by Diz, Harry Richard

Abstract (Summary)
This dissertation reports the design of a process (patent pending) to remove iron from acid mine drainage (AMD) without the formation of metal hydroxide sludge. The system includes the oxidation of ferrous iron in a packed bed bioreactor, the precipitation of iron within a fluidized bed, the removal of manganese and heavy metals (Cu, Ni, Zn) in a trickling filter at high (>9) pH, with final neutralization in a carbonate bed. The technique avoided the generation of iron oxyhydroxide sludge. In the packed bed bioreactor, maximum substrate oxidation rate (R,max) was 1500 mg L-1 h-1 at dilution rates of 2 h-1, with oxidation efficiency at 98%. The half-saturation constant (similar to a Ks) was 6 mg L-1. The oxidation rate was affected by dissolved oxygen below 2 mg L-1, with a Monod-type Ko for DO of 0.33 mg L-1. Temperature had a significant effect on oxidation rate, but pH (2.0 to 3.25) and supplemental CO2 did not affect oxidation rates. Iron hydroxide precipitation was not instantaneous when base was added at a OH/Fe ratio of less than 3. Induction time was found to be a function of pH, sulfate concentration and iron concentration, with a multiple R2 of 0.84. Aqueous [Al (III)] and [Mn (II)] did not significantly (a = 0.05) affect induction time over the range of concentrations investigated. When specific loading to the fluidized bed reactor exceeded 0.20 mg Fe m-2 h-1, dispersed iron particulates formed leading to a turbid effluent. Reactor pH determined the minimum iron concentration in the effluent, with an optimal at pH 3.5. Total iron removals of 98% were achieved in the fluidized bed with effluent [Fe] below 10 mg L-1. Further iron removal occurred within the calcium carbonate bed. Heavy metals were removed both in the fluidized bed reactor as well as in the trickling filter. Oxidation at pH >9 caused manganese to precipitate (96% removal); removals of copper, nickel, and zinc were due primarily to sorption onto oxide surfaces. Removals averaged 97% for copper, 70% for nickel and 94% for zinc. The treatment strategy produced an effluent relatively free of iron (< 3 mg/L), without the formation of iron sludge and may be suitable for AMD seeps, drainage from acidic tailings ponds, active mine effluent, and acidic iron-rich industrial wastewater.
Bibliographical Information:

Advisor:John T. Novak; Donald S. Cherry; William R. Knocke; Nancy G. Love; J. Donald Rimstidt

School:Virginia Polytechnic Institute and State University

School Location:USA - Virginia

Source Type:Master's Thesis

Keywords:civil engineering


Date of Publication:09/16/1997

© 2009 All Rights Reserved.