KR200162877Y1 - Transportation appararus for radioisotope irradiation chamber - Google Patents

Abstract

The present invention is connected to the carrying cable (3), the connecting grip (5), the connecting grip (5) is attached to the transport hook (9) for the radiation source disk irradiation container (7), the carrying hook (9) A radioisotope irradiation vessel composed of a support (11) configured to guide the carrying hook (9) in a state where the irradiation vessel (7) is placed so that the irradiation vessel (7) can be easily fixed and fixed. With respect to the draw-out and transport mechanism (1), it makes it easier to attach and detach the irradiation container to the transport cable when transporting the radioactive isotope charging container in the working pool.

Description

Radioisotope Retrieval Containers

The present invention relates to a radioactive isotope irradiation container withdrawal and transport mechanism, and more specifically, to produce a radiation source disk that can be used by the general public by irradiating a small iridium disk and several kinds of elements with neutrons The present invention relates to a transport vessel transport mechanism in the form of a hook that is charged with a container and charged into a reactor hole of a nuclear reactor to be irradiated with neutrons, or is removed from the hole and transported to a work bench.

The range of use and technology of radioisotopes is rapidly evolving today, and despite the tendency to generally dislike radiation from radioisotopes, this high usage is due to the inherent properties of radioisotopes. Representative among them is that it can sufficiently emit radiation having a small amount and strong penetrating power, and can be used in industrial and various fields therefrom.

This means that radioactive isotopes are energy sources with little or no mass and that is why they make a distinct contribution to industry, medicine and scientific research. As of 1995, more than 1,000 companies using radioisotopes were radiodestructive tests, radioisotope gauges, industrial radiotracers, in-vivo diagnostics and treatments, in vitro diagnostics, in vitro radiation therapy, radiation sterilization, radiological food investigation, and radiation genetic engineering. The use of radioactive isotopes in various forms, such as research, contributes to the development of industrial technology, productivity improvement, pollution prevention, industrial safety, medical technology development and welfare, food production and food preservation, and basic science development. It is true.

However, in order to enjoy the full benefits of using radioactive isotopes, the supply must be smooth. Then, domestic radioisotopes must be able to be sufficiently supplied to satisfy demand. Radioactive isotopes can be produced from nuclear reactors or accelerators, but unfortunately in Korea, only 2MW small research reactors have been operated until recently. Only medical microtrons in hospitals have been in operation. In addition, accelerators are generally only used for the production of medical short-lived radioisotopes, which could be expected to be used as research reactors to meet the overall radioactivity requirements.

In order to increase the self-sufficiency of the radioisotopes required in Korea, multipurpose research reactors have been developed in order to increase the supply of radioactive isotopes in order to achieve overall development in science and technology such as industrial technology, medical technology, basic science, industrial safety, and environmental conservation. In addition, as a part of research and development for mass production of radioisotopes using medium-sized nuclear reactors, auxiliary equipment suitable for mass production has also been developed. In other words, since it is impossible to increase the production efficiency of radioisotopes in the manner used in the related art, accompanying development of auxiliary equipment or handling equipment was required.

Developed as one of these supplementary equipment, it is a target irradiation container that can be irradiated by charging a large amount of material at the same time depending on the type of element, and also a reactor and neutron irradiation for neutron irradiation by inserting an irradiation container. It is a pool where work benches are installed for the work before and after.

As shown in FIGS. 1 and 2, the neutron irradiation pool 101 includes a reactor pool 103, a work pool 105, a waste fuel storage pool 107, and a reactor pool 103 and a work pool ( It consists of a flow channel 109 connecting the 105. Man-bridge crane (111) for transporting work is installed at the upper end of the entire pool (101) so as to be movable to the left and right of the pool (101), and the reactor (113) at the bottom of the reactor pool (103). Is installed, and the work bench 115 is provided on the bottom surface of the work pool 105.

In addition, the pool 101 is filled with distilled water as about 7 to 80% as a means of shielding the radiation emitted from the irradiated irradiation vessel or work equipment due to the neutron irradiation, the neutron in the irradiation hole 117 of the reactor 113 The irradiation vessel 119 irradiated is moved to the work bench 115 of the work pool 105 while being submerged in shielded distilled water using the crane 111.

As such, in order to move the irradiation vessel 119 to the manbridge crane 111, a cable 121 as shown in FIG. 3 and a rocking mechanism 123 mounted at the end of the cable 121 are conventionally provided. lock system). Here, the cable 121 is made of a SUS wire, and a ring 125 for fixing to the manbridge crane 111 is attached to the upper end, and a ball rock 123 is provided through the Al chain 127 at the lower end. It is connected.

The ball lock 123 is attached to the connector 129, the chain connector 129 for connection with the chain 127, as shown in the cross-sectional view in Figure 4 so that the irradiation vessel 119 is coupled to the bottom It has a structure consisting of a spindle 133, the projection 131 is fitted to the top of the irradiation vessel 119 and the shank 135 is mounted therein. Therefore, the irradiation vessel 119 is inserted into the mounting hole 137 of the working table 115 shown in a planar state in FIG. 5, and then the protrusion 131 is inserted into the spindle 133 of the rock 123. After the swivel arm 141 is fastened between the chain connector 129 and the shank 135 and the chain connector 129 is pulled upward, the ball 137 mounted on the lower side of the spindle 133 so as to be movable left and right is provided. The irradiation vessel 119 is fixed to the ball 123 by being separated from the groove 139 at the lower end of the inner circumference of the shank 135 and being inserted into the outer circumference of the protrusion 131 in a wedge manner.

Then, the irradiation vessel 119 coupled to the cable 121 is transferred to the reactor pool 103 through the crane 111 and injected into the reactor 113 irradiation hole 117. In the irradiation hole 117 while moving to the cable 121, the irradiation vessel 119, which has been completed with neutron irradiation, is moved back to the working table 115 and inserted into the mounting hole 137, and then the swivel arm 141 of FIG. 3, the arm 141 is inserted between the chain connector 129 and the shank 135 of the rock mechanism 123 as shown in FIG. 3. Then, the connector 129 is pushed down by using the working tool to release the coupling between the ball 137 and the protrusion 131 which are wedge-coupled, thereby completing the transport of the irradiation container 119.

As described above, the irradiation vessel 119 is coupled to the irradiation vessel 119 and the rocking mechanism 123 through a complicated operation so that all the instruments used for the transportation except the irradiation vessel 119 are not disposable. Although it is because the worker cannot directly operate the device once it is radiated, the work time required before and after the neutron irradiation operation is excessively delayed due to the use of a complicated structure such as the rocking mechanism 123, and the irradiation container ( The operation for coupling the 119 to the cable 121 is not only very demanding, but also the production cost of the rocking mechanism 123 itself is expensive, and as a result, the production cost of the radiation source disk has been raised.

Therefore, in order to solve the problems as described above, various methods have been sought in the field of producing an isotope production investigation vessel, and the present invention has been devised as a part thereof. Therefore, the object of the present invention is not only simple and inexpensive structure can be manufactured to replace the rocking mechanism having a complex detachable structure, but also easy to combine the irradiation container, but can be surely achieved. To provide the drawer and take-out vessels for the investigation.

1 is a front view schematically showing a neutral yarn irradiation facility used for the production of radioisotopes.

2 is a schematic plan view of the neutron irradiation installation shown in FIG.

3 is a schematic view illustrating a state in which the irradiation container is fitted to a conventional irradiation container transporting device.

4 is an exploded cross-sectional view showing a chain connector, a spindle, and a shank of an easy-to-use transport lock device.

FIG. 5 is a plan view of a work bench showing the swivel arm shown in FIG.

Figure 6 is a front view showing the hook of the irrigation container withdrawal and transport mechanism according to the present invention.

7 is a side view of the hook shown in FIG.

8 is a bottom view of the hook shown in FIG.

Figure 9 is a front view showing the hook support block of the retrieval container take-out and transport mechanism according to the present invention.

10 is a plan view of the support block shown in FIG.

* Explanation of symbols for main parts of the drawings

1: Drawout and transport mechanism of irradiation vessel 3: Transport cable

5: connection grip 7: irradiation container

9: carrying hook 11: support

13: side slot 15: through hole

17: Bell Slot 21: Hanging Jaw

23: body 33: coupling pin

39: mounting hole

The present invention for achieving the above object is provided with a slot that is inserted into the chain of the transport cable at the top, and the cylindrical hole that is penetrated in the transverse direction so that the pin hole into which the coupling pin for chain connection is pressed. Connecting grips;

Through-holes are formed in the upper center to connect the connecting grips in the longitudinal direction so that the irradiation container for the production of radioisotopes is fixed to the connecting grips. The through hole is opened so as to intersect the transverse slot concentrically with the central axis, and a longitudinal slot is formed in the lower portion of the transverse slot from the through hole to the circumferential surface, and inserted into the upper through slot. A rivet ball coupled to the connecting grip and the rivet is provided in parallel, and a lower end of the through-hole has a carrying hook formed of a cylindrical body having a locking jaw formed therein;

An oval opening is formed in the upper part so that the transport hook can be fixed by hanging the irradiation container, and a mounting hole for inserting the irradiation container is formed in the lower part of the opening, and the irradiation container is seated at the bottom of the mounting hole. It is an object of the present invention to provide a radioisotope retrieval container withdrawal and transport mechanism including a support on which the seat portion is processed.

Hereinafter, with reference to the accompanying drawings, the radioisotope irradiation container withdrawal and transport mechanism according to the present invention will be described in detail as follows.

6 to 10, the irradiation container withdrawal and transport mechanism (1) according to the present invention is the end of the cable (3) suspended on a manbridge crane (not shown) as in the conventional rocking mechanism A cylindrical connecting grip 5 connected to the chain 4 fastened to the hook, a transport hook 9 attached to the connecting grip 5 to hang and carry the container 7 for irradiation with the radiation source disc, and Support 11 for guiding the transport container 9 to easily hang the irradiation container 7 with the irradiation container 7 placed therein when the irradiation container 7 is to be transported by hooking the irradiation container 7 to the transport hook 9. )

Here, the carrying hook 9 has a cylindrical body 23, as shown in Figs. 6 to 8, and a square slot 13 is formed in the front middle portion of the body 23 in the transverse direction. It is. The transverse slot 13 has a height of the length of the head 25 so that the projection 27 can be inserted into the head 25 portion of the projection 27 when the irradiation container 7 is hooked with the hook 9. It is longer.

In addition, the through hole 15 is opened in the central portion of the body 23 of the hook 9 concentrically with the central axis. The through hole 15 intersects with the slot 13, and the horizontal slot ( As in 13, the inner diameter is processed larger than the outer diameter of the head 25 so that the head 25 of the projection 27 can pass. The longitudinal slot 17 is opened in the longitudinal direction from the inner circumferential surface of the through hole 15 to the outer surface of the body 23 at the lower front side of the horizontal slot 13 of the through hole 15, while the horizontal slot 13 The rivet hole 19 penetrates in the upper part so that it may cross | intersect a center axis parallel to this slot 13. As shown in FIG.

Here, the longitudinal slot 17 is wider than the diameter of the cylindrical body of the projection 27 and narrower than the outer diameter of the head 25 in order to prevent the irradiation vessel 7 from being separated, the longitudinal slot 17 On the front surface, that is, the part where the longitudinal slot 17 and the outer circumferential surface of the body of the hook 9 meet, the projection 27 of the irradiation container 7 can be guided when the irradiation container 7 is caught by the hook 9. The V-shaped guide surface 28 is machined on both sides of the edge surface.

A locking jaw 21 is formed in the lower edge portion of the through hole 15 in the circumferential direction, so that the projection 27 of the irradiation vessel 7 head 25 when the irradiation vessel 7 is lifted by the hook 9. Is fixed. In addition, the bottom surface 10 of the carrying hook 9 facing the locking jaw 21 has the same profile so as to be in contact with the spherical surface 26 forming the upper surface of the body 8 of the irradiation container 7. The funnel-shaped shoulder 30 is processed concentrically with the central axis.

The connection grip 5 coupled to the body 23 by the rivet 29 inserted into the rivet hole 19 formed through the body 23 by being inserted into the upper portion of the through hole 15 of the carrying hook 9 is The slot 31 in which the chain 4 of the cable 3 is inserted is opened at the upper end, and the pin hole 35 into which the coupling pin 33 for connecting the chain 4 is press-fitted intersects the slot 31. Penetrates in the transverse direction;

The support 11 shown in FIGS. 9 and 10 has an elliptical opening 37 formed thereon. A mounting hole 39 into which the irradiation vessel 7 is inserted is formed at the bottom of the bottom of the opening 37, and the sealing cap 12 of the irradiation vessel 7 is seated at the bottom of the mounting hole 39. The sheet part 41 to be processed is processed. In addition, the drain hole 43 penetrates through the center of the seat portion 41 of the mounting hole 39 so that the radiation shielding distilled water filled in the mounting hole 39 when the irradiation container 7 is inserted can be easily discharged. To make sure.

Therefore, according to the irradiation container withdrawal and transport mechanism 1 configured as described above, before the neutron irradiation operation commences, the devices necessary for the operation are installed in the working pool in advance, in the same manner as the conventional method. Place the irradiation vessel (7) on the workbench on which the support (11) is located.

Then, when the irradiation operation is started, the cable 3 is moved to the work pool, and the transport hook 9 is aligned with the upper opening 37 of the support 11 to be inserted into the hook seat 38 at the bottom of the opening. . The protrusion 27 of the irradiation vessel 7 is then guided along the V-shaped guide hole 28 of the hook 9 so that the protrusion 27 enters the through hole 15 through the longitudinal slot 17. To do that. Then, when the connecting grip 5 connected by the chain 4 is pulled up by the cable 3, the hook 9 is caught when the catching jaw 21 touches the head 25 portion of the irradiation container 7. To rise.

In this way, when the projection 27 of the irradiation container 7 is caught in the through hole 15 of the hook 9, the diameter of the head 25 is larger than the width of the longitudinal slot 17, so that the irradiation container 7 The cable is lifted by the cable 3 without being pulled out of the carrying hook 9. Then, when the cable 3 is moved to the reactor pool by a man bridge crane, the irradiation container 7 is put into the neutron irradiation hole while the irradiation container 7 is fastened to the rock, and the conventional neutron irradiation was required. Unlike the method, since the irradiation vessel 7 can be easily removed from the hook 9, the irradiation vessel 7 is inserted into the irradiation hole of the reactor and irradiated, and then the hook 9 is hooked to the irradiation vessel 7. In the reverse order, the irradiation vessel 7 can be more easily released from the hook 9.

As such, according to the radioactive isotope irradiation container withdrawal and transport mechanism of the present invention, it is necessary to move the irradiation vessel between the reactor pool and the work pool in order to produce the radioisotope. As a means for the use, a transport mechanism consisting of a transport hook and a support bar, which is inexpensive, simple in structure, and easy to manufacture, not only makes the transport of the irradiation container easier, but also the attachment and detachment of the irradiation container and the transport hook is simple. It can achieve with certainty and can achieve the effect which cuts the previous working time by half.

Although the present invention has been shown and described in connection with specific embodiments, it is common knowledge in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the appended utility model registration claims. Anyone who has a can easily know.

Claims (7)

The slot 31 into which the chain 4 of the carrying cable 3 is inserted is opened, and the pin hole 35 into which the coupling pin 33 for connecting the chain 4 is pressed is inserted into the slot 31. A cylindrical connecting grip 5 penetrated laterally so as to intersect with the other; A through hole 15 in which the connecting grip 5 is longitudinally coupled is formed at the top center so that the irradiation container 7 for fixing the radioisotope is fixed to the connecting grip 5. The slot 13 is formed in the front middle part in the transverse direction, the through-hole 15 is opened so as to intersect the slot 13 concentrically with the central axis, and the lower part of the horizontal slot 13 A longitudinal slot 17 is opened in the circumferential surface from the through hole 15, and the connection grip 5 and the rivet 29 inserted into the through hole 15 in the upper portion of the slot 13. A rivet hole 19 to be coupled therethrough and a transport hook 9 formed of a cylindrical body 23 having a locking jaw 21 formed at a lower surface of the through-hole 15; An oval opening 37 is formed at an upper portion thereof so that the carrying hook 9 can be fixed by hanging the irradiation vessel 7, and a lower portion of the opening 37 is provided for inserting the irradiation vessel 7. The mounting hole 39 is formed, and the bottom surface of the mounting hole 39 is characterized in that it comprises a support 11 on which the sheet portion 41 on which the irradiation vessel 7 is seated is processed. Draw-in and carry-out of radioisotope investigation vessels. 2. A radioisotope irradiation container withdrawal and delivery mechanism according to claim 1, characterized in that the transverse slot (13) of the carrying hook (9) is higher than the head (25) of the irradiation vessel (7). The radioisotope irradiation container withdrawal and delivery mechanism according to claim 1, characterized in that the through hole (15) of the carrying hook (9) is larger in diameter than the diameter of the head (25) of the irradiation vessel (7). . The radioisotope irradiation vessel according to claim 1, wherein the longitudinal slots (17) of the carrying hook (9) are wider than the projections (27) of the irradiation vessel (7) and narrower than the head (25). Withdrawal and Carrying Equipment. The front surface of the longitudinal slot (17) of the carrying hook (9) according to claim 1, wherein the guide surface of the V-shape to guide the projection (27) when the irradiation vessel (7) is caught by the hook (9) A radioactive isotope irradiation container withdrawal and transport mechanism, characterized in that (28) has been processed. The bottom surface (10) of the carrying hook (9) is a funnel-shaped shoulder (30) concentric with the central axis so as to contact the spherical surface (26) of the upper end of the body (8) of the irradiation container (7). A radioactive isotope irradiation container withdrawal and transport mechanism, characterized in that is processed. The drain hole 43 for discharging the radiation shielding distilled water filled in the mounting hole 39 when the irradiation container 7 is inserted into the bottom surface of the mounting hole 39 A radioactive isotope irradiation container withdrawal and transport mechanism, characterized in that.