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    HEAT simulation and IR data comparison for ST40 plasma-facing components

    New search for: E.J.C. Tinacba
    New search for: T.K. Gray
    New search for: M. Moscheni
    New search for: C. Marsden
    New search for: E. Vekshina
    New search for: O. Asunta
    New search for: P. Bunting
    New search for: S. McNamara
    New search for: A. Rengle
    New search for: T. Looby
    New search for: E.A. Unterberg

    The Heat Flux Engineering Analysis Toolkit (HEAT) (Looby et al., 2022) was used to simulate the heat flux, qtarget, on ST40 molybdenum divertors. Results were compared with experimental infrared (IR) data. Two shots, 11419 and 11376 at time instants 119 ms and 120 ms, with lower-biased disconnected double null geometries, were studied. Single-λ and multi-λ heat flux profiles were used as input in HEAT simulation. The simulated qtarget was used in OpenFOAM to calculate the corresponding temperature, T, on the divertors. Results showed that a good agreement on the simulated qtarget, T and shape of the heat flux on the divertor with the IR data was achieved when a multi-λ heat flux profile was used for 11419, and single-λ heat flux profile for 11376. This indicates that HEAT can be reliable in analyzing and understanding the heat loading of plasma facing components in tokamak devices.

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    HEAT simulation and IR data comparison for ST40 plasma-facing components

    New search for: E.J.C. Tinacba
    New search for: T.K. Gray
    New search for: M. Moscheni
    New search for: C. Marsden
    New search for: E. Vekshina
    New search for: O. Asunta
    New search for: P. Bunting
    New search for: S. McNamara
    New search for: A. Rengle
    New search for: T. Looby
    New search for: E.A. Unterberg

    The Heat Flux Engineering Analysis Toolkit (HEAT) (Looby et al., 2022) was used to simulate the heat flux, qtarget, on ST40 molybdenum divertors. Results were compared with experimental infrared (IR) data. Two shots, 11419 and 11376 at time instants 119 ms and 120 ms, with lower-biased disconnected double null geometries, were studied. Single-λ and multi-λ heat flux profiles were used as input in HEAT simulation. The simulated qtarget was used in OpenFOAM to calculate the corresponding temperature, T, on the divertors. Results showed that a good agreement on the simulated qtarget, T and shape of the heat flux on the divertor with the IR data was achieved when a multi-λ heat flux profile was used for 11419, and single-λ heat flux profile for 11376. This indicates that HEAT can be reliable in analyzing and understanding the heat loading of plasma facing components in tokamak devices.

    Access

    Download

    HEAT simulation and IR data comparison for ST40 plasma-facing components

    New search for: E.J.C. Tinacba
    New search for: T.K. Gray
    New search for: M. Moscheni
    New search for: C. Marsden
    New search for: E. Vekshina
    New search for: O. Asunta
    New search for: P. Bunting
    New search for: S. McNamara
    New search for: A. Rengle
    New search for: T. Looby
    New search for: E.A. Unterberg

    The Heat Flux Engineering Analysis Toolkit (HEAT) (Looby et al., 2022) was used to simulate the heat flux, qtarget, on ST40 molybdenum divertors. Results were compared with experimental infrared (IR) data. Two shots, 11419 and 11376 at time instants 119 ms and 120 ms, with lower-biased disconnected double null geometries, were studied. Single-λ and multi-λ heat flux profiles were used as input in HEAT simulation. The simulated qtarget was used in OpenFOAM to calculate the corresponding temperature, T, on the divertors. Results showed that a good agreement on the simulated qtarget, T and shape of the heat flux on the divertor with the IR data was achieved when a multi-λ heat flux profile was used for 11419, and single-λ heat flux profile for 11376. This indicates that HEAT can be reliable in analyzing and understanding the heat loading of plasma facing components in tokamak devices.

    Access

    Download

    Access

    Download

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    Document information
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    Title:

    HEAT simulation and IR data comparison for ST40 plasma-facing components

    Contributors:

    E.J.C. Tinacba (author) / T.K. Gray (author) / M. Moscheni (author) / C. Marsden (author) / E. Vekshina (author) / O. Asunta (author) / P. Bunting (author) / S. McNamara (author) / A. Rengle (author) / T. Looby (author)

    Published in:

    Nuclear Materials and Energy, Vol 41, Iss , Pp 101791- (2024)

    Publication date:

    2024

    ISSN:

    2352-1791

    DOI:

    https://doi.org/10.1016/j.nme.2024.101791

    Type of media:

    Article (Journal)

    Type of material:

    Electronic Resource

    Language:

    Unknown

    Keywords:

    Fusion , Heat flux calculation , ST40 , IR thermography , Nuclear engineering. Atomic power , TK9001-9401

    Metadata by DOAJ is licensed under ​CC BY-SA 1.0

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