| dc.description.abstract | This study investigates the risks associated with hydrogen transport through high-pressure
pipelines, focusing on potential leakages and their impacts. Using Computational Fluid
Dynamics (CFD) simulations, various conditions, including soil type, pipe depth, leak
size, and groundwater level, were analyzed to understand their influence on hydrogen
leakage. A Monte Carlo analysis was employed to account for uncertainties regarding the
conditions under which these leakages might occur.
The results indicate that leak size is the most critical factor affecting leakage rates,
followed by the type of surrounding soil. The maximum horizontal dispersion of hydrogen
was found to be 4.5 meters, suggesting that this should be considered the minimum
safety distance to prevent hydrogen-fueled fires. On average, it was determined that
approximately 0.06% of the hydrogen transported will leak annually. The environmental
impact of these leakages is minimal, particularly when compared to current natural gas
emissions. However, the financial implications can be significant, with potential losses
accounting for nearly 10% of Gasunie’s total profits in the worst-case scenario. These
findings underscore the importance of implementing accurate and efficient leak detection
methods to mitigate the risks associated with hydrogen transport. | |
