Hydrogen-fueled gas turbines represent a promising technology due to their efficiency and environmental friendliness. However, these turbines operate under extreme conditions, making components prone to corrosion and subsequent hydrogen leakages.
Addressing these leakages quickly and accurately is vital to ensure safety. This research introduces a pioneering approach using deep learning to estimate the location and intensity of hydrogen leakages in gas turbines.
Challenges in Detecting Hydrogen Leakages
Hydrogen leakages present significant challenges due to their explosive and flammable nature. Traditional methods for source term estimation (STE) rely on atmospheric transport and dispersion models, which are computationally intensive and unsuitable for real-time applications. The intricate flow dynamics around gas turbines, the potential for multiple leakages, and high-dimensional data further complicate the problem.
Innovative Approach with Deep Learning
To overcome these obstacles, the researchers developed a deep learning-based STE approach. They utilized a long short-term memory auto-encoder (LSTM-AE) network to extract dynamic features from multi-sensor data. They subsequently employed a deep neural network to correlate these features with hydrogen leakage parameters. Computational fluid dynamics (CFD) simulations provided the data required for various leakage scenarios.
Results Showcase Enhanced Performance
The novel approach demonstrated superior hydrogen leakage source localization and intensity estimation performance. The localization accuracy was highly impressive at 0.9798, while the R-squared value for leakage strength estimation reached 0.9632. The model maintained high accuracy even with limited training data, indicating its robustness and efficiency.
Potential Applications and Future Directions
This deep learning-based method offers a significant advancement in real-time hydrogen leakage detection. Its application could extend beyond gas turbines to other industrial sectors with prevalent hydrogen usage. This technology paves the way for safer and more reliable hydrogen energy systems by ensuring swift and precise leakage detection.
The study illustrates the powerful potential of integrating deep learning with advanced simulations to address critical safety issues in hydrogen-fueled gas turbines. As the energy sector evolves, such innovative approaches will be crucial in maintaining safety and advancing sustainable energy technologies.