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  • 1.
    Fröjdh, C.
    et al.
    Mid Sweden University, Sweden.
    Norlin, B.
    Mid Sweden University, Sweden.
    Reza, S.
    Mid Sweden University, Sweden.
    Nordin, T.
    RISE - Research Institutes of Sweden.
    Precision scan-imaging for paperboard quality inspection utilizing X-ray fluorescence2018In: Journal of Instrumentation, E-ISSN 1748-0221, Vol. 13, no 1, article id C01021Article in journal (Refereed)
    Abstract [en]

    Paperboard is typically made up of a core of cellulose fibers [C6H10O5] and a coating layer of [CaCO3]. The uniformity of these layers is a critical parameter for the printing quality. Current quality control methods include chemistry based visual inspection methods as well as X-ray based methods to measure the coating thickness. In this work we combine the X-ray fluorescence signals from the Ca atoms (3.7 keV) in the coating and from a Cu target (8.0 keV) placed behind the paper to simultaneously measure both the coating and the fibers. Cu was selected as the target material since its fluorescence signal is well separated from the Ca signal while its fluorescence's still are absorbed sufficiently in the paper. A laboratory scale setup is built using stepper motors, a silicon drift detector based spectrometer and a collimated X-ray beam. The spectroscopic image is retrieved by scanning the paperboard surface and registering the fluorescence signals from Ca and Cu. The exposure time for this type of setups can be significantly improved by implementing spectroscopic imaging sensors. The material contents in the layers can then be retrieved from the absolute and relative intensities of these two signals.

  • 2.
    Wilbur, S.
    et al.
    University of Sheffield, UK.
    Anastopoulos, C.
    University of Sheffield, UK.
    Angelmahr, M.
    Fraunhofer, Germany.
    Asfis, G.
    TWI Hellas, Greece.
    Koch, J.
    Fraunhofer, Germany.
    Lindblom, Magnus
    RISE Research Institutes of Sweden, Digital Systems, Smart Hardware.
    Lohwasser, K.
    University of Sheffield, UK.
    Margulis, Walter
    RISE Research Institutes of Sweden, Digital Systems.
    Flexible X-ray imaging detectors using scintillating fibers2022In: Journal of Instrumentation, E-ISSN 1748-0221, Vol. 17, no 10, article id C10013Article in journal (Refereed)
    Abstract [en]

    We present early design and simulation work on a novel X-ray imaging detector. The intent of the FleX-RAY project is to create a digital X-ray detector that is capable of producing high-resolution images, is flexible enough to produce an image on a curved surface, and is capable of self-reporting its final shape. The X-rays will be detected on a sheet of scintillating optical fibers, which will guide the scintillation light to single-photon avalanche photodiodes. This setup allows the electronics and hardware to be moved out of the path of the X-ray beam, limiting the need for additional shielding. Self-shape-reporting will be achieved using a flexible ultra-thin glass substrate with optical waveguides and Bragg gratings, processed by femtosecond laser point-by-point writing. The functionalized glass substrate allows precise measurement of strains, which can be used to calculate the shape. © 2022 The Author(s).

  • 3.
    Åström, E.
    et al.
    LKAB, Sweden.
    Bonomi, G.
    University of Brescia, Italy.
    Calliari, I.
    University of Padova, Italy.
    Calvini, P.
    University of Genova, Italy; Sezione INFN di Genova, Italy.
    Checchia, P.
    INFN Sezione di Padova, Italy.
    Donzella, A.
    University of Brescia, Italy.
    Faraci, E.
    Centro Sviluppo Materiali SPA, Italy.
    Forsberg, F.
    Luleå University of Technology, Sweden; LKAB, Sweden.
    Gonella, F.
    INFN Sezione di Padova, Italy.
    Hu, Xianfeng
    RISE, Swerea, MEFOS.
    Klinger, J.
    INFN Sezione di Padova, Italy.
    Sundqvist Ökvist, Lena
    RISE, Swerea, MEFOS.
    Pagano, D.
    University of Brescia, Italy.
    Rigoni, A.
    University of Padova, Italy.
    Ramous, E.
    University of Padova, Italy.
    Urbani, M.
    University of Padova, Italy.
    Vanini, S.
    University of Padova, Italy.
    Zenoni, A.
    University of Brescia, Italy.
    Zumerle, G.
    University of Padova, Italy.
    Precision measurements of linear scattering density using muon tomography2016In: Journal of Instrumentation, E-ISSN 1748-0221, Vol. 11, no 7, article id P07010Article in journal (Refereed)
    Abstract [en]

    We demonstrate that muon tomography can be used to precisely measure the properties of various materials. The materials which have been considered have been extracted from an experimental blast furnace, including carbon (coke) and iron oxides, for which measurements of the linear scattering density relative to the mass density have been performed with an absolute precision of 10%. We report the procedures that are used in order to obtain such precision, and a discussion is presented to address the expected performance of the technique when applied to heavier materials. The results we obtain do not depend on the specific type of material considered and therefore they can be extended to any application.

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