GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Fiseni, Alexander
Breidenbach, Christof
Abrégé
A method of forming a probe holder includes forming a plurality of layers from at least one body material, wherein adjacent ones of the plurality of layers are bonded to one another to define a body of an ultrasonic probe holder. The body can include a distal end, a chamber, and a fluid channel. The distal end can secure the body to a proximal end of a wear sole. The chamber can be configured to receive an ultrasonic probe and a volume of fluid couplant. A fluid channel extends through a portion of the body to the distal end and the fluid channel can receive a flow of fluid couplant. The plurality of layers can define a first region including a first probe holder material exhibiting a first acoustic or structural property and a second region including a second probe holder material exhibiting a second acoustic or structural property.
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/28 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails pour établir le couplage acoustique
B33Y 80/00 - Produits obtenus par fabrication additive
B22F 10/12 - Formation d’un corps vert par photopolymérisation, p.ex. stéréolithographie [SLA] ou traitement numérique de la lumière [DLP]
B22F 10/14 - Formation d’un corps vert par projection de liant sur un lit de poudre
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Neuser, Eberhard
Sawatzky, Alex
Rothe, Nils
Suppes, Alexander
Abrégé
Systems and methods for non-destructive testing by computed tomography are provided. The system can include a stationary radiation source, a stage, and a plurality of stationary radiation detectors. The source can be configured to emit, from a focal point, a beam of penetrating radiation having a three-dimensional geometry and to direct the beam in a path incident upon a target. The stationary radiation source can be positioned with respect to the plurality of stationary radiation detectors and the stage such that, a first plurality of beam segment paths is defined between the focal point and respective sensing faces of the plurality of radiation detectors and at least one second beam segment path is defined between the focal point and a predetermined gap.
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Suppes, Alexander
Rothe, Nils
Abrégé
Scatter correction for tomography: for each position, two images are acquired, a first image without and a second image with a scatter reducing aperture plate (50). A scatter image is calculated by subtracting the second image from the first image. The apertures (48) in the scatter reducing plate (50) are arranged hexagonally in order to optimise the packaging density of the apertures.
G01N 23/04 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux
A61B 6/00 - Appareils pour diagnostic par radiations, p.ex. combinés avec un équipement de thérapie par radiations
G21K 1/02 - Dispositions pour manipuler des particules ou des rayonnements ionisants, p.ex. pour focaliser ou pour modérer utilisant des diaphragmes, des collimateurs
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
4.
Fast industrial computed tomography for large objects
GE SENSING & INSPECTION TECHNOLOGIES, GMBH (Allemagne)
Inventeur(s)
Neuser, Eberhard
Sawatzky, Alex
Rothe, Nils
Suppes, Alexander
Abrégé
Systems and methods for non-destructive testing by computed tomography are provided. The system can include a stationary radiation source, a stage, and a plurality of stationary radiation detectors. The source can be configured to emit, from a focal point, a beam of penetrating radiation having a three-dimensional geometry and to direct the beam in a path incident upon a target. The stationary radiation source can be positioned with respect to the plurality of stationary radiation detectors and the stage such that, a first plurality of beam segment paths is defined between the focal point and respective sensing faces of the plurality of radiation detectors and at least one second beam segment path is defined between the focal point and a predetermined gap.
A61B 6/00 - Appareils pour diagnostic par radiations, p.ex. combinés avec un équipement de thérapie par radiations
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
GE SENSING & INSPECTION TECHNOLOGIES, GMBH (Allemagne)
Inventeur(s)
Ratering, Ralf
Abrégé
Systems, methods, and computer readable mediums are provided for selecting a precise value within a large value range. Data received from an ultrasonic testing environment can include a range of values associated with one or more parameters to be configured for performing ultrasonic inspection of a test object. A control in a user interface of the ultrasonic testing environment can be provided and include a display portion displaying one or more parameters and one or more values within the range of values associated with the one or more parameters. The control also includes an interactive portion configured to receive a plurality of inputs. Based on the inputs a selected value associated with a first parameter can be determined. The selected value associated with the first parameter can be output as a static display within the display portion of the control.
G06F 3/048 - Techniques d’interaction fondées sur les interfaces utilisateur graphiques [GUI]
G06F 3/0481 - Techniques d’interaction fondées sur les interfaces utilisateur graphiques [GUI] fondées sur des propriétés spécifiques de l’objet d’interaction affiché ou sur un environnement basé sur les métaphores, p.ex. interaction avec des éléments du bureau telles les fenêtres ou les icônes, ou avec l’aide d’un curseur changeant de comport
G06F 3/01 - Dispositions d'entrée ou dispositions d'entrée et de sortie combinées pour l'interaction entre l'utilisateur et le calculateur
G01N 29/06 - Visualisation de l'intérieur, p.ex. microscopie acoustique
G06F 3/0488 - Techniques d’interaction fondées sur les interfaces utilisateur graphiques [GUI] utilisant des caractéristiques spécifiques fournies par le périphérique d’entrée, p.ex. des fonctions commandées par la rotation d’une souris à deux capteurs, ou par la nature du périphérique d’entrée, p.ex. des gestes en fonction de la pression exer utilisant un écran tactile ou une tablette numérique, p.ex. entrée de commandes par des tracés gestuels
G06F 3/0484 - Techniques d’interaction fondées sur les interfaces utilisateur graphiques [GUI] pour la commande de fonctions ou d’opérations spécifiques, p.ex. sélection ou transformation d’un objet, d’une image ou d’un élément de texte affiché, détermination d’une valeur de paramètre ou sélection d’une plage de valeurs
6.
Wear sole for ultrasonic inspection and method of manufacture
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Fiseni, Alexander
Breidenbach, Christof
Kahmann, Frank
Abrégé
A method for forming a wear sole includes forming a plurality of layers from a frame material, adjacent layers bonded to one another to define a frame. The frame can include a proximal surface configured to secure the frame to a probe holder, a distal surface configured to contact a portion of a target, a body extending between proximal and distal surfaces, an aperture extending through proximal and distal surfaces and the body, and a channel extending from the proximal surface to a chamber in fluid communication with the distal surface. The method can optionally include placing a membrane within the aperture. The membrane can be coupled to the body by a seal, inhibiting passage of a fluid through the proximal surface via the aperture. The chamber can extend within the body between a distal surface of the membrane and the distal surface of the frame.
G01N 29/28 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails pour établir le couplage acoustique
G01N 29/26 - Dispositions pour l'orientation ou le balayage
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
7.
Method for the non-destructive testing of the volume of a test object and testing device configured for carrying out such a method
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Stuke, Ingo
Abrégé
A method for the non-destructive testing of the volume of a test object, during the course of which a volume raw image of the test object is recorded by a suitable non-destructive imaging testing method. Then, those regions of the volume raw image are identified that are not to be attributed to the test object material. It is checked whether an identified region is completely embedded in regions that are to be associated with the test object material. If necessary, such a region is assimilated to those regions that are to be associated with the test object material, forming a filled volume raw image. Finally, a difference is generated between the volume raw image and the filled volume raw image, forming a first flaw image.
G06T 7/33 - Détermination des paramètres de transformation pour l'alignement des images, c. à d. recalage des images utilisant des procédés basés sur les caractéristiques
G01B 7/00 - Dispositions pour la mesure caractérisées par l'utilisation de techniques électriques ou magnétiques
G01B 15/00 - Dispositions pour la mesure caractérisées par l'utilisation d'ondes électromagnétiques ou de radiations de particules, p.ex. par l'utilisation de micro-ondes, de rayons X, de rayons gamma ou d'électrons
G01B 17/00 - Dispositions pour la mesure caractérisées par l'utilisation de vibrations infrasonores, sonores ou ultrasonores
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
G01N 27/90 - Recherche ou analyse des matériaux par l'emploi de moyens électriques, électrochimiques ou magnétiques en recherchant des variables magnétiques pour rechercher la présence des criques en utilisant les courants de Foucault
G01N 29/06 - Visualisation de l'intérieur, p.ex. microscopie acoustique
G06K 9/62 - Méthodes ou dispositions pour la reconnaissance utilisant des moyens électroniques
G06T 5/50 - Amélioration ou restauration d'image en utilisant plusieurs images, p.ex. moyenne, soustraction
8.
Condition monitoring of ultrasonic transducers and probes
GE SENSING & INSPECTION TECHNOLOGIES, GMBH (Allemagne)
Inventeur(s)
Fiseni, Alexander
Schmitz, Stephan
Breidenbach, Christof
Falter, Stephan
Koers, Daniel
Parusel, Marek
Rohpeter, Lars
Runte, Sven
Standop, Sebastian
Abrégé
Systems and methods for monitoring the condition of ultrasonic transducers and ultrasonic probes used in non-destructive testing are provided. In one aspect, a degree of deterioration and end of life of an ultrasonic transducer can be estimated based upon measured environmental and/or operating parameters of the ultrasonic transducer. In another aspect, testing parameters acquired by a single ultrasonic probe or different ultrasonic probes can be measured and analyzed to identify deterioration of an ultrasonic probe.
G01N 29/30 - Dispositions pour l'étalonnage ou la comparaison, p.ex. avec des objets standard
G01N 27/02 - Recherche ou analyse des matériaux par l'emploi de moyens électriques, électrochimiques ou magnétiques en recherchant l'impédance
G01N 29/265 - Dispositions pour l'orientation ou le balayage en déplaçant le capteur par rapport à un matériau fixe
G01N 29/28 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails pour établir le couplage acoustique
G01N 29/34 - Génération des ondes ultrasonores, sonores ou infrasonores
G01N 29/44 - Traitement du signal de réponse détecté
9.
Wobble compensation for computed tomography applications
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Wuestenbecker, Michael
Abrégé
Systems, methods, and devices for determining relative and absolute positions and orientations of a detector and an inspection part of a CT system. In some cases positions/orientations of the detector and the inspection part can be defined, at least in part, by tilt angles relative to reference axes and/or planes defined by various combinations of the reference axes. In some embodiments, sensors coupled to the detector and to a stage assembly having the inspection part coupled thereto can be used to determine the tilt angles of the inspection part and the detector, respectively. Data from the sensors characterizing tilt angles of the detector and the inspection part can be used to adjust projectional radiographs of the inspection part to correct for the mechanical wobble of the stage. By using tilt data to adjust projectional radiographs, the quality of tomographic images and 3-dimensional reconstructions of the inspection part can be improved.
G01K 9/00 - Mesure de la température basée sur les mouvements provoqués par une redistribution de poids, p.ex. thermomètre basculant
G01B 15/06 - Dispositions pour la mesure caractérisées par l'utilisation d'ondes électromagnétiques ou de radiations de particules, p.ex. par l'utilisation de micro-ondes, de rayons X, de rayons gamma ou d'électrons pour mesurer la déformation dans un solide
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
G01T 1/29 - Mesure effectuée sur des faisceaux de radiations, p.ex. sur la position ou la section du faisceau; Mesure de la distribution spatiale de radiations
10.
Ultrasonic-pulse-echo flaw inspection at a high testing speed on thin-walled pipes in particular
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Prause, Reinhard
Dick, Wolfgang
Abrégé
Embodiments relate to a method for ultrasonic testing according to the pulse-echo method as well as an arrangement for performing such a method. By means of an ultrasonic transducer, an ultrasonic pulse is obliquely incident into a sound incidence surface of a test object. Next, an echo signal is received from the test object. This takes place either by means of the ultrasonic transducer, which has emitted the ultrasonic pulse or with another ultrasonic transducer. The time amplitude characteristic of the echo signal is evaluated in a predefined defect expectation interval of time. The evaluation step includes, in at least one section of the amplitude characteristic, an amplification of the amplitude and/or a reduction in the threshold value. For example, the amplitude of the received echo signal is then compared with the predefined threshold value.
G01N 29/11 - Analyse de solides en mesurant l'atténuation des ondes acoustiques
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Jobst, Matthias
Abrégé
A pattern recognizing ultrasonic testing system and methods for using the same are provided. The system can include an ultrasonic probe and an analyzer. The ultrasonic probe can be configured to acquire ultrasonic measurements from target, where the ultrasonic measurements can contain one or more ultrasonic patterns representing a target characteristic. The analyzer can be in communication with the ultrasonic probe. The analyzer can also be configured to receive the ultrasonic measurements, receive a first classifier configured to identify a predetermined target characteristic based upon one or more predetermined first ultrasonic patterns, examine the received ultrasonic measurements using the first classifier, and identify ultrasonic patterns of the received ultrasonic measurements that correspond to the predetermined ultrasonic patterns as representing the predetermined target characteristic. With pattern recognition, it can be possible to not only identify but distinguish between different target characteristics contained within the received ultrasonic measurements.
G06K 9/00 - Méthodes ou dispositions pour la lecture ou la reconnaissance de caractères imprimés ou écrits ou pour la reconnaissance de formes, p.ex. d'empreintes digitales
12.
Method and device for the near surface, nondestructive inspection by means of ultrasound of a rotationally symmetric workpiece having a diameter that changes from section to section
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Chinta, Prashanth Kumar
Abrégé
A method and a device for the near-surface, non-destructive inspection by means of ultrasound of a rotationally symmetric workpiece having a diameter that changes from section to section are provided. The method and device are based on the insonification of an ultrasonic test pulse into the workpiece at a defined insonification angle and the subsequent recording of an ultrasonic echo signal from the workpiece. Echo signals that trace back to a near-surface region ROI of the workpiece are identified and evaluated. Then, a graphic representation of the surface of the workpiece is generated.
G01N 29/06 - Visualisation de l'intérieur, p.ex. microscopie acoustique
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/38 - Détection du signal de réponse par filtrage temporel, p.ex. en utilisant des fenêtres temporelles
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Pfortje, René
Hoemske, Benjamin
Breidenback, Christof
Fiseni, Alexander
Falter, Stephan
Abrégé
A wear sole, an ultrasonic inspection apparatus having a wear sole, and methods for using the same are provided. In one embodiment, the ultrasonic inspection apparatus can include a body, a wear sole, and a fluid channel. The body can define a first chamber configured to receive a first volume of ultrasonic couplant and a distal end of an ultrasonic probe. The wear sole can define a second chamber configured to receive a second volume of ultrasonic couplant and the wear sole can be removably coupled to a distal end of the body. The wear sole can also have a membrane extending thereacross for separating the first chamber from the second chamber. The fluid channel can extend through the body and the wear sole can be configured to deliver the second volume of ultrasonic couplant to the second chamber.
G01N 29/28 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails pour établir le couplage acoustique
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Suppes, Alexander
Rothe, Nils
Abrégé
A method for imaging an object is presented. The method includes acquiring a first projection image of the object using a source and a detector, positioning a scatter rejecting aperture plate between the object and the detector, and acquiring a second projection image of the object with the scatter rejecting aperture plate disposed between the object and the detector. A scatter image of the object is generated based on the first projection image and the second projection image, and stored for subsequent imaging. A volumetric CT system for imaging an object is also presented. The system is configured to acquire a plurality of projection images of the object from a plurality of plurality of projection angles.
A61B 6/00 - Appareils pour diagnostic par radiations, p.ex. combinés avec un équipement de thérapie par radiations
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
G21K 1/02 - Dispositions pour manipuler des particules ou des rayonnements ionisants, p.ex. pour focaliser ou pour modérer utilisant des diaphragmes, des collimateurs
15.
Method for detecting flaw in train wheel with single ultrasonic pulse and testing device therefor
GE Sensing & Inspection Technologies, GmbH (Allemagne)
Inventeur(s)
Falter, Stephan
Scaccabarozzi, Luca
Abrégé
The invention relates to a method for testing of a train wheel by ultrasound. The method is based on a pulsed ultrasonic field in the train wheel to be tested by an array of individually controllable ultrasonic transmitting transducers acoustically coupled to the train wheel each controlled with a specific analog transient excitation signal. Each analog transient excitation signal generated based on an ultrasonic transmitting transducer-specific stored digital transient excitation function. The resulting echo signals from the train wheel to be tested are recorded by an array of individually controllable ultrasonic receiving transducers. Each ultrasonic receiving transducer can provide an analog, time-resolved echo signal. The received echo signals can be digitized in a transducer-specific way and stored in a set. A plurality of different reception processing rules can then be applied to the latter. Furthermore, the invention relates to a device for carrying out the method.
G01N 29/27 - Dispositions pour l'orientation ou le balayage en déplaçant le matériau par rapport à un capteur fixe
G01S 15/89 - Systèmes sonar, spécialement adaptés à des applications spécifiques pour la cartographie ou la représentation
G10K 11/34 - Procédés ou dispositifs pour transmettre, conduire ou diriger le son pour focaliser ou pour diriger le son, p.ex. balayage par commande électrique de systèmes de transducteurs, p.ex. en dirigeant un faisceau acoustique
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Stuke, Ingo
Abrégé
A method for the non-destructive testing of the volume of a test object, during the course of which a volume raw image of the test object is recorded by a suitable non-destructive imaging testing method. Then, those regions of the volume raw image are identified that are not to be attributed to the test object material. It is checked whether an identified region is completely embedded in regions that are to be associated with the test object material. If necessary, such a region is assimilated to those regions that are to be associated with the test object material, forming a filled volume raw image. Finally, a difference is generated between the volume raw image and the filled volume raw image, forming a first flaw image.
G06T 7/33 - Détermination des paramètres de transformation pour l'alignement des images, c. à d. recalage des images utilisant des procédés basés sur les caractéristiques
G01B 7/00 - Dispositions pour la mesure caractérisées par l'utilisation de techniques électriques ou magnétiques
G01B 15/00 - Dispositions pour la mesure caractérisées par l'utilisation d'ondes électromagnétiques ou de radiations de particules, p.ex. par l'utilisation de micro-ondes, de rayons X, de rayons gamma ou d'électrons
G01B 17/00 - Dispositions pour la mesure caractérisées par l'utilisation de vibrations infrasonores, sonores ou ultrasonores
G01N 23/046 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux en utilisant la tomographie, p.ex. la tomographie informatisée
G01N 27/90 - Recherche ou analyse des matériaux par l'emploi de moyens électriques, électrochimiques ou magnétiques en recherchant des variables magnétiques pour rechercher la présence des criques en utilisant les courants de Foucault
G01N 29/06 - Visualisation de l'intérieur, p.ex. microscopie acoustique
G06K 9/62 - Méthodes ou dispositions pour la reconnaissance utilisant des moyens électroniques
G06T 5/50 - Amélioration ou restauration d'image en utilisant plusieurs images, p.ex. moyenne, soustraction
17.
Device for the non-destructive ultrasound testing of workpieces with improved handling and method
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Ratering, Ralf
Abrégé
The present embodiments relate to a device for the non-destructive ultrasound testing of workpieces. The device comprises an ultrasonic test probe with an ultrasonic transducer, the ultrasonic test probe being configured for generating and coupling ultrasonic signals into a workpiece or/and for receiving ultrasonic signals from the workpiece. Furthermore, an electronic control unit is provided. The ease of operation is improved as a whole by a special configuration of the test probe and the control unit. Furthermore, the embodiments relate to a method for the non-destructive ultrasound testing of workpieces.
G01N 29/26 - Dispositions pour l'orientation ou le balayage
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
18.
Ultrasonic-pulse-echo flaw inspection at a high testing speed on thin-walled pipes in particular
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Prause, Reinhard
Dick, Wolfgang
Abrégé
Embodiments relate to a method for ultrasonic testing according to the pulse-echo method as well as an arrangement for performing such a method. By means of an ultrasonic transducer, an ultrasonic pulse is obliquely incident into a sound incidence surface of a test object. Next, an echo signal is received from the test object. This takes place either by means of the ultrasonic transducer, which has emitted the ultrasonic pulse or with another ultrasonic transducer. The time amplitude characteristic of the echo signal is evaluated in a predefined defect expectation interval of time. The evaluation step includes, in at least one section of the amplitude characteristic, an amplification of the amplitude and/or a reduction in the threshold value. For example, the amplitude of the received echo signal is then compared with the predefined threshold value.
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/40 - Détection du signal de réponse par filtrage en amplitude, p.ex. par application d'un seuil
Method and device for the reduction of flashover-related transient electrical signals between the acceleration section of an X-ray tube and a high-voltage source
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Friedemann, Reinhard
Schmitt, Andreas
Aslami, Farid
Goellner, Florian
Abrégé
A high-voltage resistant cable for connecting a high-voltage source and an acceleration section of an X-ray tube that each have a respective socket and a flange. The cable includes an inner conductor, a surrounding electrical insulator, an enveloping shielding made of an electrically conductive material, and plugs at each respective end. Each plug includes a plug flange for cooperating with the respective flange and having a hollow interior, and an electrical insulator that includes a conic-shape portion for extending into the respective socket, and a cylindrical portion extending within the hollow interior of the plug flange. The cable including absorber elements at each of the two ends of the cable for absorbing the energy of high-voltage discharge-related transients. Each absorber element is configured as a ring-shape, the ring-shape absorber element encircling the cylindrical portion and being located within the hollow interior of the plug flange.
GE Sensing & Inspection Technologies GMBH (Allemagne)
Inventeur(s)
Wuestenbecker, Michael
Abrégé
A system for the automated serial testing and/or measuring of a plurality of substantially identical components by X-radiation, the system comprising a testing device with a support, a rotor mounted so as to be continuously rotatable on the support, and an X-ray device disposed on the rotor, a protective enclosure surrounding the testing device, a handling device for handling a component during X-ray testing, and a control/evaluation unit configured for automatically controlling the system as well as evaluating the X-ray signals by computer tomography. The handling device is configured for periodically reciprocating between a loading region and a testing region and comprises an end face element on which the component can be disposed on the side of the end face.
G01N 23/04 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux
G01N 23/18 - Recherche de la présence de défauts ou de matériaux étrangers
G01N 1/00 - Echantillonnage; Préparation des éprouvettes pour la recherche
21.
Method and device for the near surface, nondestructive inspection by means of ultrasound of a rotationally symmetric workpiece having a diameter that changes from section to section
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Chinta, Prashanth Kumar
Abrégé
A method and a device for the near-surface, non-destructive inspection by means of ultrasound of a rotationally symmetric workpiece having a diameter that changes from section to section are provided. The method and device are based on the insonification of an ultrasonic test pulse into the workpiece at a defined insonification angle and the subsequent recording of an ultrasonic echo signal from the workpiece. Echo signals that trace back to a near-surface region ROI of the workpiece are identified and evaluated. Then, a graphic representation of the surface of the workpiece is generated.
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/00 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Lingenberg, Dieter
Abrégé
A method and a device for the non-destructive inspection of a rotationally symmetric workpiece having sections with different diameters by a non-destructive inspection technique, such as ultrasound, are provided. Within the context of the method, a test data set characterizing the material properties of the workpiece is generated by the inspection technique. An azimuth angle-dependent indicated value set is generated therefrom. Subsequently, a representation of the workpiece is generated, wherein the elements of the indicated value set are depicted in the representation in a spatially resolved manner. In particular, a graphic representation of the surface of the workpiece can be generated in which flaw signals are displayed that may have been found.
G01N 29/00 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/38 - Détection du signal de réponse par filtrage temporel, p.ex. en utilisant des fenêtres temporelles
G01N 23/18 - Recherche de la présence de défauts ou de matériaux étrangers
G01N 29/06 - Visualisation de l'intérieur, p.ex. microscopie acoustique
G01N 29/44 - Traitement du signal de réponse détecté
G01N 27/90 - Recherche ou analyse des matériaux par l'emploi de moyens électriques, électrochimiques ou magnétiques en recherchant des variables magnétiques pour rechercher la présence des criques en utilisant les courants de Foucault
23.
Computed tomography method, computer software, computing device and computed tomography system for determining a volumetric representation of a sample
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Neuser, Eberhard
Suppes, Alexander
Rothe, Nils
Hoetter, Michael
Frost, Anja
Abrégé
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.
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Suppes, Alexander
Pokutnev, Pavel
Neuser, Eberhard
Rothe, Nils
Abrégé
A method and system for determining geometric imaging properties of a flat panel detector in an x-ray inspection system are described herein. The method can include arranging a calibration phantom between an x-ray source and the flat panel detector, the calibration phantom including at least one discrete geometric object. Additionally, the method can include recording at least one x-ray image of the calibration phantom with the flat panel detector. At least one discrete geometric shape is generated in the x-ray image by imaging the at least one discrete geometric object of the calibration phantom. Further, the method can include determining a location-dependent distortion error of the flat panel detector from the at least one x-ray image on the basis of at least one characteristic of the at least one discrete geometric shape. All characteristics of the at least one discrete geometric shape used for determining the location-dependent distortion error are independent of the dimensions of the calibration phantom.
G01N 23/04 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux
G01T 7/00 - MESURE DES RADIATIONS NUCLÉAIRES OU DES RAYONS X - Détails des instruments de mesure des radiations
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Neuser, Eberhard
Schmitt, Andreas
Sperner, Wolfgang Johannes
Abrégé
An apparatus is provided for a micro focus X-ray tube for a high-resolution X-ray including a housing, an electron beam source for generating an electron beam and a focusing lens for focusing the electron beam on a target. The micro focus X-ray tube includes a substantially rotationally symmetrical, ring-shaped cooling chamber configured to circulate a liquid cooling medium.
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Neuser, Eberhard
Suppes, Alexander
Rothe, Nils
Hötter, Michael
Frost, Anja
Abrégé
A computed tomography method for determining a volumetric representation of a sample comprising reconstruction initial volume data of the sample from x-ray projections of the sample taken by an x-ray system, determining a part of the reconstructed initial volume data to be updated, and executing an iterative update process configured to generate, using an iterative reconstruction method, updated volume data only for the part of the volume data determined to be updated. Determining the part of the sample volume to be updated comprises individually evaluating every single voxel in the reconstructed initial volume data, based on available quality information for the reconstructed initial volume data, whether or not the voxel fulfils a predetermined condition indicating that an update is required for the voxel, and the iterative update process generates the updated volume data only for the voxels which have been determined that an update is required.
G06K 9/00 - Méthodes ou dispositions pour la lecture ou la reconnaissance de caractères imprimés ou écrits ou pour la reconnaissance de formes, p.ex. d'empreintes digitales
G06F 19/00 - Équipement ou méthodes de traitement de données ou de calcul numérique, spécialement adaptés à des applications spécifiques (spécialement adaptés à des fonctions spécifiques G06F 17/00;systèmes ou méthodes de traitement de données spécialement adaptés à des fins administratives, commerciales, financières, de gestion, de surveillance ou de prévision G06Q;informatique médicale G16H)
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Cadera, Tom
28.
Method for the non-destructive inspection of a test object of great material thickness by means of ultrasound, the use of a test probe for carrying out the method, an ultrasonic test probe, a control unit for an ultrasonic test probe and a device for the non-destructive inspection of a test object of great material thickness by means of ultrasound
GE Sensing & Inspection Technologies GMBH (Allemagne)
Inventeur(s)
Oberdoerfer, York
Abrégé
Method and apparatus for the non-destructive inspection of a test object with a large material thickness by means of ultrasound. The apparatus includes an ultrasonic test probe with an ultrasonic transducer divided into a plurality of individually activatable transducer segments wherein the transducer segments are concentric circles or rings, or sections thereof. A first group j (j=1, 2, 3, . . . ) of transducer segments is selected in such a way that a parallel activation of these transducer segments results in a circular active surface Fj of the ultrasonic transducer (22). An ultrasound inspection of the test object is undertaken with the first group j (j=1, 2, 3, . . . ) of transducer segments, wherein they are activated in parallel.
G01N 29/00 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet
G01N 29/34 - Génération des ondes ultrasonores, sonores ou infrasonores
G01N 29/26 - Dispositions pour l'orientation ou le balayage
G01N 29/44 - Traitement du signal de réponse détecté
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01S 15/89 - Systèmes sonar, spécialement adaptés à des applications spécifiques pour la cartographie ou la représentation
29.
Multi-part mounting device for an ultrasonic transducer
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Oberdoerfer, York
Duerscheid, Judith
Zilz, Jochen
Warkowski, Willi
Parusel, Marek
Abrégé
A multi-part mounting device for an ultrasonic transducer, the mounting device comprising a first part configured to mount the mounting device on a housing of an ultrasonic test probe, and a second part configured to retain the ultrasonic transducer, wherein the second part is at least in touching contact with the ultrasonic transducer, wherein the second part comprises a first plastic and is connected by positive fit to the first part, and wherein the first part has a greater hardness than the second part.
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/26 - Dispositions pour l'orientation ou le balayage
G01N 29/27 - Dispositions pour l'orientation ou le balayage en déplaçant le matériau par rapport à un capteur fixe
G10K 11/00 - Procédés ou dispositifs pour transmettre, conduire ou diriger le son en général; Procédés ou dispositifs de protection contre le bruit ou les autres ondes acoustiques ou pour amortir ceux-ci, en général
30.
Coupling medium supply of an ultrasonic test device
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Prause, Reinhard
Breidenbach, Christof
Abrégé
An ultrasonic testing method is provided. The ultrasonic method includes non-destructively testing a test object with an ultrasound generated by an ultrasound probe, continuously circulating a liquid coupling medium outside of the test probe before and/or during non-destructively testing the test object, branching a part of the liquid coupling medium off from the circulation, and feeding the branched liquid coupling medium to a coupling chamber arranged between the ultrasound probe and the test object.
G01N 29/27 - Dispositions pour l'orientation ou le balayage en déplaçant le matériau par rapport à un capteur fixe
G01N 29/28 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails pour établir le couplage acoustique
G01N 29/265 - Dispositions pour l'orientation ou le balayage en déplaçant le capteur par rapport à un matériau fixe
31.
Test probe as well as family of test probes for the non-destructive testing of a workpiece by means of ultrasonic sound and testing device
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Kleinert, Wolf-Dietrich
Splitt, Gerhard
Abrégé
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. The test probe or the family of test probes and the testing device are suitable in particular for the angular intromission of sound or for a utilization on curved workpiece surface areas.
GE SENSING & INSPECTION TECHNOLOGIES GMBH (Allemagne)
Inventeur(s)
Stuke, Ingo
Guenzler, Til Florian
Wuestenbecker, Michael
Kraemer, Jan
Lux, Holger
Bretzke, Nicolas
Abrégé
An apparatus for materials testing of test objects using X-rays, the apparatus comprising an X-ray device, comprising: an X-ray source for irradiating a test object held in a test position; an X-ray linear diode array detector comprising at least two detection sections and configured to acquire a complete radial cross-section of the test object; and an electronic control device configured to control the X-ray device, wherein during X-ray testing the test object and the X-ray device are rotatable relative to each other only around an essentially vertical axis of rotation.
G01N 23/04 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et formant des images des matériaux
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
De Odorico, Walter
Koch, Roman
Abrégé
A device and a method for ultrasonic testing by means of a local immersion technique of a stringer component section of a flat component are provided. The device includes a test head assembly mounted as moving floatingly by a holding device in the Y-direction longitudinally. The test head assembly includes: a test head that can be connected to an automatically actuated handling device and that can be moved by the handling device along the stringer; a test head holder; and a counter-holder coupled with the test head holder by an actuation element, wherein the actuation element is configured to steer the test head holder and the counter-holder from a closed position to an open position, the test head holder and the counter-holder being mounted floatingly along a guiding rail running in the X-direction transversely to the stringer, and fit, in a force-loaded manner, to each side surface of the stringer.
G01N 29/22 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet - Détails
G01N 29/265 - Dispositions pour l'orientation ou le balayage en déplaçant le capteur par rapport à un matériau fixe
34.
Pulse-echo method by means of an array-type probe and temperature compensation
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Neuser, Eberhard
Suppes, Alexander
Rothe, Nils
Hoetter, Michael
Frost, Anja
Abrégé
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.
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Meinert, Damian
Prause, Reinhard
Vierhaus, Rainer
Abrégé
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.
G01N 29/00 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Meinert, Damian
Falter, Stephan
Lingenberg, Dieter
Prause, Reinhard
Vierhaus, Rainer
Abrégé
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 starting on the outer lateral surface of the workpiece, and then in a rising manner.
G01N 29/00 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet
38.
Method for the non-destructive testing of a test object by way of ultrasound and apparatus therefor
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Oberdörfer, York
Kleinert, Wolf-Dietrich
Abrégé
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 βcan be read off at least qualitatively.
G01N 29/00 - Recherche ou analyse des matériaux par l'emploi d'ondes ultrasonores, sonores ou infrasonores; Visualisation de l'intérieur d'objets par transmission d'ondes ultrasonores ou sonores à travers l'objet
39.
Method for the non-destructive testing of a test object by way of ultrasound and apparatus therefor
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Wuestenbecker, Michael
Stuke, Ingo
Abrégé
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.
G01N 23/083 - Recherche ou analyse des matériaux par l'utilisation de rayonnement [ondes ou particules], p.ex. rayons X ou neutrons, non couvertes par les groupes , ou en transmettant la radiation à travers le matériau et mesurant l'absorption le rayonnement consistant en rayons X
H05G 1/02 - Appareils à rayons X utilisant des tubes à rayons X; Circuits pour ces appareils - Détails de structure
GE Sensing & Inspection Technologies GmbH (Allemagne)
Inventeur(s)
Lingenberg, Dieter
Prause, Reinhard
Abrégé
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.