PL218983B1 - Working container for isotopic sources - Google Patents

Description

Description of the invention

The subject of the invention is a working container of isotope sources intended for use in research and measurement devices based on the phenomenon of low and medium energy gamma radiation absorption.

The working container of isotope sources known from the Polish application P.379777 of the invention consists of an upper part and a lower part, filled inside with a material strongly absorbing low and medium energy gamma radiation. In the upper part there is an isotope socket and a rotating cylinder-shaped screen. On the side surface of this cylinder there is a collimation hole through its center. The roller is inseparably connected to one end of the control roller, at the other end of which there is a two-position ball latch. The slide bearings of the control shaft are placed in a plug that closes the upper part of the container. The upper part of the container has a centrally located through hole.

Known from the Polish description of the utility model Ru 55774 is a shield for medical syringes with a radioactive solution, which has a lead body made in the shape of a sleeve. At the end of the sleeve there is a brass outer ring with a radially positioned locking screw with a knurled head. On the opposite side of the body there is a lead glass sight glass.

From the Polish application P.372052 of the invention, there is known a reservoir for a vial with a radioactive drug and a set for its transport or for its infusion in a patient, in which the disclosed polymethyl methacrylate reservoir consists of a reservoir with a space suitable for placing a vial of a radioactive pharmaceutical, and a lid screwed onto the tank to close it. The cover has a central through hole.

Also known from the Polish application P.375052 of the invention is a protective pharmaceutical isotope container and a method of its use, in which the protective container is used to transport a syringe containing a liquid radio-pharmaceutical. The protective container has a lid that is detachably attached to the base. Shielding elements are closed in the lid and the base. An inner liner may be used in the base of the container.

The working container of isotope sources, consisting of two parts filled with material absorbing isotopic radiation, the upper one with a collimation hole, with an isotope seat and a detachable element closing this part, and the lower one, according to the invention, has a second isotope seat in the collimation hole. These sockets are spaced apart from each other, have different diameters and are connected by a common axis of the collimation hole. Preferably, the second isotope seat is located in the collimation opening of the lower part of the container. The collimation opening is two-part, in the upper part it is two-stage, with the present diameter on the outlet side and the larger diameter on the side containing the first isotope socket, and a single stage in the upper and lower part containing the second isotope socket. The diameters and lengths of the collimation hole are adapted to the type of isotopes used and the geometrical dimensions of their capsules. The first isotope nest contains the americium isotope and the second isotope nest contains the cesium isotope. The upper part of the container has the shape of a cylinder turning into a cylindrical truncated cone and joins the lower cylindrical part with a truncated cone.

Placing isotopes of different diameters in two sockets distant from each other and adjusting the diameters of the collimation hole to the diameters of these isotopes prevents the loss of up to 40% of the active area of the isotope with a larger diameter and prevents obtaining a beam of radiation of a poorly collimated isotope with a smaller diameter. On the other hand, adjusting the length of the collimation hole to the individual length of the collimation path of each isotope prevents further loss of the radiation beam of these isotopes and thus results in their effective use in measurements and tests. The shape of the upper and lower parts of the container allows for its economical implementation.

The subject of the invention is shown in an exemplary embodiment in the drawing showing the container in an axial section.

The container consists of two parts 1, 2 connected by a collimation opening 3. The upper part 1 and the detachable element 4 closing it and the lower part 2 are filled with material 5 absorbing isotopic radiation. Each of the parts 1, 2 has in the collimation hole 3 one, spaced apart, 6, 7 isotope socket, connected by a common vertical axis 8 of this collimation hole 3. The isotope 6 in the upper part 1 has a diameter greater than the 7 isotope socket in the lower part 2. The collimation opening 3 in the upper part 1 is two-stage, with a smaller diameter

PL 218 983 B1 from the side of the outlet and the larger diameter from the opposite side, containing the 6 isotope socket with the americium 9 isotope, and the single-stage in the upper and lower parts 1, 2 containing at its bottom the second 7 isotopic socket with the cesium 10 isotope 10. Diameter and length of the opening collimation 3 are matched to the type of isotopes 9, 10 of americium and cesium used. The upper part 1 on the outlet side has the shape of a cylinder transforming into a cylindrical truncated cone. The lower part 2 joining the upper part 1 has the shape of a cylinder with a truncated cone.

The gamma rays from the isotopes: americium 9, low energy and cesium 10, medium energy, from the working container of isotope sources placed under the conveyor belt, pass through the carbon layer on this conveyor and go to the scintillation probe located above the conveyor belt. The value of the attenuation of gamma radiation fluxes read in the probe allows to determine the height of the carbon layer and its ash content.

Claims (6)

1. A working container of isotopic sources consisting of two parts filled with material absorbing isotopic radiation, the upper one with a collimation hole, isotope seat and an element closing this part, and the lower one, characterized in that it has a second isotope seat (7) in the collimation hole (3) , wherein the isotope seats (6, 7) have different diameters and are spaced apart from each other and are connected by a common axis (8) of the collimation opening (9). 2. A container according to claim The method of claim 1, characterized in that the second isotope seat (7) is located in the collimation opening (3) of the lower part (2) of the container. 3. A container according to claim The collimation opening (3) is two-part, in the upper part (1) it is two-stage with a smaller diameter from the outlet side and a larger diameter from the side containing the first isotope seat (6), and one-stage in the upper and lower part (1) , 2) housing a second isotope seat (7). 4. A container according to claim 1 The method of claim 1, characterized in that the diameters and lengths of the collimation opening (3) are matched to the type of isotopes used and the geometrical dimensions of their capsules. 5. A container according to claim 1 The method of claim 1, wherein the first isotope seat (6) houses an americium isotope and the second isotope seat (7) houses the cesium isotope. 6. A container according to claim 1 A device according to claim 1, characterized in that the upper part (1) has the shape of a cylinder turning into a truncated cone ending with a cylinder and joins the lower part (3) in the shape of a cylinder ending a truncated cone.