WO2013167461A1 - Method for determining features of a measurement object - Google Patents

Abstract

Method for determining features of a measurement object. The invention relates to a computer tomography method for dimensionally determining features on a measurement object, in which the measurement object fastened to a mechanical rotary shaft is x-rayed by the radiation from a radiation source in a plurality of positions relative to the sensor system, at least consisting of the radiation source and a two-dimensional detector, in each case in a plurality of rotational positions around a rotary shaft, and associated 2D x-ray images are recorded in each case, wherein those x-ray images from the different relative positions which are recorded in the same rotational position with respect to the particular starting angle of rotation of the different relative positions are each combined to form a resulting x-ray image, and three-dimensional volume information in the voxel format (so-called voxel volume) is calculated from the resultant x-ray images by means of reconstruction, wherein this voxel volume contains data relating to the local beam absorption, wherein surface points are preferably generated from the voxel data in the region of the material transitions. In order to avoid measurement errors during the computer tomographic measurements of measurement objects in a plurality of relative positions between the measurement object and the x-ray sensor system, it is proposed that the different relative positions are selected in such a manner that the distance between the focal point of the radiation source (focal spot) and the rotary shaft remains the same.

Description

 Method for determining features of a measurement object

The present invention describes a method for the dimensional determination of features on measurement objects with computed tomography methods, in which the measurement object is measured in a plurality of relative positions.

In particular, the invention relates to a computed tomography method for the dimensional determination of features on a measurement object, in which the measurement object attached to a mechanical axis of rotation in several relative positions with respect to the sensor system, at least consisting of radiation source and 2-dimensional detector, in each case in several rotational positions an axis of rotation is irradiated by the radiation of the radiation source and respectively associated 2D transmission images are recorded, wherein the transmission images from the various relative positions are each assembled into a resulting radiographic image, which was taken with respect to the respective starting rotational angle of the various relative positions at the same rotational position, and off The resulting radiographic images are reconstructed by 3-dimensional volume information in voxel format (so-called voxel volume), in which voxel volume Date n are included for local beam absorption, wherein surface points are preferably generated from the voxel data, in the region of the material transitions. To set the rotational positions of the turntable, which is also referred to as a mechanical axis of rotation, this consists of a fixed and a rotatable part. Insofar as reference is made to the rotation or rotational position of the mechanical axis of rotation, the following always means the rotatable part. The rotatable part is rotated about a mathematical axis, which is called "rotation axis" in the following: The orientation, ie direction, and position, for example of a point, of this axis of rotation in space is also referred to as position of the axis of rotation The direction of the mechanical axis of rotation is thus also referred to as the direction of the (mathematical) axis of rotation, whereas the position of the mechanical axis of rotation is referred to as the position in space at which the entire mechanical axis of rotation, ie fixed and rotatable part, is arranged. If the position of the mechanical axis of rotation is changed, for example in one of the three lateral directions x, y and z that are at right angles to each other, the position of the (mathematical) axis of rotation inevitably changes, but only in such a way that it is displaced in parallel So their orientation does not change.

In order to measure measuring objects completely with computer tomography, which are larger than the measuring range of the computer tomograph in the respectively selected magnification setting, there are methods in which the measuring object is only partially detected in several partial measurements. A distinction is made between methods in which the measurement object has larger dimensions in the direction of the axis of rotation or at right angles to the axis of rotation than the measuring range of the computer tomograph. In addition, either the measurement object with respect to the radiation source and the detector can be moved or only the detector is moved to obtain a virtually enlarged detector. The procedures are also combined.

If the measurement object only extends beyond the measuring range of the computer tomograph in the direction of the axis of rotation of the computer tomograph, several partial measurements are carried out, between which the measurement object runs along the axis of rotation is moved. In this case, the measuring object leaves the measuring range perpendicular to the axis of rotation in any of the rotational positions. This makes it possible to evaluate the partial measurements separately from one another by reconstructing the respectively assigned radiographic images and calculating partial voxel volumes. The voxel volumes can then be assembled together and it can be a common determination of surface points based on z. B. Threshold method can be performed. Alternatively, surface points on the sub-volume can also be determined. The method is also known by moving the detector along a parallel to the axis of rotation axis.

The radiographic images determined in the partial measurements can alternatively also be combined to resulting radiographic images per rotary position. The reconstruction then takes place on the composite set of transmission images. However, it should be noted that the magnification of the image changes. A necessary correction of the radiographic images before combining was not yet known, which results in measurement deviations.

If the measurement object leaves the measuring area of the computer tomograph at right angles to the rotation axis in at least one rotational position, the measurement object is wider than the measurement area of the computer tomograph transversely to the rotation axis, then several partial measurements are carried out in which the measurement object is perpendicular to the rotation axis and simultaneously in a plane parallel to the detector plane is moved. In this procedure, only the combined or composite radiographic images corresponding to the respective rotational positions can be reconstructed. Again, magnification changes and perspective distortions occur. The method is also known by moving the detector perpendicular to the rotational axis direction in the detector plane.

In the known method, the measurement object is therefore scanned in its height and / or its width. Here, a displacement of the measurement object with respect to the sensor always takes place in a plane parallel to the detector plane. As a result, the ratio describing the imaging scale changes from the distance detector - Focus point of the X-ray source to DUT - Focus point of the X-ray source. The measurement errors that occur as a result are not yet corrected and thus lead to the determination of incorrect dimensions on the measurement object. In addition, due to the changed directions of impact of the radiation on the detector, perspective distortions result in the different relative positions. The transmission images corresponding to the same angle from the different relative positions are not correctly combined by the two effects.

The object of the present invention is the avoidance of measurement errors in the computed tomographic measurements of measurement objects in a plurality of relative positions between the measurement object and the x-ray sensor system.

To solve the problem, the invention provides in particular that the different relative positions are chosen so that the distance between the focal point of the radiation source (focal spot) and the axis of rotation remains the same.

In particular, the invention provides that the different relative positions are on a circular path around the focal point of the radiation source and in a plane whose normal vector is parallel to the direction of the axis of rotation.

Another proposal of the invention is characterized in that each adjacent relative positions are selected so that a part of the measurement object is detected in some of the rotational positions in each case two relative positions, so an overlap area exists.

In particular, it is provided that when changing the relative position on a circular path, the fixed part of the rotation axis is not rotated and the rotatable part of the rotation axis is rotated together with the measurement object for determining the start rotation angle by the angle of the changed orbit position.

During the movement of the entire mechanical axis of rotation to the new position, first the entire axis (lower part, fixed with the CMM or the translatory axes of the CMM is attached, and upper part, ie rotatable turntable with measuring object) including measuring object ONLY translationally shifted. Subsequently, the rotatable part of the rotation axis (ie the turntable) performs a rotational movement to rotate the measurement object in the starting angle position. Equally effective, the entire mechanical axis of rotation could be rotated around the focal spot.

The invention is further characterized in that the respective rotational positions in the different relative positions are set in their starting angle so that the angle of incidence of the measuring object detecting area of the measuring radiation remains the same in relation to the Meßobjektkoordinatensystem, the measurement object in the overlapping area in the same Direction is irradiated, in particular the start rotation angle is thus changed by the angle by which the entire mechanical axis of rotation was moved around the focal spot.

The aim is that the measurement object is arranged in the new position in the transition region in the starting rotational position so that it is irradiated in the same direction, as in the measurement in the first position. Otherwise the radiographic images could not be put together. The transition region thus ideally produces the same radiographic image (or part of the radiographic image) in both relative positions. The combining of the radiographs could then also be done by stitching. But this is not necessary if the positions and rotational positions are known.

An inventive concept further provides that in each relative position, the respective further rotational positions are set equal with respect to the respective starting angle, preferably the rotational angle increment is constant.

The invention also provides that the perspective distortions of the image on the radiation detector corrected by changing the starting angle and / or by the relative movement of the measurement object on a circular path are corrected be, preferably by resampling the respective radiographic image and / or by consideration in the reconstruction.

In particular, it is proposed on the basis of the invention that the various relative positions are arranged on a circular path around the focal point of the radiation source, which is located in a plane which is spanned by the axis of rotation and the direct connection between detector center and radiation source.

Another idea to be emphasized of the invention provides that when changing the relative position on a circular path, the entire mechanical axis of rotation is tilted according to the orbit position and the rotatable part of the axis of rotation remains together with the measurement object for determining the starting rotational angle in the rotational position.

In particular, the invention is characterized in that the entire mechanical axis of rotation is tilted in the different relative positions in the plane of rotation axis and connection between the detector center and radiation source, that the angle of incidence of the measuring object detecting area of the measuring radiation remains the same in relation to the measuring object coordinate system, the Measuring object in the overlapping area is thus irradiated in the same direction.

Preferably, it is provided according to the invention that the perspective distortions of the image on the radiation detector resulting from a change in the starting angle and / or by the relative movement of the measurement object on a circular path are corrected, preferably by the inclination of the entire mechanical axis of rotation and / or by resampling at the respective one Radiation image and / or by consideration during reconstruction.

Due to the teaching according to the Invention, the same magnification is used for all partial measurements. Preferably, perspective distortions are corrected. According to the invention, the relative position between the measurement object and the X-ray sensor system is set for all partial measurements such that the same imaging scale is present. This is achieved by selecting the relative positions so that the distance between the focal point of the radiation source and the measurement object is always the same. For this purpose, provision is made in particular for the relative positions to be set on circular paths around the focal point.

It should be noted in particular that the measured object assumes a changed angle of rotation after the relative displacement in front of the radiation source. This must be corrected by rotating the measurement object with the rotatable part of the mechanical axis of rotation so that the starting angle of rotation is adapted for the plurality of rotational positions in the form that the radiation direction remains the same with respect to the measuring object coordinate system. In addition, perspective distortions arise on the radiation detector, because at least parts of the measurement object are located after the relative displacement in an altered relative position to the detector and thus impinge the then passing through the measurement object partial beams at a different angle to the detector. These distortions are corrected in accordance with the invention by re-sampling the transmission images, since the size of the distortions is known on the basis of the known start angle, and / or by taking account of the distortion during the reconstruction algorithm.

If the various relative positions are assumed to be almost along a line parallel to the axis of rotation, the entire mechanical axis of rotation is tilted with the measurement object itself such that the angle of incidence of the measurement radiation which detects the measurement object remains the same with respect to the measurement object coordinate system. In this case too, the perspective distortions are corrected by re-sampling on the radiographic image or by taking account of the reconstruction.

Further details, advantages and features of the invention will become apparent not only from the claims, the features to be taken from them - for themselves and / or in Combination - but also from the following description of the drawing to be taken preferred embodiments.

Show it:

1 shows an arrangement of a measurement object in a first relative position in FIG

 Terms of an X-ray sensor and

2 shows an arrangement of a measurement object in a second relative position in FIG

 Reference to the X-ray sensor.

1 shows an arrangement of a measurement object 1 in a first relative position with respect to an X-ray sensor system 2, comprising a radiation source, such as X-ray source with focal point or focal spot 3, and a detector 4. The measurement object 1 -also called component-is rotatable about a rotation axis 5 , which is shown in plan view. The component 1 is fixedly mounted on the rotatable part of the rotation axis 5. In the illustrated first relative position, the angle 6 between the connection between the center 7 of the detector 4 and the focal spot 3 and the connection between the center of rotation axis 5 and the focal spot 3 is zero degrees. Parts of the measurement object 1 project in at least some of the rotational positions about the rotation axis 5 out of the area detectable by the detector 4, limited by the edges 8 and 9 of the radiation area projected into the plane of projection. Therefore, only the single hatched area 10 of the measurement object 1 can be detected and measured. The non-hatched area can not be measured. Duplicated hatched, the transitional or overlapping regions 11 and 12 of the measuring object 1 are shown, which are measured in further relative positions together with the areas not hatched in FIG. The transition region 11 is again detected and measured in the second relative position shown in FIG.

In Fig. 1, the transition region 11 is exemplified in this first rotational position about the axis of rotation 5, so the rotational position of the starting angle, for example from the Beam 13 passes through the angle 14. The beam 13 strikes the detector 4 at an angle 15.

According to the invention, further measurements are carried out to determine further regions of the measurement object 1 in at least one further relative position of the mechanical rotation axis 5 and the measurement object 1. For this purpose, the entire mechanical rotation axis 5 and the measurement object 1 are displaced on a circular path 16 around the focal spot 3. In the example shown in FIG. 1, this circular path is located in the plane of the drawing, ie in a plane whose normal vector is parallel to the direction of the axis of rotation 5. This is a special case of the requirement of the constant distance between the focal point of the radiation source (focal spot 3) and the axis of rotation 5.

2 shows an arrangement for a second measurement, in which the measurement object 1 and the entire mechanical rotation axis 5 are displaced in a second relative position relative to the X-ray sensor system 2 on the circular path 16. The angle 6 'shows the changed angle between the connection between the center of the detector 7 and focal point 3 and the connection between the axis of rotation 5 and the focal spot 3. FIG. 2 shows the measuring object 1 in the now changed starting angle for the various rotational positions about the axis of rotation. 5 for computer tomographic measurement, wherein the starting angle was changed exactly by the angle 6 '. At least in this starting angle position, in turn, the overlapping region 11 is detected by the measuring radiation, for example by the radiation beam 13 ', again at the same angle 14 as in the first relative position between the measurement object and the X-ray sensor system.

This ensures that the measuring object 1 is irradiated in the same direction in the starting angular position in the same measuring object areas and thus the transmission length is the same in each case and that the corresponding respective angle radiographic images from the different relative positions are correctly assembled. However, the beam 13 'now hits the detector 4 at the changed angle 15'. This results in perspective distortions of the radiographic images. These are inventively by the known angle 15 and 15 'are corrected, and the transmission images are sampled accordingly or the distortion is taken into account in the reconstruction.

In order to capture the entire measurement object 1 by computer tomography, measurements in further relative positions of the measurement object 1 and the entire mechanical rotation axis 5 by displacement along the circular path 16 may be necessary. Analogous to the procedure explained in FIG. 2, the overlap region 12 of the measurement object 1 is detected, for example, in the case of an opposite movement about the angle 6 'on the circular path 16. Again, the starting rotation angle is again set so that the transmission, in this case by the beam 17, again in the same direction.

An analogous procedure takes place in the displacement of the entire mechanical axis of rotation with the measurement object along a circular path, which is located in a plane which is formed from the axis of rotation and the direct connection between the detector center and radiation source (focal spot). In contrast to the illustrations in FIGS. 1 and 2, the axis of rotation runs parallel to the longer, illustrated body edge of the measurement object 1 and in the plane of the drawing, and the measurement object is arranged centrally above the mechanical axis of rotation, ie in the direction of the axis of rotation. Fundamentally, however, FIGS. 1 and 2 can be used for clarification. In the second relative position corresponding to Fig. 2 but then no adjustment of the starting rotation angle takes place, but the entire mechanical axis of rotation is tilted together with the measurement object in the drawing plane.

Claims

Claims: A method for determining features of a measurement object

1. Computed tomography method for the dimensional determination of features on a measurement object, wherein the mounted on a mechanical axis measurement object in several relative positions with respect to the sensor, at least consisting of radiation source and 2-dimensional detector, each in a plurality of rotational positions about a rotation axis of the radiation the radiation source is irradiated and respectively associated 2D radiographic images are taken, wherein the radiographic images from the different relative positions are each assembled into a resulting radiographic image, which was taken with respect to the respective starting rotational angle of the various relative positions at the same rotational position, and from the resulting radiographic images by means of reconstruction 3-dimensional volume information in voxel format (so-called voxel volume) are calculated, in which voxel volume data for local beam absorption are included , where surface points are preferably generated from the voxel data, in the area of the material transitions,

 characterized,

 that the different relative positions are selected so that the distance between the focal point of the radiation source (focal spot) and the axis of rotation remains the same.

2. Method according to at least one of the preceding claims,

 characterized,

that the different relative positions are in a circular orbit around the focal point of the radiation source and in a plane whose normal vector is parallel to the direction of the axis of rotation.

3. Method according to at least one of the preceding claims, characterized in that

 that respective adjacent relative positions are selected such that a part of the measurement object is detected in some of the rotational positions in respectively two relative positions, ie an overlapping area exists.

4. The method according to at least one of the preceding claims,

 characterized,

 that when changing the relative position on a circular path of the fixed part of the rotation axis is not rotated and the rotatable part of the rotation axis is rotated together with the measurement object for determining the starting rotation angle by the angle of the changed orbit position.

5. The method according to at least one of the preceding claims,

 characterized,

 the respective rotational positions in the different relative positions are determined in their starting angle such that the angle of incidence of the measuring area of the measuring radiation remains the same with respect to the measuring object coordinate system, ie the measuring object in the overlapping area is irradiated in the same direction, in particular the starting rotational angle the angle is changed by which the entire mechanical axis of rotation was moved around the focal spot.

6. The method according to at least one of the preceding claims,

 characterized,

that in each relative position, the respective further rotational positions are set equal with respect to the respective starting angle, preferably the rotational angle increment is constant.

7. The method according to at least one of the preceding claims,

 characterized,

 in that the perspective distortions of the image on the radiation detector resulting from a change in the starting angle and / or by the relative movement of the measurement object on a circular path are corrected, preferably by resampling methods on the respective radiographic image and / or by consideration during the reconstruction.

8. The method according to at least one of the preceding claims,

 characterized,

 in that the various relative positions are arranged on a circular path around the focal point of the radiation source, which is located in a plane which is spanned by the axis of rotation and the direct connection between the detector center and the radiation source.

9. The method according to at least one of the preceding claims,

 characterized,

 that when changing the relative position on a circular path, the entire rotation axis is tilted according to the circular path position and the rotatable part of the rotation axis remains together with the measurement object for determining the starting rotation angle in the rotational position.

10. The method according to at least one of the preceding claims,

 characterized,

that the entire mechanical axis of rotation in the different relative positions is tilted in the plane of rotation axis and connection between detector center and radiation source, that the angle of incidence of the measuring object detecting area of the measuring radiation remains the same in relation to the measuring object coordinate system, the measurement object in the overlapping area in the same Direction is irradiated.

11. The method according to at least one of the preceding claims,

 characterized,

 in that the perspective distortions of the image on the radiation detector resulting from a change in the starting angle and / or by the relative movement of the measurement object on a circular path are corrected, preferably by the inclination of the entire mechanical axis of rotation and / or by resampling on the respective radiographic image and / or by taking into account the reconstruction.