Abstract: Provided is a radiation generating apparatus, including: a radiation generating unit for emitting radiation; and a movable diaphragm unit including a light projecting/sighting system for making a simulation display of a radiation field with visible light. The light projecting/sighting system includes: a light source of the visible light; a light guiding plate that is provided across a radiation axis, and causes the visible light from the light source to exit from a front surface of the light guiding plate; and a louver that gives directivity to the visible light exiting from the front surface of the light guiding plate.

Abstract: An arrangement for an X-ray image system with a grid frame arranged to enable the grid frame to oscillate is provided. The arrangement includes a switch unit, with which an anti-scatter grid inserted into the grid frame may be detected. An X-ray emission is only triggered by the switch unit at a predeterminable activation time if an anti-scatter grid is inserted.

Abstract: An X-ray imaging apparatus and an X-ray imaging method for use in the X-ray imaging apparatus are provided. The X-ray imaging apparatus includes a separating element configured to spatially separate an X-ray generated by an X-ray generator unit and a scintillator array including a plurality of first scintillators arranged therein, where the separated X-rays are made incident on the first scintillators. Each of the first scintillators is configured to vary an intensity of fluorescence induced by the X-ray in accordance with an incident position of the X-ray. The X-ray imaging apparatus further includes a detector configured to detect the intensity of fluorescence emitted from the scintillator array.

Abstract: A radiographic apparatus including an X-ray generating means which irradiates an object with X-rays, the apparatus comprises a first housing which includes an X-ray reception unit formed by a member having a higher X-ray transmittance than a frame member, a buffer material which is placed on the first housing and reduces a load on the X-ray generating means, an X-ray detection sensor which is placed on the buffer material and detects X-rays transmitted through the object, a support member whose support surface to support the X-ray detection sensor is placed on the X-ray detection sensor, and a second housing which includes a concave portion engaging with the convex portion formed on the support member and constrains movement of the support member.

Abstract: A radiation imaging apparatus includes an imaging unit and a handle unit detachably attached to the imaging unit. The imaging unit includes a digital radiation detector including a detection area, a housing incorporating the digital radiation detector, a power arranged on one side surface of the housing, and a display unit arranged on the one side surface and configured to indicate a state of the digital radiation detector. The handle unit includes a frame unit covering at least part of each of three side surfaces other than the one side surface of the housing and a grasping portion forming an opening between the handle unit and at least part of the one side surface, with the handle unit attached to the imaging unit.

Abstract: Disclosed is a radiographic apparatus including a detachable manipulation panel which includes a capturing device to generate X-rays and to irradiate the X-rays to a subject so as to capture the subject, a controller connected to the capturing device to control the capturing device, and a manipulation device mounted to the capturing device to allow an inspector to input commands to control the capturing device, wherein the manipulation device is detachably mounted to the capturing device and, in a state in which the manipulation device is separated from the capturing device, is connected to the controller using a wireless interface to control the capturing device.

Abstract: An x-ray tube includes a casing having a cathode and an anode enclosed therein, and a separator attached to an inner wall of the casing and having a conductance limiter therein, the separator positioned to separate the anode from the cathode.

Abstract: A multiplane medical imaging system is provided. The multiplane medical imaging system comprises a first X-ray machine and a second X-ray machine, each X-ray machine comprising an X-ray tube and an X-ray detector, wherein the first and second X-ray machines each comprise respective mobile automatic devices on which the respective X-ray tubes and the respective X-ray detectors are mounted in order to control the movement of the first and second X-ray machines.

Abstract: A radiation imaging apparatus is provided. The apparatus has moving means moving a pair of an X-ray tube and a detector relatively to an object. The apparatus further has means which acquire digital frame data outputted from the detector. The frame data are acquired from the same portion being imaged of the same object at different time points. The apparatus has means which use the frame data to produce a plurality of three-dimensional optimally focused images at the respective time points, an actual position and shape of the portion being imaged being reflected in the images, and means which estimate changes of the plural three-dimensional optimally focused images.

Abstract: An X-ray intensity correction method makes the background uniform by adjusting a raster element and an X-ray diffractometer. An X-ray intensity correction method for correcting the intensity of diffracted X-rays includes the steps of focusing X-rays on a sample for correction placed at a gonio center, entering fluorescent X-rays excited by the focused X-rays into a raster element formed by polycapillaries and having a unique focal point, detecting the fluorescent X-rays having passed through the raster element; and adjusting the arrangement of the raster element so that the fluorescent X-rays can uniformly be detected regardless of the detecting position. Since fluorescent X-rays are used, it is possible to adjust the position of the raster element because if the focal point of the raster element coincides with the gonio center, the intensity becomes uniform regardless of the detected position.

Abstract: X-ray devices for Phase Contrast Imaging (PCI) are often built up with the help of gratings. For large field-of-views (FOV), production cost and complexity of these gratings could increase significantly as they need to have a focused geometry. Instead of a pure PCI with a large FOV, this invention suggests to combine a traditional absorption X-ray-imaging system with large-FOV with an insertable low-cost PCI system with small-FOV, The invention supports the user to direct the PCI system with reduced FOV to a region that he regards as most interesting for performing a PCI scan thus eliminating X-ray dose exposure for scanning regions not interesting for a radiologist. The PCI scan may be generated on the basis of local tomography.

Abstract: The present invention provides a multi-view X-ray inspection system. In one embodiment, a beam steering mechanism directs the electron beam from an X-ray source to multiple production targets which generate X-rays for scanning which are subsequently detected by a plurality of detectors to produce multiple image slices (views). The system is adapted for use in CT systems. In one embodiment of a CT system, the X-ray source and detectors rotate around the object covering an angle sufficient for reconstructing a CT image and then reverse to rotate around the object in the opposite direction. The inspection system, in any configuration, can be deployed inside a vehicle for use as a mobile detection system.

Abstract: Radiation is directed at an object, and radiation scattered by the object is sensed. An angular distribution of scatter in the sensed scattered radiation relative to a path of the radiation directed at the object is determined, and the angular distribution is evaluated. One or more atomic numbers, or effective atomic numbers, of materials composing the object is determined based on evaluating the angular distribution.

Abstract: An apparatus and method are provided for measuring flow velocity of a multi-phase fluid mixture. The proposed apparatus includes a radiation device, a detection device, and an analysis device. The radiation device generates a beam of photons to irradiate the mixture spatially over a section of flow of the mixture. The detection device is spatially configured to receive photons emanating from the section of flow of the mixture at different intervals of time. The detection device provides an image of a spatial distribution of the received photons for each the interval of time. The analysis device determines flow velocity of one or more phases of the mixture based on a temporal sequence of the images of the spatial distributions of the received photons.

Abstract: A multiple-energy X-ray imaging apparatus and a method obtain a plurality of X-ray images when the heart of a patient is in the same phase by measuring the electrocardiogram of the patient. A sensor is installed on a handle or a foot stool to measure the electrocardiogram when the patient grips the handle or makes contact with the foot stool without having to attach an electrode to the body of the patient, which removes the inconvenience in measuring the electrocardiogram.

Abstract: A circuit arrangement is disclosed for a detector. In at least one embodiment, the circuit arrangement includes a directly-converting semi-conductor material and pulse-shaper in the signal readout electronics assembly. A method is disclosed for a readout of count impulses generated in the semi-conductor material, wherein part of the pulse-shaper is equipped with a relatively longer shaping time constant and a different part of the pulse-shaper is equipped with a relatively shorter shaping time constant.

Abstract: The present invention relates to a post frame for X-ray apparatus and a ceiling type X-ray apparatus. The post frame according to the present invention comprises: a main frame comprising a fixed frame fixed to the X-ray apparatus and a plurality of movable frames received by and arranged in the fixed frame; and a bearing part provided on the main frame, wherein the main frame comprises: a guide integrated with the main frame, that protrudes inward from the main frame and has an insertion groove at both sides; and a connecting bar that is inserted into the insertion grooves and is in contact with a bearing of the bearing part. Since the welding of the guide is not required, time and cost for manufacturing the post frame are reduced. The connecting bar can be assembled easily by simply inserting it into the guide groove.

Abstract: In a radiation imaging apparatus, an envelope has a first window for transmitting radiation and is filled with an insulating liquid, and a radiation tube in the envelope has, at a position facing the first window, a second window for transmitting the radiation, and a shielding member. A solid insulating member is arranged between the shielding member and the inner wall of the envelope, and an opening is formed at a position on the insulating member corresponding to the first window. The shortest distance from the shielding member to the first window or the inner wall of the envelope through the opening of the insulating member without the insulating member is made to be longer than the shortest distance from the shielding member to the first window or the inner wall of the envelope through the insulating member, thereby improving withstand voltage performance without reducing an radiation amount.

Abstract: An X-ray imaging apparatus comprises a grating configured to form an interference pattern by diffracting X-rays from an X-ray source, a amplitude grating configured to partly shield X-rays forming the interference pattern, and an X-ray detector configured to detect an intensity distribution of X-rays from the amplitude grating. The amplitude grating is comprised of a central area and a peripheral area and the peripheral area shows an X-ray transmittance higher than the central area relative to X-rays perpendicularly entering the amplitude grating.

Abstract: A method for detecting an anomaly in a biological material is disclosed, including the steps of: irradiating the biological material with electromagnetic radiation of at least two different energy levels; measuring the amount of radiation transmitted through the biological material; and determining, for each energy level, a transmission value. Before or after irradiation of the biological material, a reference material of a predetermined thickness is irradiated and the amount of radiation transmitted is determined. For each energy level, a transmission calibration reference value is determined and a calibrated transmission value is determined for the biological material and the calibration reference. A material value based on a relationship between the calibrated transmission value and the presence of an anomaly in the biological material is determined by comparing the determined and expected material values for the biological material. A corresponding apparatus is also disclosed.