RU2072575C1 - Device for control of x-ray and gamma beams - Google Patents

Abstract

FIELD: X- ray and gamma ray focusing and collimating in diffraction meters, tomographs, lithographic devices. SUBSTANCE: device has cylindrical housing, in which axial-symmetry body is located. Said body has two parts, one of which has barrel-shaped concave coaxial layers of capillaries; its another part has convex capillary layers. On output end of concave part ends of capillaries are directed to point, while capillaries of convex part has varied diameter along their length. Concave and convex parts of body have clamping units which are connected to housing and are mounted in it coaxial with space provided between input end of convex part and output end of concave part. Convex part has lesser number of capillaries than concave part and has mechanism for its axial movement. EFFECT: increased functional capabilities. 4 cl, 1 dwg

Description

 The invention relates to technical physics and can be used for focusing and collimation of x-ray and γ-quanta.

 A device for forming a converging beam of x-ray or γ-radiation (ed. St. USSR N 1536448, class G 21 K 1/02, publ. 15.05.90), containing a conical focusing collimator with many collimation channels and located on the side of it wide base primary beam converter. Moreover, the collimation channels are made with a variable aperture, increasing in the direction from the center of the collimator to its periphery.

 The disadvantage of this device is the large loss of radiation at the entrance to the collimator, since the area of the inlet of the collimator is an order of magnitude smaller than the area of the base of the body of the collimator. In addition, the collimator provides focusing only from a source having a large radiation surface, and also does not allow to obtain a quasi-parallel radiation beam, which reduces its scope.

 There is another device for focusing x-ray radiation (ed. St. USSR N 1324072, class G 21 K 1/06, publ. 15.07.87), containing the base and two autonomous buildings. Each housing has two fixed cylindrical supports with design diameters depending on the X-ray optical scheme of the monochromator and the place of support along the beam axis. On each pair of supports from two sides two mirrors are symmetrically supported, pressed by movable supports, which are affected by plates, the movement of which is carried out by a pressure screw. The plates are spring-loaded with springs, and their lateral displacement is limited by guides.

 The disadvantage of this device is that it can provide focusing of photons only from a source having a small radiation surface and, thus, does not allow to obtain an x-ray beam of significant aperture. In addition, the device does not allow to obtain a quasi-parallel microbeam of photons, which reduces its scope.

 The closest technical solution (prototype) is a device for controlling beams of x-ray and γ-radiation (international application N 92/08235, CL G 21 K 1/00, publ. 05/14/92), including a housing in which two axisymmetric coaxially mounted bodies, separated by gaps, equipped with attachment points to the body and consisting of capillaries-X-ray tubes, made with a variable diameter along the length and arranged in layers having convex and concave sections.

 The disadvantage of this device is the complex technology of its manufacture and significant loss of radiation during passage through the focusing system. In addition, the device does not allow to change the width of the output concentrated microbeam of photons, which reduces its scope.

 The objective of the invention is the creation of such a device for controlling beams of x-ray and γ-radiation, which would have a simple manufacturing technology and would reduce radiation losses when passing through the focusing system, and would also allow changing the width of the output concentrated microbeam of radiation to expand the scope of the device.

 The problem is solved in that the device comprising a cylindrical body in which two axisymmetric bodies are mounted coaxially, separated by a gap, provided with attachment points to the body and consisting of x-ray capillaries made with a diameter variable in length and arranged in layers having convex or concave sections according to the invention, the first body has barrel-shaped convex layers of capillary X-ray tubes, and the second body has concave layers of capillary X-ray tubes, the second body compared to the first body m is satisfied with a smaller number of capillaries.

 The attachment site of the second body to the body has a mechanism for axial movement of this body relative to the body.

 At the exit end of the first body, the capillaries are oriented to a point.

 The angles of inclination to the axis of the device of the outer layers of capillaries at the exit end of the first body and at the input end of the second body are made equal to each other.

 In addition, the device is equipped with a set of interchangeable second bodies with concave layers of capillaries having different diameters of the input and / or output ends.

 The implementation of the second body of the device with fewer capillaries can significantly simplify the manufacturing technology of the device. Both axisymmetric bodies can be made of different materials and select simpler manufacturing techniques. The proposed device design allows you to perform the first body, for example, by layering capillaries and fixing them with an adhesive composition, and the second body by temperature softening and drawing out a package of glass capillaries. From experimental data it is known that with a decrease in the number and length of capillaries in the bag, the drawing technology is greatly simplified. The diameter of one capillary during the drawing process in the prototype must be reduced by 100 or more times to obtain the output end of the focusing system with a width of not more than 1 mm, and the proposed device - not more than 10 times to obtain the output end of the focusing system of the same size. In addition, the implementation of the composite body allows the use of capillaries with thinner walls during its manufacture, which reduces radiation losses at the entrance to the body capillaries. When photons pass through the proposed device, one part of the path they pass through the capillaries due to total external reflection from the wall surface, and the second part of the path through the air layer in the gap between the convex and concave parts of the body, which significantly reduces radiation loss compared to the prototype, where the focus radiation is produced only due to the complete multiple external reflection of photons from the inner surface of the capillaries.

 A set of interchangeable second bodies with concave layers of capillaries allows you to expand the functionality of the device and its scope, as this ensures a change in the width of the output radiation beam without replacing the main parts of the device.

 The mechanism of axial movement of the concave part of the body increases the usability of the device, allows you to quickly configure it.

 Setting the ends of the capillaries at one point at the output end of the first body, as well as equal tilting of the outer layers of the capillaries to the axis of the device at the input end of the second body and at the output end of the first body, reduces radiation losses at the entrance to the second body, since the bulk of the photons it enters either along trajectories parallel to the axis of the capillaries, or at angles close to the angle of total external reflection of the photons. In addition, the second body can be made in the form of a single capillary with a diameter variable in length, the input end of which is installed in the focus of the x-ray beam emerging from the capillaries of the first body.

 The drawing shows a diagram of a device for controlling beams of x-ray and g-radiation.

где D₁ диаметр выходного конца первого осесимметричного тела;
D₂ диаметр входного конца второго осесимметричного тела;
α угол схождения пучка фотонов в фокус на выходе из первого тела.A device for controlling x-ray and g-ray beams includes a cylindrical body 1, in which two axisymmetric bodies are assembled, assembled from concentric layers of capillary-x-ray tubes. The first body 2 is made with barrel-shaped convex layers of capillaries 3, and the other body 4 with concave layers of capillaries 5. Body 2 and body 4 are equipped with attachment nodes 6, 7 to the housing 1 and are mounted coaxially and with a gap (H) formed between the output end 8 body 2 and the input end 9 of body 4. Body 4 is made with fewer capillaries 5 compared to the number of capillaries 3 of body 2. The capillaries 5 of body 4 are tightly packed and have a variable diameter, decreasing towards the output end 10 of this body. At the input 11 and output 8 ends of the body 2, the ends of the capillaries 3 are oriented to a point (focus). The angle a _{1 of the} inclination to the axis of the device of the outer layer of capillaries 3 at the output end of the body 2 is made equal to the angle α _{2 of the} inclination of the outer layer of the capillaries 5 to the axis of the device at the inlet end of the body 4. In addition, the device is equipped with a set of replaceable axisymmetric bodies 4 having different input diameters 9 and weekend 10 ends. The node 7 of the attachment of the body 4 to the housing 1 and the axial movement of this body 4 relative to the housing 1 contains a ring 12 mounted in the housing 1 coaxially to it. In the wall of the housing 1, several through longitudinal slots 13 are evenly spaced along the perimeter 13. The ring 12 is provided with radially mounted screws 14, the heads 15 of which are brought out through the slots 13 to the outer side of the housing 1, and the ends of the screws 14 are passed through the through holes with a thread in the ring 12 and have elastic elements 16 pivotally attached to them. In addition, the screws 14 are equipped with lock nuts 17 installed between the housing 1 and the heads 15 of the screws 14. The gap (H) between the body 2 and the body 4 can be determined experimentally or by the formula:

where D _{1 the} diameter of the output end of the first axisymmetric body;
D _{2 the} diameter of the input end of the second axisymmetric body;
α the angle of convergence of the photon beam into focus at the exit from the first body.

With the correct manufacturing technology of the device, the following equality of angles is observed: a ₁ = α ₂ = α / 2
Bodies 2 and 4 can be made of different materials using the most optimal assembly technologies. For example, the body 2 can be assembled by layering the capillaries 3 and fixing them with an adhesive composition. The number of capillaries 3 with an external diameter of 0.4 mm will be required with up to 2 6 thousand pieces. A body 4 with a smaller (10 or more times) number of glass capillaries 5 is made, for example, by temperature exposure of a packet of capillaries until the glass softens, followed by drawing of the packet, in which the capillaries acquire a diameter that is variable in length and bend in layers, tapering to the outlet end. The output end 10 of the body 4 may have a diameter of not more than 1.0 mm

 Before starting the operation of the device, the body 4 is selected with the required diameters of the input 9 and output 10 ends and installed in the housing 1 using the mount 7. By moving the ring 12 in the housing 1, the device is aligned, setting the required clearance (H) between the body 2 and the body 4.

 The device operates as follows.

 A beam of x-ray or gamma quanta enters the capillaries 3 and passes through them, experiencing multiple total reflections on the mirror internal walls of these capillaries 3. At the exit from the body 2 of the device, the diverging quantum beam is converted into a converging beam, which, passing through the air gap (H), decreases cross section (focuses) and enters the capillaries 5 of body 4. In body 4, the quantum beam also experiences multiple total reflections on the mirrored internal walls of the capillaries 5 and is converted to quasi-parallel at the output end 10 The first microbeam of quanta, which can later be used, for example, in X-ray diffractometry for the study of materials.

 Thus, the proposed device in comparison with the prototype and known analogues simplifies the technology of its manufacture by making the body composite with a different number of capillaries in the bodies 2, 4. According to estimates, due to the possibility of reducing the thickness of the walls of the capillaries by 2 times, the loss of photons in water the capillaries are reduced from 25 (in the prototype) to 10 in the proposed device. The composite body of the device allows 1.5 to 2 times reduce the length of the passage of quanta through the capillaries by providing the main stage of focusing radiation in the gap (H) between the axisymmetric bodies of the device, which also reduces radiation loss.

 The invention can be applied in industrial technology, medicine and scientific research, in particular, in diffractometers, tomographs, etc. for focusing and collimation of x-ray and γ-quanta.

Claims (4)

 1. A device for controlling beams of x-ray and gamma radiation, including a cylindrical body, in which two axisymmetric bodies are mounted coaxially, separated by a gap, provided with attachment points to the body and consisting of capillaries-x-ray tubes made with variable diameter channels and arranged in layers, moreover, the first body has barrel-shaped convex layers of capillaries, and the second body concave layers of capillaries, characterized in that the capillaries at the output end of the first body are oriented to a point, and the second body is Compared with the first one, it was performed with fewer capillaries.  2. The device according to claim 1, characterized in that it is equipped with a set of replaceable second axisymmetric bodies with concave layers of capillaries having different diameters of the input and / or output ends.  3. The device according to claim 1, characterized in that the attachment point of the second body to the body has a mechanism for axial movement of this body relative to the body.  4. The device according to claim 1, characterized in that the angles of inclination of the outer layers of the capillaries to the axis of the device at the input end of the second body and at the output end of the first body are made equal to each other.