Study on Dose Rate on the Surface of Cask Packed with Activated Cut-off Pieces from Decommissioned Nuclear Power Plant

Article information

J. Radiat. Prot. Res. 2020;45(4):178-186
Publication date (electronic) : 2020 December 31
doi : https://doi.org/10.14407/jrpr.2020.45.4.178
1Nuclear Decommissioning Technology & Business Development Team, Doosan Heavy Industries and Construction, Changwon, Korea
2RAF Team, KEPCO KPS, Naju, Korea
3Radiation & Environmental Laboratory, Korea Hydro & Nuclear Power Co. Ltd., Daejeon, Korea
4Nuclear Energy Team, KONES Corporation, Seoul, Korea
Corresponding author: Kwang Soo Park, Doosan Heavy Industries and Construction, 555-1 Gwigok-dong, Seongsan-gu, Changwon 51711, Korea, E-mail: kwangsoo.park@doosan.com, https://orcid.org/0000-0002-0442-472X
Received 2020 August 30; Revised 2020 October 15; Accepted 2020 October 30.

Abstract

Background

Reactor pressure vessel (RV) with internals (RVI) are activated structures by neutron irradiation and volume contaminated wastes. Thus, to develop safe and optimized disposal plan for them at a disposal site, it is important to perform exact activation calculation and evaluate the dose rate on the surface of casks which contain cut-off pieces.

Materials and Methods

RV and RVI are subjected to neutron activation calculation via Monte Carlo methodology with MCNP6 and ORIGEN-S program—neutron flux, isotopic specific activity, and gamma spectrum calculation on each component of RV and RVI, and dose rate evaluation with MCNP6.

Results and Discussion

Through neutron activation analysis, dose rate is evaluated for the casks containing cut-off pieces produced from decommissioned RV and RVI. For RV cut-off ones, the highest value of dose rate on the surface of cask is 6.97×10−1 mSv/hr and 2 m from it is 3.03×10−2 mSv/hr. For RVI cut-off ones, on the surface of it is 0.166×10−1 mSv/hr and 2 m from it is 1.04×10−1 mSv/hr. Dose rates for various RV and RVI cut-off pieces distributed lower than the limit except the one of 2 m from the cask surface of RVI. It needs to adjust contents in cask which carries highly radioactive components in order to decrease thickness of cask.

Conclusion

Two types of casks are considered in this paper: box type for very-low-level waste (VLLW) as well as low-level waste (LLW) and cylinder type for intermediate-level waste (ILW). The results will contribute to the development of optimal loading plans for RV and RVI cut-off pieces during the decommissioning of nuclear power plant that can be used to prepare radioactive waste disposal plans for the different types of wastes—ILW, LLW, and VLLW.

Introduction

When decommissioning a nuclear power plant, lots of metal wastes are produced and various studies have been carried out to characterize and to recycle them [13]. In South Korea, Kori Unit 1 is expected to be decommissioned and activation analysis for reactor pressure vessel (RV), reactor pressure vessel internal (RVI), and bio-shield has been carried out [4]. RV is composed of carbon steel and most RVI’s are composed of stainless steel type 304. The specific activities of RVI lie between 3.0×103 Bq/g and 6.0×109 Bq/g [4] depending on installation position in the core. In order to classify radioactive waste level and to make a plan for transportation and storage, the specific activity data is very important for RV and RVI components. Most irradiated RV and RVI are classified into very-low-level waste (VLLW), low-level waste (LLW), and intermediate-level waste (ILW) depending on the specific activity. After several years cooling period, the irradiated metal components shall be transported to the waste deposition site.

In order to transport RV and RVI components’ cut-off pieces safely, it is necessary to be cut into proper sized pieces. The cutting pieces are designed based on the load weight, radioactive waste level, and cask size. Thus, the cut-off pieces become smaller in order to load more possible and to decrease number of casks. The cask shape is also important parameter. In this study, two kinds of casks are considered such as the box type and the cylinder type. An optimization analysis for loading radioactive wastes is carried out to decrease number of casks and to minimize load burden.

In this paper, an optimal loading is suggested for RV and RVI components based on the load balanced and shielding analysis. The radiation shielding is one of the important parameters to transport radioactive wastes. Therefore, the Monte Carlo simulation is carried out to estimate the surface dose rate of various cases of cut-off pieces loaded in two kinds of casks.

In Section 2, a brief description is provided on the cutting procedure and loading strategy. Section 3 provides activation analysis simulation results and loading conditions. In Section 4, shielding analyses are carried out for various casks for RV and RVI components.

Materials and Methods

1. Cutting Procedure and Loading Strategy

Main materials of RV and RVI are stainless steel type 304, carbon steel (SA508 Grade 2 forged material) and Inconel as shown in Table 1. For the transportation of VLLW and LLW based on the activation calculation and cutting plan, box-type cask will be used as depicted in Fig. 1. The specification of box-type cask is described in Table 2. The allowed maximum content weight is about 10 ton and it is specially designed to load in under water condition. Therefore, stillage is equipped for the safe loading in the water, too. The stillage material is carbon steel and other body components are composed of stainless steel type 304. The main reason of using box-type casks for VLLW and LLW is to optimize the packing condition in the cask, so it is possible to reduce the number of casks. The most important things for decommissioning nuclear power plant are not only safety but also economy, even though safety is much more important. After RV and RVI are dismantled safely and cut-off pieces are produced, it is necessary to consider economy as achievable as possible in the second place. It means that radioactive waste disposal expense should be reduced with optimized cask packing design through dose rate evaluation on the surface of it. If the certified 200 L drum is used for VLLW and LLW, the estimated number of drum is about 484. However, only 48 box-type casks are required in order to store and pack the same contents. It is achieved both reduction of transportation burden and economic benefit considering movement from decommissioning site to disposal place. Fig. 2 shows loading examples when using the typical 200 L drum. It is found that lots of vacant area and inefficient regions exist in each drum. However, there is little vacant area in box-type cask and it is more efficient to store wastes.

RV and RVI Component and Material

Fig. 1

Box-type cask for radioactive waste package.

Specification of Box-Type Cask

Fig. 2

Loading example in 200 L drum for reactor pressure vessel.

For the purpose of ILW storage, cylinder-type cask is taken into consideration as depicted in Fig. 3. The specification of the cylinder-type cask is described in Table 3. Allowed maximum content weight is about 25 ton. Cask material is stainless steel type 304 which is good for both shielding capability and structural maintenance. Outer body of cask material is made of concrete whose thickness is about 41 cm.

Fig. 3

Cylinder-type cask for radioactive waste storage.

Specification of Cylinder-Type Cask

Two main strategies for packing plan are developed as follows. The first consideration item is to store as many cut-off pieces as possible in the cask. Thus maximum volume and weight become the main dependent parameters to be considered. The second one is to meet the radiation shielding requirement on the surface of it for safety. So, in order to store maximum loading contents, the size of each cut-off piece should be produced as much smaller, otherwise, it requires more number of casks and it becomes uneconomical. Thus, optimized cutting plan applying activation evaluation result and cask size should be prepared, and loading contents should meet satisfaction of dose rate on the surface of casks.

When RV is planned to be dismantled, several small cut-off pieces are produced due to complex and curved shape considering loading capacity in cask. As many small cut-off pieces as produced, cutting procedure also requires more time and man-power, so, cutting strategy should be prepared for all aspects. Fig. 4 shows an example of loading configurations for RV cut-off pieces in the box-type cask. As expected, various shapes of RV curvature play main role of planning cutting procedure. The thicknesses of box-type cask are designed as 2 cm for both RV and 20 cm for RVI components caused by the difference of radioactive waste level.

Fig. 4

An example of optimal loading for the box-type cask for reactor pressure vessel components.

Results and Discussion

1. Dose Rate Evaluation of Cask for RV and RVI Cut-off Pieces

MCNP6 [5] code is used to calculate the neutron flux distribution during irradiation period and ORIGEN-S [6] code is also used to evaluate isotopic inventories. From the analysis of 40 years irradiation, the total decay gamma intensity and spectrum are obtained by including various impurities for stainless steel type 304 and carbon steel [7]. In case of carbon steel in RV central region, the specific activities of various isotopes are tabulated in Table 4. Fig. 5 depicts the gamma spectrum after 10 year cooling for 1 g of carbon steel. Table 5 provides activation analysis results for stainless steel type 304 in RVI component. Fig. 6 also shows the gamma spectrum after 10-year cooling for 1 g of stainless steel type 304.

Isotopic Specific Activities for RV for Various Cooling Time

Fig. 5

Gamma spectrum for reactor pressure vessel for 10-year cooling.

Isotopic Specific Activities for RVI for Various Cooling Time

Fig. 6

Gamma spectrum for reactor pressure vessel internal for 10-year cooling.

The contents of RV and RVI components are classified based on the total activity for satisfaction of limit surface dose rate. Table 6 summarizes RV components. Lots of components are included such as RV main body, RV bottom head, a bottom-mounted instrumentation (BMI) nozzle, inlet and outlet nozzle, and insulation. Table 7 provides RVI components. One cask may contain several components based on the weight and total activity. Fig. 7 shows some typical casks which contain various RV and RVI components.

Cask Information for RV Components

Cask Information for RVI Components

Fig. 7

Several examples of cask loading configurations: (A) reactor pressure vessel (upper shell), (B) reactor pressure vessel internal (lower core plate), and (C) reactor pressure vessel internal (core barrel).

In order to transport safely RV and RVI cut-off pieces by using box and cylinder-type casks, the limit of surface dose rates are specified based on the Korean Nuclear Safety Law as follows:

  • - Surface of cask: 10 mSv/hr

  • - 2 m from surface: 0.1 mSv/hr

The box-type cask for RV components is modeled by MCNP6 in order to estimate dose rate. The model is shown in Fig. 8. Total particle simulation number is 1.0×107 in order to have sufficiently high reliability and the International Commission on Radiological Protection Publication 21 (ICRP-21) dose conversion factor is used as given in Table 8. When photon intensity of 2.8×109 photons/s/MeV is assumed for RV component, the surface dose rates are obtained from MCNP calculation using surface tally (F2) as given in Table 9. At the surface and 2 m from the box-type cask, 2.0×10−2 mSv/hr and 8.7×10−4 mSv/hr are obtained, respectively, which satisfy dose rate limit sufficiently.

Fig. 8

Box-type cask model for shielding simulation: (A) horizontal view and (B) vertical view.

ICRP-21 Dose Conversion Factor

Dose Rate at Various Positions for Box-Type Cask for RV Components

For RVI components, two types of casks are considered such as the cylinder type for from RVI-01 to RVI-08 and the box type for from RVI-09 to RVI-19. Fig. 9 shows the cylinder-type cask modeling and Table 10 provides surface dose rates for the cylinder-type cask when the photon intensity of 7.4× 1013 photons/s/MeV is assumed for RVI components. And Table 11 provides surface dose rates for the box-type cask when the photon intensity of 3.0×1011 photons/s/MeV is assumed for RVI components.

Fig. 9

Cylinder-type cask model for shielding calculation: (A) horizontal view and (B) vertical view.

Dose Rate at Various Positions for the Cylinder-Type Cask for RVI Components

Dose Rate at Various Positions for the Box-Type Cask for RVI Components

Tables 12 and 13 provide the surface dose rate of various casks containing RV and RVI components, respectively.

Surface Dose Rates for RV Casks

Surface Dose Rates for RVI Casks

From Table 12, the dose rates of various casks for RV components distributed much lower than the limit. Especially, RV-15 and RV-16 provide the highest surface dose rates due to their highest source intensities. From Table 13, the dose rates of various casks for RVI components are also satisfactory. The highest dose rate happens in the RVI-07 cask due to its much higher source intensity. It needs to be adjusted contents of such a cask which carries highly radioactive components in order to decrease thickness of the box-type cask and to reduce transport burden in the future.

Conclusion

In this paper, various cut-off pieces from RV and RVI components are characterized to transport safely by using box- and cylinder-type specialized casks. The radiation source intensities are obtained from activation analysis using ORIGEN-S calculation and surface dose rates for various casks are also calculated from MCNP simulations. Optimized cask loading strategies should be prepared using activation calculation for activated components, cutting plan on each position separated by radioactive waste level, radiation intensity and weight on each cut-off piece and cask size. From the calculation results for total 50 casks, it is found that the strategy is proposed adequately by satisfying both load weight and radiation dose rate requirement on the surface of cask. However, it might be better for economical transportation by loading higher radioactive contents and the heavier components. As a conclusion, this works shall contribute to estimate optimal loading plan of RV and RVI components for the decommissioning nuclear power plants, and the results can be used to prepare radioactive wastes—ILW, LLW, VLLW—disposal plan.

Notes

Conflict of Interest

No potential conflict of interest relevant to this article was reported.

Author Contribution

Conceptualization: Park K, Kim H, Kim N, Lee C, Lee Y, Lee J, Hwang Y, Lee M, Lee D, Jung D. Data curation: Park K, Kim H, Kim N, Lee C, Lee Y, Lee D, Jung D. Methodology: Sohn H. Project administration: Park K, Kim N, Lee C, Lee Y, Lee J, Hwang Y, Lee M, Lee D, Jung D. Visualization: Sohn H. Writing - original draft: Sohn H. Writing - review & editing: Park K, Kim H. Resources: Kim H, Sohn H. Software: Sohn H. Supervision: Lee J, Hwang Y, Lee M.

Acknowledgements

This research was supported by a grant from Energy Technology Development Program Funded by Ministry of Trade, Industry and Energy of Korean government (No. 2016151-0300430).

References

1. Mostecak A, Bedekovic G. Metal waste management and recycling methods in the nuclear power plant decommissioning and dismantling process. Rudarsko-geolosko-naftni zbornik 2018;33:25–33.
2. Hansson T, Norberg T, Knutsson A, Fors P, Sandebert C. An assessment of the decommissioning cost for the Ringhals site Stockholm, Sweden: Swedish Nuclear Fuel and Waste Management Co; 2013.
3. National Education Association. Recycling and reuse of materials arising from the decommissioning of nuclear facilities Paris, France: OECD Publishing; 2017.
4. Sohn HD, Park KS, Kim HW, Kim CW, Hwang YH, Yoon JY. The study for activation evaluation on activated structures in nuclear power plant with 40 years operation history. Ann Nucl Energy 2020;141:107305.
5. Pelowitz DB. MCNP6 user’s manual - code version 6.1 (LA-CP-1300634) Los Alamos, NM: Los Alamos National Laboratory; 2013.
6. Gauld IC. ORIGEN-S: depletion module to calculate neutron activation, actinide transmutation, fission product generation, and radiation source terms (ORNL/TM-2005/39 version 61) Oak Ridge, TN: Oak Ridge National Laboratory; 2011.
7. Evans JC, Lepel EL, Sanders RW, Wilkerson CL, Silker W, Thomas CW, et al. Long-lived activation products in reactor materials (No. NUREG/CR-3474; PNL-4824) Richland, WA: Pacific Northwest Lab; 1984.

Article information Continued

Fig. 1

Box-type cask for radioactive waste package.

Fig. 2

Loading example in 200 L drum for reactor pressure vessel.

Fig. 3

Cylinder-type cask for radioactive waste storage.

Fig. 4

An example of optimal loading for the box-type cask for reactor pressure vessel components.

Fig. 5

Gamma spectrum for reactor pressure vessel for 10-year cooling.

Fig. 6

Gamma spectrum for reactor pressure vessel internal for 10-year cooling.

Fig. 7

Several examples of cask loading configurations: (A) reactor pressure vessel (upper shell), (B) reactor pressure vessel internal (lower core plate), and (C) reactor pressure vessel internal (core barrel).

Fig. 8

Box-type cask model for shielding simulation: (A) horizontal view and (B) vertical view.

Fig. 9

Cylinder-type cask model for shielding calculation: (A) horizontal view and (B) vertical view.

Table 1

RV and RVI Component and Material

System Component Material
Reactor press vessel (RV) Reactor vessel Carbon steel
Reactor vessel head Carbon steel
Inlet/Outlet nozzle Carbon steel
ICI nozzle Inconel

Reactor vessel internal (RVI) Former Stainless steel type 304
Baffle Stainless steel type 304
Core barrel Stainless steel type 304
Thermal shield Stainless steel type 304
Upper core plate Stainless steel type 304
Upper internal Stainless steel type 304
Lower core plate Stainless steel type 304
Lower internal Stainless steel type 304

ICI, in-core instrumentation.

Table 2

Specification of Box-Type Cask

Item Parameter
Size (m) 1.46×1.46×0.95 (height)

Empty weight (ton) 0.84

Content weight (ton) ~5.5

Total weight including grouting (ton) 9.4

Thickness (cm) 2.0 for RV
20.0 for RVI

Material Stillage: carbon steel
Body: stainless steel (stainless steel type 304)

Grouting After water drain

Stillage For underwater loading

Salvage Specified shielding bell salvage

RVI, reactor vessel internal.

Table 3

Specification of Cylinder-Type Cask

Item Parameter
Outer size (m) 1.686×2.44 (diameter×height)
Inner size (m) 1.636×2.14 (diameter×height)
Empty weight (ton) 10.3
Content weight (ton) ~15.0
Total weight including grouting (ton) 25.3
Thickness of outer concrete (cm) 41.0
Material Stainless steel (stainless steel type 304)
Equipment Head drain/Dry facility

Table 4

Isotopic Specific Activities for RV for Various Cooling Time

Isotope Specific activity (Bq/g)
Discharge 30-day cooling 2-year cooling 5-year cooling 10-year cooling
3H 1.05×103 1.05×103 9.41×102 7.95×102 6.00×102
14C 2.28×101 2.28×101 2.28×101 2.28×101 2.28×101
60Co 7.10×104 7.01×104 5.46×104 3.68×104 1.91×104
59Ni 4.77×103 4.77×103 4.77×103 4.77×103 4.77×103
63Ni 5.01×105 5.01×105 4.95×105 4.84×105 4.68×105
90Sr 6.91×10−10 6.89×10−10 6.58×10−10 6.11×10−10 5.40×10−10
94Nb 6.01×10−1 6.01×10−1 6.01×10−1 6.01×10−1 6.01×10−1
99Tc 2.48×10−4 2.48×10−4 2.48×10−4 2.48×10−4 2.48×10−4
129I 2.64×10−17 2.64×10−17 2.64×10−17 2.64×10−17 2.64×10−17
137Cs 3.78×10−11 3.77×10−11 3.61×10−11 3.37×10−11 3.00×10−11
Total 9.42×107 9.09×107 5.24×107 2.41×107 7.07×106

RV, reactor pressure vessel.

Table 5

Isotopic Specific Activities for RVI for Various Cooling Time

Isotope Specific activity (Bq/g)
Discharge 30-day cooling 2-year cooling 5-year cooling 10-year cooling
63Ni 5.29×107 5.29×107 5.22×107 5.11×107 4.94×107
60Co 1.00×107 9.91×106 7.72×106 5.20×106 2.69×106
59Ni 4.86×105 4.86×105 4.86×105 4.86×105 4.86×105
3H 4.40×103 4.38×103 3.94×103 3.32×103 2.51×103
14C 8.59×102 8.59×102 8.59×102 8.59×102 8.58×102
94Nb 1.96×101 1.96×101 1.96×101 1.96×101 1.96×101
99Tc 7.65 7.65 7.65 7.65 7.65
137Cs 1.56×10−4 1.56×10−4 1.49×10−4 1.39×10−4 1.24×10−4
90Sr 2.69×10−6 2.69×10−6 2.57×10−6 2.38×10−6 2.11×10−6
129I 2.46×10−13 2.46×10−13 2.46×10−13 2.46×10−13 2.46×10−13
Total 1.41×109 6.89×108 3.85×108 2.03×108 9.32×107

RVI, reactor pressure vessel internal.

Table 6

Cask Information for RV Components

Contents Cask ID Cask type Fixed weight (ton) Total activity (MBq) Photon intensity (photons/s)
RV main body RV-01 Box 6.89 4.97×104 2.88×109
RV-02 Box 5.83 5.28×104 3.06×109
RV-03 Box 4.94 5.08×104 2.94×109
RV-04 Box 5.87 3.54×104 2.05×109
RV-05 Box 6.01 3.73×104 2.16×109
RV-06 Box 6.05 3.79×104 2.19×109
RV-07 Box 5.33 2.78×104 1.61×109
RV-08 Box 7.15 5.33×104 3.09×109
RV-09 Box 6.84 4.91×104 2.84×109
RV-10 Box 5.95 3.66×104 2.12×109
RV-11 Box 5.73 3.34×104 1.93×109
RV-12 Box 5.73 3.34×104 1.93×109
RV-13 Box 7.15 5.33×104 3.09×109
RV-14 Box 7.14 5.33×104 3.09×109
RV-15 Box 7.05 1.68×106 9.73×1010
RV-16 Box 7.05 1.68×106 9.73×1010
RV-17 Box 5.88 1.15×106 6.66×1010

RV main body/ RV bottom head RV-18 Box 5.84 6.81×105 3.94×1010
RV-19 Box 6.94 1.25×106 7.24×1010

RV bottom head RV-20 Box 5.72 3.19×102 1.85×107

RV main body/ RV bottom head RV-21 Box 5.78 6.75×105 3.91×1010
RV-22 Box 5.78 6.75×105 3.91×1010
RV-23 Box 5.44 7.19×105 4.16×1010

RV bottom head/ BMI Nozzle RV-24 Box 4.93 3.64×104 2.11×109

RV bottom head RV-25 Box 4.90 2.07×102 1.20×107

Inlet RV-26 Box 4.98 7.70×103 4.46×108
RV-27 Box 4.90 7.28×103 4.22×108

Outlet RV-28 Box 4.82 6.93×103 4.01×108
RV-29 Box 4.64 6.07×103 3.51×108

Insulation (bottom head) RV-30 Box 5.14 2.03×103 1.18×108

Insulation (active fuel) RV-31 Box 4.12 1.442×104 8.35×108

RV, reactor pressure vessel; BMI, bottom-mounted instrumentation.

Table 7

Cask Information for RVI Components

Contents Cask ID Cask type Fixed weight (ton) Total activity (MBq) Photon intensity (photons/s)
Thermal shield RVI-01 Cylinder 13.2 7.64×108 4.61×1013
Thermal shield RVI-02 Cylinder 9.9 5.96×108 4.15×1014
Baffle RVI-02 Cylinder 1.2 3.13×109 4.15×1014
Former RVI-02 Cylinder 1.4 3.15×109 4.15×1014
Thermal shield RVI-03 Cylinder 14.1 7.95×108 4.80×1013
Baffle RVI-04 Cylinder 3.8 1.00×1010 7.94×1014
Former RVI-04 Cylinder 1.4 3.15×109 7.94×1014
Core barrel RVI-05 Cylinder 3.5 8.28×108 5.00×1013
Core barrel RVI-06 Cylinder 5.9 1.40×109 8.45×1013
Upper core plate RVI-07 Box 1.5 2.74×108 5.38×1014
Baffle RVI-07 Box 3.0 7.94×109 5.38×1014
Guide tube RVI-07 Box 1.9 3.45×108 5.38×1014
Support column (L) RVI-07 Box 0.9 1.56×108 5.38×1014
Support column (S) RVI-07 Box 0.6 1.00×108 5.38×1014
Mixing device stop RVI-07 Box 0.5 9.74×107 5.38×1014
Orifice plate (UCP) RVI-07 Box 0.05 8.74×106 5.38×1014
Core barrel RVI-08 Box 3.5 8.22×108 2.30×1014
Baffle RVI-08 Box 1.5 2.99×109 2.30×1014
Lower core plate RVI-09 Box 0.3 3.28×106 2.03×1011
Core support column RVI-09 Box 1.1 2.99×104 2.03×1011
Core support forging RVI-09 Box 2.1 5.71×104 2.03×1011
Core flange RVI-10 Box 2.5 3.17×106 1.91×1011
Core flange RVI-11 Box 2.9 3.56×106 2.18×1011
Mixing device stop RVI-11 Box 0.5 4.06×104 2.18×1011
Orifice plate RVI-11 Box 0.05 6.05×103 2.18×1011
Core flange RVI-12 Box 2.9 8.64×103 1.89×1011
Support column (L) RVI-12 Box 0.9 3.12×106 1.89×1011
Support column (S) RVI-12 Box 0.2 6.80×101 1.89×1011
Core supporting forging RVI-13 Box 2.1 5.61×104 6.65×109
Butt instrument column RVI-13 Box 0.8 2.05×104 6.65×109
Cruciform column RVI-13 Box 0.2 4.46×103 6.65×109
Lowe core plate RVI-13 Box 0.3 2.91×104 6.65×109
Core supporting forging RVI-14 Box 1.5 4.06×104 5.76×109
Butt instrument column RVI-14 Box 0.8 2.05×104 5.76×109
Lower core plate RVI-14 Box 0.3 3.43×104 5.76×109
Core supporting forging RVI-15 Box 1.5 4.06×104 3.77×1011
Cruciform column RVI-15 Box 0.2 6.05×103 3.77×1011
Tie plate RVI-15 Box 0.3 8.64×103 3.77×1011
Lower core plate RVI-15 Box 0.3 3.10×106 3.77×1011
Guide tube RVI-15 Box 0.3 3.10×106 3.77×1011
Tie plate RVI-16 Box 0.7 1.95×104 4.27×1012
Cruciform column RVI-16 Box 0.3 7.70×103 4.27×1012
Lower core plate RVI-16 Box 0.3 2.79×106 4.27×1012
Guide tube RVI-16 Box 0.7 6.80×107 4.27×1012
Core supporting forging RVI-17 Box 2.2 5.90×104 2.01×1011
Cruciform column RVI-17 Box 0.3 8.91×103 2.01×1011
Energy absorber RVI-17 Box 0.4 1.12×104 2.01×1011
Lower core plate RVI-17 Box 0.3 3.25×106 2.01×1011
Guide tube RVI-17 Box 0.5 5.10×101 2.01×1011
Extension nozzle RVI-18 Box 0.1 3.24×103 4.50×1011
Butt instrument column RVI-18 Box 0.2 5.67×103 4.50×1011
Offset column instrument RVI-18 Box 0.01 5.67×103 4.50×1011
Core flange RVI-18 Box 3.1 4.02×106 4.50×1011
Support column RVI-18 Box 0.2 1.81×101 4.50×1011
Core flange RVI-19 Box 3.4 4.41×106 2.66×1011
Support column (S) RVI-19 Box 1.8 1.81×101 2.66×1011
Deep beam RVI-19 Box 0.08 8.22 2.66×1011

RVI, reactor pressure vessel internal.

Table 8

ICRP-21 Dose Conversion Factor

Lower energy (MeV) Upper energy (MeV) Conversion factor (mSv/hr)/(photon/cm2/s)
1.00×10−2 5.00×10−2 2.37×10−2
5.00×10−2 1.00×10−1 2.76×10−3
1.00×10−1 2.00×10−1 7.20×10−4
2.00×10−1 3.00×10−1 7.40×10−5
3.00×10−1 4.00×10−1 1.74×10−4
4.00×10−1 6.00×10−1 4.07×10−5
6.00×10−1 8.00×10−1 4.74×10−5
8.00×10−1 1.00 3.78×10−3
1.00 1.33 7.55×10−1
1.33 1.66 2.13×10−1
1.66 2.00 1.02×10−9
2.00 2.50 5.10×10−6
2.50 3.00 4.36×10−9

ICRP-21, International Commission on Radiological Protection Publication 21.

Table 9

Dose Rate at Various Positions for Box-Type Cask for RV Components

Dose rate (mSv/hr) Relative errora)
Surface 2.00×10−2 0.0042
10 cm 1.37×10−2 0.0041
1 m 2.33×10−3 0.0038
2 m 8.70×10−4 0.0037

RV, reactor pressure vessel.

a)

Relative error=Standard deviationMean.

Table 10

Dose Rate at Various Positions for the Cylinder-Type Cask for RVI Components

Dose rate (mSv/hr) Relative errora)
Surface 1.42×10−3 0.1105
10 cm 1.15×10−3 0.1097
1 m 3.92×10−4 0.1111
2 m 1.82×10−4 0.1123

RVI, reactor pressure vessel internal.

a)

Relative error=Standard deviationMean.

Table 11

Dose Rate at Various Positions for the Box-Type Cask for RVI Components

Dose rate (mSv/hr) Relative errora)
Surface 9.56×10−4 0.1179
10 cm 9.07×10−4 0.1179
1 m 1.51×10−4 0.0858
2 m 5.99×10−5 0.0857

RVI, reactor pressure vessel internal.

a)

Relative error=Standard deviationMean.

Table 12

Surface Dose Rates for RV Casks

Cask ID Dose rate (mSv/hr)
Surface 10 cm 1 m 2 m
RV-01 2.06×10−2 1.41×10−2 2.40×10−3 8.97×10−4
RV-02 2.19×10−2 1.50×10−2 2.55×10−3 9.53×10−4
RV-03 2.11×10−2 1.44×10−2 2.46×10−3 9.17×10−4
RV-04 1.47×10−2 1.01×10−2 1.71×10−3 6.39×10−4
RV-05 1.55×10−2 1.06×10−2 1.80×10−3 6.73×10−4
RV-06 1.57×10−2 1.08×10−2 1.83×10−3 6.84×10−4
RV-07 1.15×10−2 7.90×10−3 1.34×10−3 5.02×10−4
RV-08 2.21×10−2 1.52×10−2 2.58×10−3 9.62×10−4
RV-09 2.04×10−2 1.40×10−2 2.37×10−3 8.87×10−4
RV-10 1.52×10−2 1.04×10−2 1.77×10−3 6.61×10−4
RV-11 1.39×10−2 9.50×10−3 1.62×10−3 6.03×10−4
RV-12 1.39×10−2 9.50×10−3 1.62×10−3 6.03×10−4
RV-13 2.21×10−2 1.52×10−2 2.58×10−3 9.62×10−4
RV-14 2.21×10−2 1.52×10−2 2.58×10−3 9.62×10−4
RV-15 6.97×10−1 4.78×10−1 8.12×10−2 3.03×10−2
RV-16 6.97×10−1 4.78×10−1 8.12×10−2 3.03×10−2
RV-17 4.77×10−1 3.27×10−1 5.56×10−2 2.08×10−2
RV-18 2.83×10−1 1.94×10−1 3.29×10−2 1.23×10−2
RV-19 5.19×10−1 3.55×10−1 6.04×10−2 2.26×10−2
RV-20 1.32×10−4 9.07×10−5 1.54×10−5 5.76×10−6
RV-21 2.80×10−1 1.92×10−1 3.26×10−2 1.22×10−2
RV-22 2.80×10−1 1.92×10−1 3.26×10−2 1.22×10−2
RV-23 2.98×10−1 2.04×10−1 3.48×10−2 1.30×10−2
RV-24 1.51×10−2 1.03×10−2 1.76×10−3 6.57×10−4
RV-25 8.59×10−5 5.89×10−5 1.00×10−5 3.74×10−6
RV-26 3.20×10−3 2.19×10−3 3.72×10−4 1.39×10−4
RV-27 3.02×10−3 2.07×10−3 3.52×10−4 1.31×10−4
RV-28 2.88×10−3 1.97×10−3 3.35×10−4 1.25×10−4
RV-29 2.52×10−3 1.73×10−3 2.94×10−4 1.10×10−4
RV-30 8.43×10−4 5.77×10−4 9.82×10−5 3.67×10−5
RV-31 5.99×10−3 4.10×10−3 6.97×10−4 2.60×10−4

RV, reactor pressure vessel.

Table 13

Surface Dose Rates for RVI Casks

Cask ID Dose rate (mSv/hr)
Surface 10 cm 1 m 2 m
RVI-01 9.11×10−4 7.38×10−4 2.51×10−4 1.17×10−4
RVI-02 8.10×10−3 6.56×10−3 2.24×10−3 1.04×10−3
RVI-03 9.48×10−4 7.68×10−4 2.62×10−4 1.21×10−4
RVI-04 1.55×10−2 1.26×10−2 4.29×10−3 1.99×10−3
RVI-05 9.61×10−4 7.78×10−4 2.65×10−4 1.23×10−4
RVI-06 1.62×10−3 1.32×10−3 4.48×10−4 1.23×10−4
RVI-07 1.66 1.58 2.62×10−1 1.04×10−1
RVI-08 7.09×10−1 6.73×10−1 1.12×10−1 4.44×10−2
RVI-09 6.27×10−4 5.94×10−4 9.90×10−5 3.93×10−5
RVI-10 5.90×10−4 5.60×10−4 9.32×10−5 3.70×10−5
RVI-11 6.63×10−4 6.29×10−4 1.05×10−4 4.15×10−5
RVI-12 5.81×10−4 5.51×10−4 9.17×10−5 3.64×10−5
RVI-13 2.05×10−5 1.94×10−5 3.24×10−6 1.28×10−6
RVI-14 1.78×10−5 1.68×10−5 2.80×10−6 1.11×10−6
RVI-15 1.16×10−3 1.10×10−3 1.84×10−4 7.28×10−5
RVI-16 1.32×10−2 1.25×10−2 2.08×10−3 8.26×10−4
RVI-17 6.17×10−4 5.86×10−4 9.75×10−5 3.87×10−5
RVI-18 7.51×10−4 7.12×10−4 1.19×10−4 4.70×10−5
RVI-19 8.21×10−4 7.79×10−4 1.30×10−4 5.14×10−5

RVI, reactor pressure vessel internal.