Continuous Catalytic Dehydrogenation of Decalin under Mild Conditions

Shono, Atsushi; Hashimoto, T.; Hodoshima, Shinya; Satoh, Kazumi; Saito, Yasukazu

doi:10.1252/jcej.39.211

Cited by 10 publications

(12 citation statements)

References 8 publications

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“…Furthermore, it is possible to utilize the present infrastructure, such as gas stations. Many reports have proposed the production of hydrogen from organic chemical hydrides. − However, the separation of hydrogen from other gases remains a major unsolved problem for hydrogen production systems from organic chemical hydrides. The process of separating hydrogen from other gases is generally expensive and energy-intensive.…”

Section: Introductionmentioning

confidence: 99%

Production of Hydrogen by Dehydrogenation of Cyclohexane in High-Pressure (1−8 atm) Membrane Reactors Using Amorphous Silica Membranes with Controlled Pore Sizes

Akamatsu

Ohta

Sugawara

et al. 2008

Ind. Eng. Chem. Res.

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We have developed membrane reactors to dehydrogenate cyclohexane, using amorphous silica membranes with controlled pore sizes, and successfully operated them under pressures ranging from 1 to 8 atm. The membranes were prepared by chemical vapor deposition (CVD) using tetramethoxysilane (TMOS) or dimethoxydiphenylsilane (DMDPS). Both membranes had hydrogen-permselective properties. At 473-573 K, the TMOS-derived membranes showed hydrogen permeances on the order of 10 -8 mol m -2 s -1 Pa -1 , whereas the DMDPS-derived membranes showed permeances on the order of 10 -6 mol m -2 s -1 Pa -1 . Both membrane reactors produced hydrogen with conversions greater than equilibrium, and the DMDPS-derived membrane achieved higher conversion than the TMOS-derived membrane because of the greater hydrogen extraction effect of the DMDPS-derived membrane. In addition, it should be noted that this is the first report of successful operation of membrane reactors with highly hydrogen-permselective silica membranes under pressure.

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Section: Introductionmentioning

confidence: 99%

Production of Hydrogen by Dehydrogenation of Cyclohexane in High-Pressure (1−8 atm) Membrane Reactors Using Amorphous Silica Membranes with Controlled Pore Sizes

Akamatsu

Ohta

Sugawara

et al. 2008

Ind. Eng. Chem. Res.

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“…A platinum catalyst supported on the granular activated carbon (KOH-activation, BET specific surface area 3100 m 2 /g, pore volume 1.78 cm 3 /g, average particle size 13 µm, average pore size 2.0 nm, Kansai Netsukagaku Co. Ltd – , First, granular powders of the base-pretreated activated carbon were stirred with a K 2 PtCl 4 aqueous solution at room temperature for 48 h, which was followed by dropwise addition of a NaBH 4 aqueous solution at 90 °C for 30 min. Here, all metallic species added to the granular activated carbon were experimentally confirmed to be adsorbed onto the carbon support during impregnation step by measuring the concentration of the residual metallic species in the supernatant aqueous solution after 48 h by means of the ultraviolet−visible spectroscopy (U-3300 spectrometer, Hitachi) .…”

Section: Methodsmentioning

confidence: 99%

“…In order to popularize hydrogen energy systems, e.g., fuel cells and hydrogen vehicles powered by internal combustion engines (ICE), however, any technological breakthrough on hydrogen storage and transportation is urgently required. Organic chemical hydrides, – consisting of reversible reaction pairs such as decalin dehydrogenation/naphthalene hydrogenation (eq ) and methylcyclohexane dehydrogenation/toluene hydrogenation (eq ), have been proposed by our group as the materials for carrying hydrogen due to the following excellent properties: (1) high storage capacities ( cis -decalin 7.3 wt %, 64.8 kg-H 2 /m 3 ; methylcyclohexane 6.2 wt %, 46.5 kg-H 2 /m 3 ; the target values presented by the U.S. Department of Energy (DOE) 6.5 wt %, 62.0 kg-H 2 /m 3 ); (2) facile reversibility; (3) being safe and cost-competitive. …”

Section: Introductionmentioning

confidence: 99%

“…The superheated liquid-film-type catalysis, – , a novel concept developed by our group, made it possible for the first time to generate hydrogen quite efficiently from organic chemical hydrides at moderate heating temperatures of 200−300 °C without coke formation. By charging an adequate amount of reactant solution (e.g., decalin and methylcyclohexane) to a constant amount of solid catalyst, consisting of metallic nanoparticles (e.g., platinum, platinum−rhenium, and nickel−ruthenium) supported on activated carbon, “the superheated liquid-film state” is realized. – , Since the catalyst surface is covered with a thin liquid-film of solution but not suspended, this catalyst state has been designated as a “liquid-film state”. – , This liquid-film state was confirmed to exhibit much higher catalytic activities than those with ordinary heterogeneous catalysis in the either solid−gas or solid−liquid phase. Therefore, it is possible to utilize low-quality waste heats below 300 °C as the heat source for endothermic dehydrogenation.…”

Section: Introductionmentioning

confidence: 99%

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Chemical Recuperation of Low-Quality Waste Heats by Catalytic Dehydrogenation of Organic Chemical Hydrides and Its Exergy Analysis

2008

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Any technological breakthrough on storage, transportation, and distribution of hydrogen is urgently required to popularize hydrogen energy systems. In the present paper, organic chemical hydrides with appropriate characteristics (e.g., high storage capacities, facile reversibility, and being safe and cost-competitive), consisting of reversible catalysis pairs such as methylcyclohexane dehydrogenation/toluene hydrogenation and decalin dehydrogenation/naphthalene hydrogenation, have been proposed as the suitable materials for carrying hydrogen. Efficient hydrogen generation from organic chemical hydrides at moderate heating temperatures lower than 300 °C, being low enough to avoid serious coke formation over catalyst surface, was accomplished only by using carbon-supported nanosize platinum catalysts in superheated liquid-film states. Desorption of products from catalytic active sites was enhanced with the temperature gradient formed in the superheated liquid-film state, so that both high catalytic conversions and reaction rates were attained simultaneously in spite of unfavorable temperatures for dehydrogenation. Adoption of the superheated liquid-film-type catalysis will make it possible to utilize low-quality waste heats below 300 °C as the heat source for endothermic dehydrogenation. Exhausted waste heat can be recuperated as chemical energy through the superheated liquid-film-type dehydrogenation of organic chemical hydrides, with hydrogen used for vehicles or stationary fuel cells. Exergy loss in the hydrogen storage and transportation systems ought to be suppressed through the chemical recuperation of waste heat by use of organic chemical hydrides. An exergy analysis in automotive application has revealed that organic chemical hydrides are superior to compressed hydrogen and liquefied hydrogen in terms of total exergy consumption.

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“…Properly-wetted nano-metal catalysts, supported on highly-porous activated carbon, had been chosen for efficient dehydrogenation [7][8][9][10]. Reasons of choice would be summarized as follows.…”

Section: Necessary Conditions For Properly-wetted Catalysismentioning

confidence: 99%

Dehydrogenation Catalyst for Organic Hydride on the Basis of Superheated Liquid-Film Concept

Shono¹,

Otake²,

Kobayashi

et al. 2016

J. Technol. Innov. Renew. Energy

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Reversible reaction couples of hydrogenation and dehydrogenation of organic compounds e.g. methylcyclohexane and toluene, or 2-propanol and acetone, are described in terms of hydrogen supplier to fuel cells, which will satisfy our demands of combined heat and power at various compact sizes. Carbon supported nano-sized metal particles, wetted with the liquid substrate in a reactor, was used for conversion of organic hydrides into hydrogen and organic compounds, being separable by distillation. Vigorous nucleate boiling is important for heat transfer as well as for irreversible bubble evolution, leading hydrogen to the vapor phase. Once the bubble is broken at the interface, catalytic hydrogenation will be prohibited, because gaseous hydrogen is unable to dissolve into the boiling liquid. Catalytic dehydrogenation under superheated liquid-film conditions can thus convert low-quality heats into hydrogen energy.

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Continuous Catalytic Dehydrogenation of Decalin under Mild Conditions

Cited by 10 publications

References 8 publications

Production of Hydrogen by Dehydrogenation of Cyclohexane in High-Pressure (1−8 atm) Membrane Reactors Using Amorphous Silica Membranes with Controlled Pore Sizes

Production of Hydrogen by Dehydrogenation of Cyclohexane in High-Pressure (1−8 atm) Membrane Reactors Using Amorphous Silica Membranes with Controlled Pore Sizes

Chemical Recuperation of Low-Quality Waste Heats by Catalytic Dehydrogenation of Organic Chemical Hydrides and Its Exergy Analysis

Dehydrogenation Catalyst for Organic Hydride on the Basis of Superheated Liquid-Film Concept

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