Effect of reducibility of transition metal oxides on in-situ oxidative catalytic cracking of tar

[Display omitted] •In-situ oxidative catalytic cracking improves coal pyrolysis tar quality.•Reducibility of transition metal oxides (TMOs) affects products distribution.•Heavy tar conversion increases with decrease of TMOs’ reducibility.•Fe2O3 shows the highest heavy tar conversion but the highest...

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Bibliographic Details
Published in:Energy conversion and management 2019-10, Vol.197, p.111871, Article 111871
Main Authors: Wang, Dechao, Jin, Lijun, Li, Yang, Wei, Baoyong, Yao, Demeng, Hu, Haoquan
Format: Article
Language:English
Subjects:
Carbon dioxide
Catalytic cracking
Coal pyrolysis
Conversion
Copper
Copper oxides
Fixed bed reactors
Fixed beds
Metal oxides
Metals
Oxidation
Oxidative catalytic cracking
Oxides
Pyrolysis
Pyrolysis products
Reducibility
Reduction
Tar
Temperature effects
Transition metal oxides
Transition metals
Water yield
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Summary:[Display omitted] •In-situ oxidative catalytic cracking improves coal pyrolysis tar quality.•Reducibility of transition metal oxides (TMOs) affects products distribution.•Heavy tar conversion increases with decrease of TMOs’ reducibility.•Fe2O3 shows the highest heavy tar conversion but the highest coke yield. To understand the effect of reducibility of transition metal oxides (TMOs) on tar conversion, four TMOs including Fe2O3, MnOx, CuO, and NiO were selected and in-situ oxidative catalytic cracking of coal pyrolysis tar on a two-stage fixed bed reactor at 550 °C was performed. The reducibility of TMOs was measured by H2-temperature programmed reduction (H2-TPR). The effect of reducibility of TMOs on the pyrolysis products distribution and conversion was investigated. The changes of TMOs before and after reaction were also analyzed by several characterizations. The addition of TMOs results in the decrease of tar yield and heavy tar content, and the increase of gas yield. The reduction temperature of TMOs affects the products distribution and heavy tar conversion. Among these four TMOs, Fe2O3 shows the highest reduction temperature (390–700 °C with peak centered on 570 °C) and the largest heavy tar conversion (75.3 wt%). CuO shows the lowest reduction temperature (190–470 °C with peak centered on 326 °C) and heavy tar conversion (45.8 wt%). The main reactions on CuO is complete oxidation with high water yield (12.8 wt%) and CO2 formation (110 mL/g.coaldaf). The coke formed on the used Fe2O3 is amorphous or disordered carbon, and shows the largest yield being 5.5 wt%.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2019.111871