Development of multi-physics code systems based on the reactor dynamics code DYN3D

Kliem, S.; Gommlich, André; Grahn, Alexander; Rohde, Ulrich L.; Schütze, Jochen; Frank, Th.; Gómez, Arántzazu; Sánchez, V.

doi:10.3139/124.110146

Cited by 20 publications

(4 citation statements)

References 8 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The DYN3D code has already been coupled to the CFD code ANSYS CFX (Kliem et al, 2011b) and to the thermal-hydraulics system codes ATHLET and RELAP5 (Kliem et al, 2007;Grundmann and Kliem, 2003). The experience obtained in these activities was used to conduct the coupling with FLICA4 in an efficient way.…”

Section: Coupling Of Dyn3d and Flica4 Or Flocalmentioning

confidence: 99%

Boron dilution transient simulation analyses in a PWR with neutronics/thermal-hydraulics coupled codes in the NURISP project

Varas

Herrero

Gommlich

et al. 2015

Annals of Nuclear Energy

Self Cite

View full text Add to dashboard Cite

Section: Coupling Of Dyn3d and Flica4 Or Flocalmentioning

confidence: 99%

Boron dilution transient simulation analyses in a PWR with neutronics/thermal-hydraulics coupled codes in the NURISP project

Varas

Herrero

Gommlich

et al. 2015

Annals of Nuclear Energy

Self Cite

View full text Add to dashboard Cite

“…Furthermore, a typical end-of-cycle (EOC) power distribution was assumed in the core. For this purpose, the nodal power distribution was implemented into the CFD model as obtained from a stationary full-core calculation with the neutron kinetics code DYN3D for a generic Pre-Konvoi core loading pattern [2].…”

Section: Technological Boundary Conditionsmentioning

confidence: 99%

Detailed Simulation of the Nominal Flow and Temperature Conditions in a Pre-Konvoi PWR Using Coupled CFD and Neutron Kinetics

Höhne

Kliem

2020

Fluids

View full text Add to dashboard Cite

The aim of the numerical study was the detection of possible vortices in the upper part of the core of a Pre-Konvoi Pressurized Water Reactor (PWR) which could lead to temperature cycling. In addition, the practical application of this Computational Fluid Dynamic (CFD) simulation exists in the full 3D analysis of the coolant flow behavior in the reactor pressure vessel of a nuclear PWR. It also helps to improve the design of future reactor types. Therefore, a CFD simulation of the flow conditions was carried out based on a complex 3D model. The geometry of the model includes the entire Reactor Pressure Vessel (RPV) plus all relevant internals. The core is modelled using the porous body approach, the different pressure losses along and transverse to the main flow direction were considered. The spacer-grid levels were taken into account to the extent that in these areas no cross-flow is possible. The calculation was carried out for nominal operating conditions, i.e., for full load operation. Furthermore, a prototypical End of Cycle (EOC) power distribution was assumed. For this, a power distribution was applied as obtained from a stationary full-core calculation with the 3D neutron kinetics code DYN3D. In order to be able to adequately reproduce flow vortexes, the calculation was performed transiently with suitable Detached Eddy Simulations (DES) turbulence models. The calculation showed fluctuating transverse flow in the upper part of the core, starting at the 8th spacer grid but also revealed that no large dominant vortices exists in this region. It seems that the core acts as a rectifier attenuating large-scale vortices. The analyses included several spacer grid levels in the core and showed that in some areas of the core cross-section an upward increasingly directed transversal flow to the outlet nozzle occurs. In other areas of the core cross-section, on the other hand, there is nearly any cross-flow. However, the following limitations of the model apply: In the model all fuel elements are treated identical and cross flows due to different axial pressure losses for different FA types cannot be displayed. The complex structure of the FAs (eg. flow vanes in spacer grids) could also influence the formation of large-scale vortices. Also, the possible influence of two-phase flows was not considered.

show abstract

“…The range of DYN3D applicability is greatly extended by multi-physics coupling with system codes such as ATHLET (Grundmann et al, 1995) and RELAP (Kozmenkov et al, 2007), CFD code ANSYS CFX and FLICA4 (Kliem et al, 2011), sub-channel thermal hydraulics SUBCHANFLOW (Gomez-Torres et al, 2012) and fuel performance code TRANSURANUS (Holt et al, 2015).…”

Section: Dyn3dmentioning

confidence: 99%

Hybrid microscopic depletion model in nodal code DYN3D

Bilodid

Kotlyar

Shwageraus

et al. 2016

Annals of Nuclear Energy

Self Cite

View full text Add to dashboard Cite

show abstract

Development of multi-physics code systems based on the reactor dynamics code DYN3D

Cited by 20 publications

References 8 publications

Boron dilution transient simulation analyses in a PWR with neutronics/thermal-hydraulics coupled codes in the NURISP project

Boron dilution transient simulation analyses in a PWR with neutronics/thermal-hydraulics coupled codes in the NURISP project

Detailed Simulation of the Nominal Flow and Temperature Conditions in a Pre-Konvoi PWR Using Coupled CFD and Neutron Kinetics

Hybrid microscopic depletion model in nodal code DYN3D

Contact Info

Product

Resources

About