An approach to verification and validation of MHD codes for fusion applications

S. Smolentsev; S. Badia; R. Bhattacharyay; L. Bühler; L. Chen; Q. Huang; H. G. Jin; D. Krasnov; D. W. Lee; E. Mas De Les Valls; C. Mistrangelo; R. Munipalli; M. J. Ni; D. Pashkevich; A. Patel; G. Pulugundla; P. Satyamurthy; A. Snegirev; V. Sviridov; P. Swain; T. Zhou; O. Zikanov

doi:10.1016/j.fusengdes.2014.04.049

An approach to verification and validation of MHD codes for fusion applications

S. Smolentsev, S. Badia, R. Bhattacharyay, L. Bühler, L. Chen, Q. Huang, H. G. Jin, D. Krasnov, D. W. Lee, E. Mas De Les Valls, C. Mistrangelo, R. Munipalli, M. J. Ni, D. Pashkevich, A. Patel, G. Pulugundla, P. Satyamurthy, A. Snegirev, V. Sviridov, P. SwainT. Zhou, O. Zikanov

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

100 Scopus citations

Abstract

We propose a new activity on verification and validation (V&V) of MHD codes presently employed by the fusion community as a predictive capability tool for liquid metal cooling applications, such as liquid metal blankets. The important steps in the development of MHD codes starting from the 1970s are outlined first and then basic MHD codes, which are currently in use by designers of liquid breeder blankets, are reviewed. A benchmark database of five problems has been proposed to cover a wide range of MHD flows from laminar fully developed to turbulent flows, which are of interest for fusion applications: (A) 2D fully developed laminar steady MHD flow, (B) 3D laminar, steady developing MHD flow in a non-uniform magnetic field, (C) quasi-two-dimensional MHD turbulent flow, (D) 3D turbulent MHD flow, and (E) MHD flow with heat transfer (buoyant convection). Finally, we introduce important details of the proposed activities, such as basic V&V rules and schedule. The main goal of the present paper is to help in establishing an efficient V&V framework and to initiate benchmarking among interested parties. The comparison results computed by the codes against analytical solutions and trusted experimental and numerical data as well as code-to-code comparisons will be presented and analyzed in companion paper/papers.

Original language	English
Pages (from-to)	65-72
Number of pages	8
Journal	Fusion Engineering and Design
Volume	100
DOIs	https://doi.org/10.1016/j.fusengdes.2014.04.049
State	Published - Nov 1 2015
Externally published	Yes

Keywords

Blanket
Computer code
Liquid metal magnetohydrodynamics

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10.1016/j.fusengdes.2014.04.049

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Smolentsev, S., Badia, S., Bhattacharyay, R., Bühler, L., Chen, L., Huang, Q., Jin, H. G., Krasnov, D., Lee, D. W., De Les Valls, E. M., Mistrangelo, C., Munipalli, R., Ni, M. J., Pashkevich, D., Patel, A., Pulugundla, G., Satyamurthy, P., Snegirev, A., Sviridov, V., ... Zikanov, O. (2015). An approach to verification and validation of MHD codes for fusion applications. Fusion Engineering and Design, 100, 65-72. https://doi.org/10.1016/j.fusengdes.2014.04.049

@article{8f85e4139abe48488d306d062c651fd7,

title = "An approach to verification and validation of MHD codes for fusion applications",

abstract = "We propose a new activity on verification and validation (V&V) of MHD codes presently employed by the fusion community as a predictive capability tool for liquid metal cooling applications, such as liquid metal blankets. The important steps in the development of MHD codes starting from the 1970s are outlined first and then basic MHD codes, which are currently in use by designers of liquid breeder blankets, are reviewed. A benchmark database of five problems has been proposed to cover a wide range of MHD flows from laminar fully developed to turbulent flows, which are of interest for fusion applications: (A) 2D fully developed laminar steady MHD flow, (B) 3D laminar, steady developing MHD flow in a non-uniform magnetic field, (C) quasi-two-dimensional MHD turbulent flow, (D) 3D turbulent MHD flow, and (E) MHD flow with heat transfer (buoyant convection). Finally, we introduce important details of the proposed activities, such as basic V&V rules and schedule. The main goal of the present paper is to help in establishing an efficient V&V framework and to initiate benchmarking among interested parties. The comparison results computed by the codes against analytical solutions and trusted experimental and numerical data as well as code-to-code comparisons will be presented and analyzed in companion paper/papers.",

keywords = "Blanket, Computer code, Liquid metal magnetohydrodynamics",

author = "S. Smolentsev and S. Badia and R. Bhattacharyay and L. B{\"u}hler and L. Chen and Q. Huang and Jin, {H. G.} and D. Krasnov and Lee, {D. W.} and {De Les Valls}, {E. Mas} and C. Mistrangelo and R. Munipalli and Ni, {M. J.} and D. Pashkevich and A. Patel and G. Pulugundla and P. Satyamurthy and A. Snegirev and V. Sviridov and P. Swain and T. Zhou and O. Zikanov",

year = "2015",

month = nov,

day = "1",

doi = "10.1016/j.fusengdes.2014.04.049",

language = "English",

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Smolentsev, S, Badia, S, Bhattacharyay, R, Bühler, L, Chen, L, Huang, Q, Jin, HG, Krasnov, D, Lee, DW, De Les Valls, EM, Mistrangelo, C, Munipalli, R, Ni, MJ, Pashkevich, D, Patel, A, Pulugundla, G, Satyamurthy, P, Snegirev, A, Sviridov, V, Swain, P, Zhou, T & Zikanov, O 2015, 'An approach to verification and validation of MHD codes for fusion applications', Fusion Engineering and Design, vol. 100, pp. 65-72. https://doi.org/10.1016/j.fusengdes.2014.04.049

TY - JOUR

T1 - An approach to verification and validation of MHD codes for fusion applications

AU - Smolentsev, S.

AU - Badia, S.

AU - Bhattacharyay, R.

AU - Bühler, L.

AU - Chen, L.

AU - Huang, Q.

AU - Jin, H. G.

AU - Krasnov, D.

AU - Lee, D. W.

AU - De Les Valls, E. Mas

AU - Mistrangelo, C.

AU - Munipalli, R.

AU - Ni, M. J.

AU - Pashkevich, D.

AU - Patel, A.

AU - Pulugundla, G.

AU - Satyamurthy, P.

AU - Snegirev, A.

AU - Sviridov, V.

AU - Swain, P.

AU - Zhou, T.

AU - Zikanov, O.

PY - 2015/11/1

Y1 - 2015/11/1

N2 - We propose a new activity on verification and validation (V&V) of MHD codes presently employed by the fusion community as a predictive capability tool for liquid metal cooling applications, such as liquid metal blankets. The important steps in the development of MHD codes starting from the 1970s are outlined first and then basic MHD codes, which are currently in use by designers of liquid breeder blankets, are reviewed. A benchmark database of five problems has been proposed to cover a wide range of MHD flows from laminar fully developed to turbulent flows, which are of interest for fusion applications: (A) 2D fully developed laminar steady MHD flow, (B) 3D laminar, steady developing MHD flow in a non-uniform magnetic field, (C) quasi-two-dimensional MHD turbulent flow, (D) 3D turbulent MHD flow, and (E) MHD flow with heat transfer (buoyant convection). Finally, we introduce important details of the proposed activities, such as basic V&V rules and schedule. The main goal of the present paper is to help in establishing an efficient V&V framework and to initiate benchmarking among interested parties. The comparison results computed by the codes against analytical solutions and trusted experimental and numerical data as well as code-to-code comparisons will be presented and analyzed in companion paper/papers.

AB - We propose a new activity on verification and validation (V&V) of MHD codes presently employed by the fusion community as a predictive capability tool for liquid metal cooling applications, such as liquid metal blankets. The important steps in the development of MHD codes starting from the 1970s are outlined first and then basic MHD codes, which are currently in use by designers of liquid breeder blankets, are reviewed. A benchmark database of five problems has been proposed to cover a wide range of MHD flows from laminar fully developed to turbulent flows, which are of interest for fusion applications: (A) 2D fully developed laminar steady MHD flow, (B) 3D laminar, steady developing MHD flow in a non-uniform magnetic field, (C) quasi-two-dimensional MHD turbulent flow, (D) 3D turbulent MHD flow, and (E) MHD flow with heat transfer (buoyant convection). Finally, we introduce important details of the proposed activities, such as basic V&V rules and schedule. The main goal of the present paper is to help in establishing an efficient V&V framework and to initiate benchmarking among interested parties. The comparison results computed by the codes against analytical solutions and trusted experimental and numerical data as well as code-to-code comparisons will be presented and analyzed in companion paper/papers.

KW - Blanket

KW - Computer code

KW - Liquid metal magnetohydrodynamics

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U2 - 10.1016/j.fusengdes.2014.04.049

DO - 10.1016/j.fusengdes.2014.04.049

M3 - Article

AN - SCOPUS:84942553946

SN - 0920-3796

VL - 100

SP - 65

EP - 72

JO - Fusion Engineering and Design

JF - Fusion Engineering and Design

ER -

An approach to verification and validation of MHD codes for fusion applications

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