Introduction Issues for Neutron Calculations for ITER Fusion Reactor Erik Nonbøl and Bent Lauritzen Risø DTU, National Laboratory for Sustainable Energy Roskilde, Denmark Outline 1. Fusion development 2. Issues for neutronics calculations 3. Risø DTU reasons for participating in ITER 4. Example of calculation on ITER-CTS diagnostics system NSFS meeting Ålesund, Norway May 26-30, 2008 NSFS meeting Ålesund, Norway 26-30 May 2008 2 Fusion development ITER to be build in France ITER, International Thermonuclear Experimental Reactor TORE SUPRA Fusion Research Center in France ITER CADARACHE at Aix-en Provence NSFS meeting Ålesund, Norway 26-30 May 2008 3 NSFS meeting Ålesund, Norway 26-30 May 2008 4 Fusion process The process involved is the following: Development of fusion designs D + T He 4 + n + 17,6 MeV 14.1 MeV 3.5 MeV NSFS meeting Ålesund, Norway 26-30 May 2008 5 NSFS meeting Ålesund, Norway 26-30 May 2008 6 1
JET Major progress NSFS meeting Ålesund, Norway 26-30 May 2008 7 NSFS meeting Ålesund, Norway 26-30 May 2008 8 Next steps for fusion Design principle for a fusion plant NSFS meeting Ålesund, Norway 26-30 May 2008 9 NSFS meeting Ålesund, Norway 26-30 May 2008 10 Issues for fusion vc. fission neutronics calc. TF-magnet cryostat blanket modules test blanket port plasma chamber divertor Neutron source in fission is determined by a criticality iteration Neutron source in fusion is prescribed by the plasma conditions no iteration is needed Different neutron energy spectra Fission peak 1-2 MeV Fusion peak 14 Mev vacuum vessel NSFS meeting Ålesund, Norway 26-30 May 2008 11 NSFS meeting Ålesund, Norway 26-30 May 2008 12 2
Neutron flux spectra: fusion vs. fission Fusion process and tritium breeding 10 16 Neutron flux density [cm -2 s -1 u -1 ] 10 15 10 14 10 13 10 12 HFR Petten Demo first wall D + T 4 He + n + 17.6 MeV 6 Li + n T + 4 He + 4.86 MeV 7 Li + n T + 4 He + n - 2.5 MeV 9 Be + n 2n + 2 4 He 10 11 10 1 10 2 10 3 10 4 10 5 10 6 10 7 Neutron energy [ev] NSFS meeting Ålesund, Norway 26-30 May 2008 13 NSFS meeting Ålesund, Norway 26-30 May 2008 14 Neutronics calculations Fusion Reactor Design Issues Blanket Tritium breeding, power generation, (shielding) assure tritium self-sufficiency, provide nuclear heating data for thermalhydraulic layout Shield Attenuate radiation to tolerable level assure sufficient protection of super-conducting magnet avoid structural damage, helium gas production in steel structure Safety & Environment, Maintenance Material activation minimise activation inventory with regard to short-term and long-term hazard potential maintenance service during reactor shutdown (dose level) Neutronics calculations QA/QC Fusion Reactor Design relies on data provided by nuclear design calculations Qualified computational simulations are required Appropriate computational methods, tools (codes) and data (nuclear cross-sections) Validation Qualification through integral benchmark experiments. NSFS meeting Ålesund, Norway 26-30 May 2008 15 NSFS meeting Ålesund, Norway 26-30 May 2008 16 Risø DTU reasons for participating in ITER Monte Carlo calculations Experience in calculation of neutron and gamma fluxes and neutron activation in fission reactors by means of the Monte Carlo code MCNP Validation calculations performed for Forsmark Nuclear Power Plant Local Association Euratom/Risø DTU Plasma group, need for in-house neutronics calculation capabilities for designing the Collective Thomson Scattering (CTS) diagnostics system A simplified ITER 40 degree geometry input model for MCNP-5 has been developed (about 300 cells) Detailed geometric description of the CTS diagnostics system Well suited for parametric studies short CPU time The input model has been benchmarked against the (20 degrees) ITER FEAT reference model (about 3000 cells) NSFS meeting Ålesund, Norway 26-30 May 2008 17 NSFS meeting Ålesund, Norway 26-30 May 2008 18 3
Geometry of simple model vs. ITER FEAT model Simple model ITER FEAT model Risø s CTS system CTS: Collective Thomson Scattering diagnostic of fast ions alterations to inboard blanket Neutronics: Temperature increase in the TF coil magnets Material damages due to fast neutrons NSFS meeting Ålesund, Norway 26-30 May 2008 19 NSFS meeting Ålesund, Norway 26-30 May 2008 20 Mirror 1 and Mirror 2 Blanket module Fund. Waveguides Mirror #1 Blanket Module key Beam Mirror #2 Horns Cooling manifold NSFS meeting Ålesund, Norway 26-30 May 2008 21 NSFS meeting Ålesund, Norway 26-30 May 2008 22 Blanket Cut-out CTS calculation with mirror cavity and slot TF coil Blanket #4 Vertical Gap = 10 mm Spacer (in yellow )= 8 mm Slot + mirror cavity Mirror +cavity Blanket #3 Blanket Cut-out Height = 28 mm Width front = 580 mm Width back = 410 mm Horizontal cross section Vertical cross section NSFS meeting Ålesund, Norway 26-30 May 2008 23 NSFS meeting Ålesund, Norway 26-30 May 2008 24 4
Nuclear heating of TF winding pack Fast neutron flux in TF coil insulator (epoxy) Nuclear heating of TF winding pack Fast neutron flux (E>0.1 MeV) in TF coil insulator 1.2x10-4 4.00 Design limit = 1.4 x10-4 W/g 1.1x10-4 3.50 Heat deposition [W/g] 1.0x10-4 9.0x10-5 8.0x10-5 7.0x10-5 6.0x10-5 Fast neutron flux [10 10 n cm -2 s -1 ] 3.00 2.50 2.00 1.50 Design limit 5.0x10-5 4.0x10-5 3.0x10-5 Cavity and slit No cavity 10 30 50 0 20 40 60 Slit height [mm] 1.00 0.50 Cavity and slit No cavity 10 30 50 0 20 40 60 Slit height [mm] NSFS meeting Ålesund, Norway 26-30 May 2008 25 NSFS meeting Ålesund, Norway 26-30 May 2008 26 5