TY  - GEN
AB  - Due to the penetration of stochastic low-carbon sources of production, requirements for flexible generation increase. The flexibility of pumped storage hydropower plants in pump mode can be improved by implementing hydraulic short circuit modes, which consists in operating the turbine(s) and the pump(s) in parallel. This new operating mode can be investigated by computational fluid dynamics to determine the head losses and to investigate the flow topology. Nine geometries of the Grand’Maison and Forces Motrices Hongrin-Léman (FMHL/FMHL+) plants are considered. Due to the lack of measurements, simulations are performed using different turbulence models and meshes to assess the uncertainty of the results. A statistical analysis of the results shows that low values of the head loss coefficients are obtained for geometries that limit the impingement of the flow on the walls and the development of a swirling flow downstream. Such geometries have the benefit of also limiting the wall pressure fluctuations and wall shear stresses, i.e. the risk of cavitation and the abrasion of the pipe walls due to sediment transport. These new results for the hydropower community are valuable for owners in implementing hydraulic short circuit mode in existing power plants or in designing new suitable junctions.
AD  - School of Engineering, HES-SO Valais-Wallis, HEI, HES-SO University of Applied Sciences and Arts Western Switzerland
AD  - School of Engineering, HES-SO Valais-Wallis, HEI, HES-SO University of Applied Sciences and Arts Western Switzerland
AD  - EDF CIH DT, Chambéry, France
AD  - Alpiq, Lausanne, Switzerland
AD  - School of Engineering, HES-SO Valais-Wallis, HEI, HES-SO University of Applied Sciences and Arts Western Switzerland
AU  - Decaix, Jean
AU  - Mertille, Mathieu
AU  - Drommi, Jean-Louis
AU  - Hugo, Nicolas
AU  - Münch-Alligné, Cécile
CY  - Abingdon-ont Thames, UK
DA  - 2024-01
DO  - 10.1080/27678490.2023.2290025
DO  - DOI
EP  - 2290025
ID  - 15020
JF  - LHB
KW  - CFD
KW  - RANS
KW  - hydraulic short-circuit
KW  - Ansys® Fluent®
KW  - Ansys® CFX®
KW  - OpenFOAM
L1  - https://arodes.hes-so.ch/record/15020/files/Decaix_2024_computation_fluid_dynamics_investigation_flow_junctions.pdf
L2  - https://arodes.hes-so.ch/record/15020/files/Decaix_2024_computation_fluid_dynamics_investigation_flow_junctions.pdf
L4  - https://arodes.hes-so.ch/record/15020/files/Decaix_2024_computation_fluid_dynamics_investigation_flow_junctions.pdf
LA  - eng
LK  - https://arodes.hes-so.ch/record/15020/files/Decaix_2024_computation_fluid_dynamics_investigation_flow_junctions.pdf
N2  - Due to the penetration of stochastic low-carbon sources of production, requirements for flexible generation increase. The flexibility of pumped storage hydropower plants in pump mode can be improved by implementing hydraulic short circuit modes, which consists in operating the turbine(s) and the pump(s) in parallel. This new operating mode can be investigated by computational fluid dynamics to determine the head losses and to investigate the flow topology. Nine geometries of the Grand’Maison and Forces Motrices Hongrin-Léman (FMHL/FMHL+) plants are considered. Due to the lack of measurements, simulations are performed using different turbulence models and meshes to assess the uncertainty of the results. A statistical analysis of the results shows that low values of the head loss coefficients are obtained for geometries that limit the impingement of the flow on the walls and the development of a swirling flow downstream. Such geometries have the benefit of also limiting the wall pressure fluctuations and wall shear stresses, i.e. the risk of cavitation and the abrasion of the pipe walls due to sediment transport. These new results for the hydropower community are valuable for owners in implementing hydraulic short circuit mode in existing power plants or in designing new suitable junctions.
PB  - Taylor & Francis
PP  - Abingdon-ont Thames, UK
PY  - 2024-01
SN  - 2767-8490
SP  - 2290025
T1  - Computation fluid dynamics investigation of the flow in junctions :application to hydraulic short circuit operating mode
TI  - Computation fluid dynamics investigation of the flow in junctions :application to hydraulic short circuit operating mode
UR  - https://arodes.hes-so.ch/record/15020/files/Decaix_2024_computation_fluid_dynamics_investigation_flow_junctions.pdf
VL  - 2023, 109
Y1  - 2024-01
ER  -