Toward full simulations for a liquid metal blanket: Part 2. Computations of MHD flows with volumetric heating for a PbLi blanket prototype at Ha ∼ 104and Gr ∼ 1012

L. Chen; S. Smolentsev; M. J. Ni

doi:10.1088/1741-4326/ac3fea

Toward full simulations for a liquid metal blanket: Part 2. Computations of MHD flows with volumetric heating for a PbLi blanket prototype at Ha ∼ 10⁴and Gr ∼ 10¹²

L. Chen
, S. Smolentsev
, M. J. Ni

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

21 Scopus citations

Abstract

On the pathway toward full simulations for a liquid metal (LM) blanket, this part 2 extends a previous study of purely magnetohydrodynamic (MHD) flows in a DCLL blanket in reference Chen et al (2020 Nucl. Fusion 60 076003) to more general conditions when the MHD flow is coupled with heat transfer. The simulated prototypic blanket module includes all components of a real LM blanket system, such as supply ducts, inlet and outlet manifolds, multiple poloidal ducts and a U-turn zone. Volumetric heating generated by fusion neutrons is added to simulate thermal effects in the flowing lead-lithium (PbLi) breeder. The MHD flow equations and the energy equation are solved with a DNS-type finite-volume code 'MHD-UCAS' on a very fine mesh of 470 106 cells. The applied magnetic field is 5 T (Hartmann number Ha ∼ 104), the PbLi velocity in the poloidal ducts is 10 cm s-1 (Reynolds number Re ∼ 105), whereas the maximum volumetric heating is 30 MW m-3 (Grashof number Gr ∼ 1012). Four cases have been simulated, including forced- and mixed-convection flows, and either an electrically conducting or insulating blanket structure. Various comparisons are made between the four computed cases and also against the purely MHD flows computed earlier in reference Chen et al (2020 Nucl. Fusion 60 076003) with regards to the (1) MHD pressure drop, (2) flow balancing, (3) temperature field, (4) flows in particular blanket components, and (5) 3D and turbulent flow effects. The strongest buoyancy effects were found in the poloidal ducts. In the electrically non-conducting blanket, the buoyancy forces lead to significant modifications of the flow structure, such as formation of reverse flows, whereas their effect on the MHD pressure drop is relatively small. In the electrically conducting blanket case, the buoyancy effects on the flow and MHD pressure drop are almost negligible.

Original language	English
Article number	026042
Journal	Nuclear Fusion
Volume	62
Issue number	2
DOIs	https://doi.org/10.1088/1741-4326/ac3fea
State	Published - Feb 2022
Externally published	Yes

Funding

MN and LC acknowledge the support from NSFC under Grants 51927812, 52076204 and CAS under Grants XDB22040201, QYZDJ-SSW-SLH014. SS acknowledges support from the US Department of Energy grant DESC0020979.

Keywords

DCLL blanket
MHD mixed convection
high Hartmann MHD turbulence

Access to Document

10.1088/1741-4326/ac3fea

Cite this

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title = "Toward full simulations for a liquid metal blanket: Part 2. Computations of MHD flows with volumetric heating for a PbLi blanket prototype at Ha ∼ 104and Gr ∼ 1012",

abstract = "On the pathway toward full simulations for a liquid metal (LM) blanket, this part 2 extends a previous study of purely magnetohydrodynamic (MHD) flows in a DCLL blanket in reference Chen et al (2020 Nucl. Fusion 60 076003) to more general conditions when the MHD flow is coupled with heat transfer. The simulated prototypic blanket module includes all components of a real LM blanket system, such as supply ducts, inlet and outlet manifolds, multiple poloidal ducts and a U-turn zone. Volumetric heating generated by fusion neutrons is added to simulate thermal effects in the flowing lead-lithium (PbLi) breeder. The MHD flow equations and the energy equation are solved with a DNS-type finite-volume code 'MHD-UCAS' on a very fine mesh of 470 106 cells. The applied magnetic field is 5 T (Hartmann number Ha ∼ 104), the PbLi velocity in the poloidal ducts is 10 cm s-1 (Reynolds number Re ∼ 105), whereas the maximum volumetric heating is 30 MW m-3 (Grashof number Gr ∼ 1012). Four cases have been simulated, including forced- and mixed-convection flows, and either an electrically conducting or insulating blanket structure. Various comparisons are made between the four computed cases and also against the purely MHD flows computed earlier in reference Chen et al (2020 Nucl. Fusion 60 076003) with regards to the (1) MHD pressure drop, (2) flow balancing, (3) temperature field, (4) flows in particular blanket components, and (5) 3D and turbulent flow effects. The strongest buoyancy effects were found in the poloidal ducts. In the electrically non-conducting blanket, the buoyancy forces lead to significant modifications of the flow structure, such as formation of reverse flows, whereas their effect on the MHD pressure drop is relatively small. In the electrically conducting blanket case, the buoyancy effects on the flow and MHD pressure drop are almost negligible.",

keywords = "DCLL blanket, MHD mixed convection, high Hartmann MHD turbulence",

author = "L. Chen and S. Smolentsev and Ni, \{M. J.\}",

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AB - On the pathway toward full simulations for a liquid metal (LM) blanket, this part 2 extends a previous study of purely magnetohydrodynamic (MHD) flows in a DCLL blanket in reference Chen et al (2020 Nucl. Fusion 60 076003) to more general conditions when the MHD flow is coupled with heat transfer. The simulated prototypic blanket module includes all components of a real LM blanket system, such as supply ducts, inlet and outlet manifolds, multiple poloidal ducts and a U-turn zone. Volumetric heating generated by fusion neutrons is added to simulate thermal effects in the flowing lead-lithium (PbLi) breeder. The MHD flow equations and the energy equation are solved with a DNS-type finite-volume code 'MHD-UCAS' on a very fine mesh of 470 106 cells. The applied magnetic field is 5 T (Hartmann number Ha ∼ 104), the PbLi velocity in the poloidal ducts is 10 cm s-1 (Reynolds number Re ∼ 105), whereas the maximum volumetric heating is 30 MW m-3 (Grashof number Gr ∼ 1012). Four cases have been simulated, including forced- and mixed-convection flows, and either an electrically conducting or insulating blanket structure. Various comparisons are made between the four computed cases and also against the purely MHD flows computed earlier in reference Chen et al (2020 Nucl. Fusion 60 076003) with regards to the (1) MHD pressure drop, (2) flow balancing, (3) temperature field, (4) flows in particular blanket components, and (5) 3D and turbulent flow effects. The strongest buoyancy effects were found in the poloidal ducts. In the electrically non-conducting blanket, the buoyancy forces lead to significant modifications of the flow structure, such as formation of reverse flows, whereas their effect on the MHD pressure drop is relatively small. In the electrically conducting blanket case, the buoyancy effects on the flow and MHD pressure drop are almost negligible.

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