Citation
Raheem, Abdul and Dupont, Valerie and Channa, Abdul Qadir and Zhao, Xiou and Vuppaladadiyam, Arun K. and Yap, Taufiq Yun Hin and Zhao, Ming and Harun, Mohd Razif
(2017)
Parametric characterization of air gasification of Chlorella vulgaris biomass.
Energy & Fuels, 31 (3).
2959 - 2969.
ISSN 0887-0624; ESSN: 1520-5029
Abstract
The gasification of green algae Chlorella vulgaris in air was investigated using both a thermogravimetric analyzer
(TGA) and a bench scale horizontal axis quartz tube reactor (HQR). The full range of solid state kinetic models produced best fits with TGA results varied for the five subzones of conversion vs temperature, with the nucleation and nuclei growth “A2” followed by “A3” or contracting volume models producing close matches for T ≤ 367 °C, a zero-order model between 358 and 468 °C, and contracting surface models for T ≥ 458 °C; each model yielding their set of apparent activation energy (E < 41 kJmol−1) and pre-exponential factors (A > 0.04 s−1) corresponding to rate constants in the range 0.001−0.005 s−1. The HQR was used to investigate the effects of microalgal biomass loading, temperature, and equivalence ratio (ER) on CnHm/CO/H2 gas yield and composition, carbon conversion efficiency (CCE), and lower heating value (LHV) of syngas under air gasification conditions. Increasing microalgal biomass loading from 1 to 2 g led to a decrease in H2 content (24.2−19.5 vol %) in the gases. An optimal temperature of 950 °C resulted in the highest H2, CO, and CH4 yields at 2.9, 22.8, and 10.1 wt % of biomass from a maximum gas yield of 76.1 wt %, and highest H2/CO ratio (1.75) and CCE of 56.3%. The effect of ER was measured in two phases 0.1−0.26 and 0.26−35, respectively. During the first phase, the positive effect of ER played a major part compared to second phase, so the H2 content, H2 yield, CCE, and LHV were increased.
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