Your search keyword '"Stober, J. K."' showing total 11 results

1. Feedback controlled, reactor relevant, high-density, high-confinement scenarios at ASDEX Upgrade

Author

Lang, P.T., Blanken, T.C., Dunne, M., McDermott, R.M., Wolfrum, E., Bobkov, V., Felici, F., Fischer, R., Janky, F., Kallenbach, A., Kardaun, O., Kudlacek, O., Mertens, V., Mlynek, A., Ploeckl, B., Stober, J. K., Treutterer, W., Zohm, H., Lang, P.T., Blanken, T.C., Dunne, M., McDermott, R.M., Wolfrum, E., Bobkov, V., Felici, F., Fischer, R., Janky, F., Kallenbach, A., Kardaun, O., Kudlacek, O., Mertens, V., Mlynek, A., Ploeckl, B., Stober, J. K., Treutterer, W., and Zohm, H.

Abstract

One main programme topic at the ASDEX Upgrade all-metal-wall tokamak is development of a high-density regime with central densities at reactor grade level while retaining high-confinement properties. This required development of appropriate control techniques capable of coping with the pellet tool, a powerful means of fuelling but one which presented challenges to the control system for handling of related perturbations. Real-time density profile control was demonstrated, raising the core density well above the Greenwald density while retaining the edge density in order to avoid confinement losses. Recently, a new model-based approach was implemented that allows direct control of the central density. Investigations focussed first on the N-seeding scenario owing to its proven potential to yield confinement enhancements. Combining pellets and N seeding was found to improve the divertor buffering further and enhance the operational range accessible. For core densities up to about the Greenwald density, a clear improvement with respect to the non-seeding reference was achieved; however, at higher densities this benefit is reduced. This behaviour is attributed to recurrence of an outward shift of the edge density profile, resulting in a reduced peeling-ballooning stability. This is similar to the shift seen during strong gas puffing, which is required to prevent impurity influx in ASDEX Upgrade. First tests indicate that highly-shaped plasma configurations like the ITER base-line scenario, respond very well to pellet injection, showing efficient fuelling with no measurable impact on the edge density profile.

Published

2018

2. The enhanced high speed inboard pellet fuelling system at ASDEX Upgrade

Author

Plöckl, B., Lang, P. T., Sellmair, G., Stober, J. K., Treutterer, W., Vinyar, I., ASDEX Upgrade Team, and ASDEX Upgrade Team

Subjects

Tokamak, Temperature control, Computer science, Mechanical Engineering, Process (computing), Programmable logic controller, Functional requirement, Automotive engineering, law.invention, Technical progress, Nuclear Energy and Engineering, ASDEX Upgrade, law, Control system, General Materials Science, Civil and Structural Engineering

Abstract

After more than 20 years of operation and numerous modifications, a substantial modernisation of the inboard pellet injection system on ASDEX Upgrade was carried out. This enhancement was necessary to meet new functional requirements and to benefit from technical progress as well. New requirements are the integration in discharge control system, variation of settings of pellet train parameters during one discharge, temperature control of ice extrusion and overcome process limits caused by out-dated vacuum components. The programmable logic controller system is now fully migrated to S7-300 using High Speed Boolean Processor FM352-5 to replace hard-wired logic elements and enable flexible control of process parameters. First applications on ASDEX Upgrade concerning high density operation and ELM control are presented to confirm usefulness of implemented features.

Published

2013

3. Commissioning of inline ECE system within waveguide based ECRH transmission systems on ASDEX upgrade

Author

Bongers, W. A., Kasparek, W., Doelman, N., van den Braber, R., van den Brand, H., Meo, Fernando, de Baar, M. R., Amerongen, F. J., Donne, A. J. H., Elzendoorn, B. S. Q., Erckmann, V., Goede, A. P. H., Giannone, L., Grünwald, G., Hollman, F., Kaas, G., Krijger, B., Michel, G., Lubyako, L., Monaco, F., Noke, F., Petelin, M., Plaum, B., Purps, F., ten Pierik, J. G. W., Schüller, C., Slob, J. W., Stober, J. K., Schütz, H., Wagner, D., Westerhof, E., and Ronden, D. M. S.

Abstract

A CW capable inline electron cyclotron emission (ECE) separation system for feedback control, featuring oversized corrugated waveguides, is commissioned on ASDEX upgrade (AUG). The system is based on a combination of a polarization independent, non-resonant, Mach-Zehnder diplexer equipped with dielectric plate beam splitters [2, 3] employed as corrugated oversized waveguide filter, and a resonant Fast Directional Switch, FADIS [4, 5, 6, 7] as ECE/ECCD separation system. This paper presents an overview of the system, the low power characterisation tests and first high power commissioning on AUG.

Published

2012

4. Edge fluctuations in the absence of large ELMs on JET

Author

Maddison, G. P., Alper, B., Beurskens, M. N. A., Sebastien Hacquin, Koslowski, H. R., Lönnroth, J., Saibene, G. R., Sharapov, S., Stober, J. K., Parail, V., and JET EFDA Contributors

Published

2005

5. Improved confinement in JET hybrid discharges

Author

Hobirk, J., Imbeaux, F., Crisanti, F., Buratti, P., Challis, C. D., Joffrin, E., Alper, B., Andrew, Y., Beaumont, P., Beurskens, M., Boboc, A., Botrugno, A., Brix, M., Calabro', G., Coffey, I., Conroy, Sean, Ford, O., Frigione, D., Garcia, J., Giroud, C., Hawkes, N. C., Howell, D., Jenkins, I., Keeling, D., Kempenaars, M., Leggate, H., Lotte, P., de la Luna, E., Maddison, G. P., Mantica, P., Mazzotta, C., McDonald, D. C., Meigs, A., Nunes, I., Rachlew, E., Rimini, F., Schneider, M., Sips, A. C. C., Stober, J. K., Studholme, W., Tala, T., Tsalas, M., Voitsekhovitch, I., de Vries, P. C., Hobirk, J., Imbeaux, F., Crisanti, F., Buratti, P., Challis, C. D., Joffrin, E., Alper, B., Andrew, Y., Beaumont, P., Beurskens, M., Boboc, A., Botrugno, A., Brix, M., Calabro', G., Coffey, I., Conroy, Sean, Ford, O., Frigione, D., Garcia, J., Giroud, C., Hawkes, N. C., Howell, D., Jenkins, I., Keeling, D., Kempenaars, M., Leggate, H., Lotte, P., de la Luna, E., Maddison, G. P., Mantica, P., Mazzotta, C., McDonald, D. C., Meigs, A., Nunes, I., Rachlew, E., Rimini, F., Schneider, M., Sips, A. C. C., Stober, J. K., Studholme, W., Tala, T., Tsalas, M., Voitsekhovitch, I., and de Vries, P. C.

Abstract

A new technique has been developed to produce plasmas with improved confinement relative to the H-98,H-y2 scaling law (ITER Physics Expert Groups on Confinement and Transport and Confinement Modelling and Database ITER Physics Basics Editors and ITER EDA 1999 Nucl. Fusion 39 2175) on the JET tokamak. In the mid-size tokamaks ASDEX upgrade and DIII-D heating during the current formation is used to produce a flat q-profile with a minimum close to 1. On JET this technique leads to q-profiles with similar minimum q but opposite to the other tokamaks not to an improved confinement state. By changing the method utilizing a faster current ramp with temporary higher current than in the flattop (current overshoot) plasmas with improved confinement (H-98,H-y2 = 1.35) and good stability (beta(N) approximate to 3) have been produced and extended to many confinement times only limited by technical constraints. The increase in H-98,H-y2-factor is stronger with more heating power as can be seen in a power scan. The q-profile development during the high power phase in JET is reproduced by current diffusion calculated by TRANSP and CRONOS. Therefore the modifications produced by the current overshoot disappear quickly from the edge but the confinement improvement lasts longer, in some cases up to the end of the heating phase.

Published

2012

6. Improved confinement in JET hybrid discharges

Author

Hobirk, J., Imbeaux, F., Crisanti, F., Buratti, P., Challis, C. D., Joffrin, E., Alper, B., Andrew, Y., Beaumont, P., Beurskens, M., Boboc, A., Botrugno, A., Brix, M., Calabro', G., Coffey, I., Conroy, S., Ford, O., Frigione, D., Garcia, J., Giroud, C., Hawkes, N. C., Howell, D., Jenkins, I., Keeling, D., Kempenaars, M., Leggate, H., Lotte, P., De La Luna, E., Maddison, G. P., Mantica, P., Mazzotta, C., McDonald, D. C., Meigs, A., Nunes, I., Rachlew, Elisabeth, Rimini, F., Schneider, M., Sips, A. C. C., Stober, J. K., Studholme, W., Tala, T., Tsalas, M., Voitsekhovitch, I., De Vries, P. C., Hobirk, J., Imbeaux, F., Crisanti, F., Buratti, P., Challis, C. D., Joffrin, E., Alper, B., Andrew, Y., Beaumont, P., Beurskens, M., Boboc, A., Botrugno, A., Brix, M., Calabro', G., Coffey, I., Conroy, S., Ford, O., Frigione, D., Garcia, J., Giroud, C., Hawkes, N. C., Howell, D., Jenkins, I., Keeling, D., Kempenaars, M., Leggate, H., Lotte, P., De La Luna, E., Maddison, G. P., Mantica, P., Mazzotta, C., McDonald, D. C., Meigs, A., Nunes, I., Rachlew, Elisabeth, Rimini, F., Schneider, M., Sips, A. C. C., Stober, J. K., Studholme, W., Tala, T., Tsalas, M., Voitsekhovitch, I., and De Vries, P. C.

Abstract

QC 20140923

Published

2009

7. Progress in preparing scenarios for operation of the International Thermonuclear Experimental Reactor.

Author

Sips, A. C. C., Giruzzi, G., Ide, S., Kessel, C., Luce, T. C., Snipes, J. A., and Stober, J. K.

Subjects

DEUTERIUM, ELECTRON cyclotron resonance heating, PLASMA gases, HYDROGEN, FUSION reactor walls

Abstract

The development of operating scenarios is one of the key issues in the research for ITER which aims to achieve a fusion gain (Q) of ~10, while producing 500 MW of fusion power for =300s. The ITER Research plan proposes a success oriented schedule starting in hydrogen and helium, to be followed by a nuclear operation phase with a rapid development towards Q ~ 10 in deuterium/tritium. The Integrated Operation Scenarios Topical Group of the International Tokamak Physics Activity initiates joint activities among worldwide institutions and experiments to prepare ITER operation. Plasma formation studies report robust plasma breakdown in devices with metal walls over a wide range of conditions, while other experiments use an inclined EC launch angle at plasma formation to mimic the conditions in ITER. Simulations of the plasma burn-through predict that at least 4 MW of Electron Cyclotron heating (EC) assist would be required in ITER. For H-modes at q95 ~ 3, many experiments have demonstrated operation with scaled parameters for the ITER baseline scenario at ne/nGW ~ 0.85. Most experiments, however, obtain stable discharges at H98(y,2) ~ 1.0 only for ßN=2.0-2.2. For the rampup in ITER, early X-point formation is recommended, allowing auxiliary heating to reduce the flux consumption. A range of plasma inductance (li(3)) can be obtained from 0.65 to 1.0, with the lowest values obtained in H-mode operation. For the rampdown, the plasma should stay diverted maintaining H-mode together with a reduction of the elongation from 1.85 to 1.4. Simulations show that the proposed rampup and rampdown schemes developed since 2007 are compatible with the present ITER design for the poloidal field coils. At 13-15 MA and densities down to ne/nGW ~ 0.5, long pulse operation (>1000s) in ITER is possible at Q ~ 5, useful to provide neutron fluence for Test Blanket Module assessments. ITER scenario preparation in hydrogen and helium requires high input power (>50 MW). H-mode operation in helium may be possible at input powers above 35MW at a toroidal field of 2.65T, for studying H-modes and ELM mitigation. In hydrogen, H-mode operation is expected to be marginal, even at 2.65 T with 60 MW of input power. Simulation code benchmark studies using hybrid and steady state scenario parameters have proved to be a very challenging and lengthy task of testing suites of codes, consisting of tens of sophisticated modules. Nevertheless, the general basis of the modelling appears sound, with substantial consistency among codes developed by different groups. For a hybrid scenario at 12 MA, the code simulations give a range for Q=6.5-8.3, using 30MW neutral beam injection and 20MW ICRH. For non-inductive operation at 7-9 MA, the simulation results show more variation. At high edge pedestal pressure (Tped ~ 7keV), the codes predict Q=3.3-3.8 using 33MW NB, 20MW EC, and 20MW ion cyclotron to demonstrate the feasibility of steady-state operation with the day-1 heating systems in ITER. Simulations using a lower edge pedestal temperature (~3keV) but improved core confinement obtain Q=5-6.5, when ECCD is concentrated at mid-radius and ~20MW off-axis current drive (ECCD or LHCD) is added. Several issues remain to be studied, including plasmas with dominant electron heating, mitigation of transient heat loads integrated in scenario demonstrations and (burn) control simulations in ITER scenarios. [ABSTRACT FROM AUTHOR]

Published

2015

8. Pedestal conditions for small ELM regimes in tokamaks

Author

Oyama, N, primary, Gohil, P, additional, Horton, L D, additional, Hubbard, A E, additional, Hughes, J W, additional, Kamada, Y, additional, Kamiya, K, additional, Leonard, A W, additional, Loarte, A, additional, Maingi, R, additional, Saibene, G, additional, Sartori, R, additional, Stober, J K, additional, Suttrop, W, additional, Urano, H, additional, West, W P, additional, and Group, the ITPA Pedestal Topical, additional

Published

2006

9. Development of a reactor relevant high density high confinement scenario at ASDEX Upgrade

Author

Lang, P. T., Bobkov, V., Dunne, M., Kallenbach, A., Kardaun, O. J. W. F., Mcdermott, R., Mlynek, A., Mertens, V., Potzel, S., Bernhard Ploeckl, Stober, J. K., Wolfrum, E., Zohm, H., and ASDEX Upgrade Team, Max Planck Institute for Plasma Physics, Max Planck Society

10. Combined electron cyclotron emission and heating for the suppression of magnetic islands in fusion plasmas

Author

Den Brand, H., Baar, M. R., Hennen, B. A., Oosterbeek, J. W., Bongers, W. A., Egbert Westerhof, Kasparek, W., Doelman, N., Klop, W., Giannone, L., Stober, J. K., Monaco, F., Schütz, H., Wagner, D., and ASDEX Upgrade Team, Max Planck Institute for Plasma Physics, Max Planck Society

11. Experimental studies of ITER demonstration discharges

Author

F. Köchl, Massimiliano Mattei, T. A. Casper, V.V. Parail, R. Sartori, E. J. Doyle, Shunsuke Ide, G.L. Jackson, T. Suzuki, Diii-D Team, G. M. D. Hogeweij, P. J. Lomas, Frederic Imbeaux, Ian H. Hutchinson, J. Hobirk, Charles Kessel, Jet-Efda Contributors, G. Giruzzi, J. Stober, Alfredo Portone, A. C. C. Sips, S.M. Wolfe, Naoyuki Oyama, Earl Marmar, C-Mod Team, Yutaka Kamada, G. Saibene, Amanda Hubbard, L. D. Horton, T.C. Luce, I. Nunes, Akihiko Isayama, X. Litaudon, Y. Gribov, Sips, A., Casper, T., Doyle, E., Giruzzi, G., Gribov, Y., Hobirk, J., Hogeweij, G., Horton, L., Hubbard, A., Hutchinson, I., Ide, S., Isayama, A., Imbeaux, F., Jackson, G., Kamada, Y., Kessel, C., Kochl, F., Lomas, P., Litaudon, X., Luce, T., Marmar, E., Mattei, Massimiliano, Nunes, I., Oyama, N., Parail, V., Portone, A., Saibene, G., Sartori, R., Stober, J., Suzuki, T., Wolfe, S., A. C. C., Sip, T. A., Casper, E. J., Doyle, G., Giruzzi, Y., Gribov, J., Hobirk, G. M. D., Hogewej, L. D., Horton, A. E., Hubbard, I., Hutchinson, S., Ide, A., Isayama, F., Imbeaux, G. L., Jackson, Y., Kamada, C., Kessel, F., Kochl, P. J., Loma, X., Litaudon, T. C., Luce, E., Marmar, I., Nune, N., Oyama, V., Parail, A., Portone, G., Saibene, R., Sartori, T., Suzuki, G., Tardini, S., Wolfe, THE C., MOD TEAM, THE ASDEX UPGRADE, Team, THE DIII D., TEAM AND JET EFDA CONTRIBUTORS, Sips, A. C. C., Casper, T. A., Doyle, E. J., Hogeweij, G. M. D., Horton, L. D., Hubbard, A. E., Jackson, G. L., Luce, T. C., Mattei, M., Stober, J. K., and Wolfe, S. M.

Subjects

Physics, Nuclear and High Energy Physics, Plasma breakdown, Nuclear engineering, Plasma, Condensed Matter Physics, law.invention, Inductance, ASDEX Upgrade, Electromagnetic coil, law, Fusione Termonucleare, Tokamak, Modellistica e Controllo di plasmi, Atomic physics, Transformer, Ohmic contact, Voltage

Abstract

Key parts of the ITER scenarios are determined by the capability of the proposed poloidal field (PF) coil set. They include the plasma breakdown at low loop voltage, the current rise phase, the performance during the flat top (FT) phase and a ramp down of the plasma. The ITER discharge evolution has been verified in dedicated experiments. New data are obtained from C-Mod, ASDEX Upgrade, DIII-D, JT-60U and JET. Results show that breakdown for E axis < 0.23–0.33 V m−1 is possible unassisted (ohmic) for large devices like JET and attainable in devices with a capability of using ECRH assist. For the current ramp up, good control of the plasma inductance is obtained using a full bore plasma shape with early X-point formation. This allows optimization of the flux usage from the PF set. Additional heating keeps l i(3) < 0.85 during the ramp up to q 95 = 3. A rise phase with an H-mode transition is capable of achieving l i(3) < 0.7 at the start of the FT. Operation of the H-mode reference scenario at q 95 ∼ 3 and the hybrid scenario at q 95 = 4–4.5 during the FT phase is documented, providing data for the l i (3) evolution after the H-mode transition and the l i (3) evolution after a back-transition to L-mode. During the ITER ramp down it is important to remain diverted and to reduce the elongation. The inductance could be kept ⩽1.2 during the first half of the current decay, using a slow I p ramp down, but still consuming flux from the transformer. Alternatively, the discharges can be kept in H-mode during most of the ramp down, requiring significant amounts of additional heating.

Published

2009