Hydrogen production from absorption-enhanced steam gasification of Enteromorpha prolifera and its char using Ce-doped CaO material

Yan, Xianyao; Li, Yingjie; Sun, Chaoying; Wang, Zeyan

doi:10.1016/j.fuel.2020.119554

Cited by 29 publications

(8 citation statements)

References 60 publications

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“…Hydrogen is a clean and efficient energy carrier that can be utilized in transport, industrial and district applications. 1,2 Currently, hydrogen production technologies are water electrolysis, microbial, or photo fermentation and fossil fuels processing, such as gasification of coal, or reforming of natural gas. [2][3][4][5] However, the high cost of water electrolysis, the inefficiency of biological methods and the emission of toxic and greenhouse gases in combination with the depletion of fossil fuels reserves, make the use of renewable, sustainable, carbon-neutral feedstocks, such as biomass, a very promising alternative for versatile hydrogen applications in the near future.…”

Section: Introductionmentioning

confidence: 99%

“…[2][3][4][5] However, the high cost of water electrolysis, the inefficiency of biological methods and the emission of toxic and greenhouse gases in combination with the depletion of fossil fuels reserves, make the use of renewable, sustainable, carbon-neutral feedstocks, such as biomass, a very promising alternative for versatile hydrogen applications in the near future. 1,[3][4][5][6] One of the most effective ways for hydrogen generation on a large scale is considered the thermochemical conversion of biomass via steam gasification. This process leads to syngas with elevated hydrogen content and high energy density, as well as less tar production, in comparison to air gasification.…”

Section: Introductionmentioning

confidence: 99%

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Sustainable Management of Forest and Building Wastes for Hydrogen- Rich Syngas from Catalytic Steam Gasification with Minimum CO<sub>2</sub> Emissions

D. Vamvuka,

S. Panagiotidou,

A. Orfanoudaki

et al. 2024

SCE

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The current study aimed at the exploitation of forest residues and their industrial waste for biofuel production, together with the exploitation of building demolition wastes (BDW) for CO2 capture from the gasification process. Selected materials were gasified by steam in a fixed bed unit, using BDW as sorbent and CeO2 and K2CO3 as catalysts. The effects of sorbent/biomass ratio, catalyst loading and temperature on final conversion, product gas composition and heating value, syngas and hydrogen yield and energy recovery were examined and optimum conditions were determined. Analysis of gases was performed in a thermogravimetric-mass spectrometric (TG-MS) system. At a ratio of Ca/C = 1, the amount of CO2 captured at 750 °C was 73.2-76%, the concentration of hydrogen in the product gas was 56.2-59.3% mol and the higher heating value was 13.1 MJ/m3. An increase of catalyst loading up to 20% wt resulted in higher conversion and syngas and hydrogen yields. K2CO3 catalyst showed a better overall performance. In this case, conversion ranged between 80.7% and 84.8%, the molar fraction of hydrogen in the product gas was 67-80.5%, syngas yield varied from 1.9 m3/kg to 2.6 m3/kg, with a heating value of 13.1-13.8 MJ/m3 and energy recovery was higher.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Sustainable Management of Forest and Building Wastes for Hydrogen- Rich Syngas from Catalytic Steam Gasification with Minimum CO<sub>2</sub> Emissions

D. Vamvuka,

S. Panagiotidou,

A. Orfanoudaki

et al. 2024

SCE

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“…3,4 Low cost and broad applicability make calcium looping (CaL) one of the most promising CCUS technologies. 5,6 Apart from the application in cyclic CO 2 capture, the CaO-based material also demonstrates the versatility of being used as the catalyst/absorbent in the sorption-enhanced hydrogen production 7,8 and heat carrier in the thermal chemical energy storage coupling with concentrating solar energy. 9,10 The common demand for the CaObased material among the scenarios mentioned above lies in the cyclic durability and mechanical strength.…”

Section: Introductionmentioning

confidence: 99%

“…Reducing carbon emissions has become an international consensus to prevent global warming . CO 2 capture, utilization, and storage (CCUS) technology becomes a preferable option to achieve near-zero carbon emissions considering technical feasibility and investment cost. , Low cost and broad applicability make calcium looping (CaL) one of the most promising CCUS technologies. , Apart from the application in cyclic CO 2 capture, the CaO-based material also demonstrates the versatility of being used as the catalyst/absorbent in the sorption-enhanced hydrogen production , and heat carrier in the thermal chemical energy storage coupling with concentrating solar energy. , The common demand for the CaO-based material among the scenarios mentioned above lies in the cyclic durability and mechanical strength.…”

Section: Introductionmentioning

confidence: 99%

Enhanced CO₂ Capture Durability and Mechanical Properties Using Cellulose-Templated CaO-Based Pellets with Steam Injection during Calcination

Rong

Wang

Liu

et al. 2023

Ind. Eng. Chem. Res.

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Cellulose-templated CaO-based pellets were prepared via an extrusion–spheronization method. However, the CO2 capture capacity of the modified sorbents still deteriorated rapidly after multiple cycles, and the mechanical properties were also reduced. Steam injection during calcination was conducted to enhance the CO2 capture performance of the sorbents. The modified pellets with 10 vol % steam injection present a faster carbonation rate compared to sorbents calcined under higher steam concentrations. A CO2 uptake of 0.32 g/g was obtained after 20 cycles, 133 and 60% higher than the raw sorbent and modified sorbent without steam reactivation. Moreover, the simultaneous thermal and atmosphere-induced sintering resulted in a nearly 4 times enhancement of the mechanical strength of the sorbents from 3.9 to 14.7 N. Under the harsh environment (calcined at 950 °C), the presence of steam further aggravated the sintering of the sorbent, resulting in a dramatic decrease in CO2 uptake.

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“…Разнообразие способов получения водорода является одним из главных преимуществ водородной энергетики. В настоящее время наиболее доступным и дешевым процессом является паровая конверсия метана и природного газа [1-3], а также пиролиз угля [4,5]. Согласно прогнозам, она будет использована только в начальной стадии перехода к водородной экономике.…”

Section: Introductionunclassified

Plasma-electrolyte discharges in a gas-liquid medium for the production of hydrogen

Gaisin

Bagautdinova

et al. 2021

«Izvestiya vysshikh uchebnykh zavedenii. PROBLEMY ENERGETIKI»

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THE PURPOSE. Comprehensive study of the effect of direct current electric discharge plasma in a gas-liquid medium of inorganic mixtures in order to obtain gaseous hydrogen. Obtain volt-ampere, volt-second and ampere-second characteristics of the discharge at various concentrations of electrolyte. Study the process of electrolysis, breakdown, discharge ignition and discharge flow in a dielectric tube at a constant current. METHODS. To solve this problem, experimental studies were carried out on a model installation, which consists of a power supply system, a discharge chamber, equipment for monitoring and controlling the operation of the installation and measuring the characteristics of an electric discharge. To analyze the stability of the discharge, the time dependences of the voltage ripple and the discharge current were obtained. RESULTS. Experimental studies were carried out between the electrolytic cathode and the electrolytic anode at constant current and at atmospheric pressure with the following parameters: discharge voltage U = 0.1-1.5 kV, discharge current I = 0.02-2.3 A, interelectrode distance l = 100 mm , 1%, 3% and 5% solutions of sodium chloride in tap water were used as electrolytes. CONCLUSION. It is shown that electrical breakdown and ignition of a discharge that is stable in time depends on the conductivity of the gas-liquid medium of the electrolyte. The nature of the current-voltage characteristics depends on the random processes occurring in the gas-liquid medium, which is associated with numerous breakdowns occurring in the gas-liquid medium of the electrolyte, combustion and attenuation of microdischarges, the appearance of bubbles, and the movement of the electrolyte inside the dielectric tube. It is shown that the generation of hydrogen and hydrogen-containing components can occur both at the stage of electrolysis and during discharge combustion. A feature of this method is that electrical discharges in the tube increase the release of hydrogen. In this installation, inorganic and organic liquids of a certain composition and concentration can be used. The results of experimental studies made it possible to develop and create a small-sized installation for producing gaseous hydrogen. Tests have shown that a small-sized plant can be taken as the basis for a industrial plant for the production of hydrogen gas.

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Hydrogen production from absorption-enhanced steam gasification of Enteromorpha prolifera and its char using Ce-doped CaO material

Cited by 29 publications

References 60 publications

Sustainable Management of Forest and Building Wastes for Hydrogen- Rich Syngas from Catalytic Steam Gasification with Minimum CO<sub>2</sub> Emissions

Sustainable Management of Forest and Building Wastes for Hydrogen- Rich Syngas from Catalytic Steam Gasification with Minimum CO<sub>2</sub> Emissions

Enhanced CO₂ Capture Durability and Mechanical Properties Using Cellulose-Templated CaO-Based Pellets with Steam Injection during Calcination

Plasma-electrolyte discharges in a gas-liquid medium for the production of hydrogen

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Hydrogen production from absorption-enhanced steam gasification of Enteromorpha prolifera and its char using Ce-doped CaO material

Cited by 29 publications

References 60 publications

Sustainable Management of Forest and Building Wastes for Hydrogen- Rich Syngas from Catalytic Steam Gasification with Minimum CO<sub>2</sub> Emissions

Sustainable Management of Forest and Building Wastes for Hydrogen- Rich Syngas from Catalytic Steam Gasification with Minimum CO<sub>2</sub> Emissions

Enhanced CO2 Capture Durability and Mechanical Properties Using Cellulose-Templated CaO-Based Pellets with Steam Injection during Calcination

Plasma-electrolyte discharges in a gas-liquid medium for the production of hydrogen

Contact Info

Product

Resources

About

Enhanced CO₂ Capture Durability and Mechanical Properties Using Cellulose-Templated CaO-Based Pellets with Steam Injection during Calcination