Multicomponent Biosorption of Heavy Metals Using Fluidized Bed of Algal Biomass

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Abbas Hameed Sulaymon
Ahmed Abed Mohammed
Tariq Jwad Al-Musawi

Abstract

This paper aims to study the biosorption for removal of lead, cadmium, copper and arsenic ions using algae as a biosorbent. A series of experiments were carried out to obtain the breakthrough data in a fluidized bed reactor. The minimum fluidization velocities of beds were found to be 2.27 and 3.64 mm/s for mish sizes of 0.4-0.6 and 0.6-1 mm diameters, respectively. An ideal plug flow model has been adopted to characterize the fluidized bed reactor. This model has been solved numerically using MATLAB version 6.5. The results showed a well fitting with the experimental data. Different operating conditions were varied: static bed height, superficial velocity and particle diameter. The breakthrough curves were plotted for each metal. Pb2+ showed the largest breakthrough time compared with others, while Cd2+ had the lowest value

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How to Cite

“Multicomponent Biosorption of Heavy Metals Using Fluidized Bed of Algal Biomass” (2013) Journal of Engineering, 19(04), pp. 469–484. doi:10.31026/j.eng.2013.04.05.

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