An improved model for the accurate calculation of parallel heat fluxes at the JET bulk tungsten outer divertor

JET Contributors

doi:10.1088/1741-4326/aad83e

An improved model for the accurate calculation of parallel heat fluxes at the JET bulk tungsten outer divertor

JET Contributors

United Kingdom Atomic Energy Authority
Jülich Research Centre
ITER
Queen's University Belfast
Commissariat à l’énergie atomique et aux énergies alternatives
Czech Academy of Sciences
Aix-Marseille University
Culham Science Centre
Royal Military Academy
JET
Max Planck Institute for Plasma Physics
Princeton Plasma Physics Laboratory
Institute for Plasma Research
University of Lisbon
University of Helsinki
VTT Technical Research Centre of Finland Ltd.
National Institutes for Quantum and Radiological Science and Technology
University of Naples Federico II
National Distance Education University
National Research Council of Italy
Russian Research Centre Kurchatov Institute
University of Naples Parthenope
Agenzia nazionale per le nuove tecnologie, l'energia e lo sviluppo economico sostenibile
Troitsk Institute for Innovation and Fusion Research
Uppsala University
The National Institute for Cryogenics and Isotopic Technology
University of Catania
Fusion for Energy
Toki
Massachusetts Institute of Technology
Aalto University
Imperial College London
CIEMAT
University of Oxford
EUROfusion Programme Management Unit
Oak Ridge National Laboratory
Karlsruhe Institute of Technology
University of York
KTH Royal Institute of Technology
Maritime University Of Szczecin
Institute of Nuclear Physics Polish Academy of Sciences
University of Trento
Swiss Federal Institute of Technology Lausanne
Wigner Research Centre for Physics
Comenius University
Lviv Polytechnic National University
University of Milan - Bicocca
The National Institute for Optoelectronics
Fourth State Research
University of Texas at Austin
Belgian Nuclear Research Center
National Centre for Nuclear Research
University of Cagliari
University of Warwick
Andrzej Soltan Institute for Nuclear Studies
Dutch Institute for Fundamental Energy Research
National Institute for Laser, Plasma and Radiation Physics
Ghent University
J. Stefan Institute
Université de Lorraine
CAS - Institute of Plasma Physics
University of California at San Diego
Horia Hulubei National Institute of Physics and Nuclear Engineering
Chalmers University of Technology
European Commission
Technical University of Madrid
University of Campania Luigi Vanvitelli
Warsaw University of Technology
University of Basilicata
Barcelona Supercomputing Center (BSC)
Aix Marseille Université
University of Seville
Centro Brasileiro de Pesquisas Físicas
University of Rome Tor Vergata
Ioffe Physico-Technical Institute
General Atomics
University of Innsbruck
University of Toyama
University of Strathclyde
National Technical University of Athens
Tuscia University
Technical University of Denmark
Korea Advanced Institute of Science and Technology
Seoul National University
University College Cork
TU Wien
University of Opole
Daegu University
University of Latvia
National Fusion Research Institute
Dublin City University
PELIN LLC
Arizona State University
Complutense University
University of Basel
Universidad Carlos III de Madrid
Consorzio CREATE
Demokritos National Centre for Scientific Research
Purdue University
ULB-Campus Plaine
University of California
Universidade de São Paulo
Lithuanian Energy Institute
HRS Fusion
Polytechnic University of Turin
University of Cassino and Southern Lazio
University of Electronic Science and Technology of China

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

Parallel heat flux calculations at the JET divertor have been based on the assumption that all incoming heat is due to the projection of the heat flux parallel to the magnetic line, q∥, plus a constant background. This simplification led to inconsistencies during the analysis of a series of dedicated tungsten melting experiments performed in 2013, for which infrared (IR) thermography surface measurements could not be recreated through simulations unless the parallel heat flux was reduced by 80% for L-mode and 60% for H-mode. We give an explanation for these differences using a new IR inverse analysis code, a set of geometrical corrections, and most importantly an additional term for the divertor heat flux accounting for non-parallel effects such as cross-field transport, recycled neutrals or charge exchange. This component has been evaluated comparing four different geometries with impinging angles varying from 2 to 90. Its magnitude corresponds to 1.2%-1.9% of q∥, but because it is not affected by the magnetic projection, it accounts for up to 20%-30% of the tile surface heat flux. The geometrical corrections imply a further reduction of 24% of the measured heat flux. In addition, the application of the new inverse code increases the accuracy of the tile heat flux calculation, eliminating any previous discrepancy. The parallel heat flux computed with this new model is actually much lower than previously deduced by inverse analysis of IR temperatures-40% for L-mode and 50% for H-mode-while being independent of the geometry on which it is measured. This main result confirms the validity of the optical projection as long as a non-constant and non-parallel component is considered. For a given total heating power, the model predicts over 10% reduction of the maximum tile surface heat flux compared to strict optical modelling, as well as a 30% reduced sensitivity to manufacturing and assembling tolerances. These conclusions, along with the improvement in the predictability of the divertor thermal behaviour, are critical for JET future DT operations, and are also directly applicable to the design of the ITER divertor monoblocks.

Original language	English
Article number	106034
Journal	Nuclear Fusion
Volume	58
Issue number	10
DOIs	https://doi.org/10.1088/1741-4326/aad83e
Publication status	Published - 30 Aug 2018

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy
SDG 9 Industry, Innovation, and Infrastructure

Keywords

divertor
ITER-like wall
JET
optical projection
parallel heat flux

Access to Document

10.1088/1741-4326/aad83e

Cite this

@article{23274b48615144e18d7e9bbd6a6b2ef3,

title = "An improved model for the accurate calculation of parallel heat fluxes at the JET bulk tungsten outer divertor",

abstract = "Parallel heat flux calculations at the JET divertor have been based on the assumption that all incoming heat is due to the projection of the heat flux parallel to the magnetic line, q∥, plus a constant background. This simplification led to inconsistencies during the analysis of a series of dedicated tungsten melting experiments performed in 2013, for which infrared (IR) thermography surface measurements could not be recreated through simulations unless the parallel heat flux was reduced by 80\% for L-mode and 60\% for H-mode. We give an explanation for these differences using a new IR inverse analysis code, a set of geometrical corrections, and most importantly an additional term for the divertor heat flux accounting for non-parallel effects such as cross-field transport, recycled neutrals or charge exchange. This component has been evaluated comparing four different geometries with impinging angles varying from 2 to 90. Its magnitude corresponds to 1.2\%-1.9\% of q∥, but because it is not affected by the magnetic projection, it accounts for up to 20\%-30\% of the tile surface heat flux. The geometrical corrections imply a further reduction of 24\% of the measured heat flux. In addition, the application of the new inverse code increases the accuracy of the tile heat flux calculation, eliminating any previous discrepancy. The parallel heat flux computed with this new model is actually much lower than previously deduced by inverse analysis of IR temperatures-40\% for L-mode and 50\% for H-mode-while being independent of the geometry on which it is measured. This main result confirms the validity of the optical projection as long as a non-constant and non-parallel component is considered. For a given total heating power, the model predicts over 10\% reduction of the maximum tile surface heat flux compared to strict optical modelling, as well as a 30\% reduced sensitivity to manufacturing and assembling tolerances. These conclusions, along with the improvement in the predictability of the divertor thermal behaviour, are critical for JET future DT operations, and are also directly applicable to the design of the ITER divertor monoblocks.",

keywords = "divertor, ITER-like wall, JET, optical projection, parallel heat flux",

author = "\{JET Contributors\} and D. Iglesias and P. Bunting and Coenen, \{J. W.\} and Matthews, \{G. F.\} and Pitts, \{R. A.\} and S. Silburn and I. Balboa and I. Coffey and Y. Corre and R. Dejarnac and J. Gaspar and E. Gauthier and S. Jachmich and K. Krieger and S. Pamela and V. Riccardo and M. Stamp and X. Litaudon and S. Abduallev and M. Abhangi and P. Abreu and M. Afzal and Aggarwal, \{K. M.\} and T. Ahlgren and Ahn, \{J. H.\} and L. Aho-Mantila and N. Aiba and M. Airila and R. Albanese and V. Aldred and D. Alegre and E. Alessi and P. Aleynikov and A. Alfer and A. Alkseev and M. Allinson and B. Alper and E. Alves and G. Ambrosino and R. Ambrosino and L. Amicucci and V. Amosov and L. Avotina and D. Conka and M. Halitovs and J. Jansons and G. Kizane and E. Pajuste and A. Vitins and A. Zarins",

note = "Publisher Copyright: {\textcopyright} 2018 EURATOM.",

year = "2018",

month = aug,

day = "30",

doi = "10.1088/1741-4326/aad83e",

language = "English",

volume = "58",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "10",

}

TY - JOUR

T1 - An improved model for the accurate calculation of parallel heat fluxes at the JET bulk tungsten outer divertor

AU - JET Contributors

AU - Iglesias, D.

AU - Bunting, P.

AU - Coenen, J. W.

AU - Matthews, G. F.

AU - Pitts, R. A.

AU - Silburn, S.

AU - Balboa, I.

AU - Coffey, I.

AU - Corre, Y.

AU - Dejarnac, R.

AU - Gaspar, J.

AU - Gauthier, E.

AU - Jachmich, S.

AU - Krieger, K.

AU - Pamela, S.

AU - Riccardo, V.

AU - Stamp, M.

AU - Litaudon, X.

AU - Abduallev, S.

AU - Abhangi, M.

AU - Abreu, P.

AU - Afzal, M.

AU - Aggarwal, K. M.

AU - Ahlgren, T.

AU - Ahn, J. H.

AU - Aho-Mantila, L.

AU - Aiba, N.

AU - Airila, M.

AU - Albanese, R.

AU - Aldred, V.

AU - Alegre, D.

AU - Alessi, E.

AU - Aleynikov, P.

AU - Alfer, A.

AU - Alkseev, A.

AU - Allinson, M.

AU - Alper, B.

AU - Alves, E.

AU - Ambrosino, G.

AU - Ambrosino, R.

AU - Amicucci, L.

AU - Amosov, V.

AU - Avotina, L.

AU - Conka, D.

AU - Halitovs, M.

AU - Jansons, J.

AU - Kizane, G.

AU - Pajuste, E.

AU - Vitins, A.

AU - Zarins, A.

PY - 2018/8/30

Y1 - 2018/8/30

N2 - Parallel heat flux calculations at the JET divertor have been based on the assumption that all incoming heat is due to the projection of the heat flux parallel to the magnetic line, q∥, plus a constant background. This simplification led to inconsistencies during the analysis of a series of dedicated tungsten melting experiments performed in 2013, for which infrared (IR) thermography surface measurements could not be recreated through simulations unless the parallel heat flux was reduced by 80% for L-mode and 60% for H-mode. We give an explanation for these differences using a new IR inverse analysis code, a set of geometrical corrections, and most importantly an additional term for the divertor heat flux accounting for non-parallel effects such as cross-field transport, recycled neutrals or charge exchange. This component has been evaluated comparing four different geometries with impinging angles varying from 2 to 90. Its magnitude corresponds to 1.2%-1.9% of q∥, but because it is not affected by the magnetic projection, it accounts for up to 20%-30% of the tile surface heat flux. The geometrical corrections imply a further reduction of 24% of the measured heat flux. In addition, the application of the new inverse code increases the accuracy of the tile heat flux calculation, eliminating any previous discrepancy. The parallel heat flux computed with this new model is actually much lower than previously deduced by inverse analysis of IR temperatures-40% for L-mode and 50% for H-mode-while being independent of the geometry on which it is measured. This main result confirms the validity of the optical projection as long as a non-constant and non-parallel component is considered. For a given total heating power, the model predicts over 10% reduction of the maximum tile surface heat flux compared to strict optical modelling, as well as a 30% reduced sensitivity to manufacturing and assembling tolerances. These conclusions, along with the improvement in the predictability of the divertor thermal behaviour, are critical for JET future DT operations, and are also directly applicable to the design of the ITER divertor monoblocks.

AB - Parallel heat flux calculations at the JET divertor have been based on the assumption that all incoming heat is due to the projection of the heat flux parallel to the magnetic line, q∥, plus a constant background. This simplification led to inconsistencies during the analysis of a series of dedicated tungsten melting experiments performed in 2013, for which infrared (IR) thermography surface measurements could not be recreated through simulations unless the parallel heat flux was reduced by 80% for L-mode and 60% for H-mode. We give an explanation for these differences using a new IR inverse analysis code, a set of geometrical corrections, and most importantly an additional term for the divertor heat flux accounting for non-parallel effects such as cross-field transport, recycled neutrals or charge exchange. This component has been evaluated comparing four different geometries with impinging angles varying from 2 to 90. Its magnitude corresponds to 1.2%-1.9% of q∥, but because it is not affected by the magnetic projection, it accounts for up to 20%-30% of the tile surface heat flux. The geometrical corrections imply a further reduction of 24% of the measured heat flux. In addition, the application of the new inverse code increases the accuracy of the tile heat flux calculation, eliminating any previous discrepancy. The parallel heat flux computed with this new model is actually much lower than previously deduced by inverse analysis of IR temperatures-40% for L-mode and 50% for H-mode-while being independent of the geometry on which it is measured. This main result confirms the validity of the optical projection as long as a non-constant and non-parallel component is considered. For a given total heating power, the model predicts over 10% reduction of the maximum tile surface heat flux compared to strict optical modelling, as well as a 30% reduced sensitivity to manufacturing and assembling tolerances. These conclusions, along with the improvement in the predictability of the divertor thermal behaviour, are critical for JET future DT operations, and are also directly applicable to the design of the ITER divertor monoblocks.

KW - divertor

KW - ITER-like wall

KW - JET

KW - optical projection

KW - parallel heat flux

UR - https://www.scopus.com/pages/publications/85053392766

U2 - 10.1088/1741-4326/aad83e

DO - 10.1088/1741-4326/aad83e

M3 - Article

AN - SCOPUS:85053392766

SN - 0029-5515

VL - 58

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 10

M1 - 106034

ER -

An improved model for the accurate calculation of parallel heat fluxes at the JET bulk tungsten outer divertor

Abstract

UN SDGs

Keywords

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