EP2462470A2

EP2462470A2 - Computer tomography device

Info

Publication number: EP2462470A2
Application number: EP10750031A
Authority: EP
Inventors: Martin Simon
Original assignee: Wenzel Volumetrik GmbH
Current assignee: Wenzel Volumetrik GmbH
Priority date: 2009-08-07
Filing date: 2010-08-05
Publication date: 2012-06-13
Also published as: WO2011015357A2; DE102009036579A1; US20120148015A1; WO2011015357A3; CN102597807A

Abstract

The invention relates to a computer tomography device for non-medical applications, in particular a non-medical material or workpiece test, having a sensor carrier unit comprising a plurality of individual pixels provided adjacent to one another, said sensor carrier unit being designed to detect invasive radiation of an x-ray radiation source by means of a detector surface. According to the invention the detector surface extends in at least one plane in the shape of an arc, wherein the sensor carrier unit has a contour that is arced at least in sections and/or comprises a plurality of individual detector elements (20) arranged in a faceted shape, each comprising a flat detector surface (3), disposed adjacent to and/or adjoining one another along an arced line (6), and an object carrier, designed as a rotary plate (30), for a workpiece to be subjected to tomographic inspection is provided in a beam path between the x-ray radiation source (1) and the sensor carrier unit.

Description

Computer tomographic device

The present invention relates to a computer tomographic device according to the preamble of the main claim.

In addition to the field of medical tomography, in particular X-ray tomography has recently been established for testing workpieces or materials, whereby, analogously to human or veterinary computer tomography, workpieces are exposed to a high-power X-ray beam as invasive radiation and transilluminated. The workpiece as a measuring object is located between a (high-power) X-ray source and an electronic X-ray detector, which converts the received beam signal into an electronically evaluable signal and then by means of otherwise known methods of digital imaging from this signal, the desired image, including the image of any Defects, cavities or the like. a workpiece, constructed.

In addition to the formation of the X-ray source, the realization of the X-ray detector is critical for the image quality, resolution and image noise of such object images to be recorded. In an otherwise known manner, this is implemented as an array of a plurality of planarly arranged detector pixels, which are provided with scintillator coatings for detecting the X-ray radiation and for subsequent conversion into semiconductor-detectable radiation.

It is known from the prior art to select the detector size (array size) in accordance with the dimensions of a measurement object or the geometry in a tomograph interior. In this case, a principle-related disadvantage already exists in that an idealized point source X-ray source, which radiates on a flat detector surface, brings a (distance-dependent) different radiation intensity and onto the individual pixels of the detector, depending on whether a respective individual pixel is more central or edge is arranged. Furthermore, the non-perpendicular impingement of the rays on a respective pixel leads to a further reduction of the intensity. A consequence of this is a worsening of the detector dynamics or contrast resolution, as well as non-homogeneous solid angles between the X-ray exit point and the respective pixels, which have an adverse effect on a realizable image resolution and quality. A further disadvantage of detector devices known from the prior art is that over the period of use the strongly ionizing X-ray radiation leads to a degradation of the detector pixel and detector electronics, in other words the useful life of conventional detectors is limited.

Finally, as is known from the prior art, it is necessary to assemble them from a plurality of individual detectors (each having a flat detector surface) in the case of a particularly large-area required detector surface. However, there is the problem here that pixel inaccuracies are generated at a transition between two adjacent individual detectors in that virtually no seamless joining of adjacent individual detectors is possible - this is because the electronic components extend beyond the respective edge lengths of the (pure) detector surface and so an adjacent arrangement must always consider maximum edge lengths.

In view of this background situation, it is therefore an object of the present invention to provide an improved x-ray detector device in which the imaging quality and resolution of a detected x-ray signal, in particular from a point-shaped x-ray source, is improved and, in particular, quality differences in the imaging between peripheral edges Single pixels and central single pixels are reduced. In addition, it is an object of the present invention, adverse damage or Degradation of electronic imaging arrays by the invasive, ionizing radiation to prevent or minimize their adverse effect on the detector electronics. Finally, it is an object of the present invention to create the preconditions for a pixel-precise arrangement of mutually adjacent individual detectors, without an effective detector surface being widened or distorted by non-detecting housing components.

The object is achieved by the computed tomography apparatus having the features of the main claim and by the apparatus having the features of independent claim 9; advantageous developments of the invention are described in the subclaims.

The computer tomographic device according to the invention provides that a sensor carrier unit embodied as a detector device faces an (otherwise known) X-ray source, wherein a slide designed as a turntable, at least in the operating state of the device, extends into the beam path between the X-ray source and the detector device, where appropriate examining workpieces or materials are then provided on the turntable. It is preferred within the scope of the invention, a rotational axis of the turntable in such a way that it is aligned perpendicular to the first plane, namely the plane of the curved detector surface. As a result, an approximately as assumed plan bearing surface of the turntable in the first plane or parallel to this, and in this way advantageous and further education low also large objects using the advantages to be explained in detail below, realized by the arc shape of the detector surface advantages recorded tomographic can be.

In accordance with the invention, the detector surface according to the present invention extends at least in one plane, namely the first plane, floor-shaped, where "arcuate" in the context of the invention not only a continuous, kink-free arch shape is meant, but in particular also following a bow shape multi-faceted sequence of flat individual surfaces, which are arranged according to a preferred embodiment along an arcuate shape.

According to this first solution aspect, the geometric prerequisites are created for reducing or eliminating image quality and sharpness differences of a punctiform X-ray source by the detector device, in particular if the arch form has an (approximately) constant radius with respect to the center of the point-shaped X-ray source , Approximately each individual pixel along the arc is equally spaced, thus the best conditions for optimum image quality are given (which in the embodiment of the invention in facet form the respective image errors by appropriate design of the individual facets and the number of individual detectors control and manageable remain). The faceted angled provision of adjoining individual detectors on their detector surface also makes it possible, in a very extensive manner, to realize a pixel-by-pixel uninterrupted transition of the detector surface between adjacent individual sensors, so that geometrical advantages are realized in this way too (by arranging against each other in the first plane) Namely stay in particular back widened housing dimensions of a single detector without influence on the overall arrangement on the detector surface).

In a preferred development of this solution, according to the invention, it is additionally provided to geometrically separate the actual (front) detector surface as a radiation entrance surface from a (typically) semiconductor-based, such as CCD detector array, between which radiation or light-guiding means are provided. This measure also has a positive effect in two ways in the sense of the stated task: On the one hand, the radiation or light guide functionality makes it possible to shift the (potentially) voluminous, wide electronics components backwards relative to the detector surface and thus to prevent these preclude a pixel-precise transition between adjacent single detectors. On the other hand, It is even the refinement of the radiation or light-guiding means provided by means of a relatively offset entry and exit surface for the radiation to be transmitted to completely place the (sensitive) detector elements out of the (X-ray) beam path, so that the Degradation of semiconductor-based sensor arrays can be avoided or reduced by invasive radiation. It is precisely this second measure according to the invention that is particularly assisted by diaphragms provided for further development, for example in the form of a collimator, which, suitably placed in front of the detector surface, ensures that incident X-ray radiation is concentrated only on the detector surface.

In the preferred embodiment, it is on the one hand low, the Strahlungsbzw. Light guide, which further preferably as a light-conducting fiberboard or the like. can be realized light-conducting body, so to design that parallelogram-like the inlet and outlet surface allow an offset of the beam path. Alternatively, it is provided in the context of a preferred embodiment of the invention to connect the inlet and outlet surface over an arcuate shape and in this respect at an angle relative to each other (which may be typically even 90 °, ie the radiation or light guiding a typically horizontally incident X-ray beam , if necessary after appropriate conversion, bend down by 90 ° downwards). By suitable protective or veneering measures, it is then possible to protect a detector arranged there, namely on the exit surface, directly in front of the harmful invasive radiation.

While it is favorable according to the present invention for the approximation of the most ideal arc shape to arrange as many Einzelfacetten (each with planar detector surface) adjacent to each other, a minimum segment number of 3, more preferably of 5, has been found to be favorable in the invention. Independent protection within the scope of the invention is claimed for an x-ray detector device in which - in the direction of the beam path - a second detector surface, either adjacent or overlapping, can be provided in front of or next to the first detector surface (to be stationary). This second detector surface, typically on a second carrier unit (alternatively but also on the same carrier unit), can be brought, pivoted, adjusted or inserted by suitable mechanical or electromechanical measures (alternatively fixed in the same plane next to the first detector surface be present), which can be done in this way very simple and elegant and without large structural-geometric modifications in a scanner interior to special detection requirements of an alternative object to be measured or different measurement processes can be performed sequentially.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings; these show in:

Fig. 1: a schematic plan view of the computer tomographic

Device according to a first embodiment of the invention with five individual detectors arranged along an arcuate shape relative to an X-ray source;

FIG. 2: a schematic sectional view analogous to the section line A - A in FIG.

1, wherein additionally a collimator arrangement for beam focusing or for generating a beam stop is shown and additionally the exit face is arranged offset downwards;

Fig. 3: an opposite to the representation of FIG. 2 alternative embodiment of

Radiation or light-guiding means of the detector device; 4 shows a schematic view of a detector device having a first and a second detector surface, which are provided adjacent to each other, and FIG. 5 shows a schematic longitudinal section arrangement, with a first and a second detector surface, wherein a second carrier unit with the second detector surface movable into the Beam path in front of the first detector surface can be brought. FIG. 1 shows a schematic plan view of a first embodiment of the present invention. A plurality of five individual detectors 20 are arranged in the horizontal plane along the circular arc 6 (radius 2), as can be seen in the plan view of FIG that inside the clamped angle 2, a facet shape with respect to an X-ray source 1 (to be assumed to be punctiform) arises. A designed as a turntable 30 slide is placed, ideally along the line A - A, in the beam path, wherein the X-rays of the source 1 then penetrates an object held on it and is received by the detector assembly 20. The turntable has correspondingly an axis of rotation which is perpendicular to the plane of the drawing of Fig. 1, so that a direction of rotation along the bottom arrow 32 of the turntable takes place in accordance with the arcuate curvature along the circular arc 6. In addition, according to further education, it is also provided in the context of preferred embodiments of the invention to make the turntable 30 vertically movable along the axis of rotation, for example by appropriately provided on or in the turntable drive means. In this way, for example, a large (high) workpiece, which exceeds the detector height in the projection, can be scanned successively.

It is obvious, first of all, that this circular arc arrangement has considerable geometric advantages in comparison to a single planar detector. Viewing a uniform length of the beam path: Only with the (drastically reduced) flatness error of the individual segments nor differences in length between the point-shaped X-ray source 1 and a respective detector surface 3.

As FIGS. 2 and 3 additionally show, each of the individual detector elements 20 is constructed here as a sequence of a detector surface 3 displaced spatially along the beam path (in this case a scintillator surface is applied by otherwise known coatings, with which the X-ray photons are converted into detectable photons be formed), wherein the thus formed entrance surface is connected via a Lichtleitbereich 4 (realized in the illustrated embodiment of Fig. 2 as a parallelogram fiber optic fiber plate) with a relative to the entrance surface provided exit surface 5, in which case in a manner not shown in detail a detector array for the generation of corresponding electronic signals is provided. 2 also clarifies that the light emitter surface (and correspondingly the detector array provided there) lies outside of the beam path 2 of the X-ray radiation due to the parallelogram shape of the light guide 4, and therefore is no longer impaired by this invasive radiation.

FIG. 2 additionally illustrates by reference numeral 7 a collimator arrangement with which the radiation incidence of the X-ray beam 2 can be limited only to the entrance surface 2 (detector surface). 3 illustrates an alternative embodiment of the radiation or light guide 4. In the example of Fig. 3, this conductor (again suitable as a fiber optic fiber arrangement or the like. Body-like realized) designed in an arc shape, so that between the entrance surface 3 and the exit surface 5 in the example, a 90 ° angle can be realized. Here, too, the advantage of attaching optically downstream detector arrays outside the X-ray radiation path can be realized. Figures 4 and 5 illustrate an alternative solution form of the present invention. Thus, the front view of FIG. 4 shows how, within a detector arrangement 8, two individual detector surfaces 9 (large area) and 10 (small area), adjacent to each other here and non-overlapping, can be provided. This arrangement makes it advantageous, especially in conjunction with a height-adjustable workpiece carrier, without major conversion measures or the like. geometric changes in a tomograph interior different object sizes, measuring methods or the like. apply, simply by different wiring of the detectors 9 and 10 and appropriate positioning of a workpiece relative to these detectors and the radiation source.

5 illustrates a further variant of such an arrangement with two detector surfaces, wherein these overlap here in the direction of the beam path 2 and a second (smaller) detector surface 10 by only schematically indicated support means movable (eg pivotable, pluggable or the like) before the stationary carrier unit 8 can be moved with the stationary detector 9. Even such a procedure allows a simple and elegant way to adapt to different radiation, object and measurement conditions.

The present invention is not limited to the embodiments shown. So it is on the one hand in the context of the invention, the detector units 4, in particular by means of the provided Lichtleitanordnungen to design suitable for a particular application, which, as shown in FIGS. 2 and 3, can be offset or bent, but alternatively also simple can bridge a linear optical distance. It is also within the scope of the invention to provide any desired plurality of individual sensors according to FIG. 1 for forming an arcuate shape, although this arcuate shape is advantageously circular-arc-shaped, but the arcuate shape is not restricted to the circular arc shape. It is also possible within the scope of preferred developments to provide an arcuate shape in two dimensions (that is to say in the shape of a dome), so that an arcuate shape could also be realized in the vertical, relative to the plane of the figure in FIG. 2.

Claims

claims

1. Computer tomographic device for non-medical applications, in particular a non-medical material or

Workpiece testing, with

a sensor carrier unit having a plurality of individual pixels provided adjacently to each other and being formed by means of a detector surface for detecting invasive radiation of an X-ray source, characterized in that the detector surface extends arcuately in at least one first plane, wherein the sensor carrier unit has an at least partially curved one Contour and / or faceted a plurality of each having a plane detector surface (3) having single detector elements (20) along a curved line (6) adjacent to each other and / or abutting, and in a beam path between the X-ray source (1) and the

Sensor support unit designed as a turntable (30) slide for a tomographically examined workpiece is provided.

2. Apparatus according to claim 1, characterized in that the detector surface as radiation entrance surface via radiation and / or

Light conducting means (4) is connected to at least one semiconductor-based detector array for electronic signal generation.

3. Apparatus according to claim 1 or 2, characterized in that the detector surface (3) scintillator means, which for converting from

X-ray photons are formed in detectable by a semiconductor-based detector array photons.

4. Apparatus according to claim 2 or 3, characterized in that the radiation or light-guiding means are formed as an arrangement of a plurality of mutually parallel optical fibers and / or as a light-conducting fiber serplatte (4).

5. Device according to one of claims 2 to 4, characterized in that the radiation or light-guiding means are longitudinally formed so that a plane entrance surface (3) of the radiation or light-conducting relative to a plane exit surface (5) of the radiation or Lichtleitmittel is offset, in particular parallelogram-like or angular and / or arcuately offset.

6. The device according to claim 5, characterized in that an offset between the inlet and the outlet surface is set up so that a radiation entering along an X-ray path in the entrance surface emerges from the exit surface such that a detector array provided thereon is located outside the beam path.

7. Device according to one of claims 1 to 6, characterized in that the detector surface Kollimatormittel (7) are associated so that they act to hide invasive radiation outside the detector surface.

8. Device according to one of claims 1 to 7, characterized in that the arc shape of the detector surface is a circular path (6) on which facet-like at least three, preferably at least five of the individual detectors (20) are arranged abutting one another.

9. Computer tomographic device for non-medical applications, in particular a non-medical material or

Workpiece testing, with

a sensor carrier unit (8) having a plurality of individual pixels provided adjacent to one another, surface (9, 10) are designed to detect invasive radiation, characterized in that

the detector surface has a first stationary detector surface (9) and a second detector surface (10) which, relative to a radiation path of the invasive radiation, adjoins the first detector surface on the sensor carrier unit or is detachable and / or movable in front of the first detector surface can be arranged.

10. The device according to claim 9, characterized in that the second detector surface (10) has a relative to the first stationary detector surface (9) reduced detector surface.

11. Apparatus according to claim 9 or 10, characterized by means for pivoting, moving, detachable placement, screwing or plugging a second detector surface forming the second

Carrier unit on the stationary detector surface and / or the sensor carrier unit.