Determination of Hydraulic Residence Times in Several UK Mine Water Treatment Systems and their Relationship to Iron Removal

In the UK, the Coal Authority has more than 40 mine water treatment systems, most of which are wetland systems with settlement lagoon pretreatment. The purpose of treatment in wetlands is the oxidation of ferrous to ferric iron and the subsequent hydrolysis and precipitation of ferric hydroxide with...

Full description

Saved in:
Bibliographic Details
Published in:Mine water and the environment 2009-06, Vol.28 (2), p.115-123
Main Authors: Kruse, Natalie A. S., Gozzard, E., Jarvis, A. P.
Format: Article
Language:English
Subjects:
Acid mine drainage
Adsorptivity
Coal
Coal mines
Coal mining
Consortia
Design
Drainage control
Earth and Environmental Science
Earth Sciences
Ecotoxicology
Ferric hydroxide
Flow measurement
Geology
Hydraulics
Hydrogeology
Hydrology
Hydroxides
Industrial Pollution Prevention
Influents
Iron
Kinetics
Lagoons
Mine drainage
Mine waters
Mineral Resources
Mines
Oxidation
Removal
Residence time
Residence time distribution
Studies
Technical Article
Tracers
Water analysis
Water control
Water pollution
Water Quality/Water Pollution
Water sampling
Water treatment
Wetlands
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In the UK, the Coal Authority has more than 40 mine water treatment systems, most of which are wetland systems with settlement lagoon pretreatment. The purpose of treatment in wetlands is the oxidation of ferrous to ferric iron and the subsequent hydrolysis and precipitation of ferric hydroxide within the wetland. It is generally accepted (Hedin et al., Passive treatment of coal mine drainage, 1994 , p 35; Skousen and Ziemkiewicz, Acid mine drainage control and treatment, 1996 , p 362; Younger et al., Mine water: hydrology, pollution, remediation, 2002 , p 442) that this process proceeds by a first-order rate law, although most systems are designed based on an areal removal rate (10 g/m 2 /day) developed by the U.S. Bureau of Mines (Hedin et al., Passive treatment of coal mine drainage, 1994 , p 35); this design guideline inherently assumes a constant removal rate. Given the actual kinetics of iron removal in wetlands, it follows that residence time will control iron removal; given the wide range of system geometries and aspects, it is logical to ascertain the actual hydraulic residence time of wetlands and settlement lagoons and determine the effect this has on iron removal. To make a preliminary assessment of this link, hydraulic residence time of two Coal Authority wetlands (Lambley and Whittle) and two Coal Authority settlement lagoons (Acomb East, Acomb West and Whittle) were measured using bromide tracer tests. Water samples for iron analysis and flow measurements were taken during each tracer test. The Lambley wetland performs well in terms of residence time, and, as reeds become established and adsorptive processes increase, its iron removal performance (currently 58% removal) may improve, but the low influent iron concentration appears to be a significant impediment to meeting the original performance target. In contrast, the hydraulic performance of the Whittle wetland system is poor, which appears to be due to accumulation of dead plant material coupled with a high length to width ratio. However, performance in terms of iron removal is good (92% removal), which appears to be due to the higher influent iron concentration, and especially the fact that the iron enters the wetland largely in particulate form. The longer residence time of water within the Acomb lagoons (≈12 h) resulted in far more effective iron removal (72% in the east lagoon and 85% in the west lagoon) than the shorter residence time at Whittle (24% iron removal, ≈5 h residence tim
ISSN:1025-9112
1616-1068
DOI:10.1007/s10230-009-0068-6