Abstract: The invention relates to a nondestructive ultrasonic test method in which at least one ultrasonic pulse is emitted into a workpiece under test by at least one ultrasonic transmitter (3), the ultrasonic pulse is reflected on boundary surfaces within the workpiece, the reflected ultrasound is received by at least one ultrasonic receiver (2), and the associated signals are evaluated, the ultrasound penetrating a damping block (4) that is arranged between the workpiece and the transmitter or receiver.

Abstract: The subject of the invention is a device for the nondestructive recording of a rotational movement, e.g. of a probe, on the surface of a specimen. In a developed configuration, a translational movement on the surface of the specimen can be detected. To this end, the device comprises a transmitter which is set up to transmit a temporal sequence of excitation signals Si, which penetrate into the specimen at least to some extent and interact with it. Furthermore, an array is provided, which is based on a plurality of receivers which are set up to receive echo signals, which result from the interaction of the excitation signals Si, transmitted by the transmitter, with the specimen. The echo signals for an excitation signal Si which are absorbed by the receivers form a set M (Si) of measurement values.

Abstract: A method of using computed tomography for determining a volumetric representation of a sample, involving a first reconstruction for reconstructing first reconstructed volume data of the sample from first x-ray projection data of the sample taken by an x-ray system, a second reconstruction for reconstructing second reconstructed volume data of the sample from second x-ray projection data of the sample taken by an x-ray system, characterized by calculating first individual confidence measures for single voxels of the first reconstructed volume data, calculating second individual confidence measures for single voxels of the second reconstructed volume data, and calculating, in a subsequent step, at least one resulting set of individual values for each voxel based on the first individual confidence measures and the second individual confidence measures.

Abstract: The invention relates to a nondestructive ultrasonic test method in which at least one ultrasonic pulse is emitted into a workpiece under test by means of at least one ultrasonic transmitter (3), the ultrasonic pulse is reflected on boundary surfaces within the workpiece, the reflected ultrasound is received by at least one ultrasonic receiver (2), and the associated signals are evaluated, the ultrasound penetrating a damping block (4) that is arranged between the workpiece and the transmitter or receiver.

Abstract: The non-destructive testing of a test object by way of ultrasound includes: (a) radiating directed ultrasonic pulses into the test object at an irradiation angle ? wherein the irradiation angle ? is set electronically, (b) recording echo signals that result from the ultrasonic pulses radiated into the test object, and (c) determining an irradiation position X0 in which echo signals can be recorded that can be associated with an error in the volume of the test object. The method also includes (d) determining the irradiation angle ?max for which the ERS value of the error reaches its maximum at position X0, (e) changing the irradiation position X0?X1 on the surface of the test object, the change of the irradiation position being captured, and (f) electronically adjusting the irradiation angle ? in such a manner that the ERS value of the error reaches its maximum in the changed irradiation position X1.

Abstract: The invention relates to an ultrasound inspection device for the inspection of tubular workpieces, where the ultrasound inspection device can be coupled to the workpiece by means of a fluid medium, so that sound emitted from a transducer unit hits an insonification point on the lateral surface of the workpiece, the workpiece and the ultrasound inspection device can be moved relative to each other, and where the transducer unit is pivotable on a pivoting line which corresponds to an arc of a circle whose center is formed by the insonification point.

Abstract: A high-voltage connector component for a high-voltage cable comprises an insulator made of a polymer material which surrounds a cable end portion of the high-voltage cable, wherein the insulator is received in a housing and is made of an elastomer material, wherein the elastomer material is filled, cast or injected into the housing in order to form the insulator. The connector component is designed such that upon connection to a corresponding connector component a basically closed pressure chamber is formed between the housing, the corresponding connector component and the cable end portion, wherein the pressure chamber is basically provided for being completely occupied by the insulator.

Abstract: A planar probe for the coupling of ultrasonic signals to a planar component to be tested by means of water-free jet technology is provided. The planar probe includes: at least one preflow chamber; a flow chamber located downstream of at least one preflow chamber, wherein the flow chamber extends through a slot-shaped water outlet opening to a lower surface of the planar probe; a probe, wherein a lateral surface of the probe comprises emitting/receiving elements and forms an inner wall section of the flow chamber; a base body for the reception of the probe; and a sliding plate comprising the slot-shaped water outlet opening, whose planar extension along the component is larger than the planar extension of the base body along the component, wherein the planar probe is connected to the sliding plate.

Abstract: A computed tomography method for determining a volumetric representation of a sample comprises using reconstructed volume data of the sample from x-ray projections of the sample taken by an x-ray system, computing a set of artificial projections of said sample by a forward projection from said reconstructed volume data, and determining, essentially from process data of said reconstruction including said reconstructed volume data and/or said x-ray projections, individual confidence measures for single voxels of said volume data based on calculating, for each of said measured x-ray projections, the difference between the contribution of this measured x-ray projection to the voxel under inspection and the contribution from a corresponding artificial projection to the voxel under inspection.

Abstract: A method for the non-destructive testing of a test specimen by means of ultrasound and a corresponding device, the method including insonification of directed ultrasonic pulses into the test specimen 100 at an insonification angle ?, wherein the insonification angle ? is adjusted electronically, a. recording echo signals that result from the ultrasonic pulses insonified into the test specimen 100, b. calculation of an ERS value of a flaw 102 in the volume of the test specimen from echo signals that can be assigned to the flaw 102 for a plurality of insonification angles ?, and c. generation of a graphic representation of the flaw 102, from which the dependence of the calculated ERS values of the flaw on the insonification value ?can be read off at least qualitatively.

Abstract: The invention relates to an ultrasound inspection device for the inspection of tubular workpieces, where the ultrasound inspection device can be coupled to the workpiece by means of a fluid medium, the workpiece and the ultrasound inspection device can be moved relative to each other, a transducer unit substantially disposed in a cluster housing is provided, where the cluster housing includes a wear sole which is adapted to the respective diameter of the workpiece and which can be placed on an outer lateral surface of the workpiece and is configured such that a chamber forms between the workpiece and the transducer unit, at least one fluid inlet channel, which, with a fluid inlet opening, opens into the chamber, at least one fluid outlet channel for venting and draining the chamber, which opens into the chamber where the mouth of the fluid outlet channel and the fluid outlet channel are configured and disposed such that a filling process of the chamber and of the fluid outlet channel can be carried out starti

Abstract: A method for nondestructive testing of a test object by means of ultrasound, and a corresponding device, the method including radiating directed ultrasonic pulses into the test object 100 at an irradiation angle ?, whereby the irradiation angle ? is set electronically, recording of echo signals that result from the ultrasonic pulses radiated into the test object 100, determining an ERS value of an error 102 in the volume of the test object from echo signals, which can be associated with the error 102.

Abstract: The invention relates to a method for the non-destructive ultrasound inspection of a high-pressure line as a testing piece by means of the pulse-echo method, where the high-pressure line is conveyed to a near-field range of at least one ultrasonic transducer and an ultrasonic pulse is emitted with a perpendicular sound incidence on the high-pressure line in such a way that the high-pressure line is completely captured in its cross section by the near-field sound emission caused by the ultrasonic transducer, and the reflected ultrasonic pulse(s) is/are received by the ultrasonic transducer and/or, optionally, further ultrasonic transducers, the associated echo delay times are recorded and, optionally, evaluated.

Abstract: A cathode element for a microfocus x-ray tube includes a heatable filament formed of a wire for thermionic emission of electrons for generating an electron beam. The filament, in a source area of the electron beam, has an elongate extension in two directions perpendicular to the electron beam.

Abstract: A method and system for automated testing and/or measurement of a plurality of substantially identical components by means of X-ray radiation comprises a testing/measuring device with an X-ray device, a protection cabin surrounding the testing/measuring device, a conveying device for continuously conveying components to or away from the testing/measuring device, and a control/evaluation unit, which is set up for automated control of the system and for evaluation of the X-ray signals. The testing/measuring device comprises a support and a rotor mounted on the support so as to be continuously rotatable, the X-ray device being arranged on the rotor and the conveying device being set up for serial conveying of the components through the rotor and the control/evaluation unit for computer tomographic evaluation of the X-ray signals.

Abstract: An inspection apparatus can include an application guiding an inspector in the performance of an inspection. The application can be provided in such form as to be modified. In one embodiment, an application for guiding an inspector can be modified responsively to data collected by an inspection apparatus of an inspection system. In one embodiment an application for guiding an inspector can be modified responsively to data output by a data output device.

Abstract: A visual inspection apparatus can include a handset, elongated inspection tube extending from the handset and a light source bank disposed within a hand held housing of the handset. For reduction of heat energy radiating from the light source bank, the apparatus can include one or more of a thermal control system and a particularly designed heat sink assembly.

Abstract: The invention relates to a test probe 10 for the non-destructive testing of a workpiece by means of ultrasonic sound. The test probe has an ultrasonic transducer 20 for the generation of an ultrasonic field, which is coupled acoustically to a delay line body 12, which is provided to be attached for a coupling of the ultrasonic field into the workpiece on a surface of the workpiece. Furthermore, the invention relates to a family of test probes as well as to a testing device for the non-destructive testing of a workpiece by means of ultrasonic sound, with a test probe 10, whose ultrasonic transducer 20 has a majority of independently controllable individual oscillators. Furthermore, a control unit 50 is provided, which is equipped to control the individual oscillators of the ultrasonic transducer 20 with phase accuracy in such a way, that a sound field rotationally symmetrical to the central beam is generated.

Abstract: The invention relates to a method for the non-destructive testing of a test object (100) by way of ultrasound, said method comprising the following steps: (a) radiating directed ultrasonic pulses into the test object (100) at an irradiation angle ?, said irradiation angle ? being set electronically, (b) recording echo signals that result from the ultrasonic pulses radiated into the test object (100), (c) determining an irradiation position X0 in which echo signals can be recorded that can be associated with an error (102) in the volume of the test object, (d) determining the irradiation angle ?max for which the ERS value of the error (102) reaches its maximum at position X0, (e) changing the irradiation position X0?X1 on the surface of the test object (100), the change of the irradiation position being captured, (f) electronically adjusting the irradiation angle ? in such a manner that the ERS value of the error (102) reaches its maximum in the changed irradiation position X1.