Browsing: Hydrogen

This research, published in the International Journal of Hydrogen Energy, sheds light on using Planar Laser-Induced Fluorescence (PLIF) technology to explore the dynamics of hydrogen combustion.

The tender aims to solicit consultancy services to redesign and modernize motorway service areas in Luxembourg, with a significant focus on incorporating hydrogen refueling infrastructure. This step is a part of Luxembourg’s commitment to reducing carbon emissions and promoting clean energy sources.

This cutting-edge technology employs metal-organic frameworks (MOFs)-derived manganese-doped indium oxide (In2O3) hollow nanotubes, marking a significant advancement in hydrogen detection capabilities.

Advanced CFD simulations are critical to the research, providing a high-resolution understanding of flame behavior. To decipher the interactions, the researchers carefully controlled and monitored flame parameters, including velocity, temperature distributions, and flame length.

The research focuses on modeling cryogenic hydrogen vapor clouds and analyzing how these clouds spread in different atmospheric boundary layers. The key findings highlight the significant influence of various atmospheric conditions on the behavior and dispersion of hydrogen vapor.

A recent study delves into premixed hydrogen (H2) and methane (CH4) behavior in air mixtures when subjected to narrow-space ignition conditions.

The main objective of this tender is to secure the installation of high-grade stainless steel pipelines capable of safely transporting hydrogen. This project is essential for creating a robust and reliable hydrogen supply chain, thereby facilitating the use of hydrogen as a clean energy source.

The primary objective of the tender is to identify and select cutting-edge technological solutions for hydrogen production.

The research primarily focuses on understanding how variations in hydrogen injection pressure and timing affect exhaust emissions, mechanical vibration, and noise levels in a CI engine.

The study employs an extended Kalman filter (EKF) to estimate the oxygen concentration in the fuel cell system. These estimations allow the researchers to accurately identify and quantify the presence of hydrogen leaks.