An advanced biomass gasification technology with integrated catalytic hot gas cleaning. Part III: Effects of inorganic species in char on the reforming of tars from wood and agricultural wastes

Zhang, Shu; Song, Yao; Song, Yintao; Yi, Qun; Dong, Li; Li, Ting Ting; Zhang, Lei; Feng, Jie; Li, Wen Ying

doi:10.1016/j.fuel.2016.06.078

Cited by 66 publications

(19 citation statements)

References 30 publications

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“…Previous studies [11,16] pointed out the char loaded with some catalytically active species showed much higher reactivity for tar reforming than the char itself. The transition metal of iron is believed as an attractive catalytically active species of char-supported catalyst to reform tar during the gasification of biomass by reasons of its high economic feasibility, adequate catalytic activities and non-toxicity [16,17].…”

Section: Introductionmentioning

confidence: 98%

“…To date, numerous tar elimination techniques, such as thermal cracking, physical capture, catalytic reforming, plasma cracking etc., have been exploited [6,7]. Among these techniques, catalytic tar reforming has been believed widely as a technically and economically feasible method to convert tar into light gas [8][9][10][11][12]. Recently, char/char-supported catalysts, which have the below advantages: (ⅰ) inexpensive and easily available due to the easy and abundant production of char from coal/biomass pyrolysis; (ⅱ) the spent catalyst can be directly/simply gasified/burned to recover the char's energy without any additional regeneration and disposal, have been widely reported as a promising medium to substantially reform/crack tar into light gases and coke [4,11,[13][14][15].…”

Section: Introductionmentioning

confidence: 99%

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Evolution of structure and activity of char-supported iron catalysts prepared for steam reforming of bio-oil

Wang

Jiang

et al. 2017

Fuel Processing Technology

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The aim of this study is to investigate the changes in iron phase, crystal size, surface area, and char structure/reactivity of the char-supported iron catalysts after them being used for bio-oil reforming. The catalysts were prepared under different conditions (varying in temperatures, gasification agents and iron concentrations) and then used to reform bio-oil under a fixed experimental condition at 800 °C. The results show that the catalysts prepared from the steam gasification of Fe-loaded coal were preferred in terms of catalytic performance. The X-ray diffraction analysis indicates that the iron phases in the fresh catalysts varied while the used catalysts nearly showed identical iron phase of magnetite (Fe 3 O 4). The crystal iron particle in the catalysts would apparently increase after reforming when the initial iron phase was carbides (γ-Fe and/or α-Fe). The char structure of the catalysts was significantly affected by the "volatile-char interactions" during reforming process. And the catalysts" surface area and reactivity in air were both reduced mainly due to the coke formation.

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Evolution of structure and activity of char-supported iron catalysts prepared for steam reforming of bio-oil

Wang

Jiang

et al. 2017

Fuel Processing Technology

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“…This topic has been increasingly investigated over the past few years. Previous studies reported that four characteristics of the chars determined their activity even if their role remains not clear: the porous structures [43,44], the presence of Ocontaining groups on the char surface [45][46][47][48][49], the structure of the carbonaceous matrix [50,51], and the active sites formed by the inherent alkaline (i.e. : Na, K) and alkaline earth (i.e.…”

Section: Introductionmentioning

confidence: 99%

Catalytic cracking of ethylbenzene as tar surrogate using pyrolysis chars from wastes

Hervy

Villot

Gérente

et al. 2018

Biomass and Bioenergy

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This paper aims at studying the catalytic activity of waste-derived chars for the reforming of a tar compound (ethylbenzene), and to identify the relationships between the modification process, the physicochemical properties and their resulting catalytic behaviour. Two chars were produced by pyrolysis: (1) used wood pallets (UWP), and (2) a mixture of food waste (FW) and coagulation-flocculation sludge (CFS) from wastewater treatment plant. Two chemical-free modification processes were separately applied to the pyrolysis chars: a gas phase oxygenation at 280°C, or a steam activation at 850°C. At 650°C, the ethylbenzene conversion due to thermal cracking was significantly increased by the catalytic activity of the chars (from 37.2 up to 85.8%). Ethylbenzene was decomposed into six molecules: hydrogen, carbon dioxide, ethylene, benzene, styrene, and toluene. Cracking, oxidative dehydrogenation, and hydrogenolysis reactions were involved in the decomposition mechanism of ethylbenzene. The catalytic efficiency of the char was also discussed based on the energy transferred from tar to syngas during tar cracking reactions. The characterization, performed with SEM, XRD, Raman, XRF, BET and TPD-μGC, evidenced that the presence of mineral species in the metallic form strongly increased the syngas production and quality by catalysing aromatic-ring opening reactions and Boudouard reaction. The oxidation of mineral species, occurring during the oxygenation process, decreased the char efficiency, while rising S BET increased the syngas production for UWP-based chars. This study demonstrated that waste-based chars were efficient catalysts to convert the lost energy contained in tar into useful syngas, thus increasing simultaneously the syngas yield and quality.

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“…De‐SDC10 catalyst reached the maximum syngas yield. The CO and H 2 yields were enhanced, while CO 2 yield decreased from 0.21 to 0.16 mL/g when comparing thermal cracking without catalyst and catalytic cracking with pure char catalyst, which was because of water‐gas shift reaction and the Boudouard reaction between char, H 2 O, and CO 2 in Equations and . In addition, the mass loss of the used SDC catalyst can also verify that char support participated in the reaction at high temperature to produce more CO and H 2 .…”

Section: Resultsmentioning

confidence: 95%

The influence of preparation method of char supported metallic Ni catalysts on the catalytic performance for reforming of biomass tar

Zhang

2019

Int J Energy Res

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Summary The char‐supported nickel catalysts prepared by wet impregnation and precipitation‐deposition methods under different nickel loadings and catalytic temperatures for catalytic reforming of rice husk tar were investigated. The influences of preparation methods on the physicochemical properties of catalysts and catalytic activity towards tar conversion and gas yield were studied. The results showed that char‐supported metallic Ni catalysts can be directly used without a reduction process because of carbon thermal reaction during calcination. The preparation method had a significant influence on the porosity and Ni dispersion of catalysts. The addition of Ni to char improved the specific surface area from 60 m2 g−1 to 346.8 m2 g−1 because of activation effect of nickel nitrate on char pore structure. The precipitation‐deposition method produced higher surface area, smaller Ni nanoparticulates with more corner and step sites, as well as more concentrated size distribution than those of wet impregnation method, leading to higher catalytic activity, in terms of high tar conversion efficiency (83%) and increasing syngas yield. The selectivity to phenols and naphthalene for precipitation‐deposited catalysts was strengthened, and the relative content of heavy tars was decreased remarkably. The increasing H2 yield and concentration were indicative of efficient conversion of macromolecular organic matters into small molecules gases. In addition, the precipitation‐deposited catalyst exhibited weaker Ni sintering after reaction. The catalytic cracking temperature of 800°C and Ni loading of 10 wt% exhibited the best catalytic effects on gas distribution and tar conversion.

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An advanced biomass gasification technology with integrated catalytic hot gas cleaning. Part III: Effects of inorganic species in char on the reforming of tars from wood and agricultural wastes

Cited by 66 publications

References 30 publications

Evolution of structure and activity of char-supported iron catalysts prepared for steam reforming of bio-oil

Evolution of structure and activity of char-supported iron catalysts prepared for steam reforming of bio-oil

Catalytic cracking of ethylbenzene as tar surrogate using pyrolysis chars from wastes

The influence of preparation method of char supported metallic Ni catalysts on the catalytic performance for reforming of biomass tar

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