An inspection device is provided in which X-rays are radiated in a fan-like shape with respect to an extension direction of steel cords, are transmitted through a conveyor belt, and reach an X-ray line sensor. A control device makes an X-ray generator and the X-ray line sensor move in a fixed relative position at a certain speed within a certain movement range in a direction parallel with a plane and orthogonal to an extension direction of the steel cords. The control device generates two-dimensional image information on the basis of an X-ray transmission signal obtained each time the X-ray generator and the X-ray line sensor move a unit amount equal to a pixel pitch of the X-ray line sensor. The control device detects measurement information relating to the conveyor belt and the steel cords on the basis of the obtained two-dimensional image information.

Systems and methods for real time, nondestructive inspection of an object being formed by additive manufacturing is provided. The disclosed systems and methods can be used with any additive manufacturing system and can detect defects introduced during fabrication. In operation, additive manufacturing of the object can be paused and the object rotated within the build chamber. An x-ray pulse can then be directed through a linear aperture towards the object being formed inside the build chamber. A linear x-ray detector array can detect the x-ray pulse and an x-ray image of the object being formed can be created. By rotating the object being formed during exposure to the x-ray pulse at least one half of one full rotation, the entire volume of the object can be inspected.

A method for detecting surface impurities on a surface of a component by X-ray fluorescence analysis uses a hand spectroscope for application to the surface of a component. The hand spectroscope comprises an X-ray source, a fluorescent radiation detector, an analyzer and a display. The method comprises irradiating the surface of the component with X-rays using the X-ray source; detecting fluorescent radiation, which is emitted by the surface of the component as a result of the irradiation with the X-rays, using the fluorescent radiation detector; measuring a radiation spectrum of the detected fluorescent radiation; generating an evaluation result by analyzing the measured radiation spectrum using the analyzer, the evaluation result comprising a quantitative measure of the surface impurity of the surface due to predetermined characteristic substances; and outputting the generated evaluation result on the display.

A method of making X-ray fluorescence, XRF, measurements of a layered sample is described. At least two measurements are made, one through one surface of the sample and another through the opposite surface. This may be conveniently done by inverting the sample between the measurements. The data from the additional measurements may be used to calculate multiple parameters of the sample, such as the concentration, density or thickness of each of the layers.

A spectroscopy method and system, the method comprising irradiating an object with a laser-accelerated particle beam and detecting photons emitted by the object as a result of the interaction between the laser-accelerated particle beam and the object. The system comprises a laser; a particle source, positioned at a distance from the object; and a spectrometer and a detector; wherein the particle source generates a laser-accelerated particle beam under irradiation by the laser; and the spectrometer and the detector detect photons emitted from the object under irradiation by the laser-accelerated particle beam.

A method of manufacturing a test component and a method of testing a test component for non-destructive testing (NDT) together with a method of validating an NDT process for a component manufactured by an additive manufacturing (AM) process are disclosed. The validation method includes the steps of forming a first test specimen by the AM process, the test specimen containing one or more defects of a specified type and size, confirming both by destructive testing and by a first NDT step the type and size of the defects, forming the component by the said AM process with an aperture to receive the test specimen, forming a second test specimen by the same AM process which contains defects of the same type and size, inserting into the aperture the second test specimen, arranging the performance of a second NDT step on the component for defects, and comparing the results of the first and second NDT steps to validate the method.

The present disclosure relates to a method for detecting a fibre misalignment in an elongated structure, such as a wind turbine blade component. The elongated structure has a length along a longitudinal direction and comprises a plurality of stacked reinforcing fibre layers. The plurality of fibre layers comprises fibres having an orientation aligned, unidirectionally, substantially in the longitudinal direction. The method comprises scanning a surface of the elongated structure for identifying one or more surface irregularities, selecting one or more regions of interest comprising said one or more surface irregularities, examining said region of interest using penetrating radiation, and determining a position and/or size of the fibre misalignment based on said examining step.

An X-ray inspection system is presented. The X-ray inspection system comprises an X-ray source, an X-ray scintillator, a light detector, a first objective lens, and a second objective lens. The first objective lens is positioned between the X-ray scintillator and the light detector. The second objective lens is positioned between the first objective lens and the light detector.

This X-ray phase imaging apparatus is provided with a control unit that acquires information on a defect of a material based on a dark field image of the material.

A method and system for inspection of an item, and a use thereof, are presented. The method comprises acquiring a plurality of projection images of an item at a plurality of projection angles for performing a tomographic reconstruction of the item. A plurality of objects are detected in the tomographic reconstruction and each object has a generic shape described by a parametric three-dimensional numerical model. Said detection comprises determining initial estimates of position and/or orientation of each object and at least one geometrical parameter of the three-dimensional model for each object. The initial estimates are iteratively refining by using a projection-matching approach, in which forward projection images are simulated for the objects according to operating parameters of the radiation imaging device and a difference metric between acquired projection images and simulated forward projection images is reduced at each iteration step.