1. Aligned with ReNew Thrust 15
“CAD-centric” Integrated Multi-physics Simulation Predictive Capability for Plasma Chamber Nuclear Components
Aligned with ReNew Thrust 15
Unlike FSP, the integrated modeling is progressed in a smaller scale fashion
A. Ying (UCLA), R. Reed (graduate student), R. Munipalli (HyPerCom)
Acknowledgements to graduate(d) students M. Narula, R. Hunt, and H. Zhang (UCLA)
Others working on separate parts of the subject
M. Abdou, M. Ulrickson (and team), M. Sawan (and team), M. Youssef, B. Merrill
FNST meeting
August 2, 2010
UCLA

2. Integrated Simulation Predictive Capability (ISPC) as a part of ReNeW Thrust 15: Creating integrated models for attractive fusion power systems
ReNeW Thrust 15 Integrated Model Objectives:
Develop predictive modeling capability for nuclear components and associated systems that are science-based, well-coupled, and validated by experiments and data collection.
Extend models to cover synergistic physical phenomena for prediction and interpretation of integrated tests and for optimization of systems.
Develop methodologies to integrate with plasma models to jointly supply first wall and divertor temperature and stress levels, electromagnetic responses, surface erosion, etc.
Today’s Trend in Simulation:
Treat complexity of entire problem
Extreme geometric complexity
Multi-physics, Multi-scales
Inter-disciplinary approach
Modernize codes & Interpret phenomena from interrelated scientific disciplines
High accuracy & thorough understanding at each level
Interactive visualization and post processing (Intelligent Expert System) 2

3. “ITER Baking in progress”
An integrated model tool potentially contributes to more efficient FNST R&D
Provide high level of accuracy and substantially reduce risk and cost for the development of complex plasma chamber in-vessel components
Facilitate simulation of normal and off normal operational scenarios.
Offer capabilities for system optimization
Allow insight and intuition into the interplay between key multi-physics phenomena (occurring at a level where instruments cannot be installed.)
Better understand the state of the operation through limited diagnostics
The time-dependent BLKT outlet temperature can be used in RELAP5 system code for heating control analysis.
The flow pattern and associated heat transfer inside a FW/BLKT is very complex, which RELAP5 cannot model.
FW/BLKT temperature response with time with water inlet temperature at 10K/h ramp-up rate.
“ITER Baking in progress”
BLKT-12 CATIA model
FW (Be)
Shield Module

4. CAD-centric modeling tools are being used in the US ITER FW/Blanket Shield Design (design by analysis) (led by Mike Hechler-ORNL and Mike Ulrickson-SNL)
Mechanical load under a disruption
Snapshots of velocity magnitudes at different pipes (BLKT-12 SM)
Nuclear heating profile
CFD/thermo-fluid
X-Y plane (8 cm above mid-plane)
FW/BLKT-12

5. ITER FW/shield design still evolving Rows or panels affected
Design by analysis incorporating CAD model becomes even more important in regard to first wall panels shaped as local limiters
ITER FW/shield design still evolving
In recent design, slot was removed
The heat flux profile is extremely non-uniform: heat flux as high as 5 MW/m2 (7.5 MW start-up and ramp down), 40% of wall EHF modules
A shaped FW design brings forth the importance of using “prototype” in the analysis
location
Peak heat flux
Rows or panels affected
Inboard : start-up
4.4 MW/mm²
3,4
Outboard
3.6 MW/m²
14,15,16,17
Shine thru
4.0 MW/m²
6 panels on rows 15,16
Top
4.6 MW/m²
Reference: R. Mitteau et. al., Heat loads and shape design of the ITER first wall, ISFNT-9 (2009)
CuCrZr
Von Mises (Pa)
CuCrZr

6. DCLL He-coolant inlet manifold
Simulation performed on an engineering CAD model allows practical design assessments
Mid-plane nuclear heating (gamma: left; neutron: right)
W/cc
Location of the instrument and the associated perturbation to the data
Analysis with a detailed geometric drawing with instrumentations in-place needed
Thermomechanics Analysis
Proper manifold designs to provide uniform flow distributions among many parallel flow paths
Adequate cooing to all parts
DCLL He-coolant inlet manifold
He-velocity
High temperature at upper structures
PbLi velocity
Velocity :m/s
Stress concentration
Initial results with simplified geometry
& operating condition
Inlet to 2nd FW cooling panel
ISPC can potentially reduce risk and cost of the component development

8. Hybrid code ADVANTG (MCNP + Denovo)
What numerical software are available for CAD-centric integrated model?
ITER 40o A-lite Neutronic model
(many neutronics codes available: deterministic or Monte Carlo)
MOAB & CGM
CAD
Voxels
MCNP(X)
MCNPX
Native
Geometry
(Other)
DAG-MCMP
ITER FW Panel
Attila: Commercial Software
Tetrahedral mesh
Hybrid code ADVANTG (MCNP + Denovo)
ORNL
Attila is now being used to calculate radioactivity of components
MCNP – MCAM
Community Developed
Orthogonal mesh
Total (neutron + photon) flux

9. Solving individual physics using its optimized numerical technique and running simultaneously with a smart transfer of information
Adopting one numerical technique for all simulations in ISPC can limit the size of the problem and is undesirable.
Overcoming CAD discrepancy (e.g. overlapping) is common source of difficulty for MCNP
Sample analysis codes and mesh requirements in ISPC
Physics
Analysis code
Mesh specification
Neutronics
MCNP
Monte Carlo mesh tally (cell based)
Attila
Unstructured tetrahedral mesh (node based)
Electro-magnetics
OPERA
(Cubit)
Unstructured tetrahedral (Hex-) mesh (node based)
ANSYS
Unstructured Hex/Tet mesh (node based and edge based formulations)
CFD/ Thermo-fluids
SC/Tetra
Unstructured hybrid mesh (node based)
Fluent/CFX etc.
Unstructured hybrid mesh (cell based)
MHD
HIMAG
Structural analysis
ANSYS/
ABAQUS
Unstructured second order Hex/Tet mesh (node based)
Species transport
COMSOL or others: TMAP, ASPEN
Unstructured second order mesh (node based)
Safety
RELAP5-3D
MELOCR
System representation code
DAG-MCNP (UW)
Imprinting A F B C E D
Merging 9

10. A multi-disciplinary effort
Integration of computational software forms the heart of FNST performance prediction
Data mapping and interpolation across various analysis meshes/codes has to be fast, accurate and satisfy physical conservation laws
Large scale simulation, leading-edge high performance computing, advanced computational methods, and the development and application of new mathematical models
Verification & Validation
Material database/Constitutive equations/ Irradiation effect
CAD- Geometry
Mesh services
Adaptive mesh/
mesh refinement
Visualization
Data Management: Interpolation
Neutral format
Time step control for transient analysis
Partitioning Parallelism
Neutronics Radiation damage rates
Thermo-fluid
Species (e.g. T2) transport
Electro-magnetics
MHD
Coupled effect
Special module
Radioactivity
Transmutation
Safety
e.g. source
Structure/
thermo-mechanics

11. ISPC Design Process Flow
Maintain consistency in the geometric representation among the analysis codes
The CAD-based solid model is the common element across physical disciplines
FW/Plasma Facing Surface Phenomena
profile
FW/PFC Thermo-fluid
Neutron source profile
Neutronics
CAD Model q”
DMS
Thermo-fluid
& LM MHD
FUN *
Electromagnetics
3-D design iterative assessment important
DMS
DMS
Stress/Deformation-Analysis
Specialized physics models
FUN *
Structural Support
Tremendous work for ITER FW/SB at SNL
Species Transport
FUN
specialized user FUNction
Safety or
Transient events
Data Mapping Script

12. Need experimental data for code verification & validation
RF-CHF
Within ITER project, some R&D being carried out and providing data for design support and code benchmark
TCs installed in the mockup have provided data
US-CHF mock-up
Jet impingement
He inlet
He outlet
Temperature and He flow characteristics under 10 MW/m2
Verification/validation needed on integration method

13. “How to” incorporate a bigger resource into ISPC?
Similar efforts are being pursued in various fields:
within DOE Vision 21 project (Improved asset optimization by integrating ASPEN PLUS and FLUENT)
Nuclear Energy and Simulation Hub
FSP (Fusion Simulation Project)
Advanced computational tools are continuously being developed in various projects:
SciDAC, ITAPS, CCA, etc.
“to apply existing modeling and simulation capabilities to create a user environment that allows engineers to create a simulation of a currently operating reactor that will act as a "virtual model" of that reactor.---”
Nuclear Energy Innovation Hub
Look for synergism
Not re-inventing the wheel but riding on state-of-the-art methodology

14. Next Steps How do you see this moving forward?
Three activities (ITER FW/shield design, TBM program, and FNSF assessment study) provide mechanism, panorama, and opportunity for the development/ benchmark/test of the idea to the extent possible.
However, a substantial effort requires FSP-like or NESH-like commitment
Near term goal
Continue to build/enhance interface and data management (increase degree of automation)
Establish test cases to further explore the limit of the capability
Example test cases
Enhance existing neutronics computational platform for TBM radioactive dose calculations extended to ITER port cell area
FNSF tritium breeding assessment through a complete 3-D base breeding blanket exploratory design analysis
Develop schemes to link to plasma facing surface phenomena, and address FW tritium inventory and permeation losses
Periodic recovery of implanted tritium has an impact on the TBR requirement; however, its degree of impact is affected by losses from tritium permeation into FW coolant

15. Summary
Adopt the state-of-the-art computer technique, high-powered computing, advanced modeling and simulation that is 3-dimensional, high-resolution
Develop highly integrated predictive capabilities for many cross-cutting scientific & engineering disciplines and deliver faster and more detailed insights into the R&D of in-vessel FNST components and systems
Imagine if critical performance parameters can be projected and examined in advance----
The goal of an integrated simulation effort then is to be able to model and design a complete DEMO system including irradiation effects, thermofluid/MHD, temperatures and mechanical loads, tritium accountability in entire system (tritium retention, and tritium production and transport processes), and FW/divertor erosion.