Optimal CAM Computation of Kaplan Turbines Accounting for Wear and Tear Originated by Frequency Control

Nowadays, the importance of providing frequency stability to power systems with hydropower units is significantly increasing due to the growing proportion of volatile renewable energy sources. However, the provision of such services, as frequency containment reserve, inevitably increases the wear and tear, decreasing the performance of the hydraulic machines, especially the Kaplan ones. In view of a growing demand for frequency containment reserve, it is important to quantify the performance decline and occasionally recompute the characteristic curves of the hydraulic machine to update the control system and reduce the efficiency loss. Since this process is usually expensive, as it requires off-line tests, this paper proposes a data-driven method to estimate the performance decrease of Kaplan turbines by leveraging operational recorded data. The proposed approach is applied to compute a new CAM relation for the run-of-river power plant of Vogelgrun. The new CAM, obtained with the proposed method is finally compared with real operational data.

Model testing beyond the scope of International Standards: an outlook.

Loïc Andolfatto, François Avellan

The roles of hydropower plants within the energy system has been evolving during the last two decades. The potential to provide ancillary services to the grid is often harnessed, leading to a major change in hydropower plants operations. Ancillary services provision can nowadays be considered as one of the main functions of the power plant during the design of greenfield and refurbishment projects. Reduced scale physical model testing of hydraulic machines are meant to experimentally determine their main hydraulic performances. Model testing also provides a valuable opportunity to accurately gather information and to build models of the machine behavior that are of critical importance to fuel the transition of hydropower into the digital era triggered by some of the major industrial actors of the hydropower market. The quantities of interest within the scope of the guaranteed hydraulic performance are likely to be enriched following the new needs and expectations of the hydropower plants operators. The manufacturers also intend to deliver innovative digital solutions aside with their machines. This contextual breakthrough leads to supplementary requirements for future model testing campaigns that are not necessarily fully addressed within the current International Standards corpus, especially within the IEC 60193 International Standard referring to hydraulic turbines, storage pumps and pump-turbines model acceptance test. The purpose of this paper is to propose an outlook of the model testing beyond the scope of the IEC 60193 International Standard. Activities and techniques aiming at the characterization of the stability of the units, their transient behaviors and the machine condition within various operating modes and regimes are described. The maturity of the described practices is considered according to multiple points of view ranging from instrumentation and procedures to model vs. prototype transposition. The potential impact on the units operation is also discussed. A review of the outcomes from recent research and development projects is proposed together with their transfer into industrial practices. A reflection is also conducted about the foreseeable needs for model testing in the coming years, the gap with the existing state of the art and the envisioned paths to close it.

2018

Hydroacoustic modelling and numerical simulation of unsteady operation of hydroelectric systems

Christophe Nicolet

Hydropower represented in 1999 19% of the world electricity production and the absolute production is expected to grow considerably during the next 30 years. Francis turbines play a major role in the hydroelectric production due to their extended range of application. Due to the deregulated energy market, hydroelectric power plants are increasingly subjecting to off design operation, start-up and shutdown and new control strategies. Consequently, the operation of Francis turbine power plants leads to transients phenomena, risk of resonance or instabilities. The understanding of these propagation phenomena is therefore paramount. This work is a contribution to the hydroacoustic modelling of Francis turbine power plants for the investigation of the aforementioned problematic. The first part of the document presents the modelling of the dynamic behavior and the transient analysis of hydroelectric power plants. Therefore, the one-dimensional model of an elementary pipe is derived from the governing equations, i.e. momentum and continuity equations. The use of appropriate numerical schemes leads to a discrete model of the pipe consisting of a T-shaped equivalent electrical circuit. The accuracy in the frequency domain of the discrete model of the pipe is determined by comparison with the analytical solution of the governing equations. The modelling approach is extended to hydraulic components such as valve, surge tanks, surge shaft, air vessels, cavitation development, etc. Then, the modelling of the Francis, Pelton and Kaplan turbines for transient analysis purposes is presented. This modelling is based on the use of the static characteristic of the turbines. The hydraulic components models are implemented in the EPFL software SIMSEN developed for the simulation of electrical installations. After validation of the hydraulic models, transient phenomena in hydroelectric power plants are investigated. It appears that standard separate studies of either the hydraulic or of the electrical part are valid only for design purposes, while full hydroelectric models are necessary for the optimization of turbine speed governors. The second part of the document deals with the modelling and analysis of possible resonance or operating instabilities in Francis turbine power plants. The review of the excitation sources inherent to Francis turbine operations indicates that the draft tube and the rotor-stator interaction pressure fluctuations are of the major concern. As the modelling of part load pressure fluctuations induced by the cavitating vortex rope that develops in the draft tube at low frequencies is well established, the focus is put on higher frequency phenomena such as higher part load pressure fluctuations and rotorstator interactions or full load instabilities. Three hydroacoustic investigations are performed. (i) Pressure fluctuations identified experimentally at higher part load on a reduced scale model Francis turbine are investigated by means of hydroacoustic simulations and high speed flow visualizations. The resonance of the test rig due to the vortex rope excitation is pointed out by the simulation while the special motion and shape of the cavitating vortex rope at the resonance frequency is highlighted by the visualization. A description of the possible excitation mechanisms is proposed. (ii) A pressure and power surge measured on a 4 × 400 MW pumped-storage plant operating at full load is investigated. The modelling of the entire system, including the hydraulic circuit, the rotating inertias and the electrical installation provides an explanation of the phenomenon and the related conditions of apparition. A non-linear model of the full load vortex rope is established and qualitatively validated. (iii) The rotor-stator interactions (RSI) are studied in the case of a reduced scale pump-turbine model. An original modelling approach of this phenomenon based on the flow distribution between the stationnary and the rotating part is presented. The model provides the RSI pressure fluctuation patterns in the vaneless gap and enables to predict standing waves in the spiral case and adduction pipe. The proposed one-dimensional modelling approach enables the simulation, analysis and optimization of the dynamic behavior of hydroelectric power plants. The approach has proven its capability of simulating properly both transient and periodic phenomena. Such investigations can be undertaken at early stages of a project to assess the possible dynamic problems and to select appropriate solutions ensuring the safest and optimal operation of the facility.

EPFL2007

Renovation of hydraulic power plant: how to select the best technical options?

Loïc Andolfatto, François Avellan, Joao Gomes Pereira Junior, Christian Landry, Christophe Nicolet

With the Energy Strategy 2050, Switzerland wishes to focus on balanced utilization of hydropower potentials and new renewable energy sources to cope with nuclear energy phasing out. Integration of large amounts of new renewable energies such as wind and solar power represents a challenging task as far as the power network stability is concerned. Indeed, the intermittent pattern of new renewable energies needs substitution and storage capabilities that hydropower can offer due to the variety of possible technical solutions featuring large flexibility and high performances control capabilities. The production capacity potential must be addressed together with the ancillary services capacity to ensure the stability of the electrical grid. The decision making process for the modernization of hydraulic power plant involves to overcome huge number of possible combinations at early design stages, when each decision has a major impact on the final performance of the hydropower plant. The RENOVHydro project rely on a systematic assessment of the hydropower plants generation increase of each upgrade possible option using the SIMSEN software as a backbone to identify the most cost-effective civil and hydro-electrical options. The SIMSEN simulation software enables to model an entire hydro power plant including hydraulic, mechanical and electrical system and their related control. The numerical models enable considering various hydraulic layout configurations, including non-linear head losses, realistic empirical turbine performance hill chart, generator efficiency as well as operating flexibility offered by variable speed technology. Thus, each hydropower plant upgrade option can be assessed by considering hydraulic structure, hydro units and hydropower station interaction with the grid for the provision of ancillary services, as well. This paper presents the methodology of the RENOVHydro project to determine the best cost-effective modernization options. The RENOVHydro methodology is illustrated on a hydropower plant test case with 80MW installed capacity and comprising 4 Francis turbines operated under a maximum head of 107mWC. Different civil and hydro-electrical options compared by taking into account the available hydrology and the electricity market for a typical year, and then computing the annual energy, the profitability and the energy coefficient to select the optimal solution. Finally, with these systematic studies adaptable to any type of hydraulic machine, the assessment of any scenario is made possible considering economical, technical and environmental aspects. This high level of support for the decision-making process drastically reduces the risks of selecting under-optimal solution. The assessment of the ancillary services of the most promising solutions is then introduced.

2018

Hydroacoustic modelling and numerical simulation of unsteady operation of hydroelectric systems

Christophe Nicolet

EPFL2007

Model testing beyond the scope of International Standards: an outlook.

Loïc Andolfatto, François Avellan

2018

Renovation of hydraulic power plant: how to select the best technical options?

Loïc Andolfatto, François Avellan, Joao Gomes Pereira Junior, Christian Landry, Christophe Nicolet

2018