Your search keyword '"Yiwa, Geng"' showing total 4 results

1. Numerical simulation of a toroidal single-phase natural circulation loop with a k-kL-ω transitional turbulence model

Author

Yiwa Geng, Xiongbin Liu, Xiaotian Li, and Yajun Zhang

Subjects

Single-phase, Natural circulation, Transition flow, Stability, Numerical simulation, Turbulence modeling, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The wall friction correlations of oscillatory natural circulation loops are highly loop-specific, making it difficult to perform 1-D system simulations before obtaining specific experimental data. To better predict the friction characteristics, the nonlinear dynamics of a toroidal single-phase natural circulation loop were numerically investigated, and the transition effect was considered. The k-kL-ω transitional turbulence and k-ω SST turbulence models were used to compute the flow characteristics of the loop under different heating powers varying from 0.48 to 1.0 W/cm2, and the results of both models were compared with previous experiments. The mass flow rates and friction factors predicted by the k-kL-ω model showed a better agreement with the experimental data than the results of the k-ω SST model. The oscillation frequencies calculated using both models agreed well with the experimental data. The k-kL-ω transitional turbulence model provided better friction-factor predictions in oscillatory natural circulation loops because it can reproduce the temporal and spatial variation of the wall shear stress more accurately by capturing the movement of laminar, transition turbulent zones inside unstable natural circulation loops. This study shows that transition effects are a possible explanation for the highly loop-specific friction correlations observed in various oscillatory natural circulation loops.

Published

2024

2. Numerical simulation and optimization of In-Vessel primary heat exchangers of NHR200-II

Author

Yiwa, Geng, Xiongbin, Liu, Ziyi, Li, Xiaotian, Li, and Yajun, Zhang

Published

2024

3. Analysis of a parallel-channel natural circulation loop in the passive residual heat removal system of the NHR200-II reactor

Author

Yiwa, Geng, Xiongbin, Liu, Xiaotian, Li, and Yajun, Zhang

Published

2024

4. Analysis of transient characteristics and design improvement of the passive residual heat removal system of NHR-200-II.

Author

Yiwa, Geng, Xiongbin, Liu, Ziyi, Li, Shuliang, Huang, Lanyu, Zhou, Yanfang, Xue, Xiaotian, Li, Yajun, Zhang, Wu, Di, and Yu, Dali

Subjects

HEATING, PRESSURIZED water reactors, TRANSIENT analysis, STEAM generators, HEAT exchangers, FEYNMAN integrals

Abstract

NHR-200-II is a small integrated pressurized water reactor with 200 MW core thermal power. The core heat is transferred to two independent intermediate circuits via fourteen in-vessel primary heat exchangers (PHE), and the heat in the intermediate circuits is transferred to feedwater by two steam generators (SG) in the two intermediate circuits respectively. A passive residual heat removal (PRHR) branch is connected to each intermediate circuit to remove core decay heat under postulated accidents. During normal operation, PRHR branches are isolated by valves while SG branches in intermediate circuits are open. The valves in PRHR branches will be opened and the isolation valves of SG branches will be closed during decay heat removal scenarios. The decay heat removal capacity of NHR-200-II PRHRS could be seriously deteriorated once the isolation valves for SG branches fail to close, which was confirmed in a scaled integral test loop previously. Current understanding of PRHRS's thermal- hydraulic characteristics with possible isolation failure in SG branches is limited. In this paper, the NHR-200-II PRHRS is modeled with RELAP5 considering the case of success and fail to isolate SG branches. A series of numerical simulations are carried out to study the impact of various parameters, such as the initial temperature, the size of the intermediate circuits' header, and the initial flow direction in the intermediate circuits. Oscillatory flow is found when SG branches fail to be isolated under certain parameters combinations. An improved PRHRS design is purposed to eliminate possible flow oscillations, and the purposed improved design are tested by numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2024