Surface heat loads on the ITER divertor vertical targets

Gunn, J.; Carpentier-Chouchana, S.; Escourbiac, F.; Hirai, T.; Panayotis, S.; Pitts, R.A.; Corre, Y.; Dejarnac, R.; Firdaouss, M.; Kočan, M.; Komm, M.; Kukushkin, A.S.; Languille, P.; Missirlian, M.; Zhao, Weiduo; Zhong, Guangwu

doi:10.1088/1741-4326/aa5e2a

Cited by 149 publications

(167 citation statements)

References 50 publications

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“…Kinetic modelling including the self-consistent sheath electric field [3] and measurements [4] in the COMPASS tokamak have confirmed the physics of LE heating, and provide further justification for the decision to include a toroidal bevel at the high heat flux areas of the divertor vertical targets [5]. An unexpected prediction of [2] is that toroidal MB edges that are nearly parallel to the magnetic field could exceed allowable limits due to steady state heat loads and mitigated ELMs, even if those should avoid full melting of the principal plasmafacing surface. The heat deposition mechanism in intra-PFU TGs has been experimentally confirmed in the COMPASS tokamak [6] in a dedicated experiment designed to test the predictions.…”

Section: Introductionmentioning

confidence: 94%

“…The heat deposition mechanism in intra-PFU TGs has been experimentally confirmed in the COMPASS tokamak [6] in a dedicated experiment designed to test the predictions. Furthermore, despite the toroidal bevel, tiny regions of the poloidal LEs known as "optical hot spots" (OHS), accessible along magnetic field lines through TGs, were identified [2]. The intense parallel heat flux from ELMs onto those optical hot spots could be large enough to trigger tungsten boiling.…”

Section: Introductionmentioning

confidence: 99%

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A study of planar toroidal–poloidal beveling of monoblocks on the ITER divertor outer vertical target

et al. 2019

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The design of the monoblocks constituting the ITER divertor vertical targets comprises a simple toroidal (i.e. toroidally-facing) bevel of 0.5 mm in order to magnetically shadow poloidal (i.e. poloidally-running) leading edges, arising from radial misalignments between toroidally neighbouring blocks, from parallel heat loads between and during ELMs. Previous studies suggest that excessive heating of long toroidal edges could also occur, possibly leading to melting during ELMs. Furthermore, despite the toroidal bevel, tiny regions of the poloidal leading edges known as "optical hot spots", accessible along magnetic field lines through toroidal gaps, remain exposed to parallel heat flux from ELMs. The intense heat flux onto those optical hot spots could be large enough to trigger tungsten boiling. A possible solution at the outer vertical target is to implement a planar toroidal-poloidal bevel that would hide all poloidal and toroidal edges and eliminate the optical hot spot. It will be demonstrated that a reasonable "shallow" toroidal-poloidal bevel solution solves all these problems with minimal trade-offs, under the condition that monoblocks on neighbouring plasma-facing units be well aligned poloidally in order to prevent the appearance of exposed leading edges, meaning, in the worst case, a stepwise downward shift of each toroidally upstream plasmafacing unit by -2±2 mm with respect to their downstream neighbours. A more deeply beveled solution has also been studied that is immune to poloidal misalignments, but which comprises important trade-offs in terms of higher heat load to the main wetted surface, and excessive ELM heat loads onto the magnetically shadowed side of the toroidal gaps. Unfortunately, due the inclination of magnetic flux surfaces, the planar toroidal-poloidal beveling solution does not work at the inner vertical target, meaning that its application at the outer target alone leaves the inner toroidal gaps unprotected. This, together with the technologically challenging requirement for a high degree of poloidal alignment of toroidally neighbouring plasma-facing units, has led to a decision not to apply the poloidal-toroidal bevel solution on the ITER vertical targets.

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

A study of planar toroidal–poloidal beveling of monoblocks on the ITER divertor outer vertical target

et al. 2019

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“…1) [2]. The heat loads deposited per unit of area can then lead to a local melting of components and irreversible damages [3], [4]. Designs are proposed to reduce the risk induced by misalignments.…”

Section: Introduction and Contextmentioning

confidence: 99%

The very high spatial resolution infrared thermography on ITER-like tungsten monoblocks in WEST Tokamak

Houry

Pocheau

Aumeunier

et al. 2019

Fusion Engineering and Design

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A new Infrared diagnostic has been developed by CEA-IRFM and installed in the WEST tokamak to measure surface temperature of the actively cooled W-monoblocks components as foreseen for the ITER Divertor, with a very high spatial resolution of 100µm. The goals are to investigate the effects of the shaping of these components on the heat load deposition pattern, the evolution of pre-damaged components specifically introduced in WEST, the behavior of the leading edges regarding the assembling tolerances between adjacent monoblocks, and finally to contribute to the specification assessment of the ITER divertor units. In WEST, each Plasma Facing Unit is composed of 35 W-monoblocks of individual surface of 28x12mm. To analyze heat load pattern and phenomena on such tiny surfaces, the leading edges and in the narrow gaps between monoblocks (400-500µm), a 100µm spatial resolution is required. Then, a Very High spatial Resolution (VHR) infrared diagnostic has been specially developed at CEA-IRFM. The VHR operates at 1.7µm wavelength to take advantage of the dynamic of the signal for the temperature range (400 to 3600°C). The VHR infrared diagnostic is now operational above the divertor sector made of actively cooled W-monoblocks and graphite inertial components with W coating. This paper gives a description of the diagnostic.

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“…Depending on their amplitudes and frequencies, ELMs are classified into types I (large amplitudes -hence often termed as 'giant' ELMs) and II and III (smaller, hence often known as 'grassy' ELMs). Current predictions estimate [21,40,41] the heat flux due to ELMs on the divertor plates at ITER (the world's biggest experimental tokamak) will be up to 20 times larger than what can be tolerated for a reasonable lifetime of the target materials. This makes research into ELM control and mitigation of primary importance for making fusion a viable source of energy.…”

Section: Elmsmentioning

confidence: 99%

Application of the parareal algorithm to simulations of ELMs in ITER plasma

Samaddar

Coster

Bonnin

et al. 2019

Computer Physics Communications

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This paper explores the application of the parareal algorithm to simulations of ELMs in ITER plasma. The primary focus of this research is identifying the parameters that lead to optimum performance. Since the plasma dynamics vary extremely fast during an ELM cycle, a straightforward application of the algorithm is not possible and a modification to the standard parareal correction is implemented. The size of the time chunks also have an impact on the performance and needs to be optimized. A computational gain of 7.8 is obtained with 48 processors to illustrate that the parareal algorithm can be successfully applied to ELM plasma.

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Surface heat loads on the ITER divertor vertical targets

Cited by 149 publications

References 50 publications

A study of planar toroidal–poloidal beveling of monoblocks on the ITER divertor outer vertical target

A study of planar toroidal–poloidal beveling of monoblocks on the ITER divertor outer vertical target

The very high spatial resolution infrared thermography on ITER-like tungsten monoblocks in WEST Tokamak

Application of the parareal algorithm to simulations of ELMs in ITER plasma

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