Hydrides chemical

Catalytic hydrogen supply from a decalin-based chemical hydride under superheated liquid-film conditions... [Pg.177]

The storage capacity of some lithium hydrides are compared with other promising hydrides in Table 11.4. While considering a recyclable process, one of the important issues is the ability to regenerate the chemical hydride. Lithium hydroxide forms a monohydrate, which is easily decomposed when heated to about 100°C. In contrast, many of the bimetal hydrides form multihydrates on reacting with water, and require much higher temperatures to decompose [59]. [Pg.390]

Hydrogen Storage in Organic Chemical Hydrides on the Basis of Superheated Liquid-Film Concept... [Pg.437]

Efficient Hydrogen Generation from Organic Chemical Hydrides with... [Pg.437]

Catalytic Dehydrogenation of Organic Chemical Hydrides over... [Pg.437]

Onboard Hydrogen Supply from Organic Chemical Hydrides.462... [Pg.437]

Hydrogen energy systems by use of organic chemical hydrides. [Pg.440]

Removal of thermodynamic restriction through reactive distillation and enhancement of hydrogen generation reactivity due to this concept made it possible to utilize organic chemical hydrides in the field of hydrogen storage from a novel standpoint. [Pg.442]

Chemical Hydrides with Superheated Liquid-Film-Type Catalysis in Batchwise Operation... [Pg.443]

Catalytic Dehydrogenation of Organic Chemical Hydrides over Carbon-Supported Nickel-Based Nanoparticles under Superheated Liquid-Film Conditions... [Pg.452]

Catalytic Hydrogen Generation from Organic Chemical Hydrides under Superheated Liquid-Film Conditions by Use of Laboratory-Scale Continuous Reactor... [Pg.455]

To realize efficient hydrogen generation from organic chemical hydrides with the superheated liquid-film-type catalysis in a continuous operation, catalytic dehydrogenation by use of a continuous reactor was investigated on a laboratory scale [13,14]. [Pg.455]

Chemical Recuperation of Waste Heat by Utilizing Organic Chemical Hydrides... [Pg.463]

At present, waste heat exhausted from the ICE is removed with any efficient radiator system through direct apparent heat exchanging. On the contrary, organic chemical hydrides can recuperate the chemical energy of endothermic reaction heat during exhausted heat removal. Heat transfers accompanying the phase change of evaporation and condensation of aromatic products and unconverted reactants will certainly facilitate the removal of heat from the ICE parts, with adoption of any new radiator system compelled. [Pg.463]