Reinforcement learning for heliostat aiming: Improving the performance of Solar Tower plants
Jose A. Carballo, Javier Bonilla, N.C. Cruz, Jesús Fernández‐Reche, J.D. Álvarez, Antonio L. Ávila-Marín, Manuel Berenguel
Abstract
Solar Tower (ST) systems use heliostats to concentrate solar radiation onto a tower-mounted receiver. Optimizing the aiming strategy for these heliostats over the receiver remains a critical challenge due to the dynamic nature of solar radiation and the need to maximize energy capture while ensuring operational safety. This paper introduces a novel, model-free deep Reinforcement Learning (RL) approach to optimize heliostat aiming strategies, utilizing the Soft Actor–Critic (SAC) algorithm. This advanced RL method enhances the traditional Actor–Critic framework with two neural networks. The proposal dynamically adjusts the aiming points across the receiver surface in real time, trying to improve the overall performance of the ST plant. The strategy was simulated and evaluated over a full operational year and compared with traditional methods. The results show an increase of more than 8.8% in yearly absorbed power, a significant improvement that directly enhances performance and contributes to better economic outcomes for the technology. This technique also eliminates the need for constant human intervention and is applicable to both existing and future plants. • Novel RL-based aiming strategy for solar tower heliostats using Soft Actor–Critic (SAC). • Optimizes heliostat aiming in real-time without predefined points, enhancing efficiency. • Continuous receiver surface aiming adapts dynamically to sun and heliostat states. • Year-long validation shows improved energy output and reduced operational risks. • Comparative analysis of different aiming strategies reveals benefits of RL optimization.