CN204203474U - A kind of portable beam exposure apparatus - Google Patents
A kind of portable beam exposure apparatus Download PDFInfo
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- CN204203474U CN204203474U CN201420642158.4U CN201420642158U CN204203474U CN 204203474 U CN204203474 U CN 204203474U CN 201420642158 U CN201420642158 U CN 201420642158U CN 204203474 U CN204203474 U CN 204203474U
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Abstract
The utility model discloses a kind of portable beam exposure apparatus, comprise shield, be placed in the radioactive source in described shield, the radiation hole that described shield side is offered, be placed in described radiation hole for drawing the collimating apparatus of radioactive ray, also comprise one and be arranged at scattering chamber in described shield, for reducing the scattered radiation of described irradiation unit self, also comprise one and be arranged on radioactive stand in the through hole that described shield is offered, described radioactive stand adopts Liftable type design, during irradiation, radioactive source is positioned at center, scattering chamber, radioactive source produce ray through collimating apparatus and wherein arrange tungalloy collimation diaphragm collimation plastotype after form the field calibration work of reference radiation for fixed type environmental radiation monitor, described scattering chamber and described tungalloy collimation diaphragm reduce the occupational exposure dosage of scattered radiation in reference radiation and operating personnel.
Description
Technical field
The utility model relates to ionising radiation metering device, is specifically related to a kind of portable beam exposure apparatus.
Background technology
Along with the quick growth of Chinese national economy, need newly-built large quantities of nuclear facilities (as: nuclear power plant reactor, research nuclear reactor and Experiment Fast Reactor etc.) to meet energy development and the demand such as utilization, scientific research.For ensureing the safety of Radial-stricken Workers in Nuclear Industry, surrounding resident and environment, relevant laws and regulations must carry out Radiation monitoring work in nuclear facilities inside and surrounding area, fixed type environmental Radiation monitoring instrument is one of visual plant of nuclear facilities Radiation monitoring, can be provided for evaluating the very useful data such as environmental radiation pollution situation and development trend.
All be provided with multiple stage fixed type environmental γ radiation continuous monitor around most nuclear facilities, under field conditions (factors), when not having periodic calibration, the reliability of monitoring result just can not be protected in this kind of instrument long-term work.Specify that these measuring instruments should regularly be examined and determine in China national metrological verification regulations JJG 521-2006 " environmental monitoring X, γ radiation air kerma (absorbed dose) rate instrument ", standard GB/T 12379-90 " environment nuclear radiation monitoring regulation " and Environmental Technology specification HJ/T 61-2001 " radiation environmental monitoring technical manual ".But, the probe of stationary appliance, cable and measurement main frame are usually not easy to dismounting and install, in dismounting, install and easily cause damage in transport, and the censorship cycle is longer, have impact on the continuity of monitoring system data, these difficulties hinder the calibrating on schedule of stationary radiation instrument, and the applying unit of stationary appliance proposes strong demand to field calibration work.Therefore these are fixed or revocable dosage measurement instrument is also very important for scale to set up an accurate Reference radiation field.
Consult the patent " Portable multi-range reference radiation device " that Chinese Patent Application No. is CN201110392048, its structure comprises the radioactive source be placed in lead shield, be provided with longitudinal radioactive source in lead shield and promote passage, be provided with control rod in passage, described radioactive source is located at the lower end of control rod; Be provided with the collimating apparatus for drawing radioactive ray in the one side of lead shield, the outside of collimating apparatus is provided with plumbous attenuator; Lead shield body is divided into upper and lower two parts, can be convenient to load and unload radioactive source; Have employed simple tapered cone collimator, the cross section of tapered cone collimator is circular.
This utility model designs based on the test problems to stationary radiation instrument, but still fails effectively to solve the problem of the scattered radiation reduced in reference radiation.
In view of above-mentioned defect, the utility model creator obtains this creation finally through long research and practice.
Utility model content
The purpose of this utility model is, provides a kind of portable beam exposure apparatus, in order to overcome above-mentioned technological deficiency.
For achieving the above object, the technical solution adopted in the utility model is, provide a kind of portable beam exposure apparatus, comprising shield, radiation hole that the radioactive source be placed in shield, shield side are offered, being placed in described radiation hole for drawing the collimating apparatus of radioactive ray, it is characterized in that, also comprise a scattering chamber, described scattering chamber is arranged in described shield, be connected with described radiation hole, for reducing the scattered radiation in reference radiation.
Preferably, described collimating apparatus comprises at least two panels collimation diaphragm, and described collimation diaphragm is thrown in described radiation hole, is separated each other between diaphragm by a space, and each space is as the drip catcher of last diaphragm edge scatter photon.
Preferably, described collimation diaphragm selects tungsten alloy material.
Described irradiation unit also comprises a radioactive stand, and described radioactive stand is arranged in the through hole that described shield is offered, and described through hole is connected with described scattering chamber, and described radioactive stand can do oscilaltion action in described through hole.
Preferably, described radioactive stand bottom is connected with one for placing the source of bank savings box of described radioactive source, and upper end can combine with the locating unit that described irradiation unit is arranged, and described positioning unit is for locking described radioactive stand present position.
Preferably, described source of bank savings box also comprises a bonnet, changes described radioactive source for opening and closing tailgate.
Preferably, described irradiation unit also comprises a storage source capsule room, described storage source capsule room is arranged at below described scattering chamber, and be connected with described scattering chamber, for storing described source of bank savings box, described storage source capsule room expands the space in described scattering chamber simultaneously, is conducive to the scattered radiation reducing described irradiation unit self.
Preferably, described irradiation unit also comprises a stopper, and described stopper inserts when described irradiation unit non-working condition and has been equipped with in the described radiation hole of described collimating apparatus, the leakage of radioactive source radiation during for reducing non-working condition.
Preferably, described stopper tail end is provided with one for controlling the draw ring of stopper action, and the outside correspondence position of described irradiation unit is provided with a locking unit, for during non-working condition to the locking of plug position.
Preferably, described scattering chamber is preferably rectangular parallelepiped or cylindrical structure.
Preferably, described rectangular structure preferred size is 20mm × 20mm × 40mm.
Preferably, described shield comprises plumbous internal layer and steel plate is outer, and described steel plate skin is provided with steel plate as support, and steel plate inwall installs steel wire barb additional, prevents plumbous in handling process and outer wall loose, thus improves the intensity of device entirety.
Preferably, described irradiation unit also comprises the laser locator that sidepiece is installed, in order to guarantee that described radioactive source just irradiates instrument to be checked.
Preferably, described radioactive source is
137cs.
The beneficial effects of the utility model are: the scattering chamber in (1) described portable beam exposure apparatus and tungalloy collimation diaphragm reduce the occupational exposure dosage of scattered radiation in reference radiation and operating personnel.(2) setting of described storage source capsule room expands the space in described scattering chamber, is conducive to the scattered radiation reducing described irradiation unit self.(3) positioning unit that when locking unit that the stopper described in and described irradiation unit correspondence position are arranged prevents non-working condition, leakage (4) the described radioactive stand of x radiation x and described irradiation unit correspondence position are arranged prevents irregular operation.
Accompanying drawing explanation
Fig. 1 is the structure principle chart of the portable beam exposure apparatus embodiment one of the utility model;
Fig. 2 is the structure cut-open view of the portable beam exposure apparatus embodiment two of the utility model;
Fig. 3 is the field calibration schematic diagram of the portable beam exposure apparatus embodiment two of the utility model;
Fig. 4 is distance radioactive source 1 meter of radiation field uniformity analog result figure of the portable beam exposure apparatus embodiment two of the utility model;
Fig. 5 is the collimation field method principle schematic that the utility model portable beam exposure apparatus embodiment two field calibration adopts.
Embodiment
Below in conjunction with accompanying drawing and concrete embodiment, the utility model will be further described.
Consult shown in Fig. 1, for the structure principle chart of the portable beam exposure apparatus embodiment one of the utility model, as shown in fig. 1, the radiation hole 10 that described portable beam exposure apparatus comprises shield 8, the radioactive source 4 be placed in shield 8, shield 8 side are offered, described radiation hole 10 is placed in for drawing collimating apparatus 2 and a scattering chamber 5 of radioactive ray.Wherein, described shield 8 has good shield effectiveness, for shielding the radiation that described radioactive source 4 leaks, prevent the diffusion that outwardly exceeds standard, described collimating apparatus 2 is for retraining shape and the size of radiotherapy beam, described scattering chamber 5 is arranged in described shield 8, is connected with described radiation hole 10, for reducing the scattered radiation of described irradiation unit self.
During use, the ray that described radioactive source 4 produces in described scattering chamber 5, after the collimating apparatus 2 in described radiation hole 10 collimates plastotype, forms the field calibration work that reference radiation is used for fixed type environmental radiation monitor.
Like this, described collimating apparatus 2 and scattering chamber 5 reduce the occupational exposure dosage of scattered radiation in reference radiation and operating personnel.
Consult as shown in Figure 2, for the structure cut-open view of the portable beam exposure apparatus embodiment two of the utility model, as shown in FIG., described portable beam exposure apparatus comprises radioactive stand 1, collimating apparatus 2, stopper 3, radioactive source 4, scattering chamber 5, source of bank savings box 6, stores source capsule room 7 and shield 8.Wherein, described radioactive stand 1 is arranged in the through hole that described shield 8 is offered, lifting action can be carried out in described through hole, described scattering chamber 5 is positioned at described shield 8, and be connected with described through hole, described collimating apparatus 2 is arranged in the radiation hole 10 offered described shield 8 side, described radiation hole 10 is connected with described scattering chamber 5, described source of bank savings box 6 is arranged at the bottom of described radioactive stand 1, it is inner place described in radioactive source 4, and be provided with a bonnet, described radioactive source 4 is changed for opening and closing tailgate, described storage source capsule room 7 is arranged in described shield 8, be positioned on the downside of described scattering chamber 5, and be connected with described scattering chamber 5, described stopper 3 can fill in described being equipped with in the described radiation hole 10 of described collimating apparatus 2.
Described shield comprises plumbous internal layer 8 and steel plate skin 9, the ray that described plumbous internal layer 8 radiates for shielding described radioactive source, and prevent all directions in environment to overflow radiation, it has good shield effectiveness and higher intensity; Described steel plate outer 9 is the steel plate that 7mm is thick, and be provided with steel plate as support, steel plate inwall installs steel wire barb additional, prevents plumbous in handling process and outer wall loose, thus improves the intensity of device entirety.
Described radioactive source is
137cs, its active region is the right cylinder of φ 4mm × 4mm, and density is 3.988g/cm
3, outside, active region is surrounded by stainless steel cladding, and radioactive source physical dimension is the right cylinder of φ 8mm × 10mm, can radiate gamma-rays.
Described collimating apparatus 2 is arranged in the radiation hole 10 of described shield 8 side, described radiation hole 10 is connected with described scattering chamber 5, described collimating apparatus is for drawing radioactive ray and radiation ray being carried out to the constraint of shape and size, four collimation diaphragms are provided with in collimating apparatus described in the present embodiment, described collimation diaphragm is made up of tungalloy (W89%, Ni7%, Cu4%), and density is 17g/cm
3.Atmospheric density is 0.001293g/cm
3, be made up of oxygen (23.2%), nitrogen (76%) and the element such as carbon and argon (0.8%); Four described collimation diaphragms, thickness is from inside to outside followed successively by 1.5cm, 1.5cm, 1.5cm and 0.5cm, and subtended angle is 12 °, is separated each other between diaphragm by the space of 20mm, and each space is as the drip catcher of last diaphragm edge scatter photon.In order to understand the impact of collimation diaphragm on radiation field uniformity, MCNP is utilized to cover the card process simulation horizontal homogeneity of Reference radiation field, laterally place multiple little rectangular parallelepiped counting lattice cell at distance radioactive source 1m place respectively and analog computation is carried out to radiation field uniformity, obtain as shown in Figure 4, for the distance radioactive source 1m place radiation field uniformity analog result figure of the portable beam exposure apparatus embodiment two of the utility model, learnt by result: because collimation diaphragm is to the plastotype effect of radiation field, distance radioactive source 1m place, within the scope of beam axle center ± 11cm, homogeneity is better than 5%, meet design requirement.
Described scattering chamber 5 is arranged in described shield 8, be connected with the radiation hole 10 of described radioactive stand 1 with described shield 8 side, for reducing the scattered radiation of described irradiation unit self, its effect larger of scattering chamber is more obvious, but also greatly can increase the weight of device.MCNP program is utilized to simulate the reference radiation that different scattering chambeies irradiation unit produces, the scattering diluent dose rate calculating distance radioactive source 1m place accounts for (mainly comprising: self scattering and air scattering) number percent of accumulated dose rate, and result of calculation is as shown in table 1 below:
Table 1: the scattered radiation in different scattering chamber
As shown in Table 1: the diameter in cylindrical scattering chamber is less to influence of scattered radiation, the height h in scattering chamber is comparatively large on the impact of scattered radiation, and that is the height in scattering chamber is higher, and the scattered radiation brought by irradiation unit shielding main body is less.Under condition when the height in right cylinder scattering chamber is equal with the height in rectangular parallelepiped scattering chamber at same size, rectangular parallelepiped scattering chamber is less than the scattered radiation in right cylinder scattering chamber.Therefore, according to analog result, scattering chamber is designed to the rectangular parallelepiped of 20mm × 20mm × 40mm (height), the dose rate of scattered radiation in Reference radiation field can be made minimum, be 3.2% of accumulated dose rate, meet the requirement of relevant criterion.Described scattering chamber also can be rectangular parallelepiped or the cylindrical structure of other sizes.
Described stopper 3 is formed primarily of tungalloy, can insert described collimating apparatus 2 from irradiation unit outside, for the protection to device inside after testing, its tail end is provided with one for controlling the draw ring of tungalloy stopper action, and screwed enters the threads hole of described stopper 3; The outside corresponding described draw ring position of described irradiation unit is provided with a locking unit, described locking unit comprises one with the banking stop of spacing hole, described banking stop one end is connected by bolt and nut combined moving with described irradiation unit, the effect of the other end by realizing locking to the handling of another bolt and nut group and unclamp, wherein said spacing hole can limit described draw ring when described shown unit lockup state and pull described stopper, make like this stopper can not non-working condition time open, enhance security.
Described emissive source support 1 material is aluminium alloy, by aluminium (93.5%), silicon (0.5%) and other elements as: iron and copper etc. (altogether 6%) form, and density is 2.78g/cm
3; It is arranged in the through hole that described shield 8 is offered, described through hole is connected with described scattering chamber 2, described radioactive stand 1 can do oscilaltion action in described through hole, its bottom is connected with one for placing the source of bank savings box 6 of described radioactive source 4, the described radioactive source 4 in described source of bank savings box 6 is made to be positioned at the center of described shield 8 by lifting action, this lifting action can hand-operated lifting, may also be other modes and is elevated.Described radioactive stand 1 upper end can combine with the locating unit that described irradiation unit is arranged, for locking described radioactive stand present position, in the present embodiment, it is fixing that described positioning unit is that bolt connecting mode completes the location, upper end of described radioactive stand, thus avoid informal operation; Also be fixed on the positioning by other modes.
Described source of bank savings box 6 is connected with the bottom of described radioactive stand 1, and the described radioactive source 4 of inner placement, described source of bank savings box 6 comprises a bonnet, realizes the replacing of radioactive source for opening and closing tailgate.
Described storage source capsule room 7 is arranged at below described scattering chamber 5, for storing described source of bank savings box 5, have also been enlarged the space in described scattering chamber 5 simultaneously, the height in especially described scattering chamber, higher by the height in above-mentioned test known scattering chamber, the scattered radiation brought by irradiation unit shield is less, is therefore conducive to the scattered radiation reducing described irradiation unit self.
Described irradiation unit also comprises the laser locator that sidepiece is installed, in order to guarantee that described radioactive source just irradiates instrument to be checked.
Described irradiation unit is overall to be formed primarily of lead, tungalloy and stainless steel, has good shield effectiveness, built-in
137(activity is 1.85 × 10 to Cs radioactive source
8bq) fluence through radiation can be reduced to the per mille of useful beam, meet the technical requirement of " scattered radiation dose rate is not more than 5% of accumulated dose rate " of standard GB/T/T12162.1-2000; And the general assembly (TW) of described irradiation unit is about 38kg, reach light portable effect.
A laser range finder is also needed, for determining the distance between radioactive source and instrument reference point to be checked in practical operation; And a tripod, described irradiation unit is located on adjustable for height aluminum alloy tripod, and tripod height adjustment range is 690mm ~ 1300mm, this tripod load-bearing 90kg, deadweight 7kg.
Consulting shown in Fig. 3, is the field calibration schematic diagram of the portable beam exposure apparatus embodiment two of the utility model.When actual field calibration uses, height is carried out to described tripod 22 and regulates, make described irradiation unit 20 be in isometry position with test system 21; Unclamp the stopper 3 described in the taking-up of outside locking device, regulate described radioactive stand 1 to carry out oscilaltion adjustment, and lock its present position; Laser range finder described in utilization, determines the distance between described radioactive source and meters under test reference point; Open laser locator, in order to guarantee that described radioactive source just irradiates instrument to be checked.
During irradiation, described radioactive source 4 is positioned at center, described scattering chamber 5, and the gamma-rays that radioactive source 4 produces forms the field calibration work of reference radiation for fixed type environmental radiation monitor after the tungalloy collimation diaphragm collimation plastotype of described collimating apparatus 2.This irradiation unit is 1.85 × 10 with the use of activity
8bq's
137cs radioactive source can provide dose rate to be the reference radiation of 0.5 μ Gy/h ~ 12.8 μ Gy/h (distance 1m ~ 5m), substantially covers whole ranges of ambient level dose rate instrument.
Consulting shown in Fig. 5, is the collimation field method principle schematic that the utility model portable beam exposure apparatus embodiment two field calibration adopts.Described " collimation field " method utilizes reference instrument to portable
137in the radiation field that Cs gamma-rays irradiation unit provides, certain any dose rate is demarcated, and revises the half life period of radioactive source.As shown in Figure 5, certain check point air kerma rate in radiation field
when known, the calibration factor N of instrument
iavailable following formula obtains:
(1) N in formula
ifor by the calibration factor of school instrument (dimensionless); M
ifor by the measured value of school instrument (unit: μ Gy/h);
for the conventional true value (unit: μ Gy/h) of air kerma rate.Select the two continuous monitoring points of Environmental γ-Radiation dose rate, place (the total floss hole monitoring point of radioactive waste and monitoring point, weather station) as exemplary field, field calibration is carried out to fixed type environmental γ radiation dose rate instrument.Radioactive source in portable irradiation unit is placed in the scope of distance field instrument verification point 1.5m-3m by the actual conditions according to place, irradiation unit and field instrument are with high (1.4m), the reference point utilizing laser aligner to be placed on by the check point of field instrument in radiation field is irradiated, and field calibration schematic diagram as shown in Figure 3.
In order to verify the feasibility of field calibration, being sent to after the stationary appliance of two place's exemplary field is dismantled in the gamma-rays air kerma standard laboratory in ionising radiation one-level test satellite location and calibrating, obtaining experimental data as shown in table 2 below:
Table 2: calibration experiments data
Wherein, sequence number 1-3 point is the field calibration data of the continuous monitoring point of radioactive waste total floss hole radioactive environment γ radiation dose rate, and sequence number 4-7 point is the field calibration data of the continuous monitoring point of radioactive environment γ radiation dose rate, weather station; Field instrument reading has deducted background radiation dose rate, and S300 represents that irradiation unit is positioned at the south of field instrument, and radioactive source is 300cm to field instrument reference point distance, and other are similar.
As shown in table 2, the relative error of the calibration factor that the field calibration factor of two place fixed type environmental γ radiation dose rate instrument and laboratory obtain within 1%, illustrate utilize portable
137cs irradiation unit can solve a field calibration difficult problem for fixed type environmental γ radiation dose rate continuous monitor table preferably.
Like this, the design of the collimation diaphragm described in practical operation and the design in scattering chamber reduce the occupational exposure dosage of scattered radiation in reference radiation and operating personnel, and the optimal design in described scattering chamber also significantly reduces the scattered radiation that irradiation unit self produces simultaneously; With the use of
137cs emissive source can substantially covers whole ranges of ambient level dose rate instrument; And own wt only about 38kg, comparatively lightly easily to carry.
The above is only preferred implementation of the present utility model, protection domain of the present utility model be not only confined to above-described embodiment, and all technical schemes belonged under the utility model thinking all belong to protection domain of the present utility model.It should be pointed out that for those skilled in the art, do not departing from the some improvements and modifications under the utility model principle prerequisite, these improvements and modifications also should be considered as protection domain of the present utility model.
Claims (10)
1. a portable beam exposure apparatus, comprising shield, radiation hole that the radioactive source be placed in described shield, described shield side are offered, being placed in described radiation hole for drawing the collimating apparatus of radioactive ray, it is characterized in that, also comprise a scattering chamber, described scattering chamber is arranged in described shield, is connected with described radiation hole.
2. portable beam exposure apparatus as claimed in claim 1, is characterized in that, described collimating apparatus comprises at least two panels collimation diaphragm, and described collimation diaphragm is thrown in described radiation hole, is separated each other between described collimation diaphragm by a space.
3. portable beam exposure apparatus as claimed in claim 1, it is characterized in that, described irradiation unit also comprises a radioactive stand, described radioactive stand is arranged in the through hole that described shield is offered, described through hole is connected with described scattering chamber, and described radioactive stand can do oscilaltion action in described through hole.
4. portable beam exposure apparatus as claimed in claim 3, it is characterized in that, described radioactive stand bottom is connected with one for placing the source of bank savings box of described radioactive source, upper end can combine with the locating unit that described irradiation unit is arranged, and described positioning unit is for locking described radioactive stand present position.
5. portable beam exposure apparatus as claimed in claim 4, is characterized in that, described source of bank savings box is provided with a bonnet, changes described radioactive source for opening and closing tailgate.
6. the portable beam exposure apparatus as described in claim 4 or 5, it is characterized in that, described irradiation unit also comprises a storage source capsule room, and described storage source capsule room is arranged at below described scattering chamber, and be connected with described scattering chamber, for storing described source of bank savings box.
7. portable beam exposure apparatus as claimed in claim 2, is characterized in that, described irradiation unit also comprises a stopper, and described stopper inserts when described irradiation unit non-working condition and has been equipped with in the described radiation hole of described collimating apparatus.
8. portable beam exposure apparatus as claimed in claim 7, it is characterized in that, described stopper tail end is provided with one for controlling the draw ring of stopper action, the outside corresponding described draw ring position of described irradiation unit is provided with a locking unit, and described locking unit is for the locking to plug position during non-working condition.
9. portable beam exposure apparatus as claimed in claim 1, is characterized in that, described scattering chamber is rectangular parallelepiped or right cylinder.
10. portable beam exposure apparatus as claimed in claim 9, is characterized in that, described cuboid dimensions is 20mm × 20mm × 40mm.
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| CN201420642158.4U CN204203474U (en) | 2014-10-30 | 2014-10-30 | A kind of portable beam exposure apparatus |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104345335A (en) * | 2014-10-30 | 2015-02-11 | 中国原子能科学研究院 | Portable radioactive ray irradiation device |
| CN106772549A (en) * | 2017-01-06 | 2017-05-31 | 中国工程物理研究院核物理与化学研究所 | A kind of point-like radiation source device |
| CN107807136A (en) * | 2017-09-29 | 2018-03-16 | 中国船舶重工集团公司第七〇九研究所 | A kind of radioactive skin damages accuracy of measurement calibration equipment and its method of work |
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2014
- 2014-10-30 CN CN201420642158.4U patent/CN204203474U/en active Active
Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104345335A (en) * | 2014-10-30 | 2015-02-11 | 中国原子能科学研究院 | Portable radioactive ray irradiation device |
| CN106772549A (en) * | 2017-01-06 | 2017-05-31 | 中国工程物理研究院核物理与化学研究所 | A kind of point-like radiation source device |
| CN107807136A (en) * | 2017-09-29 | 2018-03-16 | 中国船舶重工集团公司第七〇九研究所 | A kind of radioactive skin damages accuracy of measurement calibration equipment and its method of work |
| CN107807136B (en) * | 2017-09-29 | 2020-06-30 | 中国船舶重工集团公司第七一九研究所 | Measuring accuracy calibration device of radioactive aerosol monitor and working method thereof |
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