Maximized On-Demand Hydrogen Generator Design

Chung Hsing Chao; Tien Chien Jen

doi:10.4028/www.scientific.net/AMR.690-693.954

Paper Titles

The Evaluation System of Urban Low-Carbon Level
p.933

Analysis of the Effect of Natural Slope Stability due to Tunnel Excavation in Mountainous Areas
p.938

Effect of Argon Gas Flow on the Thermal Field in a Directional Solidification System for Multi-Crystalline Silicon
p.945

Effect of Sodium-Based Slag Treatment on the Distribution of Impurities in Metallurgical Grade Silicon
p.949

Maximized On-Demand Hydrogen Generator Design
p.954

Purification of Silicon by Solvent Refining with Si-Sn Alloy
p.962

Studies on the Electrochemical Behavior of Sio/C Anode Materials by AC Impedance Method
p.967

Summarize the Studies on Improving the Electrochemical Performance of Spinel LiMn₂O₄
p.971

Temperature Distribution of Multi-Crystalline Silicon Ingots in the Directional Solidification Process
p.977

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 690-693Maximized On-Demand Hydrogen Generator Design

Maximized On-Demand Hydrogen Generator Design

Abstract:

In this paper, magnesium hydride was used to react with water using a new design of control strategy to produce maximized on-demand hydrogen generation from the hydrolysis reaction. Magnesium hydride is the chemical compound MgH2, which contains 7.66% by weight of hydrogen and as a potential hydrogen source. Although the concept of reacting chemical hydride with water to produce hydrogen is not new, there have been a number of recent published papers which might be employed as on site generation of hydrogen for fuel cell applications. Under room temperature, the hydrolytic reaction between magnesium hydride and water to form a thin-layer of magnesium hydroxide on the outer surface impedes water from coming into direct contact with the magnesium hydride. The key to continual removal of this coherent magnesium hydroxide layer can induce the reaction of magnesium hydride with water near room temperature by the addition of citric acids. These additions act to disrupt the magnesium hydroxide layer on the magnesium hydride. This concept of using the magnesium hydride reaction with water to produce hydrogen has the following conclusions. This study presents a maximized on-demand hydrogen gas generator capable of producing hydrogen at an almost-constant H2 rate, which using this approach can reach the 6.4% by weight of hydrogen. In addition, based on the kinetics of magnesium hydride-water reaction, it does not need any noble-metals catalysts to meet the minimum hydrogen flow rate for fuel cell power systems. Finally, the cost of producing hydrogen from magnesium hydride-water approach would cost approximately $15 per kg hydrogen.