CN1314679A - Cobalt 60-gamma ray dot source device - Google Patents
Cobalt 60-gamma ray dot source device Download PDFInfo
- Publication number
- CN1314679A CN1314679A CN 01107083 CN01107083A CN1314679A CN 1314679 A CN1314679 A CN 1314679A CN 01107083 CN01107083 CN 01107083 CN 01107083 A CN01107083 A CN 01107083A CN 1314679 A CN1314679 A CN 1314679A
- Authority
- CN
- China
- Prior art keywords
- ball
- shield
- ball shield
- source device
- gamma ray
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Images
Abstract
The present invention belongs to the field of nuclear radiation application and the Cobalt 60 gamma ray dot source device is a new product with effective shielding and use safety. The computer transmits pulse equivalent to stepped motor to drive the conic gear pair, the reduced motion is transmitted to the rotation shaft to drive the inner lean uranium ball shielding body so that the gamma dot source is made in working position and the ray is emitted from the collimator. If the shaft is rotated by 180 deg, the gamma dot source will locate in the shielded position of outer shielding body center. The device is mainly used in ICT, and its modified type may be used in flaw detection of industry structure, level control in container and other fields.
Description
The present invention "
60The Co-gamma ray dot source device " technology relate to nuclear radiation application branch of learning field.
In isotopic radiographic source, only just be most widely used
60Co-γ source, the present document of grasping show, no matter the technology and equipment of preparation, transportation, upside-down mounting, deposit and the application in γ source all obviously falls behind.For example transport four in a kind of pen type source from Canada, size is about Φ 14 * 350mm, packs with 6 tons pig shielding unexpectedly, and upside-down mounting work is still carried out at the deep well more than 8 meters with long clamp.Some device is also very ancient, when needing the work of γ source, still with the method for directly opening the pig lid or uncapping with simple mechanism, inconvenient operation but also be absolutely unsafe not only, usually bring the danger of super metering radiation injury to operating personnel, more can not reach the accuracy requirement of detection to the source, the nuclear radiation accident that takes place on China Shanghai, Sichuan, Heilungkiang and other places all has a large amount of reports on the document.①②③
The purpose of the present invention's development promptly is to be ICT (Industrial Computer Tomography.In translated name: the industrial computed tomography imaging device), provide a kind of advanced person, high-precision, safe and reliable, easy to operate γ dot source device is looked into new conclusion and is shown that the present invention does not have identical document and patent report at home, 4. 5. 6. 7. 8..
The present invention is achieved by the following technical solutions:
As schematic diagram 1, and accompanying drawing 2, Fig. 3, Fig. 4, the major technique feature of this device is: adopting with the depleted uranium is two ball shield structures of material.Outer ball shield 8,9, on the radius of optical collimator 7 directions, the mid point of crown radius is center of circle O ' in addition, 1/2 of the exradius of ball shield 8,9 is radius in addition, forms the spherical pore of ball shield 5 in the dressing.Because assembling and arts demand, the vertical located of the spherical pore center of circle O ' of ball shield 8,9 is divided into forward and backward two halves outside, outer ball shield 8 and back outer ball shield 9 before being called, in packing into behind the ball shield 5, aim at anti-radiation leakage seam, with 6 bolts 14, with forward flange 12, rear flange 13, preceding outer ball shield 8, the outer ball shield 9 in back is assembled into an integral body.The front end of ball shielding 8 is equipped with optical collimator 7 outside preceding.Interior ball shield 5, be contained on the axle 4 with flat key 15, two ends with axle 4, be contained in respectively on two thrust ball bearings 22, thrust ball bearing 22 is contained in respectively on shell 21 and the bearing bridge 20, the input end of axle 4 is equipped with bevel gear wheel 3 with flat key 16, bevel gear wheel 3 is meshed with the bevel pinion 2 of the axle head that is fixed on stepper motor 1 with flat key 17, so just, be implemented in by the stepper motor output speed, by speed ratio is i=1/2, interior ball shield 5 is passed in motion, to realize the conversion of mask bit and working position.More than inside and outside ball shield assemble the back and be fixed on the base 23 with the bearing bridge 20 of interior ball shield, promptly finish the integral body assembling of γ dot source device.This crust of the device 21 usefulness corrosion resistant plates are packed, and shield the faint radiation of depleted uranium.
The motion of this device is achieved in that when being responsible for the ICT complete machine computer PC of control automatically, temporal information and the pulse equivalency set are transferred to stepper motor 1, the bevel pinion 2 that is contained in the stepper motor axle head is meshed with bevel gear wheel 3 on being contained in axle 17, to move with speed ratio i=1: 2 reductions of speed are passed to interior ball shield 5, use press fit to be fixed on the γ point source of interior ball shield like this, realize the conversion of working position and screening-off position, when the γ point source goes to the cylindrical point of contact O ' (being the center of optical collimator) of inside and outside circle shield is the working position of γ point source, when the center O of rotating 180 ° of ball shields outside the γ point source goes to " time be screening-off position.
Advantage of the present invention is that shielding properties is reliable, compact conformation, and the positional precision height in source is easy to operate, meets the requirement of international source apparatus.
Description of drawings:
Fig. 1, principle schematic Fig. 5, γ point source structural drawing
Fig. 2, front view
Fig. 3, vertical view
Fig. 4, left side partial cutaway schematic
Embodiment 1; Introduce the example that the present invention uses below on first batch of National Torch Plan project ICT (industrial computed tomography imaging) model machine.
Above each figure is described as follows as drawing: on the excircle of ball shield 5, the position on Fig. 2 front view was the working position of γ point source 6 in the 6 usefulness press fits of γ point source were assemblied in, and ray penetrates and works from optical collimator 7.Optical collimator 7 is screwed on the end face of ball shield 8 outside preceding.Interior ball shield 5 rotates 180 °, and 6 of γ point sources are in the center O of outer ball shield 8,9 " locate, realize masked state.Above motion realizes according to the following steps: computing machine is transferred to stepper motor 1 with the pulse equivalency of setting and drives the bevel pinion 2 that is fixed on the output axle head with flat key, again motion is passed to flat key and be fixed on the bevel gear wheel 3 of axle on 4,3 with speed ratio I=1: 2 deceleration is passed to motion axle 4 and is fixed on interior ball shield 5 on this with flat key, 5 drive 6 ball shield 8,9 transmissions to foreign round mutually of γ point source, realize the conversion of γ point source 6 working positions or mask bit.
The repeatable accuracy that γ point source 6 circumference rotate was divided into for two steps and realizes, at first was with mechanical spring register pin 10, acted in the taper hole of bevel gear wheel 3 and realized pre-determined bit, and then the precision that can be controlled by pulse equivalency is made fine positioning.γ point source 6 guarantees promptly that with respect to exact position-this position of all detector on the ICT complete machine detector display the background of each detector reception information counts error in the allowed band of complete machine error distribution, and it is to be realized by the three-dimensional fine setting piezoelectric crystal of external coordination development.Same structure is not installed with this by this mechanism, is omitted at this.
Primary clustering is as follows:
1,
60The Co-source component: active nose bar cun position Φ 4 * 4mm, physical dimension Φ 6 * 8mm, source strength 50Ci (Curie), shell are the stainless steel packing, see Fig. 5, its structure is described as follows: 31 are
60CO; 32 is Stainless Steel Shell; 33 is pad; 34 is gland.
2, shield assembly: the 6 usefulness press fits of γ point source are assemblied on the circumference of interior ball shield, the diameter of interior ball shield is about 1/2 of outer ball shield 8,9 diameters, its assembly center is positioned at 1/2 place of outer ball shield 8,9 horizontal direction radiuses, interior ball shield is 8,9 rotations of ball shielding to foreign round mutually as the center, three grade packaged requirements are calculated according to national standard, the cylindrical bulb diameter is 210mm, and interior ball diameter is 110mm.
3, optical collimator 7: its effect is the fladellum that forms certain altitude and width, the high 2mm in hole, and wide 4mm, segment angle are benchmark with the horizontal center line, see Fig. 1, α
1=48 °, α
2=59.5 °, material is a tungalloy, is fixed on the front end face of outer ball shield 8.
The major parameter table
Sequence number | Title | Technical parameter |
????1 | Radioactive source | Material 60CO point source, ray γ, source strength 50Ci, active region size Φ 4 * 4mm |
????2 | Interior cylindrical shield body | Diameter of phi 110mm; Material: depleted uranium: density 18.75g/cm 3 |
????3 | The outside cylinder shield | Diameter of phi 210mm; Material: depleted uranium: density 18.75g/cm 3 |
????4 | Optical collimator | Hole height * wide=2 * 4mm, fan angle alpha 1=48°,α 2=59.5 °, material: tungalloy |
????5 | Stepper motor | Model 86BYG001, diameter of axle Φ 9.5mm, 4 phases, 1.8 ° of stepping angles, error ± 0.18 ° |
????6 | Source revolution bearing accuracy | Machinery pre-determined bit ± 0.20mm, automatic control location 0.05mm |
????7 | Position, source three-phase trimming precision | Range 1mm, trimming precision ± 0.005~± 0.01mm (choosing wantonly) |
????8 | Radiation safety dosage | Less than 200mr/h, meet country's three grade packaged standards |
????9 | Overall dimensions | 475×300×273mm |
????10 | Weight | ≈150Kg |
Claims (4)
1, a kind of "
60The Co-gamma ray dot source device ", it is characterized in that: adopting with the depleted uranium is two ball shield structures of material.Outer ball shield 8,9, on the radius of optical collimator 7 directions, the mid point of crown radius is center of circle O ' in addition, 1/2 of the exradius of ball shield 8,9 is radius in addition, forms the spherical pore of ball shield 5 in the dressing.Because assembling and arts demand, the vertical located of the spherical pore center of circle O ' of ball shield 8,9 is divided into forward and backward two halves outside, outer ball shield 8 and back outer ball shield 9 before being called, in packing into behind the ball shield 5, aim at anti-radiation leakage seam, with 6 bolts 14, with forward flange 12, rear flange 13, preceding outer ball shield 8, the outer ball shield 9 in back is assembled into an integral body.The front end of ball shielding 8 is equipped with optical collimator 7 outside preceding.Interior ball shield 5, be contained on the axle 4 with flat key 15, two ends with axle 4, be contained in respectively on two thrust ball bearings 22, thrust ball bearing 22 is contained in respectively on shell 21 and the bearing bridge 20, the input end of axle 4 is equipped with bevel gear wheel 3 with flat key 16, bevel gear wheel 3 is meshed with the bevel pinion 2 of the axle head that is fixed on stepper motor 1 with flat key 17, so just, be implemented in by the stepper motor output speed, by speed ratio is i=1/2, interior ball shield 5 is passed in motion, to realize the conversion of mask bit and working position.
2, according to claim 1 "
60The Co-gamma ray dot source device ", it is characterized in that: adopt two ball shields.The 6 usefulness press fits of γ point source are contained on the excircle of interior ball shield 5, the diameter of interior ball shield be outer ball shield 8,9 1/2, its assembly center is positioned at outer ball shield 8,9,1/2 place of radius on the optical collimator 7 direction horizontal lines, and as 8,9 of the ball shield rotations to foreign round mutually of the middle O ' heart.According to three grade packaged criterion calculation of national standard radiation source, the cylindrical bulb diameter is 210mm, and interior ball diameter is 110mm.
3, according to claim 2 "
60The Co-gamma ray dot source device ", it is characterized in that: the interior ball shield 5 of two ball shielding constructions and the material of outer ball shield 8.9 are that employing is made the depleted uranium that gamma-rays has best shielding properties, and the density of material of depleted uranium is 18.75g/cm
3
4, according to claim 3 "
60The Co-gamma ray dot source device ", it is characterized in that the structure of γ point source: 31 are
60Co; 32 is the stainless steel housing; 33 is pad; 34 is gland.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CNB011070838A CN1139940C (en) | 2001-01-31 | 2001-01-31 | Cobalt 60-gamma ray dot source device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CNB011070838A CN1139940C (en) | 2001-01-31 | 2001-01-31 | Cobalt 60-gamma ray dot source device |
Publications (2)
Publication Number | Publication Date |
---|---|
CN1314679A true CN1314679A (en) | 2001-09-26 |
CN1139940C CN1139940C (en) | 2004-02-25 |
Family
ID=4656037
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CNB011070838A Expired - Fee Related CN1139940C (en) | 2001-01-31 | 2001-01-31 | Cobalt 60-gamma ray dot source device |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN1139940C (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102723118A (en) * | 2012-06-26 | 2012-10-10 | 成都中核高通同位素股份有限公司 | Novel cobalt-60gamma source for after-loading therapy and manufacturing method thereof |
CN113238279A (en) * | 2021-05-10 | 2021-08-10 | 中国辐射防护研究院 | Radiation device capable of generating single pulse gamma ray |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101436439B (en) * | 2008-12-23 | 2011-09-28 | 镇江市亿华系统集成有限公司 | Gamma-ray follower for radioactive source |
-
2001
- 2001-01-31 CN CNB011070838A patent/CN1139940C/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102723118A (en) * | 2012-06-26 | 2012-10-10 | 成都中核高通同位素股份有限公司 | Novel cobalt-60gamma source for after-loading therapy and manufacturing method thereof |
CN113238279A (en) * | 2021-05-10 | 2021-08-10 | 中国辐射防护研究院 | Radiation device capable of generating single pulse gamma ray |
CN113238279B (en) * | 2021-05-10 | 2023-05-12 | 中国辐射防护研究院 | Radiation device capable of generating single pulse gamma rays |
Also Published As
Publication number | Publication date |
---|---|
CN1139940C (en) | 2004-02-25 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN1028607C (en) | Rotary cone focusing type gamma-ray radiation unit | |
CN1139940C (en) | Cobalt 60-gamma ray dot source device | |
CN2439714Y (en) | (60)Co-gama rays source device | |
Spoor et al. | Protection criteria | |
CN110189848A (en) | A kind of small-sized irradiation devices based on californium 252 neutron source | |
CN210983415U (en) | Radiation protection intelligent shielding system | |
JPS56101578A (en) | Radiation type tomography device | |
CN215375820U (en) | Flying spot scanning device for X-ray source | |
US3912935A (en) | Apparatus for eluting a daughter radioisotope from a parent radioisotope | |
CN2567569Y (en) | Gamma ray radiation device for container detection system | |
CN1173170C (en) | Gamma-ray radiation source device for container inspecting system | |
Narasimhan et al. | A new method for 99m Tc generator preparation | |
CN215375807U (en) | Robot for investigating source items in annular pipeline | |
CN204679189U (en) | For the shield assembly of radioactive sample neutron residual stress measurement | |
CN208172262U (en) | A kind of pipeline radioactive pollution detection device | |
Guo et al. | Research on the application of 22Na radiolocation detection technology in advanced manufacturing process control | |
CN212907115U (en) | Beam outlet shutter device of radioactive source critical device | |
CN104776946B (en) | Screening arrangement for radioactive sample neutron residual stress measurement | |
Reinhardt et al. | Angular distribution of fast photoneutrons | |
CN210973794U (en) | Positioning and rotating device for automatic seal cover taking system of nuclear waste steel drum | |
Bechtold et al. | Industrial applications of the Karlsruhe compact cyclotron | |
CN87205498U (en) | Shielding screen against double-ball ray | |
CN116872256B (en) | Shielding glove box | |
CN213642866U (en) | High specific activity cobalt-60 radioactive source for gyro rotary type radiosurgery treatment system | |
EP3452722B1 (en) | Pump for operation in radioactive environment |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C06 | Publication | ||
PB01 | Publication | ||
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C19 | Lapse of patent right due to non-payment of the annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |