, R. Tadeusiewicz, L.J. Chmielewski, and K. Wojciechowski, Eds. Berlin: SPRINGER-VERLAG, 2010, 57–64.
  • [23] Limodin N., Salvo L., Boller E., Suery M., Felberbaum M., Gailliegue S., Madi K.: In situ and real-time 3-D microtomography investigation of dendritic solidification in an Al-10 wt.% Cu alloy. Acta Materialia, 57/2009, 2300–2310.
  • [24] Ludwig W., King A., Herbig M., Reischig P., Marrow J., Babout L., Lauridsen E.M., Proudhon H., Buffiere J.Y.: Characterization of polycrystalline materialsby combined use of synchrotron X-ray imaging and diffraction techniques. JOM, 62/2010, 22–28.
  • [25] Pfeiffer F., Weitkamp T., Bunk O., David C.: Phase retrieval and differential phase-contrast imaging with low-brilliance X-ray sources. Nature Physics, 2/2006, 258–261.
  • [26] Saúde A.V., Couprie M., Lotufo R.A.: Discrete 2D and 3D euclidean medial axis in higher resolution. Image and Vision Computing, 27/2009, 354–363.
  • [27] Spear A.D., Li S.F., Lind J.F., Suter R.M., Ingraffea A.R.: Three-dimensional characterization of microstructurally small fatigue-crack evolution using quantitative fractography combined with post-mortem X-ray tomography and high-energy X-ray diffraction microscopy. Acta Materialia, 76/2014, 413–424.
  • [28] Suery M., Adrien J., Landron C., Terzi S., Maire E., Salvo L., Blandin J.-J.: Fast in-situ X-ray micro tomography characterisation of microstructural evolution and strain-induced damage in alloys at various temperatures. International Journal of Materials Research, 101/2010, 1080–1088.
  • [29] Wielewski E., Menasche D.B., Callahan P.G., Suter R.M.: Three-dimensional α colony characterization and prior-β grain reconstruction of a lamellar Ti–6Al–4V specimen using near-field high-energy X-ray diffraction microscopy. Journal of Applied Crystallography, 48/2015, 1165–1171.
  • [30] Withers P.J.: X-ray nanotomography. Materials Today, 10/2007, 26–34.
  • [31] Yang Y., Rotter M., Ooi J., Wang Y.: Flow Channel Boundaries in Silos. Chemical Engineering & Technology, 34/2011, 1295–1302.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-733bfe14-dd03-44b7-ae47-4739538d0d14
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