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(a)Time
Radiation dose is proportional to the time spent
in the radiation field. Work in a radiation area
should be carried out quickly and efficiently.
More time spent in a radiation area, receive
more radiation
Less time spent in a radiation area, receive less
radiation
Example-1: You are working in a facility where
radiation dose level is found 01 µSv/hr. If you
do stay in this area about 60 minutes per day.
How much radiation you will receive in a year?
[5 days a week, 50 weeks a year.]](https://image.slidesharecdn.com/l-15radiationshieldingprinciples-210221160659/75/L-15-radiation-shielding-principles-ppt-5-2048.jpg)
![12
Radioactive source activity cont’d
Example-3: A 20 Ci Ir-192 is to be used in open place to
perform Industrial radiography. What distance is to be
maintained to produce control area boundary layer
keeping dose level within 7.5 µSv/hr ? [ 01 Ci=37GBq]
dose rate = gamma factor x activity/(distance)2
Example-4: A dose rate is of 2 mSv/hr is measured at 15
cm from a Cesium-137 source. What is the source’s
activity?
Example-5 : A 40 Ci (17/05/2011) Ir-192 was bought
to be used in open place to perform Industrial
radiography. What distance is to be maintained to
produce control area boundary layer keeping dose level
within 7.5 µSv/hr ? [Half life of Ir-192 is 73 days]](https://image.slidesharecdn.com/l-15radiationshieldingprinciples-210221160659/75/L-15-radiation-shielding-principles-ppt-12-2048.jpg)
![13
Solution
Example-3:
Activity = 20 Ci = 740 GBq
dose rate = gamma factor x activity/(distance)2
Distance, d = [0.13x740x1000/7.5]1/2
d = 113.3 meter (Ans)
Example-4: dose rate = gamma factor x
activity/(distance)2
= (0.081x
activity)/0.0225 mSv/hr
Activity = (2x 0.0225)/0.081
= 0.556 GBq](https://image.slidesharecdn.com/l-15radiationshieldingprinciples-210221160659/75/L-15-radiation-shielding-principles-ppt-13-2048.jpg)
Uploaded byMahbubul Hassan
L 15 radiation shielding principles. ppt
The document discusses principles of radiation shielding, including different types of radiation and common shielding materials. It describes three basic principles for controlling external radiation: time, distance, and shielding. Shielding methods include using thickness of lead, concrete, steel or other materials to reduce radiation intensity based on half-value layer and tenth-value layer measurements.
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L 15 radiation shielding principles. ppt
- 1. 1 5TH Training Courseon Radiation Protection for Radiation Control Officers (RCO) of Industrial Practices Bangladesh Atomic Energy Regulatory Authority 06-09 November 2017 L-15 : Principle of Radiation Shielding Md. Mustafijur Rahman Principal Engineer Bangladesh Atomic Energy Regulatory Authority
- 2. 2 1. Introduction Purposeof radiation shielding is to reduce the radiation exposure level to persons in the vicinity of radiation sources to a certain predetermined level There are several different types of radiation, such as: - alpha particle, - beta particle, - gamma and x-rays, and - neutron rays. These have different energy and flux levels. accordingly, they are very hazardous to human health and environment. These types of radiation results due to radioactive decay of different radioactive isotopes.
- 3. 3 There aredifferent types of common shielding materials corresponding to each type of radiation. As energy levels increase, the complexity of the required shield also increases 1. Introduction (Contd….)
- 4. 4 2. Control ofExternal Radiation There are three basic principle for control of external radiation; (a) Time (b) Distance and (c) Shielding
- 5. 5 (a)Time Radiation doseis proportional to the time spent in the radiation field. Work in a radiation area should be carried out quickly and efficiently. More time spent in a radiation area, receive more radiation Less time spent in a radiation area, receive less radiation Example-1: You are working in a facility where radiation dose level is found 01 µSv/hr. If you do stay in this area about 60 minutes per day. How much radiation you will receive in a year? [5 days a week, 50 weeks a year.]
- 6. 6 Solution Dose =Dose rate X Time Here, Time = 5x60x50/60 hrs = 250 hrs Total Radiation received = 1x250 µSv = 250 µSv
- 7. 7 (b) Distance Ionizingradiation in air travel in straight lines. In such circumstances the radiation simply diverges from a radioactive source and the dose rate decreases as the inverse square of the distance from the source. i,e: I1d1 2 = I2 d2 2 S d2, I2 d1, I1
- 8. 8 (b) Distance Consideringdistance, there are two different approaches based on which radiation level can be measured; (1) Reference dose level and (2) Radioactive source activity
- 9. 9 1. Reference doselevel Example-2: A dose rate of 03 mSv/hr is measured at 04 meter from a gamma emitting source. At what distance will the dose rate be reduced to 7.5 µSv/hr? Solution: I1 = 03 mSv/hr, d1 = 04 m, I2= 7.5 µSv/hr, d2=? I1d1 2 = I2 d2 2 03x16 = 7.5/1000 x d2 2 d = 80 meter (Ans)
- 10. 10 (2) Radioactive sourceactivity Here the term Gamma factor/Rhm is important. Gamma factor: Gamma factor is the absorbed dose rate in mSv/hr at 01 meter from 1 GBq of the radionuclide.
- 11. 11 (2) Radioactive sourceactivity The value of Gamma Factor for different sources Radioisotopes (Gamma Factor)Dose rate mSv/hr/GBq at 1 meter Ir-192 0.13 Co-60 0.351 Cs-137 0.081 Yb-169 0.0007
- 12. 12 Radioactive source activitycont’d Example-3: A 20 Ci Ir-192 is to be used in open place to perform Industrial radiography. What distance is to be maintained to produce control area boundary layer keeping dose level within 7.5 µSv/hr ? [ 01 Ci=37GBq] dose rate = gamma factor x activity/(distance)2 Example-4: A dose rate is of 2 mSv/hr is measured at 15 cm from a Cesium-137 source. What is the source’s activity? Example-5 : A 40 Ci (17/05/2011) Ir-192 was bought to be used in open place to perform Industrial radiography. What distance is to be maintained to produce control area boundary layer keeping dose level within 7.5 µSv/hr ? [Half life of Ir-192 is 73 days]
- 13. 13 Solution Example-3: Activity= 20 Ci = 740 GBq dose rate = gamma factor x activity/(distance)2 Distance, d = [0.13x740x1000/7.5]1/2 d = 113.3 meter (Ans) Example-4: dose rate = gamma factor x activity/(distance)2 = (0.081x activity)/0.0225 mSv/hr Activity = (2x 0.0225)/0.081 = 0.556 GBq
- 14. 14 © Shielding Thereare two approaches; (1) Thumb rules approaches (2) Theoritical approaches
- 15. 15 (1) Thumb rulesapproaches The radiation shielding capacity of materials can be measured in terms of Half-Value Layer (HVL) and Tenth-Value Layer (TVL) (a) Half Value Layer (HVL): The HVL is defined as the thickness of shielding material required to reduce the radiation intensity to one-half of its original value (b) Tenth Value Layer (TVL): The TVL is defined as the thickness of shielding material required to reduce the radiation intensity to one-tenth of its original value
- 16. 16 HVL and TVL Atable of HVL and TVL values for radioisotopes and common shielding materials Shielding Material and Thickness (cm) Source Ir-192 Co-60 Concrete TVL 14.74 22.86 HVL 4.82 6.85 Steel TVL 2.90 7.36 HVL 0.87 2.20 Lead TVL 1.62 4.11 HVL 0.48 1.24 Tungsten TVL 1.09 2.62 HVL 0.33 0.79 Uranium TVL 0.93 2.29 HVL 0.28 0.69
- 17. 17 Radiation Lead Concrete HVLTVL HVL TVL (a) 100 kVp X-rays 0.026 0.087 1.65 5.42 (b) 200 kVp X-rays 0.043 0.142 2.59 8.55
- 18. 18 Example-6 A container containingCo-60 gamma radiation source inside it. The radiation dose rate at the surface of this container is 20 µSv/hr. (a) If additional 2.2 cm thickness steel sheet is attached to the container for shielding, what will be the surface dose ? (b) What thickness of additional steel sheet is required to reduce the surface dose below 02 µSv/hr ?
- 19. 19 (d) MULTILAYERED SHIELDS The buildup factor is defined as the ratio of the actual gamma flux to that which would be calculated using a simple exponential attenuation with the linear absorption coefficient. The gamma ray buildup factor represents a necessary correction factor in the design calculations of the reactors shielding, medical physics field and nuclear laboratories, where the shielding is an important principle to protection from nuclear radiation. Importance of Buildup Factor: It will be observed that the numerical values of Bm can be very large, which shows the importance of the buildup of scattered radiation in shielding calculation. This means that if buildup were omitted from a calculation of the effectiveness of such a shield, the resulting exposure rate would be in error . The buildup factor, therefore, cannot be ignored.
- 20. 20 The buildupflux at P is depend upon which of the two layers comes first. Thus while a monoenergetic flux incident on the first region and producing a continuous spectrum incident on the second, gives one value of Фb at P, AND If the media are interchanged, Фb would not be the same. And, indeed, the two values of Фb in general, are different. Consider, for example, 0.5-MeV gamma-rays incident on layers composed of lead and water. It will be seen that the buildup factor of water (35.9) is much larger than that of lead (2.08) for the same thickness (10 Mean free path). It follows that there is a greater buildup of low-energy scattered radiation in water than in lead. Because in water, the low-energy radiation propagates with little photoelectric absorption. In lead, by contrast, owing to its high value of Z, photoelectric absorption is important at low energies and a buildup of low-energy radiation Is not possible. (d) Multilayered Shields
- 21. 21 If, therefore,the water were placed before the lead, the buildup radiation from the water would be absorbed as it passed through the lead, and the overall buildup through the shield would be small. On the other hand, if the lead were placed before the water, the subsequent buildup of radiation in the water would reach the observer and the overall buildup would be larger. Unfortunately, there is no simple way to obtain the exact value of the buildup factor for a layered shield in terms of the buildup factors of each layer. (d) Multilayered Shields
- 22. 22 Example-7 (a) You arecarrying an industrial radiographic source into exposure projector through the vehicle from storage pit to working place. During carrying the source, surface radiation level of that projector was about 01 mSv/hr. What arrangement to be made such that the vehicle driver can receive the dose within 02 µSv/hr? (b) A dose rate is of 2 mSv/hr is measured at 02 cm from a Cobalt-60 source container surface that one is used for nucleonic gauge purpose. During maintenance work this source is to be kept into safe and secured storage room. What arrangement to be made such that the general workers around there can do their routine work within Background Radiation level?
- 23.