1. Economic Analysis of Alternative Transition Pathways to Improve Economic Considerations in Fuel Cycle Transition
Brent Dixon
Deputy National Technical Director
Systems Analysis & Integration
Idaho National Laboratory
Co-authors: Jason Hansen, Ross Hayes, Piyush Sabharwall
3rd Technical Workshop on Fuel Cycle Simulation
FIAP Jean Monnet
Paris, France

2. Introduction

3. Problem Statement
Transition analysis reveals weakness in promising fuel cycle transition alternatives (Hoffman et al. 2015)
Low capacity factors arise from facilities built at first demand but under utilized
Low capacity factors imply higher unit costs, less efficient systems
Physics analysis shows that de-coupling is possible if SFRs started on LEU with enrichment up to 19.75% (Hoffman et al. 2015; Dixon et al. 2016)

4. Strategic buildout improves economics
Delaying the time when separations facilities brought online reduces life cycle costs while improving capacity utilization (Dixon et al. 2016)
Delay requires more fissile material in system, as some sits longer in storage
Tradeoff in increased fuel storage costs versus reduced separations facility unit costs

5. Study Goals and Objectives
Research Question: Can the economics of transition pathways be improved by leveraging LEU to start up fast reactors?
Goal: Using alternative sources of fissile material, identify lower cost transition pathways for U/Pu single tier fuel cycle (EG23*) and U/TRU two tier fuel cycle (EG30*)
EG23 and EG30 bracket the range of possibilities
Objective: maximize cost differential between base cases and alternative transition pathways
Control variable: build profile for separations facilities and for fuel fabrication facilities
Adjusting the build profile for fuel fab and separations implicitly adjusts the amount of material in storage.
The tradeoff in storage cost and savings from adjusted build profiles will be discussed with results.
*Nomenclature described on next two slides.

6. Description of EG23
Continuous recycle of U/Pu with new natural U fuel in fast critical reactors
(Wigeland et al. 2014; Hoffman et al. 2017)

7. Description of EG30
Continuous recycle of U/TRU with new natural U fuel in both fast and thermal critical reactors
(Wigeland et al. 2014; Hoffman et al. 2017)

8. Methodology

9. Modeling Approach
Scenarios are transition from open fuel cycle to EG23 and EG30
Cases are Base and Optimized for each scenario
Base case follows analysis for each scenario as outlined in the Evaluation and Screening Report (Wigeland et al. 2014)
Optimized case brings separation and remote fuel fabrication facilities online when throughput supports full capacity utilization
Identify the core transition time between phases
Find the present value of costs for each scenario and case, then compute the difference over cases
Cost model follows approach applied in (Dixon et al. 2016)
Compute the fleet capacity factors for separations and remote fuel facilities by scenario and case

10. System Description Recipes are fixed throughout the simulation
EG-23
EG-30
LWR Power [GWe] (System / each) -
44 / 1.0
SFR Power [GWe] (System / each)
100 / 0.4
56 / 0.4
LWR MOX Burnup [GWD/MTiHM] 50
SFR Burnup [GWD/MTiHM]
46.1
21.4
SFR Driver Burnup [GWD/MTiHM]
84.2
117.4
Fuel Cooling Time [yr] 5
Reprocessing Facility Size [MT/yr]
1000
Recipes are fixed throughout the simulation
Metallic fuel
Reactor build profile held constant, only thing that changes across cases/scenarios is build profile of separations/remote fuel fab facilities

11. Three Phases of Fuel Utilization
Initial Core and first reloads
LEU only (up to 19.75% enrichment)
Core Transition
Transition occurs over ~3 recycles
Pu increases and residual 235U decreases each recycle
Core evolution by scenario:
EG23: LEU to U/Pu
EG30: LEU to U/TRU
Equilibrium
EG23: Breakeven SFRs with U/Pu fuel, DU makeup
EG30: U/TRU Breeder SFRs, U/Pu MOX LWRs, DU makeup

12. EG23 Initial Core Mining Conversion DU Storage Enrichment LEU Storage
Sodium Fast Reactor
Storage
Cold Fabrication (LEU)
Fresh Cold Fuel Storage

13. EG23 Core Transition (LEU to U/Pu)
Mining
Conversion
Enrichment DU
DU Storage
makeup for
loss to waste
RU/Pu going
to driver
LEU Storage
Driver Hot Glovebox Fabrication (Recovered LEU and Pu)
Sodium Fast Reactor
Storage
Separations
(Driver and Blanket)
Storage
(RU)
Blanket Cold Fabrication (RU/DU)
RU going
to blankets
Fresh Cold Fuel Storage
Waste (MA, FP)

14. EG23 Equilibrium (Breakeven Core)
Mining
Conversion
Enrichment DU
DU Storage
makeup for
loss to waste
RU/Pu going
to driver
LEU Storage
Driver Hot Glovebox Fabrication (Recovered RU and Pu)
Sodium Fast Reactor
Storage
Separations
(Driver and Blanket)
Storage
(RU)
Blanket Cold Fabrication (RU/DU)
RU going
to blankets
Waste (MA, FP)
Fresh Cold Fuel Storage

15. EG30 Initial Core Mining Conversion DU Storage Enrichment LEU Storage
Cold Metal Fabrication (Low Enriched Uranium: start-up driver + all blankets)
Sodium Fast Reactor
Storage
Cold Fab Oxide
LWR
Storage
Disposal

16. EG30 Core Transition (LEU to U/TRU) Mining Seps Conversion DU Storage
Enrichment DU
DU Storage
RU/TRU
Hot Fabrication (U/TRU, U/Pu)
Cold Fabrication (all blankets)
SFR
Store
Seps
Storage (RU)
Waste
Cold Fab Oxide
LWR
Storage
Disposal

17. EG30 Equilibrium (Breeder)
DU Storage
Remote Hot Fabrication (Recovered Uranium and Plutonium) (driver)
SFR
Store
Separations
Waste
RU/TRU
Driver Loop
Storage (RU)
RU/Pu
Waste RU
Store
Blanket Loop
Cold Fabrication (blankets)
Separations
Waste MA
LWR Loop
LWR MOX
Glovebox Hot Fabrication (Recovered Uranium and Plutonium)
Store
Separations
U/Pu

18. Modeling Assumptions No demand growth over simulation time horizon
Simulation runs 2015 through 2200
Base results computed with zero discounting, alternative discount rates evaluated in sensitivity analysis
Pyroprocessing, electrochemical separations
Remote fuel fabrication facilities collocated with separations, follow same assumptions of construction time and operating lifetime
Contact handled fuel fabrication modeled as glovebox technology

19. Cost Model
Modeled fuel cycle system components, : uranium price, conversion, enrichment, DU storage, RU storage, contact-handled fuel fabrication, dry storage, separations with remote fuel fabrication, disposal
By the jth scenario (EG23/EG30), and by the kth case (base or optimized), sum over the ith cost component such that the total measured cost becomes:
The cost delta thus becomes:

20. Parameters in Cost Analysis

21. Results and Discussion

22. Simulated Fuel Cycle Transition Date
For all scenarios, initial cores are loaded at the beginning of the simulation with LEU
In the base case, each scenario begins core transition in 2037, but EG30 transitions sooner in the Optimized case
EG30 base reaches equilibrium the soonest, but EG30 optimized delays the longest
Core
Status
EG23
Base
EG23 Optimized
EG30
EG30 Optimized
Initial
2015
Transition
2037
2044
2039
Equilibrium
2091
2077
2082
2083

23. Build Profiles
The base case for each scenario brings full facilities online at first demand, and maintains capacity over simulation
Optimized case adjusts capacity in response to utilization target

24. Separations Capacity, Demand, Unit Cost (1)
For both scenarios, the optimized case reaches full utilization sooner
EG30 base case does not reach full utilization
“Dips” in optimized case reflect adjustments as number of facilities changes

25. Separations Capacity, Demand, Unit Cost (2)
Capacity utilization bears on unit cost – base case has much steeper unit cost at first utilization
Optimized case builds capacity congruent with demand, more stable unit cost

26. Separations Capacity, Demand, Unit Cost (3)
Similar to EG23, EG30 base case has steep unit cost at first utilization while optimized case is much less
Reduced “white space” between capacity and demand in optimized case, remaining is due to separations for LWR loop

27. Summary Cost Metrics (1)
Optimized case in each scenario generates life cycle cost savings: roughly 4% for EG23 and 10% for EG30
Levelized cost decreases, too, but more for EG30: 8% vs 3% for EG23.

28. Summary Cost Metrics (2)
Each scenario generates cost savings in excess of what the optimized case costs, but savings are larger in EG30
Optimizing each scenario increases enrichment requirements, so more cost for SWUs
Largest savings realized in separations facilities

29. Investigating the Cost Delta (1)
Note that figures do not have the same y-axis, left figure zoomed in to show small changes
No change in dry storage or disposal

30. Investigating the Cost Delta (2)
Note that figures do not have the same y-axis, left figure zoomed in to show small changes
No change in dry storage or disposal, disposal not required per EG30 assumptions

31. Summary, Conclusions and Extensions

32. In Summary . . .
Scenarios driven by fissile material availability may underutilize fuel cycle facilities
Underutilization increases unit costs
Full utilization achieved by storage of feed material and delayed construction
Facility optimization may require additional fissile material
High assay LEU is an alternative to Pu
The LEU supply chain is less fragile than for Pu
Can be enriched or enriched and fabricated in advance
Fissile value does not degrade with storage
Additional scenario studies are needed, considering more optimization parameters

33. References
Dixon, B., J. Hansen, R. Hays, and H. Hiruta Transition Economics Assessment -- FY2016 Update, Fuel Cycle Research & Development. Idaho National Laboratory: U.S. Department of Energy.
Dixon, BW, F Ganda, KA Williams, E Hoffman, and JK Hansen Advanced Fuel Cycle Cost Basis–2017 Edition. Idaho National Lab.(INL), Idaho Falls, ID (United States).
Hoffman, E., B. Carlsen, B. Feng, A. Worrall, B. Dixon, R. Hays, N. Stauff, and E. Sunny Report on Analysis of Transition to Fast Reactor U/Pu Continuous Recycle, Fuel Cycle Research & Development. Argonne National Laboratory: U.S. Department of Energy.
Hoffman, E., B. Feng, B. Dixon, T. Fei, R. Hays, J. Peterson-Droogh, A. Worrall, E. Davidson, W. Halsey, H. Hiruta, and A. Gascon Updated Analysis Results for the Most Promising Fuel Cycle Options (Evaluation Groups 23, 24, 29, and 30): Argone National Laboratory.
Wigeland, R., Taiwo, T., H. Ludewig, M. Todoso, W. Halsey, J. Gehin, R. Jubin, J. Buelt, S. Stockinger, K. Jenni, and B. Oakley Nuclear Fuel Cycle Evaluation and Screening -- Final Report. Edited by Fuel Cycle Research & Development. Idaho National Laboratory: U.S. Department of Energy.