NL1016402C2 - Radiation source storage container includes shielding body with support containing core inside bore for forming storage channel - Google Patents

Abstract

A radiation source (4) is stored inside a channel (8) at least partly formed by a core (14) present inside a bore (B) formed in a support (12) for the shielding body (6). A channel container (2) for storing a radiation source comprises a shielding body made from radiation absorbent material, inside which a channel with a bend in it is formed. During use, the radiation source is secured to a wire which is then used to pull the radiation source into the channel. The shielding body includes a support body with a bore containing a core body. At least part of the channel is present inside the core body. Independent claims are also included for the following: (a) a channel container with a spiral-shaped channel; (b) a channel container with a shielding body made from a tungsten alloy; (c) a method for making these containers by forming a groove in the mantle surface of the core body; and (d) a method for storing a radiation source by keeping it inside a spiral groove.

Description

Title: Channel container for storing a radioactive source

The invention relates to a channel container for storing a radioactive source, comprising a shielding body of radiation-absorbing material in which a channel with a bend is arranged, wherein, in use, a radioactive source which is attached to a wire using the wire can be slid into the channel for storing the source.

The invention further relates to a method for manufacturing a channel container according to the invention.

Furthermore, the invention relates to a method for storing a radioactive source.

Said channel container is known from practice and is used for storing radioactive sources. Examples of such radioactive sources are an iridium 192 isotope and a cobalt 60 isotope. An object can be exposed with the γ-radiation from the radioactive source, whereby an image of the object is projected on a radiation-sensitive screen. A possible object is a weld with which pipe sections are welded together. When illuminating this, welding errors can be detected and corrected early.

The radioactive source used, however, is permanently active and emits a radiation level to its immediate environment that exceeds the applicable safety standards. It is therefore desirable to place the source in a shielding body when it is not used for exposure purposes. The source can thereby be placed in a channel container with a screening body which is provided with a channel 25 with a bend. This bend is a so-called S-bend, which is located in a flat plane. If the source is placed in the middle of the S-bend of the channel, there is material from the source viewed in all directions from the shield body between the source and the environment outside the i Q 3 Γ \ Om #

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2 channel container. The material of the screening body here serves to at least largely absorb the radiation from the source. In particular, the S-bend included in the channel prevents "leakage radiation" from the source through the channel to the environment. With the measures discussed, it is achieved that the radiation outside the shielding body can meet the said safety standards.

If a user wants to illuminate an object with the source, the source can be pushed by the user at a safe distance through the channel outside the shielding body with the aid of the wire.

Subsequently, the exposure of the object can take place with the aid of γ radiation from the source.

A drawback of the known channel container described above is that the screening body is made of environmentally unfriendly material. In the past, shielding bodies were often made of lead. Lead is not only environmentally unfriendly but also has the disadvantage that it melts at relatively low temperatures, which temperatures can occur in a fire. Furthermore, it is a relatively soft material that can deform even under an impact load due to its own weight. Nowadays, shielding bodies are therefore mainly made from depleted uranium. Said channel in the shielding body is provided during sintering during manufacture.

However, depleted uranium is a toxic, environmentally unfriendly material that also has a major drawback that it can act as a radioactive source. It is therefore in many countries prescribed by the government to register uranium channel containers as a source of radiation, which entails administrative actions and safety measures. Furthermore, after use, the processing of these channel containers into waste must take place in a special, expensive manner. It is therefore desirable to provide a channel container made from an environmentally friendly, non-radioactive material that also has a good shielding effect from radioactive radiation. This latter requirement can be met with a material with a relatively high specific gravity. A very suitable material that has all of the aforementioned desired properties is a tungsten alloy. However, with materials of this type, when manufacturing the shield body (as opposed to materials such as lead and uranium), the problem arises that the S channel cannot be provided in the shield body during sintering. This limitation is in practice an obstacle to the manufacture of 10 channel containers from environmentally friendly material.

The invention has for its object to provide a solution to the above-described problem and therefore provides a channel container of the type mentioned in the preamble which is characterized in that the screening body comprises a bearing body with a bore in which a core body is accommodated, the channel at least partially the core body is arranged. This makes it possible to form the channel through separate machining of the core body, so that the channel does not have to be provided during sintering. The shape of the core body can be chosen such that it is relatively easy to machine. The channel can then, for example, be provided in the interior of the core body by means of a drilling operation or by means of spark machining. The channel can also be provided by machining in the lateral surface of the core body and be formed by cooperation of the core body with the support body or by cooperation of sub-bodies of the core body.

In a preferred embodiment of the channel container with a core body according to the invention, it holds that the channel extends helically. With this channel shape, it is possible to screen radioactive sources in the screening body better from the immediate environment 4 than with the known type of channel shapes with a two-dimensional S-bend. The "leakage radiation" already mentioned is thereby further reduced. A further elaborated variant of the said preferred embodiment is characterized in that the channel extends substantially in a longitudinal direction, the channel describing a rotation about a longitudinal axis with a fixed pitch. It is desirable here that the angle of rotation about the longitudinal axis, along the length of the channel, be at least 90 °.

A favorable embodiment of the channel container with a core body according to the invention has the feature that the core body has a cylindrical shape, wherein the channel is arranged on the lateral surface of the core body. Such a type of core body can be manufactured from various types of material because the provision of the channel only requires that the core body can be machined to the jacket surface. A spatially curved, three-dimensional channel can thus be realized in the core body in a simple manner, with which the desired shielding properties are achieved. In particular, it is thus possible to manufacture the channel container according to the invention from a tungsten alloy. For this purpose, the support body of the shielding body is made from the tungsten alloy, a bore being made in the support body. The cylindrical core body of the shielding body is also manufactured from the tungsten alloy, the channel being arranged in the core body. The core body is then received in the bore 25. A special channel container according to the invention is embodied in an alloy characterized in that this alloy comprises tungsten, nickel and iron. A further elaborated embodiment is characterized in that the alloy comprises 90-98 mass percent tungsten, 1-5 mass percent nickel and 1-5 mass percent iron. Examples of such an alloy are the commercially available densimet 176 and the densimet 185.

"· -Λ ·· 5 alloy. With these alloys a suitable compromise is reached between mechanical strength and hardness of the material on the one hand and sufficient workability of the material on the other. A channel container made from this material has good shielding properties of radioactive radiation and is also resistant to deformations in the event of an impact load due to its own weight.

A possible embodiment of the channel container with a core body according to the invention for storing a radioactive source comprises a screening body in which a channel with a bend is arranged, wherein, in use, a radioactive source which is attached to a wire by means of the wire can be slid into the channel for storing the source, characterized in that the channel extends helically. This second alternative embodiment provides a three-dimensional, spatially curved channel, so that, due to the geometry of the channel, the screening body has favorable screening properties. In a simple embodiment, the channel is in the form of a twisted S. The channel container is made of a material that is suitable for shielding a radioactive source, and can, for example, also be made entirely of sintered material.

Another embodiment of a channel container according to the invention for storing a radioactive source, comprising a screening body in which a radioactive source is arranged, is characterized in that the screening body is made of a tungsten small. This embodiment provides a channel container of environmentally friendly material. Such channel containers do not have to be registered with the government and only pose a small burden on the environment when the channel containers ultimately have to be processed into waste.

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An embodiment of a method according to the invention for manufacturing a channel container with a core body according to the invention is characterized in that the method comprises at least the following step: providing a slot in a lateral surface of a core body of a channel container.

A core body can thus be manufactured from a suitable material, whereafter the core body is placed in the bore of the carrier body of the shielding body while forming the channel. Optionally, the core body is hereby fixed in the bore by means of a pin-hole connection.

A further embodiment of this method for manufacturing a channel container with a core body is also characterized in that the slot is milled with a cutter which is rounded off at a cutter end, projected on a plane perpendicular to a longitudinal direction of the core body. to provide. A channel with a U-shaped cross-section is hereby arranged in the jacket surface, wherein the bottom of the slot, which bottom is furthest away from the support body, is made round. With this geometry, a cylindrical shape of the source can be better followed, so that the shielding properties of the shielding body can be further improved.

An embodiment of a method according to the invention for storing a radioactive source is characterized in that a radioactive source is stored in a spatially curved, helical groove. The helical groove has a favorable geometry for shielding radiation from the radioactive source of the environment and minimizing "leakage radiation".

Further advantageous embodiments of the invention are shown in the subclaims. It is noted that in this context, a channel can have both an open and a closed cross-section.

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The invention will now be further elucidated with reference to the drawing. Herein: figure 1 schematically shows a longitudinal section of a channel container with a core body according to the invention; Figure 2A schematically shows a longitudinal section of a core body of a channel container in which a channel is arranged; figure 2B schematically shows a cross-section of a core body of a channel container according to the invention in which a channel with a rectangular profile is arranged; Figure 2C schematically shows a cross-section of a core body of a channel container according to the invention in which a channel with a rounded bottom is arranged.

Figure 1 shows schematically a longitudinal section of a channel container 2 for storing a radioactive source 4. The channel container 2 is provided with a screening body 6 in which a channel 8 with a bend is arranged. The shielding body 6 is made of a material that is suitable for at least largely blocking radioactive radiation through absorption. Preferably this material is a tungsten alloy. This is an environmentally friendly, oxidation-insensitive material with a relatively high specific gravity and therefore has good shielding properties. A favorable tungsten alloy here comprises tungsten, nickel and iron.

The radioactive source 4 is attached to a wire with which the source 4 can be moved back and forth through the channel 8 of the shielding body 6. When the radioactive source 4 is at the center of the bend of the channel 8, according to the situation shown in Figure 1, the shielding body 6 will at least largely stop radiation coming from the source 4 in all directions, so that the immediate surroundings of the channel container 2 is not exposed to a high radiation dose.

Any "leakage radiation" occurring here through the channel 8 to the environment is prevented by the bend included in the channel. When a user wants to illuminate an object with the source 4, the source 4 can be pushed by the user, who is at a safe distance, outside the shielding body 6 of the channel container 2 by means of the wire 10, after which the said exposure can take place. The wire 10 is thereby preferably guided through a flexible hose.

The screening body 6 of the channel container 2 comprises a support body 12 in which a bore B is arranged. The bore B can be made after manufacture of the screening body, for example by means of a drilling operation. Also, when it has a simple shape, such as a cylindrical shape, the bore B can be formed with the support body 12 even with a material that is difficult to sinter. A core body 14 is placed in the bore B of the support body 12. The core body 14 is preferably cylindrical, the channel 8 being arranged as a slot in the lateral surface of the core body. The channel 8 in the channel container 2 therefore extends three-dimensionally helically. With this spatially curved geometry it is achieved that the leakage radiation, from the source 4 via the channel 8 to the immediate surroundings of the channel container 2, is further reduced than in the case of a flat surface, two-dimensional S bend.

It is desirable that, viewed from the source, there is approximately the same amount of screening material of the screening body 6 in all directions between the source and the environment outside the channel container. This is achieved with the channel container in Figure 1, inter alia, in that the bore B is arranged eccentrically in the carrier body 12 in the manner shown in this figure. As a result, in the stored state, see Figure 1, the source is located in the center of a fictional sphere, which sphere is defined by the outer surface of the shielding body 6. Here, it holds that D1 is approximately equal to D2. The radius of the fictional sphere is approximately Di.

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The core body 14 is held in the bore B by two cover caps 15 which are respectively attached to the support body 12 near the respective outlets of the bore B. Optionally the core body 14 is connected to at least one cover cap 15 by means of a pin-hole connection, as a result of which the core body 14 cannot rotate in the bore B.

Figure 2A schematically shows a cross-section of a cylindrical core body 6 in which the course of the channel 8 is indicated. The schematic cross-section of the core body 6 as shown in Figure 2B shows that the channel is arranged as a slot 16.1, with a rectangular cross-section, on the lateral surface of the cylindrical core body 6. The channel 8 formed with the slot 16.1 extends substantially in a longitudinal direction (according to arrow P in Fig. 2A), the channel 8 describing a revolution with a preferably fixed pitch 15 about the longitudinal axis (longitudinal axis in the direction of P). Here, the channel 8 in Figure 2A, measured over the length L of the channel, makes an angle of rotation α of approximately 270 degrees. However, it is equally possible to arrange channels with a different angle of rotation in the core body 6. However, the angle of rotation is preferably at least 90 degrees.

Figure 2C is a cross-section of a core body 6, wherein the slot 16.2 is provided with a rounded bottom. This can be achieved by using a cutter with a rounded end when arranging the slot in the core body 6. With the resulting geometry 25 of the channel 8, leakage radiation via the channel 8 can be reduced to a further extent.

The invention has been described with reference to a few preferred embodiments. However, as is evident to a person skilled in the art, various embodiments are possible which also fall within the scope of the invention. For example, an embodiment of a channel container with a core body is conceivable in which, to form a channel with one or more bends, a plurality of boreholes are provided in the core body, the boreholes being in communication with each other.

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Claims (15)

A channel container for storing a radioactive source, comprising a shielding body of radiation-absorbing material in which a channel with a bend is arranged, wherein, in use, a radioactive source which is attached to a wire with the aid of the wire can pass through the channel can be slid for storing the source, characterized in that the shielding body comprises a carrying body with a bore in which a core body is received, the channel being arranged at least partially in the core body. 2. Channel container according to claim 1, characterized in that the core body comprises several sub-bodies. 3. Channel container according to claim 2, characterized in that the sub-bodies form the channel through cooperation. Channel container according to one of the preceding claims, characterized in that the channel extends helically. Channel container according to claim 4, characterized in that the channel extends substantially along a longitudinal direction, the channel describing a rotation about a longitudinal axis in the longitudinal direction with a fixed pitch. Channel container according to claim 5, characterized in that an angle of revolution of the channel about the longitudinal axis, along the length of the channel, describes an angle of at least 90 ° degrees. Channel container according to one of the preceding claims, characterized in that the core body has a cylindrical shape, the channel being arranged on the lateral surface of the core body. Channel container according to one of the preceding claims, characterized in that the shielding body is made of a tungsten alloy. 9. Channel container as claimed in any of the claims 1-7, characterized in that the screening body is made of an alloy, which alloy comprises a tungsten alloy, nickel and iron. 10. Channel container as claimed in claim 9, characterized in that the alloy comprises 90-98 mass percent tungsten, 1-5 mass percent nickel and 1-5 mass percent iron. 11. Channel container for storing a radioactive source, comprising a shield body of radiation-absorbing material in which a channel with a bend is arranged, wherein, in use, a radioactive source which is attached to a wire with the aid of the wire can pass through the channel be shifted for storing the source, characterized in that the channel extends helically. 12. Channel container for storing a radioactive source, comprising a shielding body of radiation-absorbing material in which a channel with a bend is arranged, wherein, in use, a radioactive source which is attached to a wire can be passed through the channel with the aid of the wire. can be slid for storing the source, characterized in that the shielding body is made of a tungsten alloy. A method for manufacturing a channel container according to the invention, characterized in that the method comprises at least the following step: 5. arranging a slot in a lateral surface of a core body of a channel container. 14. Method as claimed in claim 13, characterized in that the slot is milled with a milling cutter which is provided with a rounding on a milling end projected on a plane perpendicular to a longitudinal direction of the core body. A method for storing a radioactive source, characterized in that a radioactive source is stored in a helical groove.