Oxygen diffusion through air–water free surfaces in a pump–turbine operating in condenser mode

The present research aims at understanding the mass transfer of air into water in a reversible pump turbine operating in condenser mode. In particular, the diffusion of oxygen through the water free-surface both in the vaneless gap between the impeller blades and the closed guide vanes and in the cone of the draft tube is investigated. A theoretical framework is carried out to compute the diffusion equation describing the oxygen diffusion process in the investigated machine. Oxygen concentration measurements together with temperature and wall pressure measurements are performed to validate the theoretical model of the mass transfer of oxygen in the water volume and to evaluate the influence of the densimetric Froude number, of the gauge pressure and of the cooling discharge on the diffusion process. Moreover, the analytical solution of the diffusion equation applied to both the free surfaces in the vaneless gap and in the cone of the draft tube allows computing the global diffusion coefficient for each air–water free- surface. The results show that the oxygen concentrations computed by the analytical model of the oxygen diffusion are in agreement with the measurements. The dependency of the oxygen concentration in water on the densimetric Froude number, on the gauge pressure and on the water-cooling discharge is also observed. The computed global diffusion coefficients are mainly dependent on the densimetric Froude number in the vaneless gap and in the cone of the draft tube. Finally, the results achieved allow estimating the air losses correlated to the oxygen diffusion causing the increase of the water level in the cone of the draft tube.

Two-phase flow phenomena in hydraulic turbines and pump-turbines operating in synchronous condenser mode

Elena Vagnoni

Hydraulic turbines and pump-turbines are often required to operate in particular conditions at which they consume active power. To keep the power consumption at a minimum, it is necessary to dewater the runner to reduce the mechanical torque. One of these operating conditions is the synchronous condenser mode for the reactive power regulation of the grid. This operating mode requires the guide vanes closure and the lowering of the tail water below the runner by injecting pressurized air in the machine. Due to the air-water mixing, torque instabilities and air losses are observed in this operating mode causing the increase of the power consumption. In this thesis, the two-phase flow phenomena characterizing the operation in synchronous condenser mode are experimentally investigated; additionally, a theoretical framework is proposed to analytically describe and predict the observed flow phenomena and the corresponding power and air losses. These research challenges are addressed by means of four different contributions. First, the development of the sloshing motion of the air-water free-surface below the runner is qualitatively and quantitatively described by using high-speed visualization, pressure fluctuations measurements and automated image processing methods. Second, the development of an air-water ring in the vaneless gap between the runner and the guide vanes is studied by means of image processing and pressure fluctuations measurements to assess both the velocity and the pressure flow field. The pressure measurements in the vaneless gap make apparent a fluctuation due to the interaction of the rotating and stationary components and of the rotating two-phase flow. This interaction is revealed by the development of the Fourier series applied to the harmonic components of the system and the modal decomposition of the pressure signal. Third, the influence of the two-phase flow phenomena on the torque swings is investigated. Measurements of the resisting mechanical torque transmitted through the coupling of the runner and the shaft and corresponding to the absorbed mechanical power of the runner in the hydraulic turbine are performed; in addition, a study on the influencing operating parameters allows building an empirical predictive model of the torque. Finally, a study on the oxygen mass transfer in the water volume is performed by measuring the oxygen concentration in the spiral case and in the draft tube of the hydraulic turbine. A theoretical framework is developed on the equations governing the diffusion of oxygen in water and the diffusion coefficients are computed and validated with experimental results. Moreover, this study allows quantifying the air losses due to the diffusion of air in water and to model the diffusion process as a function of the operating parameters of the machine. The results allow the understanding of the two-phase flow mechanism in a turbine or pump-turbine operating in synchronous condenser mode causing instabilities and air losses. Furthermore, the predictive model of the power losses due to both torque and air consumption represents a novel achievement for the study of the two-phase flow in a turbine operating in condenser mode or, more in general, in dewatered condition, and for the control of the machine behavior and consumption on the full scale prototype.

EPFL2018

Part load flow in radial centrifugal pumps

Olivier Braun

Centrifugal pumps are required to sustain a stable operation of the system they support under all operating conditions. Minor modifications of the surfaces defining the pump's water passage can influence the tendency to unstable system operation significantly. The action of such modifications on the flow are yet not fully understood, leading to costly trial and error approaches in the solution of instability problems. The part-load flow in centrifugal pumps is inherently time-dependent due to the interaction of the rotating impeller with the stationary diffuser (Rotor-Stator Interaction, RSI). Furthermore, adverse pressure gradients in the pump diffuser may cause flow separation, potentially inducing symmetry-breaking non-uniformities, either spatially stationary or rotating and either steady or intermittent. Rotating stall, characterized by the presence of distinct cells of flow separation on the circumference, rotating at a fraction of the impeller revolution rate, has been observed in thermal and hydraulic turbomachines. Due to its complexity, the part-load flow in radial centrifugal pumps is a major challenge for numerical flow simulation methods. The present study investigates the part-load flow in radial centrifugal pumps and pump-turbines by experimental and numerical methods, the latter using a finite volume discretization of the Reynolds-averaged Navier-Stokes (RANS) equation. Physical phenomena of part load flow are evidenced based on three case studies, and the ability of numerical simulation methods to reproduce part-load flow in radial centrifugal pumps qualitatively and quantitatively is assessed. A numerical study of the flow in a high specific speed radial pump-turbine using steady approaches and the hypothesis of angular periodicity between neighboring blade channels evidences the relation of sudden flow topology changes with an increase of viscous losses, impacting on the energy-discharge characteristic, and thus increasing the risk of unstable operation. When the flow rate drops below a critical threshold, the straight through-flow with flow separation zones attached to the guide vanes changes to an asymmetrical flow. Energy is drawn off the mean flow and dissipated in a large vortex-like structure. Besides flow separation in some diffuser channels, time-dependent numerical simulations of the flow in a double suction pump evidence a flow rate imbalance between both impeller sides interacting with asymmetric flow separation in the diffuser. Viscous losses increase substantially as this imbalance occurs, the resulting segment of positive slope in the energy-discharge characteristic is found for a flow rate sensibly different from measurements. Different modes of rotating stall are identified by transient pressure measurements in a low-specific-speed pump-turbine, showing 3 to 5 zones of separated flow, rotating at 0.016 to 0.028 times impeller rotation rate, depending on discharge. For operating conditions where stall with 4 cells is most pronounced, velocity is measured by Laser-Doppler methods at locations of interest. The velocity field is reconstructed with respect to the passage of stall cells by definition of a stall phase obtained from simultaneous transient pressure measurements. Time-dependent numerical simulation predicting rotating stall with 4 cells shows velocity fields that are in reasonable agreement with the measured velocity fields, but occurring at a sensibly higher flow rate than found from experiments. In consideration of the quantitative shortcomings of the numerical simulation, a novel modelling approach is proposed: Replacing the costly 3-dimensional simulation of the major part of the impeller channels by a 1-dimensional model allows a significant economy in computational resources, allowing an improved modeling for the remainder of the domain at constant computational cost. The model is validated with the challenging cases of rotating stall and impeller side flow rate imbalance. The satisfying coherence of the results with the simulation including the entire impeller channels qualifies this approach for numerous turbomachinery applications. It could also provide improved, time-dependent boundary conditions for draft tube vortex rope simulations at reasonable computational cost. Parameter studies modifying deliberately some quantities of mean flow and turbulence at the modeled boundary surfaces can be implemented in the framework of the method.

EPFL2009

Part load flow in radial centrifugal pumps

Olivier Braun

EPFL2009

Two-phase flow phenomena in hydraulic turbines and pump-turbines operating in synchronous condenser mode

Elena Vagnoni

EPFL2018