The catalytic pyrolysis of microalgae to produce syngas

The catalytic pyrolysis of microalgae to produce syngas

•Activated carbon, ZnCl2, SiC and MgO were utilized as catalysts to promote pyrolysis.•The minimum solid residue yield was gained under the effect of activated carbon.•Mixing with a higher activated carbon content can gain a lower solid residue yield.•Catalysts and contents of activated carbon affec...

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Veröffentlicht in:Energy conversion and management 2014-09, Vol.85, p.545-550
Hauptverfasser: Hu, Zhifeng, Ma, Xiaoqian, Li, Longjun, Wu, Jie
Format: Artikel
Sprache:eng
Schlagworte:
Activated carbon
Applied sciences
Catalysis
Catalysts
Catalytic pyrolysis
Chlorella vulgaris
Energy
Evaluation method
Exact sciences and technology
Microalgae
Optimization
Pyrolysis
Reactors
Residues
Syngas
Tubes
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container_start_page 545
container_title Energy conversion and management
container_volume 85
creator Hu, Zhifeng
Ma, Xiaoqian
Li, Longjun
Wu, Jie
description •Activated carbon, ZnCl2, SiC and MgO were utilized as catalysts to promote pyrolysis.•The minimum solid residue yield was gained under the effect of activated carbon.•Mixing with a higher activated carbon content can gain a lower solid residue yield.•Catalysts and contents of activated carbon affected obviously the syngas production.•3% is the optimal content of activated carbon to produce syngas. The pyrolysis of Chlorella vulgaris was carried out in a quartz tube reactor with different catalysts and contents of activated carbon. The solid residue yield, gaseous products and the evaluation method based on higher heating value and energy consumption were analyzed in order to obtain the optimal condition to produce syngas. The results indicated that catalysts obviously affected the pyrolysis products. Activated carbon was a good choice of catalyst to obtain the minimum solid residue yield (10.79wt.%), and mixing with a higher content of activated carbon could produce a lower solid residue yield; meanwhile, the effect of each 1% activated carbon will be worse. According to the evaluation methods, there was a certain impact on the syngas production under different catalysts and contents of activated carbon. Furthermore, the HVe,s indicated that activated carbon was the optimal catalyst and 3% is the optimal content of activated carbon to produce syngas.
doi_str_mv 10.1016/j.enconman.2014.04.096
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The pyrolysis of Chlorella vulgaris was carried out in a quartz tube reactor with different catalysts and contents of activated carbon. The solid residue yield, gaseous products and the evaluation method based on higher heating value and energy consumption were analyzed in order to obtain the optimal condition to produce syngas. The results indicated that catalysts obviously affected the pyrolysis products. Activated carbon was a good choice of catalyst to obtain the minimum solid residue yield (10.79wt.%), and mixing with a higher content of activated carbon could produce a lower solid residue yield; meanwhile, the effect of each 1% activated carbon will be worse. According to the evaluation methods, there was a certain impact on the syngas production under different catalysts and contents of activated carbon. 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The pyrolysis of Chlorella vulgaris was carried out in a quartz tube reactor with different catalysts and contents of activated carbon. The solid residue yield, gaseous products and the evaluation method based on higher heating value and energy consumption were analyzed in order to obtain the optimal condition to produce syngas. The results indicated that catalysts obviously affected the pyrolysis products. Activated carbon was a good choice of catalyst to obtain the minimum solid residue yield (10.79wt.%), and mixing with a higher content of activated carbon could produce a lower solid residue yield; meanwhile, the effect of each 1% activated carbon will be worse. According to the evaluation methods, there was a certain impact on the syngas production under different catalysts and contents of activated carbon. 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The pyrolysis of Chlorella vulgaris was carried out in a quartz tube reactor with different catalysts and contents of activated carbon. The solid residue yield, gaseous products and the evaluation method based on higher heating value and energy consumption were analyzed in order to obtain the optimal condition to produce syngas. The results indicated that catalysts obviously affected the pyrolysis products. Activated carbon was a good choice of catalyst to obtain the minimum solid residue yield (10.79wt.%), and mixing with a higher content of activated carbon could produce a lower solid residue yield; meanwhile, the effect of each 1% activated carbon will be worse. According to the evaluation methods, there was a certain impact on the syngas production under different catalysts and contents of activated carbon. 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subjects Activated carbon
Applied sciences
Catalysis
Catalysts
Catalytic pyrolysis
Chlorella vulgaris
Energy
Evaluation method
Exact sciences and technology
Microalgae
Optimization
Pyrolysis
Reactors
Residues
Syngas
Tubes
title The catalytic pyrolysis of microalgae to produce syngas
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