Abstract
Optimal operation of hydropower plants (HP) is a crucial task for the control of several variables involved in the power generation process, including hydraulic level and power generation rate. In general, there are three main problems that an optimal operation approach must address: (i) maintaining a hydraulic head level which satisfies the energy demand at a given time, (ii) regulating operation to match with certain established conditions, even in the presence of system’s parametric variations, and (iii) managing external disturbances at the system’s input. To address these problems, in this paper we propose an approach for optimal hydraulic level tracking based on an Inverse Optimal Controller (IOC), devised with the purpose of regulating power generation rates on a specific HP infrastructure. The Closed–Loop System (CLS) has been simulated using data collected from the HP through a whole year of operation as a tracking reference. Furthermore, to combat parametric variations, an accumulative action is incorporated into the control scheme. In addition, a Recurrent Neural Network (RNN) based on Feature Engineering (FE) techniques has been implemented to aid the system in the prediction and management of external perturbations. Besides, a landslide is simulated, causing the system’s response to show a deviation in reference tracking, which is corrected through the control action. Afterward, the RNN is including of the aforementioned system, where the trajectories tracking deviation is not perceptible, at the hand of, a better response with respect to use a single scheme. The results show the robustness of the proposed control scheme despite climatic variations and landslides in the reservoir operation process. This proposed combined scheme shows good performance in presence of parametric variations and external perturbations.
Highlights
Hydropower plants management is a problem which complexity is related to the increase of the population on the vicinities of these power generation systems
Such perturbations in storage capacity are problematic because these cause the system to be unable to satisfy the required energy demand [3], it is necessary to implement techniques to handle said external perturbations and to manage the hydraulic level without hindering power generation or the network’s energy supply
For the design of the Neural Network (NN), we find the auto-correlation of the clean data
Summary
Hydropower plants management is a problem which complexity is related to the increase of the population on the vicinities of these power generation systems. Some of the factors involved in dam volumes management include some climatic phenomena, those which may cause landslides and, as a result, changes in storage capacity [2] Such perturbations in storage capacity are problematic because these cause the system to be unable to satisfy the required energy demand [3], it is necessary to implement techniques to handle said external perturbations and to manage the hydraulic level without hindering power generation or the network’s energy supply. Several works related to the power regulation problem in hydropower plants have been published; in [9], for example, an application of a robust controller to regulate the speed of the governor was proposed. In [11], an application for a controller based on passivity was presented
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