KR100269888B1 - Target transfer and irradiation tool for jigh specific ri production in nuclear reactor - Google Patents

Abstract

The present invention is attached to the lower end of the cylindrical housing (3), the cylindrical housing (3) which is intended to charge one or more irradiation vessel (10) to support the bottom of the irradiation vessel (10) by a bottom spring (6) And a lower bundle 8 through which a plurality of distribution holes 5 penetrates on a concentric circle about an axis, and is detachably mounted on an upper end of the tubular housing 3 so that an upper end of the irradiation container 10 is disposed on the bottom spring. Regarding the irradiation vessel charging and transporting device (1) consisting of an upper bundle (16) which is pressed against (6) and is formed through a plurality of flow holes (13) concentrically about an axis, the neutron of the reactor It is intended to improve the dustproof and heat dissipation performance of the irradiation container charging and transporting device 1 so as to be suitable for producing a large amount of non-radioactive radiation source by neutron irradiation in a high in-core core.

Description

Target transfer and irradiation tool for high specific RI production in nuclear reactor

The present invention relates to a target irradiation apparatus for producing a high specific radiation source, and more particularly, a target that can be suitably used for producing a radioactive source having high specific radioactivity by neutron irradiation in an incore with high neutron flux of a nuclear reactor. It relates to an irradiation apparatus.

The range of use and technology of radioisotopes is developing rapidly today, and despite the general tendency to aversion to radiation from radioisotopes, this high usage is due to the inherent properties of radioisotopes. Representative among them is that it emits trace amount and strong penetrating radiation and can be used in industry and various fields from it.

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 1000 companies using radioisotopes were radiodestructive tests, radioisotope gauges, industrial radiotracers, in-vivo diagnosis and treatment, in-vitro diagnostics, in vitro radiation therapy, radiation sterilization, radiation food research, 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. In order to do so, 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 have been in operation. In addition, accelerators are generally only advantageous for the production of medical short-lived radioisotopes, and in order to meet the overall radioactivity requirements, there was no choice but to use them as research reactors.

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 the production efficiency of radioisotopes cannot be increased in the manner used in the related art, accompanying development of ancillary equipment or a handling device 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. A man-bridge crane (111) for work transfer is installed at the upper end of the entire pool 101 so as to be movable from side to side of the pool 101, and the reactor 104 is disposed on the bottom surface 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 of about 7 to 80% as a means of shielding radiation emitted from the irradiated irradiation vessel or working equipment due to neutron irradiation, and forms an inner core of the reactor 104. On the wall of the 122 and the outcore 124, a plurality of irradiation holes 117 opened from the upper end surface are arranged and formed in the circumferential direction.

Here, in order to move the irradiation vessel 119 to the manganese crane 111, conventionally a cable 121 as shown in Figure 3 and a ball lock mechanism (123: ball lock) mounted to the end of the cable 121 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 to which the projection 131 on the top of the irradiation vessel 119 is fitted and a shank 135 to which the spindle 133 is mounted. Therefore, the irradiation vessel 119 is inserted into the mounting hole 137 of the working table 115 shown in a flat state in FIG. 5, and then the protrusion 131 is inserted into the spindle 133 of the rock 123. When 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. The irradiation vessel 119 is fixed to the ball 123 by being separated from the groove 139 at the lower end of the shank 135 and being inserted into the outer circumferential surface of the protrusion 131.

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 104 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. Rotating so that the arm 141 is sandwiched between the chain connector 129 and the shank 135 of the rock mechanism 123 as shown in FIG. 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 apparatus once it is radiated, it is necessary to use a device having a complicated structure such as the rocking mechanism 123, and also only one irradiation container 119 at a time. Since it is intended to be charged in the neutron irradiation work time required before and after the problem was too delayed. In addition, the operation for coupling the irradiation vessel 119 to the cable 121 is not only very demanding, but also the production cost of the rock mechanism 123 itself is expensive, and as a result, there is a problem of raising the manufacturing cost of the radiation source disk.

In addition, the vacuum adsorption transfer device 201 has been proposed to solve this problem. This apparatus 201 is a vacuum pump 210 for generating a vacuum pressure, as shown in Figures 4 and 5, and the vacuum pressure generated from the vacuum pump 210 to a predetermined position in the pool 101 It consists of a vacuum hose 220 to deliver, and a vacuum suction port 230 for adsorbing the radioisotope irradiation vessel 119 by using the vacuum pressure transmitted from the vacuum hose 220.

The lower portion of the vacuum pump 210 is integrally provided with a water tank 213 for temporarily storing and discharging water sucked from the inside of the reactor pool 103. The water tank 213 has a radioactively contaminated reactor pool ( A drain hose 219 is installed to directly return the water of the 103 to the reactor pool 103 without overflowing the top of the manbridge crane 111. The vacuum hose 220 is a vacuum pump 210. The vacuum suction port 230 and communicates with, automatically wound and stored in the automatic hose reel device (221).

Such a vacuum adsorption irradiation container transfer device 201 can be loaded and removed in the irradiation hole 117 by absorbing and transporting the irradiation vessel 119 with a vacuum suction force during the production of the radioisotope, thereby providing a plurality of irradiation vessels 119. ) Can be irradiated with one irradiation hole (117) at a time and mass production of a radiation source.

Therefore, when irradiated with neutrons by irradiating neutrons into the neutron irradiation hole 117 in the out core 124 of the reactor 104 to irradiate the neutron irradiation vessel 119 with the corresponding element for the production of radioactive isotope The irradiation vessel 119 is adsorbed and moved through the vacuum suction port 230 of 201, charged into the irradiation hole 117, and neutron irradiation is performed.

By the way, when the adsorption irradiated vessel transfer device 201 is used, the problem that the structure becomes complicated or requires a lot of work in use due to the simple vacuum adsorption structure as mentioned above is somewhat resolved, but the irradiation hole ( When the number of irradiation vessels 119 is charged in 117), the number of working hours increases in proportion to the number of charges, and when the neutron inside that can be obtained from the irradiation holes 117 of the outcore 124 is lower than the target value, several times There was a problem in that the irradiation vessel 119 was transferred to another irradiation hole 117 and reloaded to continue the neutron irradiation.

First of all, the irradiation vessel transfer device as mentioned above has a low heat dissipation performance, so the neutron irradiation cannot release the reaction heat generated from the target, that is, the irradiation vessel, so that the neutron irradiation in the high neutron flux is relatively high. There is a problem that can not be applied to produce a high-radioactivity source by charging the irradiation vessel 119 into the irradiation hole 118 of the in-core 122 is generated.

Therefore, the present invention has been made to solve the problems of the conventional irradiation vessel transfer device as described above, by increasing the heat dissipation performance of the device used to charge the transfer vessel relative to the neutron irradiation due to the high neutron flux As a result, it is possible to produce a high specific radioactive radiation source from the in-core of a nuclear reactor that emits a lot of heat of reaction. The purpose is to provide a charging feeder.

In addition, by inserting a plurality of irradiation vessels in one transport device housing to irradiate several irradiation vessels at the same time with a high neutron flux, not only can produce a large amount of high-radioactivity source that can be used for multi-purpose, but also simple and stable Another object of the present invention is to provide an irradiation container charging and transporting device which is convenient for post-maintenance while allowing quick and easy charging of the irradiation container by employing a high irradiation container fixing structure.

1 is a schematic longitudinal cross-sectional view of a reactor pool.

2 is a schematic plan view of FIG. 1.

Figure 3 is a longitudinal sectional view showing a conventional rock mechanism for transporting the irradiation vessel.

4 is a schematic longitudinal cross-sectional view of a reactor pool schematically showing another conventional vessel transport apparatus.

Figure 5 is an enlarged side view of the irradiation vessel transport apparatus shown in FIG.

Figure 6 is a partially omitted longitudinal cross-sectional view showing the irradiation vessel charging and transporting device according to the present invention in the state that the irradiation vessel is loaded.

Figure 7 is an exploded view showing the side cross-section and the plane of the transfer device shown in FIG.

8 is a partial detailed view showing a state in which the shank portion and the top tip of the irradiation vessel shown in FIGS.

Figure 9 is a schematic perspective view of the reactor irradiation hole assembly groove into which the transfer device according to the present invention is inserted.

10 is a graph showing a change in pressure drop according to the flow rate of the performance test results of the transfer apparatus according to the present invention.

11 is a graph showing a change in vibration frequency according to the flow rate of the experimental results of FIG.

12 is a graph showing a change in RMS displacement according to the flow rate of the experimental results of FIG.

13 is a graph showing a change in maximum displacement according to the flow rate of the experimental results of FIG.

Explanation of symbols on the main parts of the drawings

1: irradiation container charging and transporting device 2: lower arm serration part

3: housing 7: lower body

8: lower bundle 10: irradiation vessel

11: cap 14: upper arm recessed portion

16: upper bundle 17: shank portion

19: head portion 21: upper flush portion

27: grip head 29: lower swash section

31: movable tooth 37: stopper

39: irradiation hole 40: fixed plate

41: assembly groove 43: rod tip

47: top spring

In order to achieve the above object, the present invention provides a cylindrical housing configured to charge one or more irradiation vessels, which is attached to the bottom of the cylindrical housing to support the bottom of the irradiation vessel by a bottom spring, and a plurality of concentric circles on the axis. It consists of a lower bundle through which two distribution holes penetrate, and an upper bundle that is detachably mounted on the upper end of the cylindrical housing, presses the upper end of the irradiation container against the bottom spring, and has a plurality of distribution holes penetrating through concentric circles about an axis. It is to provide an irradiation vessel charging transfer device.

Hereinafter, described in more detail with reference to the accompanying drawings, the irradiation vessel charging and transporting apparatus for producing a high specific radioactive source according to the present invention.

As shown by reference numeral 1 in FIGS. 6 and 7, the irradiation container charging and transporting device of the present invention is largely a cylindrical housing 3, a lower bundle 8 inserted into and attached to the lower opening of the cylindrical housing 3. The upper bundle 16 is detachably mounted on the upper end of the cylindrical housing 3.

Here, the cylindrical housing 3 has a cylindrical body as shown generally, and the inside of the cylindrical housing 3 is equipped with one or more irradiation vessels 10 in which a plurality of radiation sources requiring irradiation are mounted. In addition, the serration 2 extending in the longitudinal direction parallel to the axis of the housing 3 is processed on the inner circumferential surface of the housing 3 except for the portion where the lower bundle 8 and the upper bundle 16 are coupled.

As such, the serration part 2 is machined on the inner circumferential surface of the housing 3 to form a plurality of threads and screw valleys on the inner circumferential surface thereof, so that the serration portion 2 is introduced from the lower side of the housing 3 as indicated by the arrow A, and the arrow B is directed upward. Cooling water flowing out as described above is able to secure a sufficient flow path for the smooth flow between the irradiation vessel 10 and the inner peripheral surface. In addition, since the thread of the serration part 2 protrudes toward the center, it is possible to secure a sufficient flow path as described above and to suppress the lateral shaking of the irradiation container 10 due to the flow of water at the end of the thread. Will be.

The lower bundle 8 inserted into the lower end of the housing 3 to be fixed by welding or the like is further provided with a rod tip fixedly attached to the center of the lower body 7 and the lower body 7 by fixing means such as rivets. 43) and a protrusion 37 which is slidably mounted on the outer circumferential surface of the rod tip 43, wherein the lower body 7 is a kind of cap fitted to the lower opening of the housing 3, the center of which is the axis. The plurality of distribution holes 5 are formed in the axial direction through the concentric circle so that the coolant for radiating the irradiation vessel 10 can be introduced into the housing 3 from the bottom of the reactor pool. In addition, at least one mounting groove 9 is inserted into and mounted in the housing 3 by a bottom spring 6 mounted in the seating groove 9 in the center position of the lower body 7 in the axial direction from the upper surface. The irradiation container 10 is elastically supported.

The rod tip 43 inserted into and attached to the center of the lower surface of the lower body 7 is a shaft having a long and relatively thin body that fits into the assembly groove 41 of the lower fixing plate 40 of the irradiation hole 39 at the lower end thereof. The engaging protrusion 50 is formed to protrude from both the left and right sides. In addition, a stopper 37 which is configured to support the stopper spring 35 between the lower body 8 and the lower end surface of the rod tip 43 immediately above the locking protrusion 50 is slidably inserted thereinto. The stopper 37 is formed with a plurality of flow holes 45 through which the fluid flowing from the lower end of the irradiation hole 39 flows smoothly without resistance.

The upper bundle 16 detachably inserted into the upper end of the housing 3 is inserted into the cap 11, which is screwed into the upper opening of the housing 3, and the insertion hole 15 of the cap 11. The grip is composed of a grip head 27 and a movable tooth 31 mounted on the lower end of the grip head 27.

Here, the cap 11 has a lower outer circumferential surface is processed with a male screw portion 51 so as to be engaged with the female screw portion 49 formed on the upper inner circumferential surface of the housing 3, and the grip head 27 is slidably inserted on the axis. The insertion hole 15 to be penetrated is formed in the longitudinal direction. At this time, the upper end circumferential surface of the insertion hole 15 is machined in the longitudinal direction. In addition, around the insertion hole 15, a plurality of through holes 13 through which the cooling water raised through the irradiation vessel 10 passes through the insertion hole 15, and a plurality of through holes on the top surface of the cap 11 13) Any position outside is provided with a ball stopper 57 as a means to prevent the cap 11 from falling off due to the vibration of the housing 3, this ball stopper 57 serves as a general washer The ball which is in contact with the upper surface of the cap 11 is pressurized by the inner spring so as to make it.

In addition, the grip head 27 fitted into the insertion hole 15 of the cap 11 is the upper head portion 19 coupled to the external gripping means and the shank portion 17 that is slidably inserted directly into the cap 11. Here, the head portion 19 is a fastening hole 53 is formed as shown in Figure 6 or 7, for example, so as to be coupled to the external gripping means, the coupling groove 55 for fixing the fastening hole The inner peripheral surface of 53 is processed. A protruding portion 23 is further formed below the outer circumferential surface of the head portion 19 so as to press the cap spring 25 fitted around the shank portion 17 against the upper surface of the cap 11.

The shank portion 17 constituting the lower portion of the grip head 27 is inserted into the cap insertion hole 15 so as to be slidably moved up and down, and the upper portion of the upper portion of the irradiation container 10 that is single-loaded or stacked in plurality. The surface is pressed against the bottom spring 6 so as to minimize unnecessary shaking, such as fluctuation of the irradiation vessel 10 due to the coolant flow. In this case, the mounting groove 63 may be processed on the lower surface of the shank portion 17 to reinforce the restraint force on the upper tip 20 portion of the irradiation container 10 in contact with the shank portion 17.

In addition, the shank portion 17 is detachably engaged with the arm portion 14 at a position corresponding to the middle portion of the outer circumferential surface, that is, the upper portion of the cap 11 insertion hole 15. The washing section 21 is processed in the longitudinal direction. In addition, the lower tooth outer peripheral surface of the shank portion 17 is provided with a movable tooth seat 59 that supports the movable tooth 31 by a snap ring 58.

The movable tooth portion 31 mounted on the movable tooth seat 59 and configured to rotate integrally with the shank portion 17 by rotation preventing means such as a vandal key 61 or the like is provided with the shank portion 17 fitted at a center position. The through hole 33 is processed, and the outer circumferential surface is formed with the serration portion 2 of the inner circumferential surface of the housing 3 and the lower sulcusation portion 29 which can be attached or detached in accordance with the shang dong. . In addition, the movable tooth portion 31 also has a plurality of flow holes 30 penetrating in the longitudinal direction to enable the flow of the cooling water to the radially outer side of the through hole 33.

In addition, a plurality of top springs 47 are arranged concentrically on the outer side of the insertion hole 15 in the upper edge portion of the cap 11 to elastically contact the inner circumferential surface of the irradiation hole 39 as shown in FIG. The upper spring 47 is pressurized against the inner circumferential surface of the irradiation hole 39 by the repulsive force due to the bending in the form of a bent wire, and the housing 3 due to the coolant flowing through the inner and outer circumferential portions of the housing 3. The vibration of itself is suppressed.

The irradiation container charging and transporting device of the present invention having the above structure is preferably made of 60 or 61 series aluminum material having excellent heat dissipation performance, and various springs have excellent durability even when irradiated with neutrons. SUS 304 ~ 316 series steels are generally used, except that they are made of inconel, which has less ging, and these materials have high corrosion resistance and less embrittlement of mechanical properties due to recrystallization by neutron irradiation. Has the properties that appear.

Therefore, in order to produce a large amount of high specific radioactive radiation source by the irradiation vessel charging and transporting device 1 according to the present invention, first, a plurality of radiation source targets that are the target of neutron irradiation in a constant container irradiation vessel (10) It is piled up and down inside and charged.

Then, the upper bundle 16 is removed from the housing 3, and then one or more irradiation vessels 10 prepared as described above are stacked in the housing 3, and the upper bundle 16 is loaded as shown in FIG. In this case, the male screw portion 51 of the cap 11 is screwed to the female screw portion 49 of the housing 3, and the lower end portion of the shank portion 17 is irradiated with a tip ( 20) by pressing the portion to press the irradiation vessels 10 against the bottom spring 6 to suppress the shaking of the container (10).

When the charging of the irradiation container 10 is completed as described above, the head portion 19 of the top of the head grip 27 is gripped by a gripping means such as an external man crane crane to irradiate the reactor with the reactor as shown in FIG. 9 ( 39), in particular, the irradiation vessel charging and feeding apparatus of the present invention is inserted into the irradiation hole 39 of the incore portion having a high neutron flux at about 2 × 10 ¹⁴ n / cm 2 sec. When the stopper 37 of the lower bundle 8 is caught by the support plate 40 below the irradiation hole 39 during insertion, the stopper spring 35 is compressed by an external force, so that only the rod tip 43 part supports the support plate 40. After passing through the through hole 42 and the locking projection 50 of the rod tip 43 completely passes through the through hole 42 by rotating the housing 3 by 90 ° and release the external force The engaging projection 50 pressurized upward by the hydraulic pressure of the cooling water flowing in from the lower side of the support plate 40 of the 39 and the restoring force of the stopper spring 35 is provided in the assembly groove 41 processed on the lower surface of the support plate 40. The insertion of the irradiation hole of the feeder 1 is completed by being fitted.

However, in order to rotate the housing 3 as described above, the grip head 27 is pushed downward by an external gripping means so that the upper portion of the cap portion 11 and the upper portion of the shank portion 17 are flushed. And the grip head 27 should be turned in the state that the lower flushing portion 29 of the movable tooth 31 is engaged with the serration portion 2 of the inner circumferential surface of the housing 3 at the same time that the coupling is loosened. Since the 17 is idling in the insertion hole 15 of the cap 11, the cap 11 is not loosened or locked due to the rotation of the grip head 27.

When the reactor is operated after the transfer device 1 is charged into the irradiation hole 39, the radiation source loaded in the irradiation vessel 10 is irradiated with neutrons as desired, and the heat of nuclear reaction generated from the radiation source to be irradiated is housed. It cools with the cooling water which flows inside (3).

To this end, flow paths are secured at certain portions of the lower bundle 8 and the upper bundle 16 to ensure smooth flow of the cooling water. In other words, the cooling water introduced from the lower end of the irradiation hole 39 is first stopped by the stopper 37. Outward) or through the distribution hole 45 flows into the distribution hole 5 of the lower body 7 in the direction of the arrow (A). The cooling water passing through the distribution hole 5 cools the irradiation vessel 10 while passing through a flow path secured between the serration portion 2 and the irradiation vessel 10 processed on the inner circumferential surface of the housing 3. Then, through the respective discharge holes (30, 13) penetrating the movable teeth 31 and the cap 11 in the longitudinal direction is discharged in the direction of the arrow (B) to complete the cycle for cooling the irradiation vessel (10). .

However, even if the coolant flows around the irradiation vessel 10 in this manner, the irradiation vessel 10 is pressurized by the elastic repulsive force of the bottom spring 6 and at the same time, only a slight gap is caused by the threaded portion of the serration portion 2. Since it is restrained in the hold | maintained state, the shaking of the irradiation container 10 inside the housing 3, etc. are suppressed as much as possible.

In this way, when the irradiation work of one cycle of irradiation vessels is completed, the next irradiation vessel is irradiated again. For this purpose, the irradiated transport device 1 is removed from the irradiation hole 39 and moved to a separate radiation-shielded work room.

Then, when the grip head 27 is rotated as shown in FIG. 6 by remote control, the rotational force of the grip head 27 is coupled to the cap 11 through the coupling of the upper arm portion 14 and the upper arm portion 21. Only), the movable tooth 31 is idling in a state of being disengaged on the contrary, so that the cap 11 can be tightened or released. Accordingly, after removing the upper bundle 16 from the housing 3, the next irradiation vessel 10 is charged to the transfer device 1 and closed again to complete the subsequent neutron irradiation.

The pressure drop for checking whether the irradiation vessel charging and transporting device 1 manufactured as described above satisfies the operating conditions of the reactor when charged into the irradiation hole 39 and also measuring vibration characteristics, etc., of fluid inducing device 1. The summary of the vibration test results is as follows.

First, the pressure drop test is carried out three times at a circulating water temperature of 40 ° C. and a flow rate of 0.5 to 2.5 kg / s, and in the case of a vibration test, the grip head of the transfer device 1 at the same water temperature and flow rate range as the pressure drop. (27) Measured at 2 points with 90 ° intervals.

At this time, the feeder 1 charged into the reactor hole 39 of the reactor should satisfy the conditions of flow rate <12.7 kg / s, pressure drop> 200 kPa under 40 ° C of circulating water. 10 is shown. Pressure drop experiments were performed three times (tests 1, 2, 3), and the flow rate causing the pressure drop of about 200 kPa from each experiment was measured at about 1.8 kg / s. This satisfies the above limitations of the reactor.

In addition, the vibration amplitude generated from the laser vibrometer in the vibration experiment is once stored in the computer memory. Fast Fourier Trasform (FFT) is performed on the stored data to obtain a function of frequency versus amplitude. From these results, peak amplitude, root mean square (RMS) amplitude, and vibration frequency characteristics are determined. 11, 12, 13 are shown.

The vibration frequency is in the range of approximately 13-15 kHz as shown in FIG. 11, and FIG. 12 shows the vibration displacement characteristic according to the flow rate as an RMS value. In this case, it can be seen that the RMS displacement is a very small range of 3 µm or less. The maximum vibration displacement of the feeder 1 is shown in FIG. 13 as a function of flow rate. From this result, it can be seen that the maximum displacement of the feeder 1 is in the range of about 6 μm or less.

In conclusion, the pressure drop test resulted in a pressure drop of about 200 kPa under a flow rate of 1.8 kg / s, which satisfies the above-mentioned reactor limitations. As a result of the vibration test, the vibration frequency range was about 13 to 15 kHz, and the RMS vibration displacement was about 3 µm or less and the maximum vibration displacement was about 6 µm or less.

Measuring point 1 Measuring point 2 Flow rate (kg / s) Frequency Amplitude (RMS) (μm) Amplitude (max) (μm) Frequency Amplitude (RMS) (μm) Amplitude (max) (μm) 1.0 13.9 1.48 3.27 13.9 1.47 5.78 1.5 14.9 2.80 4.35 13.9 1.04 3.30 1.8 13.9 2.38 5.83 13.9 1.03 3.26 2.0 13.9 1.77 4.55 13.9 1.14 3.40 2.2 15.5 1.69 4.49 13.9 1.00 3.45

As described above, according to the irradiation container charging and transporting device according to the present invention, the inside of the housing is charged by the cooling water distribution hole which is opened in the upper and lower bundles of the conveying device and the serration part which is longitudinally processed on the inner peripheral surface of the housing. Since it is possible to prevent the lateral vibration of the irradiation vessel by the serration part while securing the flow path of the cooling water for cooling the irradiation vessel, the neutron irradiation is performed at the portion having the high neutron flux such as the reactor in-core to achieve high specific radioactivity. Even if a large amount of nuclear reaction heat is generated in the process of manufacturing a radiation source, the amount of heat generated can be sufficiently released while the mechanical effect of the cooling water is minimized.

In addition, even if the transport device is radioactively contaminated by neutron irradiation, the upper bundle, which is the cover of the transport device, can be opened and closed remotely in a radiation-shielded work room so that it can be used repeatedly without disposal. By making the structure does not interfere with the rotational motion required when inserting the irradiation hole of the transfer device, it is possible to greatly increase the service life of the transfer device while making the loading of the irradiation container quick and easy. Maintenance is also convenient.

In addition, neutron irradiation is carried out by loading a plurality of irradiation vessels into a single transfer device, and thus it is possible to produce a large amount of high-radioactive sources that can be used for various purposes, so that Cr-51, Ni-63, Re-186, Yb-169 Various enrichment targets such as Re-186, Sr-89, Sm-153, Re-188 therapeutic unsealed sources, non-destructive testing sources such as Yb-169, Ir-192, Ir-192, Co-60 and Sources for therapeutic purposes, sources for measuring bone density such as Gd-153, nuclides with large neutron radiation cross-sectional areas in epithermal neutron regions such as Mo-99, and continuous (n, I) Production of nuclides and other neutron irradiation nuclides by reaction is possible.

While the invention has been shown and described with respect to particular embodiments, it will be understood by those skilled 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 claims. Anyone can grow up easily.

Claims (6)

A cylindrical housing (3) configured to charge one or more irradiation vessels (10), attached to the bottom of the cylindrical housing (3) to support the bottom of the irradiation vessel (10) by a bottom spring (6) A lower bundle 8 through which a plurality of distribution holes 5 penetrates on a concentric circle and a detachable upper end of the tubular housing 3 are attached to an upper end of the irradiation container 10 to the bottom spring 6. Irradiating container charging and transporting device (1), characterized in that it consists of an upper bundle (16) through which a plurality of distribution holes (13) are formed through concentric circles about the axis. The inner peripheral surface of the cylindrical housing (3) is a serration (2) extending in the longitudinal direction except for the portion where the lower bundle (8) and the upper bundle (16) is coupled is processed Irradiation container charging transfer device (1), characterized in that. 2. The lower bundle (8) according to claim 1, wherein the lower bundle (8) has a lower body (7) on which a seating groove (9) is opened on the axis so as to insert the bottom spring (6), and the lower body (7). The rod tip 43 is fixed to the center of the projection hole (39) is fitted into the assembly groove 41 of the lower fixing plate 40 protrudes in the lower portion, and sliding on the outer peripheral surface of the rod tip 43 Irradiation container charging and transporting device (1), characterized in that it consists of a stopper (37) which is possibly inserted and is adapted to support the stopper spring (35) inserted around the rod tip. The irradiation container charging according to claim 3, wherein the stopper (37) is formed with a plurality of flow holes (45) for smoothly flowing the fluid flowing from the lower end of the irradiation hole (39). Conveying device. According to claim 1, wherein the upper bundle 16 is the distribution hole 13 is formed and the insertion hole 15 penetrated up and down on the axis is formed and the upper end of the insertion hole (15) Shank portion 17 is inserted into the cap 11, the insertion hole 15 of the cap 11, the upper portion sintered portion 21 is formed in the middle of the cap 11, the portion 14 is processed; A grip head 27 composed of a head portion 19 gripped by an outer gripping means and adapted to press the cap spring 25 fitted to the shank portion 17 by a lower protrusion 23; The through hole 33 is formed on the axis so as to be fixed to the lower end of the shank part 17 of the 27), and the lower flush part 29 is machined on the outer circumferential surface, and the plurality of distribution holes 30 are coaxially around the axis. Irradiation container charging and transporting device characterized in that consisting of a movable tooth 31 formed through). According to claim 1, wherein the upper end of the cap 11 of the upper bundle 16 is attached to the top spring 47 for elastically supporting the housing 3 with respect to the inner peripheral surface of the irradiation hole (39). Irradiation container charging transfer device.