Presentation is loading. Please wait.

Presentation is loading. Please wait.

Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20051 CRONOS simulations of ITER AT scenarios F. Imbeaux, J.F. Artaud, V. Basiuk,

Published byMerry Welch Modified over 8 years ago

Similar presentations

Presentation on theme: "Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20051 CRONOS simulations of ITER AT scenarios F. Imbeaux, J.F. Artaud, V. Basiuk,"— Presentation transcript:

1 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20051 CRONOS simulations of ITER AT scenarios F. Imbeaux, J.F. Artaud, V. Basiuk, L.G. Eriksson, G. Giruzzi, G. Huysmans, X. Litaudon, M. Schneider

2 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20052 Main assumptions Hybrid scenario (presented at EPS 2005, joint with TP group) Projections using various models / scalings Current drive issues Steady-state scenario : demonstration of new feedback algorithm Database submission Outline

3 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20053 Simulation parameters Hybrid (q 95 = 4) scenarios Thermal transport + current diffusion Density prescribed (flat Z eff profile, n e flat or peaked) f D = f T = 37.5 % (n D /n e ), f He = 2 %, f Be = 0.5 %, f C = 4.5 % 53 / 73 MW of additional power 33 MW NBI @ 900 keV (SINBAD) 20 MW ICRH (PION, 2 nd harmonic of T, f = 55 MHz) 0 / 20 MW of LHCD (DELPHINE, f = 5 GHz, n // = 2.0)

4 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20054 Transport model based on 2-terms scaling 1D model with a profile dependence : Most important point : C is a normalisation factor calculated at each time step so that the total energy content follows a global scaling law (IPB98(y,2) or DS03). If P in > P L-H, then a pedestal is added (fixed width). Constant  in the pedestal, pedestal energy content renormalised to a specific scaling law (2-terms approach, [Cordey et al NF 2003, 670]) P tot  max W0W0 W ped W core   ped   max   ped  core  neo  ped link

5 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20055 Scaling expressions used Scaling set A (global IPB98 + core 96-L): Scaling set A’ with reduced pedestal (global IPB98 + enhanced 96-L), more consistent with official ITER reference H mode projections Scaling set B (DS03 + pedestal scaling), no  degradation H H = 1 One example using GLF23 for  < 0.8, with edge given by scaling set B

6 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20056 Hybrid scenario for ITER, for various scalings / models I p = 13 MA only slightly lower than reference scenario (15 MA) (not lose too much on energy confinement). P aux = 53 MW (NBI + ICRH) Density peaking n e0 /n e,ped = 1.5 Greenwald fraction = 0.92 No enhancement w.r.t. scaling laws  NB : the GLF23 result uses same pedestal condition as DS03 [CRONOS]

7 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20057 Off-axis current drive needed for high  N and extended duration ?  20 MW LHCD delay significantly the occurrence of q = 1 LH [CRONOS] Sustaining high  N ~ 3 requires no or small q = 1 surface In spite of reduced I p, q = 1 finally occurs … and might trigger deleterious NTMs ? DS03 scaling

8 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20058 The Hybrid scenario achieves Q = 10 at 13 MA (using DS03 scaling more favorable at high  N ) If only 33 MW NBI and 20 MW ICRH, q = 1 appears at ~ 650 s Additional off-axis current drive might be needed to reduce the size of the q = 1 surface and delay its occurrence 20 MW LHCD allow to delay the occurrence of the q = 1 surface until 1040 s 40 MW LHCD allows to get rid completely of q = 1 surface RWM stabilisation needed (  N > 4li) Conclusions for hybrid scenario

9 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20059 Steady-state scenario

10 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200510 Steady-state scenario Multi feedback control on the steady-state scenario (9 MA) : aim at sustaining internal transport barrier without going beyond operational limits A rather optimistic transport model is used : 2-terms scaling model, using scaling set B (DS03) Shear function to produce an ITB (improvement w.r.t. global scaling)

11 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200511 The « try, wait and see » feedback algorithm Philosophy : control a given parameter without a priori knowledge of the physics of the system Aim : maximize a given parameter (here : look for maximum P fus ) Try : modify one of the actuators (here, P NBI, P ICRH, n e ) (add or substract a given incremental value) Wait : let the plasma evolve during a given time scale (here : energy confinement time) See : has the modification of the actuator fullfilled the aim ? Yes  take another incremental step on the actuator No  if it was the first variation of actuator, try variation in the opposite direction; otherwise, step back and skip to next actuator

12 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200512 Additional constraints The « try, wait and see » feedback algorithm is used with additional constraints, corresponding to physical limits and/or the desired operation space  N < 4.li : otherwise, reduce P NBI and P ICRH fr min  n/n G  fr max : otherwise : n/n G < fr min : increase density n/n G > fr max : increase P NBI and P ICRH (will increase Ip) Aim at V loop = 0 : Start at low I p (550 kA, fixed), and let I P vary as an actuator of the « try, wait and see » feedback algorithm As soon as full non-inductive current drive is reached (following the increase of the heating power), transition to constant edge flux  I p is left floating and removed from the list of TWS actuators

13 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200513 Example Current, T e and T i are simulated, as well as heat sources and current drive Heat transport model : 2-terms scaling model, using scaling set B (DS03), with shear function (s,  ) The line-averaged density is considered directly as an actuator (no particle transport calculation). The whole density profile keeps a constant shape with peaking factor = 1.2 –Constraint on operational space : 0.55 < Greenwald fraction < 0.85 Injected Power –P LH fixed at 20 MW, with a fixed profile (center = 0.5, width = 0.2 and a fixed efficiency 2.5 10 19 W/A/m² and scaling dependences) –P ICRH between 10 to 20 MW –P NBI between 0 to 32 MW « try, wait and see » feedback algorithm aiming at maximize P fus

14 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200514 Currents Transition to constant edge flux Spikes are consequences of the TWS actuators dynamics

15 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200515 PP P LH P ICRH P NBI time (s) Transition to constant edge flux Heating powers P NBI drops because of operational limit

16 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200516 Operational constraints NN 4li PP P LH P ICRH P NBI time (s) Transition to constant edge flux Constraint  N < 4li prevents from increasing PNBI As li slowly increases,  N is also allowed to increase slowly (via the density)  slow increase of fusion power time (s)

17 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200517 time (s) Bootstrap and Greenwald fractions Greenwald fraction increases slowly with  N limit, within the operational space : 0.55 < f GR < 0.85

18 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200518 Until 400 s, the ITB shrinks owing to misalignment with bootstrap current To be continued … ITB dynamics

19 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200519 « Try, wait and see » feedback algorithm allows to maximise fusion power while keeping the system in a safe operational domain Does not require a priori knowledge of the system. Very useful for transient phases of the steady-state scenario (owing to the non-linearities due to the ITB) Can be applied too much more subtle optimisation problems Conclusions for steady-state scenario

20 Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 200520 Conclusions and perspectives The Hybrid scenario achieves Q = 10 at 13 MA (using DS03 scaling more favorable at high  N ) If only 33 MW NBI and 20 MW ICRH, q = 1 appears at ~ 650 s Additional off-axis current drive might be needed to reduce the size of the q = 1 surface and delay its occurrence 20 MW LHCD allow to delay the occurrence of the q = 1 surface until 1040 s « Try, wait and see » feedback algorithm allows to maximise fusion power while keeping the system in a safe operational domain Very useful for transient phases of the steady-state scenario (owing to the non-linearities due to the ITB) CRONOS is now able to write ITER simulations in Profile DB  strategy to discuss

Download ppt "Association Euratom-Cea ITPA CDBM group meeting, St Petersburg, October 20051 CRONOS simulations of ITER AT scenarios F. Imbeaux, J.F. Artaud, V. Basiuk,"

Similar presentations

Physics Basis of FIRE Next Step Burning Plasma Experiment Charles Kessel Princeton Plasma Physics Laboratory U.S.-Japan Workshop on Fusion Power Plant.

Physics Basis of FIRE Next Step Burning Plasma Experiment Charles Kessel Princeton Plasma Physics Laboratory U.S.-Japan Workshop on Fusion Power Plant.
Density peaking and fusion power H. Weisen Role of fuel pressure profile Effect of He dilution ITPA CDBM 7-10.5 2007.

Density peaking and fusion power H. Weisen Role of fuel pressure profile Effect of He dilution ITPA CDBM
H. Weisen 1 21st IAEA FEC, Chengdu 2006 Peaked Density Profiles in Low Collisionality H-modes in JET, ASDEX Upgrade and TCV H. Weisen, C. Angioni, M. Maslov,

H. Weisen 1 21st IAEA FEC, Chengdu 2006 Peaked Density Profiles in Low Collisionality H-modes in JET, ASDEX Upgrade and TCV H. Weisen, C. Angioni, M. Maslov,
Stability, Transport, and Conrol for the discussion Y. Miura IEA/LT Workshop (W59) combined with DOE/JAERI Technical Planning of Tokamak Experiments (FP1-2)

Stability, Transport, and Conrol for the discussion Y. Miura IEA/LT Workshop (W59) combined with DOE/JAERI Technical Planning of Tokamak Experiments (FP1-2)
1 G.T. Hoang TORE SUPRA Association Euratom-Cea TTF, Madison, Apr 2003 G.T. Hoang, C. Bourdelle, B. Pégourié, J. F. Artaud, J.Bucalossi, F. Clairet, C.

1 G.T. Hoang TORE SUPRA Association Euratom-Cea TTF, Madison, Apr 2003 G.T. Hoang, C. Bourdelle, B. Pégourié, J. F. Artaud, J.Bucalossi, F. Clairet, C.
1 G.T. Hoang, 20th IAEA Fusion Energy Conference Euratom Turbulent Particle Transport in Tore Supra G.T. Hoang, J.F. Artaud, C. Bourdelle, X. Garbet and.

1 G.T. Hoang, 20th IAEA Fusion Energy Conference Euratom Turbulent Particle Transport in Tore Supra G.T. Hoang, J.F. Artaud, C. Bourdelle, X. Garbet and.
Emmanuel JoffrinXXth Fusion Energy Conference, November 2004 1 The « hybrid » scenario in JET: towards its validation for ITER E. Joffrin, A. C. C. Sips,

Emmanuel JoffrinXXth Fusion Energy Conference, November The « hybrid » scenario in JET: towards its validation for ITER E. Joffrin, A. C. C. Sips,
Momentum transport and flow shear suppression of turbulence in tokamaks Michael Barnes University of Oxford Culham Centre for Fusion Energy Michael Barnes.

Momentum transport and flow shear suppression of turbulence in tokamaks Michael Barnes University of Oxford Culham Centre for Fusion Energy Michael Barnes.
R Sartori - page 1 20 th IAEA Conference – Vilamoura Scaling Studies of ELMy H-modes global and pedestal confinement at high triangularity in JET R Sartori.

R Sartori - page 1 20 th IAEA Conference – Vilamoura Scaling Studies of ELMy H-modes global and pedestal confinement at high triangularity in JET R Sartori.
IAEA - FEC2004 // Vilamoura // 03.11.04 // EX/4-5 // A. Staebler – 1 – A. Staebler, A.C.C Sips, M. Brambilla, R. Bilato, R. Dux, O. Gruber, J. Hobirk,

IAEA - FEC2004 // Vilamoura // // EX/4-5 // A. Staebler – 1 – A. Staebler, A.C.C Sips, M. Brambilla, R. Bilato, R. Dux, O. Gruber, J. Hobirk,
Physics Analysis for Equilibrium, Stability, and Divertors ARIES Power Plant Studies Charles Kessel, PPPL DOE Peer Review, UCSD August 17, 2000.

Physics Analysis for Equilibrium, Stability, and Divertors ARIES Power Plant Studies Charles Kessel, PPPL DOE Peer Review, UCSD August 17, 2000.
TSC time dependent free-boundary simulations of the ACT1 (aggr phys) plasma and disruptions C. Kessel, PPPL ARIES Project Meeting, Jan 23-24, 2012, UCSD.

TSC time dependent free-boundary simulations of the ACT1 (aggr phys) plasma and disruptions C. Kessel, PPPL ARIES Project Meeting, Jan 23-24, 2012, UCSD.
21st Fusion Energy Conference, Chengdu, 16-21 October 2006 1 Critical Physics Issues for Tokamak Power Plants D J Campbell 1, F De Marco 2, G Giruzzi 3,

21st Fusion Energy Conference, Chengdu, October Critical Physics Issues for Tokamak Power Plants D J Campbell 1, F De Marco 2, G Giruzzi 3,
Y. Sakamoto JAEA Japan-US Workshop on Fusion Power Plants and Related Technologies with participations from China and Korea February 26-28, 2013 at Kyoto.

Y. Sakamoto JAEA Japan-US Workshop on Fusion Power Plants and Related Technologies with participations from China and Korea February 26-28, 2013 at Kyoto.
H. Urano, H. Takenaga, T. Fujita, Y. Kamada, K. Kamiya, Y. Koide, N. Oyama, M. Yoshida and the JT-60 Team Japan Atomic Energy Agency JT-60U Tokamak: p.

H. Urano, H. Takenaga, T. Fujita, Y. Kamada, K. Kamiya, Y. Koide, N. Oyama, M. Yoshida and the JT-60 Team Japan Atomic Energy Agency JT-60U Tokamak: p.
Analysis and Simulations of the ITER Hybrid Scenario C. Kessel, R. Budny, K. Indireshkumar Princeton Plasma Physics Laboratory, USA ITPA Topical Group.

Analysis and Simulations of the ITER Hybrid Scenario C. Kessel, R. Budny, K. Indireshkumar Princeton Plasma Physics Laboratory, USA ITPA Topical Group.
1 Modeling of EAST Divertor S. Zhu Institute of Plasma Physics, Chinese Academy of Sciences.

1 Modeling of EAST Divertor S. Zhu Institute of Plasma Physics, Chinese Academy of Sciences.
Integrated Modeling and Simulations of ITER Burning Plasma Scenarios C. E. Kessel, R. V. Budny, K. Indireshkumar, D. Meade Princeton Plasma Physics Laboratory.

Integrated Modeling and Simulations of ITER Burning Plasma Scenarios C. E. Kessel, R. V. Budny, K. Indireshkumar, D. Meade Princeton Plasma Physics Laboratory.
SMK – ITPA1 Stanley M. Kaye Wayne Solomon PPPL, Princeton University ITPA Naka, Japan October 2007 Rotation & Momentum Confinement Studies in NSTX Supported.

SMK – ITPA1 Stanley M. Kaye Wayne Solomon PPPL, Princeton University ITPA Naka, Japan October 2007 Rotation & Momentum Confinement Studies in NSTX Supported.
October 20 2008 Milano Core-Pedestal Energy Confinement. Empirical Scaling Laws and stiff profiles. A. Jacchia 1, F. De Luca 2 1 Consiglio Nazionale.

October Milano Core-Pedestal Energy Confinement. Empirical Scaling Laws and "stiff" profiles. A. Jacchia 1, F. De Luca 2 1 Consiglio Nazionale.

Similar presentations

Ads by Google