ARIES-AT: An Advanced Tokamak, Advanced Technology Fusion Power Plant Farrokh Najmabadi University of California, San Diego, La Jolla, CA, United States of America 9th Course on Technology of Fusion Reactors 26 July – 1 August 2004 Erice Italy Electronic Copy: ARIES Web Site: http://aries.ucsd.edu/PUBLIC ARIES Research Framework: Identify Key R&D Issues and Provide a Vision for Fusion Research Periodic Input from Goals and Scientific & Technical Energy Industry Requirements Achievements Projections and Design Options Evaluation Based on Characterization Customer Attributes of Critical Issues Attractiveness Feasibility No: Redesign Yes Balanced Assessment of R&D Needs and Attractiveness & Feasibility Development Plan ARIES Designs Are Developed Based on a Reasonable Extrapolation of Physics & Technology ARIES Rules ARIES Rules (cid:190) Plasma regimes of operation are optimized based on latest experimental (cid:190) Plasma regimes of operation are optimized based on latest experimental achievements and/or “well-founded” theoretical predictions. achievements and/or “well-founded” theoretical predictions. (cid:190) Engineering system is based on “evolution” of present-day technologies, i.e., (cid:190) Engineering system is based on “evolution” of present-day technologies, i.e., they should be available at least in small samples now. Only learning-curve they should be available at least in small samples now. Only learning-curve cost credits are assumed in costing the system components. cost credits are assumed in costing the system components. Optimization involves trade-off among Physics and Engineering Optimization involves trade-off among Physics and Engineering constraints and parameters constraints and parameters (cid:190) Trade-off between vertical stability and plasma shape (and β) (cid:190) Trade-off between vertical stability and plasma shape (and β) and fusion core configuration and blanket thickness. and fusion core configuration and blanket thickness. (cid:190) Trade-off between plasma edge condition and plasma facing (cid:190) Trade-off between plasma edge condition and plasma facing components capabilities components capabilities (cid:190) ... (cid:190) ... Customer Requirements Top-Level Requirements for Fusion Power Plants Was Developed in Consultation with US Industry Public Acceptance: Public Acceptance: (cid:190) No public evacuation plan is required: total dose < 1 rem at site boundary; (cid:190) No public evacuation plan is required: total dose < 1 rem at site boundary; (cid:190) Generated waste can be returned to environment or recycled in less than a few (cid:190) Generated waste can be returned to environment or recycled in less than a few hundred years (not geological time-scale); hundred years (not geological time-scale); (cid:190) No disturbance of public’s day-to-day activities; (cid:190) No disturbance of public’s day-to-day activities; (cid:190) No exposure of workers to a higher risk than other power plants; (cid:190) No exposure of workers to a higher risk than other power plants; Reliable Power Source: Reliable Power Source: (cid:190) Closed tritium fuel cycle on site; (cid:190) Closed tritium fuel cycle on site; (cid:190) Ability to operate at partial load conditions (50% of full power); (cid:190) Ability to operate at partial load conditions (50% of full power); (cid:190) Ability to maintain power core (availability > 80%); (cid:190) Ability to maintain power core (availability > 80%); (cid:190) Ability to operate reliably with < 0.1 major unscheduled shut-down per year. (cid:190) Ability to operate reliably with < 0.1 major unscheduled shut-down per year. (cid:190) Economic Competitiveness: Above requirements must be achieved (cid:190) Economic Competitiveness: Above requirements must be achieved simultaneously and consistent with a competitive life-cycle cost of electricity. simultaneously and consistent with a competitive life-cycle cost of electricity. Directions for Optimization Translation of Requirements to GOALS for Fusion Power Plants Requirements: (cid:190) Have an economically competitive life-cycle cost of electricity: t n • Low recirculating power (Increase plasma Q, …); COE has a “hyperbolic” e s dependence (∝ 1/x) and e • High power density (Increase P ~ β2B 4 , …) r f T p improvements “saturate” m • High thermal conversion efficiency; after certain limit o r • Less-expensive systems. f n o i t a (cid:190) Gain Public acceptance by having excellent safety and environmental l o p characteristics: y a a r d t • Use low-activation and low toxicity materials and care in design. x - t e n r e e s g (cid:190) Have operational reliability and high availability: e r r p a L • Ease of maintenance o t e • Design margins, and extensive R&D. s o l c y (cid:190) Acceptable cost of development. a t S There Is Little Economic Benefit for Operating Beyond ~ 5 MW/m2 of Wall Load (for 1000MWe) (cid:190) (cid:190) SSimimpplele a annaalylyssisis f foorr a a c cyylilninddrricicaal lp plalassmmaa ARIES-RS with length L: 10 with length L: Systems code V What we pay for, FPC 9 ) h W k c/ 8 ( E O r ∆ C 7 Hyperbolic dependence 6 0 1 2 3 4 5 Avg. wall load (MW/m2) Hyperbolic WWaalll ll oloaaddiningg I I ∝∝11/r/r (cid:190) Physics & Engineering constraints w dependence (cid:190) Physics & Engineering constraints w ∆∆ i sis s seet tb byy n neeuutrtroonn m mffpp ccaauussee d deeppaartruturere f rforomm g geeoommeetrtircicaal l dependence e.g., high field needed VV == π πLL ( ( 2 2rr∆∆ + + ∆ ∆22)) dependence e.g., high field needed FPC for high load increases TF cost. FPC for high load increases TF cost. For r >> ∆ , V ≅ 2 π Lr∆ ∝ 1 / I For r >> ∆ , V ≅ 2 π Lr∆ ∝ 1 / I FPC w FPC w (cid:190) ARIES-AT optimizes at lower (cid:190) ARIES-AT optimizes at lower FFoorr r r < <<< ∆ ∆ , , V VFPC≅≅ 22 π πLL ∆ ∆22≅≅ccoonnsst.t. wall loading because of high FPC wall loading because of high (cid:190) efficiency. (cid:190) “Knee of the curve” is at r ≅ ∆ efficiency. “Knee of the curve” is at r ≅ ∆ Continuity of ARIES research has led to the progressive refinement of research ARIES-I (1990): • Trade-off of β with bootstrap • High-field magnets to compensate for low β Need high β equilibria with high bootstrap s ARIES-II/IV, 2nd Stability (1992): c i s • High β only with too much bootstrap y h P • Marginal reduction in current-drive power d Need high β equilibria e v o with aligned bootstrap r p ARIES-RS, reverse shear (1996): m I • Improvement in β and current-drive power • Approaching COE insensitive of power density Better bootstrap alignment More detailed physics ARIES-AT, reverse shear (2000): • Approaching COE insensitive of current-drive • High β is used to reduce toroidal field Evolution of ARIES Designs 1st Stability, High-Field Reverse Shear Nb Sn Tech. Option Option 3 ARIES-I’ ARIES-I ARIES-RS ARIES-AT Major radius (m) 8.0 6.75 5.5 5.2 β (β ) 2% (2.9) 2% (3.0) 5% (4.8) 9.2% (5.4) Ν Peak field (T) 16 19 16 11.5 Avg. Wall Load (MW/m2) 1.5 2.5 4 3.3 Current-driver power (MW) 237 202 81 36 Recirculating Power Fraction 0.29 0.28 0.17 0.14 Thermal efficiency 0.46 0.49 0.46 0.59 Cost of Electricity (c/kWh) 10 8.2 7.5 5 Approaching COE insensitive of power density Approaching COE insensitive of current drive