Hydrogen production from palm kernel shell via integrated catalytic adsorption (ICA) steam gasification

Khan, Z., Yusup, S., Ahmad, M. M. and Chin, B. L. F. (2014) Hydrogen production from palm kernel shell via integrated catalytic adsorption (ICA) steam gasification. Energy Conversion and Management, 87, pp. 1224-1230. (doi: 10.1016/j.enconman.2014.03.024)

Full text not currently available from Enlighten.

Abstract

The present study investigates the integrated catalytic adsorption (ICA) steam gasification of palm kernel shell for hydrogen production in a pilot scale atmospheric fluidized bed gasifier. The biomass steam gasification is performed in the presence of an adsorbent and a catalyst in the system. The effect of adsorbent to biomass (A/B) ratio (0.5–1.5 wt/wt), fluidization velocity (0.15–0.26 m/s) and biomass particle size (0.355–2.0 mm) are studied at temperature of 675 °C, steam to biomass (S/B) ratio of 2.0 (wt/wt) and biomass to catalyst ratio of 0.1 (wt/wt). Hydrogen composition and yield, total gas yield, and lower product gas heating values (LHVgas) increases with increasing A/B ratio, while particle size has no significant effect on hydrogen composition and yield, total gas and char yield, gasification and carbon conversion efficiency. However, gas heating values increased with increasing biomass particle size which is due to presence of high methane content in product gas. Meanwhile, medium fluidization velocity of 0.21 m/s favoured hydrogen composition and yield. The results showed that the maximum hydrogen composition and yield of 84.62 vol% and 91.11 g H2/kg biomass are observed at A/B ratio of 1.5, S/B ratio of 2.0, catalyst to biomass ratio of 0.1 and temperature of 675 °C. The product gas heating values are observed in the range of 10.92–17.02 MJ/N m3. Gasification and carbon conversion efficiency are observed in the range of 25.66–42.95% and 20.61–41.95%, respectively. These lower efficiencies are due to significant CO2 capturing in using adsorbent in pilot the scale fluidized bed gasification system. Comparative study with literature shows that the combination of adsorbent and catalyst produces better results in terms of hydrogen composition and gas heating values compared to that of only using biomass in steam catalytic gasification and in steam gasification with in situ CO2 adsorbent.

Item Type:Articles
Keywords:Hydrogen production; Fluidized bed; Biomass; Gasification; CO2 adsorption; Catalyst; Oil palm wastes
Status:Published
Refereed:Yes
Glasgow Author(s) Enlighten ID:Khan, Dr Zakir
Authors: Khan, Z., Yusup, S., Ahmad, M. M., and Chin, B. L. F.
College/School:College of Science and Engineering > School of Engineering > Systems Power and Energy
Journal Name:Energy Conversion and Management
Publisher:Elsevier
ISSN:0196-8904
ISSN (Online):1879-2227
Data DOI:10.1016/j.enconman.2014.03.024

University Staff: Request a correction | Enlighten Editors: Update this record