The economic pre-treatment of coal mine drainage water with caustic and ozone-Reference-Cited by-同舟云学术

The economic pre-treatment of coal mine drainage water with caustic and ozone

Published:2017-05-05 Issue:5 Volume:76 Page:1022-1034
ISSN:0273-1223
Container-title:Water Science and Technology
language:en
Short-container-title:

Author:

Boyden B. H.¹,Nador L.¹,Addleman S.²,Jeston L.³

Affiliation:

1. CNF & Associates, Level 2, 393 George Street, Sydney, NSW 2000, Australia

2. Ozone Technologies Group Inc., 253 Portman Lane, Suite 107, Bridgeville, PA 15017, USA

3. Austar Coal Mine, Middle Road, Paxton, NSW 2325, Australia and Austar Coal Mine, Locked Bag 806, Cessnock, NSW 2325, Australia

Abstract

Coal mine drainage waters are low in pH with varying amounts of iron and manganese and are generally brackish. The Austar Coal Mine in NSW, Australia, sought alternatives to their current lime dosing as the pre-treatment before the downstream reverse osmosis plant. Undesirable operating aspects of the current system include manganese and gypsum scaling/fouling, the need for anti-scalants and reduced water recovery. Thirteen processes for acid mine drainage were initially considered. The preferred process of caustic and ozone for Mn(II) oxidation was pilot tested at up to 0.74 kL/hr at the mine site. Under proper conditions and no aeration, about 81 per cent of the Fe could be removed (initially at 156 mg/L) as green rust. Supplemental aeration followed first-order kinetics and allowed 99.9 per cent Fe(II) oxidation and removal but only with a hydraulic residence time of about 47 minutes. The addition of supplemental Cu catalyst improved Fe removal. Ozone applied after caustic was effective in stoichiometrically oxidising recalcitrant Mn(II) and any remaining Fe(II). Control of the ozonation was achieved using the oxidation reduction potential during oxidation of the Mn(II) species. The use of caustic, followed by ozone, proved economically comparable to the current lime pre-treatment.

Publisher

IWA Publishing

Subject

Water Science and Technology,Environmental Engineering

Link

http://iwaponline.com/wst/article-pdf/76/5/1022/450014/wst076051022.pdf

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