NL7907806A - Diaphragm system for radiant sources lying in parallel planes. - Google Patents

Description

* PHD 78-148 1 N.V. Philips' * Incandescent light factories in Eindhoven Diaphragm system for radiation sources lying in parallel planes.

The invention relates to a diaphragm system for several radiation sources arranged in at least one plane, of which radiation beams at least approximately cover the same object area of an object, which diaphragm system can be moved in lateral direction, successively for each of the radiation sources of different diaphragm openings for limiting the corresponding radiation beams are provided, with an aperture distribution corresponding to an in-plane radiation source distribution for optimum image transfer.

The diaphragm system contains a flat plate, which is located between the radiation sources and the object. The plate has different groups of fixed aperture openings, the radiation beams passing through each group coming from different radiation sources and covering at least approximately the same object area of an object.

The size of the aperture openings within a group is determined by the distance of the corresponding radiation sources from the plate.

By choosing different groups of aperture apertures, the radiation beams can be adapted stepwise to object regions of different sizes by moving the plate laterally in a corresponding manner. However, because the number of groups of aperture apertures on the plate is limited, the radiation beams can only be adapted to a limited number of different object areas.

A diaphragm device with fixed aperture apertures is thus only of limited use, for example in medical X-ray diagnostics, because the object areas to be examined vary widely in size there. In addition, 79 07 80 6 'i *

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PHD 78-148 2 that in order to reduce the radiation load on the object and to reduce the parasitic radiation, the individual radiation beams must be limited as much as possible so that they radiate only the object area to be examined, if possible.

The object of the invention is to provide a diaphragm device with which the radiation beams of different radiation sources lying in at least one plane lying in a simple manner can be continuously limited.

This task is fulfilled according to the invention in that the diaphragm device consists of a group of at least two diaphragm plates lying parallel to a source plane, each of which is provided with passage apertures for forming diaphragm apertures and arranged laterally with respect to each other .

If the radiation sources are arranged in only one plane (radiation source plane), the diaphragm device can consist, for example, of a group of two diaphragm plates 20, which are arranged to be displaceable in parallel with the radiation source plane.

The diaphragm plates which are displaceable in parallel with each other ensure that the aperture apertures are continuously adjustable in size, so that the radiation beams 25 of the radiation sources can be fully adapted to the size of the object area to be examined. The diaphragm plates therefore have so-called passage openings, the distribution of which on the diaphragm plates corresponds to the distribution of the in-plane radiation sources.

^ The aperture plates are thus displaced relative to each other by parallel shifting of the diaphragm plates, so that they are partly covered by the other diaphragm plate. Thus, the resulting aperture apertures remain.

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The diaphragm plates can herein lie parallel to one another or at a distance parallel to each other, whereby the displacement of the diaphragm plates can take place one after the other or simultaneously. Mechanisms 7907806 * Λ PHD 78-148 3 or E 1 electromechanical devices can be used for this displacement.

A group of diaphragm plates can also have more than two diaphragm plates. The arrangement resp. displacement of the diaphragm plates then takes place in accordance with the manner described above.

By limiting the radiation beams to the object area, irradiation of areas not to be investigated is avoided. This reduces the radiation exposure of the object. Furthermore, this reduces the parasitic radiation generated by the irradiation of the object, whereby the image sharpness and the contrast of the images displaying the object area are increased.

According to a preferred embodiment of the invention, additional groups of diaphragm plates are provided for limiting the radiation beams of radiation sources lying in mutually parallel planes, wherein each time a group of diaphragm plates is added to a surface, and in each case the diaphragm plates of a group have further openings for the 20 radiation beams not allocated to this group. These radiation beams can therefore pass the diaphragm system unhindered at any position of the corresponding diaphragm plates.

If the radiation sources lie in different planes running parallel to each other, it is desirable that, for a continuous delimitation of the radiation beams by means of diaphragm plates, a group of diaphragm plates is added to each surface. The individual groups of diaphragm plates, which may have different distances from each other and from the respective associated surfaces, each have diaphragm apertures of the same size, the size of which may, however, be different in different groups of diaphragm plates. The diaphragm plates are positioned in the beam path in such a way that the passing radiation beams completely cover the same object area of an object to be examined. The diaphragm plates hereby have extra openings for the radiation beams coming from the non-corresponding surfaces. These radiation beams 7907806 *> *

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PHD 78-148 4, however, with each position of the diaphragm plates obtained by parallel displacement, completely pass through the apertures, so that they are not extra limited.

When the object area to be examined is increased or decreased, the diaphragm openings are then opened or closed in accordance with the distance of the groups from the associated surfaces, which necessitates a corresponding parallel displacement of the diaphragm plates. The parallel shift can be performed simultaneously for all 10 diaphragm plates using mechanical resp. electromechanical devices or manual.

The drawing shows embodiments according to the invention.

FIG. 1 shows a diaphragm device consisting of a pair of diaphragm plates, FIG. 2 shows a top view of the diaphragm device according to FIG. 1 and FIG. 3 shows a diaphragm device consisting of two pairs of diaphragm plates.

Fig. 1 schematically shows three X-ray sources 1, 2 and 3 placed in a plane E. These are arranged together as a multiple radiation source in a common tank (not shown). The three X-ray sources 1, 2 and 3 each emit primary radiation beams 4, 5 and 6 which reach a diaphragm device B consisting of two superimposed diaphragm plates B1 and B2. The diaphragm device B herein has diaphragm openings 7, 8 and 9 for limiting 00 of the primary radiation beams 4, 3 and 6 ° P, the radiation beams 10, 11 and 12, which completely cover and almost lie in a superposition plane 13 lying parallel to the plane E. irradiate the same object area 15 lying within an object 14. For example, the object 14 can be a human body. Since the radiation beams 10, 11 and 12 completely cover only the object area 15 to be subducted, the smallest, parasitic volume 16 (7907806 * * PHD 78-148 5 rays) caused by dashed lines is created within the object 14. The radiation beams 10, 11 and 12 may, for example, arrive on a radiation-sensitive recording layer, for example a film 17 or on the input screen of an X-ray image amplifier for generating superposition images.

The two diaphragm plates B1 and B2, which can for instance lie parallel to each other or at a small distance, each have so-called passage openings 7a ·, 8a and 9a and Tb, 8b for forming diaphragm openings 7> 8 and 9 respectively. and 9b, the distribution of which on the diaphragm plates B1, B2 corresponds to the distribution of the X-ray sources 1, 2 and 3 in the plane E. By parallel displacement of the diaphragm plates B1, B2, which are, for example, of lead, the passage openings 7a, b, to 9a, b displaced relative to each other so that they are each partially covered by the other diaphragm plate. In this way, remaining openings are created, which, as diaphragm openings 20, 7, 8 and 9, define the radiation beams 10, 11 and 12.

The diaphragm plates B1 and B2 can be moved relative to each other by hand or with the help of an electromechanical device V.

Preferably, the diaphragm device B is mounted jointly with the displacement device Y on the tank of the multiple radiation source, so that these can be moved along with the multiple radiation source from different directions when the object region 15 is shot.

In FIG. 2 shows the top view of O® the diaphragm device B consisting of two diaphragm plates B1 and B2 according to FIG. 1.Both diaphragm plates B1 and B2, which are, for example, square and of the same size, each have three passage openings 7a, 8a, 9a, respectively. 7t >> 8b, 9¾ which are for example rectangular in shape, have the same dimensions and the long sides of which all run parallel to each other. They are always placed on both diaphragm plates B1 and B2 in such a way that they lie exactly on top of each other in the unaltered position 7907806 * * PHD 78-148 6 of the diaphragm plates B1 and B2.

In this condition, the radiation beams 10, 11 and 12 passing through the diaphragm device B radiate the largest object area 15 · By parallel displacement of the diaphragm plates B1 and B2 in one of the directions indicated by arrows a, b, c or in intermediate directions - the apertures of a diaphragm plate are covered by the different diaphragm plates. In this way diaphragm openings 7> 8 and 9> are created, which are bounded by the edges of two passage openings 1a and b, etc., each time. The aperture apertures 7, 8 and 9 always lie in the center of the primary radiation beams 4, 5 and 6. As a result of the displacement of the diaphragm plates B1 and B2, different object areas 15 can be radiated in size and shape. Of course, each time the diaphragm plates B1 and B2 can also be rotated relative to each other about an axis perpendicular to the plane of the plates, e.g. to form other aperture apertures.

Fig. 3 shows a diaphragm device B 'for radiation sources placed in two parallel surfaces. The X-ray sources 19 and 20 lie in a first plane E1 and are associated with a multiple radiation source 18, while a further X-ray source 21 and a visible light-emitting radiation source 41 are arranged in a second plane E2 below the first plane E1 and parallel to it.

The diaphragm device B * now consists of a first pair of superimposed diaphragm plates B3 and B4, which belong to the radiation sources 19 and 20 lying in plane E1, and the second pair of superimposed diaphragm plates B5 and B6, which belong to the radiation sources 21 and 41 lying in the plane E2. Both pairs of diaphragm plates are here placed under the radiation sources 19, 20, 21 and 41, the pairs being parallel to each other and to the surfaces E1, 35 and E2, and the second pair below the first. Of course, the pairs and planes can also be arranged in another suitable order.

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PHD 78-l48 ~ 7 *

The primary radiation beams 19a and 20a emanating from the X-ray sources 19 and 20 reach the associated diaphragm apertures 36 and 37 located within the first pair of diaphragm plates B3 and B4, which passages are displaced relative to each other (see

Fig. 2) were formed. The diaphragm openings 36 and 37 have the same shape and the same size and are located in the diaphragm plates B3 and B4 in such a way that the apertures respectively pass through them. bounded radiation beams 33 and 34 irradiate the same object area 27 of an object 28 to be examined, respectively. in a superposition plane 23 within the object area 27 completely cover each other. The radiation beams 33 and 34 then reach a radiation-sensitive layer 30, for example an X-ray film, for making superposition images.

In order not to cause the radiation beams 33 and 34 to interrupt through the second pair of diaphragm plates B5 and Bé, there are further openings S2 therein, through which the radiation beams 33 and 34 fully pass in any position of the parallel movable diaphragm plates B5 and B6.

Corresponding apertures S1 are also located in the first pair of diaphragm plates B3 and B4 · for the primary radiation beams 21a and 41a of the in-plane radiation sources E2 and 41. These primary radiation beams 21a and 41a reach through the apertures S1 25 the corresponding diaphragm openings 35 and 42, which are also of the same shape and size, and which were again formed from corresponding parallel displaced passage openings (see Fig. 2). The diaphragm opening 35 lies in the diaphragm plates B5, B6 in such a way that the radiation beam 22 bounded by it has the same object area 27 as the radiation beams 33, 34 and 26, respectively. same superposition plane 23 irradiates completely. The radiation beam 22 resp. the x-ray radiation source 21 hereby serves for the purpose of searching, respectively. setting the intended object area 27 · 35 The light beam 44 bounded by the aperture opening 42 forms on the object 28 a light spot 45, which corresponds to the size of the object area 27 and 7907806 i. * PHD 78-148 8 by means of which the object 28, which lies on a table 29, with displacement in different directions XYZ relative to the radiation beams 22, 33, 34 can also be positioned.

5 According to the distance of the individual diaphragm plate pairs to the planes E1 and E2, to which they belong, different aperture apertures 36, 37 and 35, 42 must be adjusted by parallel displacement of diaphragm plates when the diaphragm of an object area 27 is deenergized, 10 the displacement of the diaphragm plate pairs also depends on this distance. ¥ orders the quotient of the distance d1 of the first plate pair B3 and B4 to the plane E1 and the distance d2 of the superposition plane 23 to the plane E1 equal to the quotient of the distance d3 of the second diaphragm plate pair B5 and B6 to the plane E2 and the distance d4 from the superposition plane 23 to the plane E2 selected, then the following applies .....

dl = d2, d2 d4 20, for apertures of the same size in both diaphragm plate pairs, the diaphragm plates B3, and B5 resp. B4 and B6 are mechanically fixed together for even movement.

25 30 1 7907806 ...........

Claims (7)

1. Diaphragm system for several radiation sources placed in at least one plane, the radiation beams of which cover at least approximately the same object area of an object, which diaphragm system, which can be moved in the lateral direction, succeeds for each of the radiation sources of different aperture apertures for limiting the corresponding radiation beams are provided, wherein a distribution of the aperture apertures corresponds to a distribution of the in-plane radiation sources for optimal image transmission, characterized in that the diaphragm system (b) consists of a group of at least two parallel to the diaphragm plates (B1 and B2) lying flat (E), each of which are provided with passage openings (7a, b-9a, b) for forming the diaphragm openings (7, 8, 9) and can be moved laterally with respect to each other lined up. 2. Diaphragm device according to claim 1, characterized in that additional groups of diaphragm plates are provided for limiting the radiation beams of radiation sources lying in mutually parallel surfaces (E1 and E2), each group comprising a group of diaphragm plates, and that the diaphragm plates each have a group of further openings (S1, S2) for the radiation beams 25 coming from the surfaces not belonging to this group, which completely pass through the openings at each position of the corresponding diaphragm plates. Diaphragm device according to claims 1 and 2, characterized in that the groups consist of pairs of diaphragm plates. Diaphragm device according to Claims 1 to 3, characterized in that the diaphragm plates (B1 and B2) are mechanically connected to each other by a pair via a displacement device (v) for performing a coupled movement. Diaphragm device according to Claims 2 and 3, characterized in that the diaphragm plates on one side of the pairs are mechanically connected for simultaneous displacement 7907806 PHD 78-148 10 V *. Diaphragm device according to claim 3, characterized in that the diaphragm plates lie in pairs directly against each other. 5 Diaphragm device according to claim 1, characterized in that the passage measurements are rectangular. 15 20 25 30 35 7 907 806