FI94678C - Imaging method for determining the structure of bodies - Google Patents

Description

94678

DESCRIPTION METHOD FOR DETERMINING THE STRUCTURE OF BODIES

The invention relates to an imaging method for determining the structure of objects, in which method the imaging object and at least one radiation source and at least one detector are moved relative to each other so that the imaging object passes through the rays coming from the radiation source.

For about a hundred years, X-ray technology has been used to develop the internal structure of the pieces. The X-ray shows the details of the internal structure of the subject as overlapping X-ray absorption differences.

If the subject has many different elements with almost the same absorption coefficient, such as the human internal organs at 15 the abdomen, the image becomes difficult to interpret and the elucidation of the structure requires a person specializing in the examination. Various imaging methods have been developed for X-ray imaging, such as contrast imaging, in which the desired subject is already better visible. Today, the most advanced imaging method is 20 X-ray tomography. In this description, a cross-sectional view of the direction is obtained, in which the various objects are separated and in relatively correct places. When the desired number of cross-sectional images are taken in the longitudinal direction, an accurate three-dimensional image is obtained from the shooting area. Other types of radiation have also been used to form a three-dimensional image of the subject, and the best known at present is ultrasound. In the future, imaging will probably also be taken using infrared radiation. Current equipment is complex, expensive and slow. For example, the tomographs required for imaging the human body 30 can be taken in a few. one image per second.

For many purposes today, images of the internal structures of objects are needed automatically and quickly. In this case, the imaging does not have to have a resolution of even less than one millimeter, as is the case with the X-ray tomograph for imaging the human body. Such objects include the imaging of various objects, articles and materials in order to detect undesirable objects, objects and / or materials and to determine the internal structure of the materials and objects. In some cases, it is sufficient to determine the three-dimensional shape of the bodies, and it is not necessary to take a picture of the internal structure of the objects.

The object of the invention is to provide an imaging method for determining the structure of objects, by means of which method 10 sufficiently sufficient three-dimensional images can be formed quickly for different applications and using devices which are considerably simpler and cheaper than devices used in current tomography technology.

The object of the invention is achieved by a method which is characterized by what is stated in the claims.

In the method according to the invention, at least one detector measures changes in the intensities of the rays at least partially absorbed from at least three different angles to the subject as a function of the movement of the subject. In this case, the structural points required to describe the structure are determined from at least three directions, and when the course of the rays in the body is always known at the time of measurement, the three-dimensional structure of the body is solved. The main advantage of the invention is that, for example, in X-ray tomography, the movement of an X-ray tube or several X-ray tubes can be replaced by one fixed X-ray tube and several hundred radiation detectors can be replaced by even one detector. Lait-3C dies are simple and inexpensive in terms of manufacturing and maintenance costs. Similarly, if only the determination of the appearance is required in the imaging, a light emitting diode or a similar light-sensitive transistor can be used as the radiation source, and the transmitter / receiver pair 35 required in the imaging is very simple and inexpensive.

3,94678

The method according to the invention can be applied and used to describe the internal structures of various bodies automatically and quickly. Such subjects include the detection of harmful materials inside the pieces, such as stones and other objects accompanying logs when wood is sawn or chipped. The method can also be used to determine the locations of defects and branches in the wood to be sawn in order to optimize sawing. In addition, the method can be applied to a variety of other purposes. The recording speeds are high when using the method according to the invention, about 100-500 frames per second, and the achievable resolution is sufficient for these purposes. Furthermore, the method is used to determine the three-dimensional shape of objects. An example of this is the determination of the size and shape of pieces chopped from some material, for example in the pulp industry in the pulp industry and in the mining industry in the determination of the size and shape of crushed stone.

The invention will now be explained in more detail with reference to the accompanying drawing, in which Fig. 1A shows a side view of an embodiment of the method according to the invention, Fig. 1B shows a side view of the embodiment according to Fig. 1A, Fig. 1C shows views from different directions, Fig. 2A and 2B show a side view and a top view of another embodiment of the method according to the invention, Fig. 3 shows a side view of a third embodiment of the method according to the invention, and. Figures 4A and 4B show a fourth and top view of a fourth embodiment of the method according to the invention.

Figures 1A, 1B and 1C show the principle of an imaging method according to the invention, using as an example the description of the internal structure of a log tree. The radiation source is an X-ray tube that emits X-rays at a wide angle. The log to be imaged is transferred through an X-ray 4 94678 radiation beam. Radiation measurement takes place with row detectors 4, 5, 6, 7 and 8. The rows of II detectors run transversely as supports underneath. The row detector may consist of several parallel (e.g. 100-500) 5 separate X-ray detectors or one long detector which is location sensitive, i.e. measures not only the observation but also its position with respect to its length. Figure 1C shows descriptions from different directions of one element when the X-ray tube has moved relatively over the tree during imaging, the numbers 4, 5, 6, 7, and 8 in the bottom 10 refer to the corresponding row detectors with which the directions are described. These embryos can be, for example, 0.5 cm in diameter. The densities of the tree elements are solved precisely on the basis that each element is imaged from a different direction and their sum-15 absorptions are always obtained from the corresponding detector of the row detectors with time as the log passes through the imaging. In principle, at least 2 rows of detectors are always required for the description, there are 5 of them in the example. The number of detector rows can vary from application to application, and a larger number of detector rows will in principle provide a more accurate picture. The images are resolved, as in conventional tomography, as cross-sectional images of a certain plane, e.g. from cross-sections 1 to 6. Once all the cross-sections have been resolved, a three-dimensional density image of the tree is obtained, from which branches, cracks and often height distributions can be deduced. In addition, a profile reader can be used on the device · ’, which determines the appearance of the tree. This is used in computational techniques to aid in the formation of sectional images. Since the imaging technique describes all the elements of the tree from several directions, it is also possible to directly determine the locations of the branches of the sawn timber to be sawn from the tree.

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In the embodiments shown in Figures 2-4, the radiation source and the detector form a pair, one in place and the other 35 rotating a circular circumference so that the radiation surface being measured forms a conical surface. The object under consideration passes through this conical surface, whereby an image is generated 5 94678, usually using a computer. In practical solutions, either several detectors or radiation sources can be used. Of course, different applications can also be combined; for example, perpendicular imaging is done with a fixed row of detectors and 5 mutually oblique imaging with a rotating plate.

The following are three examples of how to use the method in detail:

Example 1. Figure 2 shows a log torchograph 10 formed by a radiation source 11 (X-ray machine) from which continuous X-rays are obtained and a rotating plate 17 to which a radiation detector 12 is attached, which measures the amount of X-rays in question. The subject, the log 13, is conveyed, for example, by a conveyor belt at a constant speed through the tomogra-15 fin. When the log enters the description cone, the cross-sectional absorption curve is measured at location 15 to obtain a transverse density profile. As the log passes through the second surface 16 of the imaging cone, lateral density profiles are obtained. From these cross-descriptions, the density distributions of the internal structure of the log can be determined, from which the location of the branches, cracks and rot sites in the tree can be further deduced, as shown in the general description. In practice, the imaging speed may be, for example, 2 m / s, and when taking clips at 1 cm intervals, the imaging speed is 200 Lei-25 frames per second. If two X-ray detectors (phase difference 90 *) are placed on the perimeter, the rotation speed is 6000 rpm, which is achieved using quite conventional techniques. The shields shown in Figure 2 are intended to prevent the detector from seeing radiation at all times. One or more detectors 30 may be used in the method and the data is read along a line to the computer 14 when only one detector is * always in radiation. As an option, a laser profiler can be used in the device, which determines the cross-sectional view of the log before defining the internal parts. This information speeds up and refines the cross-sectional image formation.

Example 2. Figure 3 shows a stone detector. Exposure of stone 94678 6, for example from peat to be burned or wood stream to be chipped, is important, but in the past there has not been a well-suited method for this. Since this resolution is not nearly as high as in the previous case, the radiation source is 21 radioisotope sources (e.g. 100 mCi Am-241). Detector 22 can now be mounted fixed to measure the intensity of the radiation. The differences in density in the transported material 23 are determined from the absorptions on the straight conical surface 25 and the oblique conical surface 26 with the aid of a computer 24.

Example 3. Figure 4 shows the determination of the chip size. One interesting measurement for the pulp industry is the dimensions of wood chips; length, width and moisture distribution. When it is not necessary to measure the internal structure, ordinary light is sufficient as the radiation source. The measurement method of Figure 4 uses light emitting diodes 30 as the source and two photomultiplier tubes 31 and 32 as detectors. The light-20 sources, which may be up to 20 or more, are mounted on a rotatable plate 36, which in this case is rotated at about 10,000 rpm. Chips 33 are sprinkled on the transparent conveyor belt 35 so that they do not overlap. The belt is conveyed, for example, at a speed of no-25 at 1 m / s, in which case each light source successively enters the belt. over the opening 37 under a transparent conveyor belt 35. If there are 20 light sources and 10,000 revolutions. per minute, there will be a sweep every 1/3 mm. The blackout time of the photomultiplier perpendicularly above gives a chip width of 30 kb. pyyhkäisykohdalta. The difference in the time of appearance of the edge, which is observed with the photomultiplier tube • 32 looking at an oblique direction, gives the height of the chip in question. pyyhkäisykohdalta. Based on these values, the chip length, width, and height are calculated on a computer.

Other variations of the shooting method can also be used, and the speeds and shooting speeds of the subjects may vary in different applications. In the above applications, the objects to be examined have been moved with respect to the radiation source and the detector, but in other solutions the radiation source and / or the detector can be moved while the object to be examined 5 remains in place. In addition to fixed detector rows, one or more rotatable plates or pads may be used. In one application, radiation detectors are placed on the rotatable base for different radius values, whereby more than two oblique cuts can be measured.

10

When using the method according to the invention, visible light, X-rays, radar radiation, gamma radiation, neutron radiation, infrared radiation, radio wave radiation, pulsed magnetic field or the like, or combinations thereof, which radiate or radiate the radiation or radiation, can be used as radiation. One type of interesting tomography is neutron tomography, in which a neutron source and a neutron detector are mounted on a large rotatable plate. If the dimensions are 3-5 meters, this method can be used to describe vehicles, containers and the like in search of possible organic substances such as explosives or hoods.

The invention is not limited to the preferred embodiments set forth above, but may vary within the scope of the conclusive idea formed by the claims.

Claims (9)

An imaging method for determining the structure of bodies, in which method an imaging object (3; 13; 23; 33) and at least one radiation source (1; 11; 21; 30) and at least one detector (4-8; 12; 22 31, 32) are moved relative to each other so that the imaging object is moved by the beams coming from the source of radiation, characterized in that with one or more detectors measured from at least three different angles the changes in the intensity of the beams, which at least partially they are absorbed into the imaging object as a function of the motion of the imaging object, whereby the points in the structure needed for imaging the structure are defined by at least three directions and where the jets of the body are always known at the time of measurement, the three-dimensional structure of the body is determined. Imaging method according to claim 1, characterized in that the imaging object (3) is moved between an in-place x-ray tube (1) and X-ray detectors (4-8) located transversely to the motion direction of the imaging object, which observes the X-ray detectors. the radiation of the X-ray tube at least from three different angles. 3C Imaging method according to claim 1, characterized in that the imaging object (13; 23; 33) is moved at least through a conical imaging surface (15, 16; 25, 26), which imaging surface is formed by at least one counting source ( 11; 21; 30) and at least one scaffold detector (22; 31, 32), at least one of which is moved along a circular circumference and the other is poured into place. 11 94678 Imaging method according to Claim 3, characterized in that a three-dimensional tomogram is used, preferably with a wooden stock (13), for which readings from at least two clips (15, 16) of different directions of intensity are used. obtained from the radiation of the x-ray tube (11) in place, which is measured with at least one detector (12) located on a rotating base (17). Imaging method according to claim 4, characterized in that the detectors (12) are placed on the rotating surface of the outer circumference, such that the other detectors are protected under the radiation shield (8) while the other detectors measure clipping (15, 15). 16). The imaging method according to claim 3, characterized in that the bodies deviating from its density from the density of the material are identified by moving the material flow between a radiation source (21) formed by a radioisotope and a radiation source (21) formed by a radioisotope. the radiation detector (22) in its place, the radiation detector measuring the radiation from conical cutouts (25, 26). 35 Imaging method according to claim 3, characterized in that the shape of the three-dimensional bodies (33) is determined by using as radiation light transmitted with light sources (30) attached to a rotatable base (36), the projection in the direction of the body surface is measured with the help of. a detector (31) located perpendicularly above the imaging aperture (37), and the height is measured from the time difference of darkness between this detector and the corresponding lamp obliquely detecting detector (32), the final image of the width, length and height of the crepe are constructed on the basis of the velocity information from these detectors (31, 32. and the transparent band (35). Imaging method according to any of claims 3-6, characterized in that on a rotatable sub-layer is placed for different radial values radiation detectors, whereby more than three oblique cuts measured for reading the tomogram are attached. The imaging method according to claim 1, characterized in that both fixed, in-line detectors are used at the same time as a rotary detector for measuring the necessary clippings. i *