Difference between revisions of "Collection of example input files"
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| 2D BWR fuel assembly geometry | | 2D BWR fuel assembly geometry | ||
| [[2D BWR fuel assembly geometry|Serpent input file]] | | [[2D BWR fuel assembly geometry|Serpent input file]] | ||
| − | | Demonstrates basic features for geometry, material and | + | | Demonstrates basic features for geometry, material and burnup |
| JLe / VTT | | JLe / VTT | ||
| 15/11/26 | | 15/11/26 | ||
| Line 31: | Line 31: | ||
| JLe / VTT | | JLe / VTT | ||
| 15/11/26 | | 15/11/26 | ||
| + | |- | ||
| + | |2D 4-HEX super-cell lattice geometry | ||
| + | | [[2D 4-HEX super-cell lattice geometry|Serpent input file]] | ||
| + | | Demonstrates the use of triangular lattices derived from a hexagonal lattice | ||
| + | | AJa / VTT | ||
| + | | 2021 | ||
|} | |} | ||
| Line 68: | Line 74: | ||
| [[HTGR fuel pebble burnup example|Serpent input file]] | | [[HTGR fuel pebble burnup example|Serpent input file]] | ||
| Single HTGR fuel pebble in an infinite lattice, demonstrates the explicit particle fuel model | | Single HTGR fuel pebble in an infinite lattice, demonstrates the explicit particle fuel model | ||
| + | | JLe / VTT | ||
| + | | 18/04/09 | ||
| + | |||
| + | |- | ||
| + | | HTGR fuel compact burnup example | ||
| + | | [[HTGR fuel compact burnup example|Serpent input file]] | ||
| + | | Single HTGR fuel compact in an infinite lattice, demonstrates the explicit particle fuel model | ||
| JLe / VTT | | JLe / VTT | ||
| 18/04/09 | | 18/04/09 | ||
| Line 81: | Line 94: | ||
|- | |- | ||
| 2D PWR assembly | | 2D PWR assembly | ||
| − | | [[Automated burnup sequence example 1# | + | | [[Automated burnup sequence example 1#Input|Serpent input file]], [[Automated burnup sequence example 1#Output|Partial output]] |
| − | | Demonstrates the basic features of the automated burnup sequence | + | | Demonstrates the basic features of the automated burnup sequence with coefficient matrix |
| JLe / VTT | | JLe / VTT | ||
| 16/02/21 | | 16/02/21 | ||
| + | |- | ||
| + | | 2D PWR assembly | ||
| + | | [[Automated burnup sequence example 2#Input|Serpent input file]], [[Automated burnup sequence example 2#Output|Partial output]] | ||
| + | | Demonstrates the basic features of the automated burnup sequence with casematrix | ||
| + | | ARi / VTT | ||
| + | | 22/05/13 | ||
|} | |} | ||
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| JLe / VTT | | JLe / VTT | ||
| 16/03/03 | | 16/03/03 | ||
| + | |- | ||
| + | |Tank filled with molten salt with natural circulation based distributions from <ref>Leppänen, J. et al. ''"Unstructured mesh based multi-physics interface for CFD code coupling in the Serpent 2 Monte Carlo code"'' In proc. PHYSOR 2014, Kyoto, Japan, Sept. 28 - Oct. 3, 2014.</ref> | ||
| + | | [[Molten salt tank with natural circulation|Serpent input files]] | ||
| + | | Simplified molten salt tank with temperature and density distributions to test the unstructured mesh based interface | ||
| + | | JLe / VTT + Manuele Aufiero | ||
| + | | 2014 | ||
| + | |- | ||
| + | | A 37 assembly SMR sized reactor core. | ||
| + | | [[Kraken SMR progression problem|Serpent input files]] | ||
| + | | A rather detailed SMR sized reactor core based on data from the BEAVRS benchmark and a core size as well as radial reflector structure from the NuScale reactor concept. | ||
| + | | ULa / VTT | ||
| + | | 2019 | ||
| + | |- | ||
| + | | HTTR full core model | ||
| + | | [[HTTR full core model|Serpent input files]] | ||
| + | | 3D model of the Japanese gas-cooled High Temperature Engineering Test Reactor (HTTR). | ||
| + | | JLe / VTT | ||
| + | | 2020 | ||
|- | |- | ||
|} | |} | ||
Latest revision as of 15:46, 11 February 2024
Contents
Simple 2D assembly geometry examples
| Description | Files | Notes | Added by | Date |
|---|---|---|---|---|
| 2D BWR fuel assembly geometry | Serpent input file | Demonstrates basic features for geometry, material and burnup | JLe / VTT | 15/11/26 |
| 2D CANDU fuel bundle geometry | Serpent input file | Demonstrates the circular array structure | JLe / VTT | 15/11/26 |
| 2D VVER-440 fuel assembly geometry | Serpent input file | Demonstrates the hexagonal lattice and calculation of flux and reaction rate spectra | JLe / VTT | 15/11/26 |
| 2D PWR MOX/UOX lattice geometry | Serpent input file | Demonstrates the use of two nested lattices (pins in assembly and assemblies in colorset) | JLe / VTT | 15/11/26 |
| 2D 4-HEX super-cell lattice geometry | Serpent input file | Demonstrates the use of triangular lattices derived from a hexagonal lattice | AJa / VTT | 2021 |
Simple burnup examples
| Description | Files | Notes | Added by | Date |
|---|---|---|---|---|
| 2D PWR pin-cell burnup example | Serpent input file | Demonstrates basic burnup input | JLe / VTT | 15/11/30 |
| 2D PWR assembly burnup example | Serpent input file | 17x17 assembly with burnable absorber, "Serpent 1" style division into depletion zones | JLe / VTT | 15/11/30 |
| 2D PWR assembly burnup example | Serpent input file | 17x17 assembly with burnable absorber, division into depletion zones using the div card | JLe / VTT | 15/11/30 |
| HTGR particle-cell burnup example | Serpent input file | Single HTGR fuel particle in an infinite lattice | JLe / VTT | 18/04/09 |
| HTGR fuel pebble burnup example | Serpent input file | Single HTGR fuel pebble in an infinite lattice, demonstrates the explicit particle fuel model | JLe / VTT | 18/04/09 |
| HTGR fuel compact burnup example | Serpent input file | Single HTGR fuel compact in an infinite lattice, demonstrates the explicit particle fuel model | JLe / VTT | 18/04/09 |
Group constant generation
| Description | Files | Notes | Added by | Date |
|---|---|---|---|---|
| 2D PWR assembly | Serpent input file, Partial output | Demonstrates the basic features of the automated burnup sequence with coefficient matrix | JLe / VTT | 16/02/21 |
| 2D PWR assembly | Serpent input file, Partial output | Demonstrates the basic features of the automated burnup sequence with casematrix | ARi / VTT | 22/05/13 |
Simple transient examples
| Description | Files | Notes | Added by | Date |
|---|---|---|---|---|
| Infinite homogeneous LWR-like system (source generation) | Serpent input file | Demonstrates the source generation for transient simulations | VVa / VTT | 16/05/09 |
| Infinite homogeneous LWR-like system (0$ transient) | Serpent input file | Demonstrates the transient simulation mode | VVa / VTT | 16/05/09 |
| Infinite homogeneous LWR-like system (0.85$ transient) | Serpent input file | Demonstrates the transient simulation mode | VVa / VTT | 16/05/09 |
| Peach Bottom 2 3D assembly (source generation) | Main input file, Pin definition file, Geometry definition file, Pin definition file | Axially finite heterogeneous 3D assembly | VVa / VTT | 16/05/09 |
| Peach Bottom 2 3D assembly (0$ transient) | Main input file, Pin definition file, Geometry definition file, Pin definition file | Axially finite heterogeneous 3D assembly | VVa / VTT | 16/05/09 |
Miscellaneous
| Description | Files | Notes | Added by | Date |
|---|---|---|---|---|
| Pu-flattop and STACY critical experiments (PU-MET-FAST-006 and LEU-SOL-THERM-007 from the ICSBEP Handbook[1]) | Serpent and MCNP input files | Used for demonstarting the dynamic simulation mode introduced at the M&C 2013 conference[2] | JLe / VTT | 15/11/26 |
| Godiva (HEU-MET-FAST-001 from the ICSBEP Handbook[1]) | Serpent, KENO, and MCNP input files | Simple input files for students who start to learn about Monte Carlo codes | Ondrej Chvala | 2016-02-23 |
| Monte Carlo performance benchmark[3] | Serpent input file | Simplified 3D PWR core for testing the performance of Monte Carlo codes | JLe / VTT | 16/03/03 |
| Tank filled with molten salt with natural circulation based distributions from [4] | Serpent input files | Simplified molten salt tank with temperature and density distributions to test the unstructured mesh based interface | JLe / VTT + Manuele Aufiero | 2014 |
| A 37 assembly SMR sized reactor core. | Serpent input files | A rather detailed SMR sized reactor core based on data from the BEAVRS benchmark and a core size as well as radial reflector structure from the NuScale reactor concept. | ULa / VTT | 2019 |
| HTTR full core model | Serpent input files | 3D model of the Japanese gas-cooled High Temperature Engineering Test Reactor (HTTR). | JLe / VTT | 2020 |
References
- ^ https://www.oecd-nea.org/science/wpncs/icsbep/handbook.html
- ^ Leppänen, J. "Development of a dynamic simulation mode in the Serpent 2 Monte Carlo code." In proc. M&C 2013, Sun Valley, ID, May 5-9, 2013.
- ^ Hoogenboom, E., Martin, W. and Petrovic, B. "Monte Carlo Performance Benchmark for Detailed Power Density Calculation in a Full Size Reactor Core." Rev. 1.2, OECD/NEA, 2011 (http://www.oecd-nea.org/dbprog/MonteCarloPerformanceBenchmark.htm).
- ^ Leppänen, J. et al. "Unstructured mesh based multi-physics interface for CFD code coupling in the Serpent 2 Monte Carlo code" In proc. PHYSOR 2014, Kyoto, Japan, Sept. 28 - Oct. 3, 2014.
