Review of URS document
Passive And Semi-Active Treatment Of Acid Rock Drainage; State
Of The Practice, April 2003
By Step by Step, June 1, 2003
SUMMARY OF DOCUMENT:
This document presents an “overview of current state of
the practice applications for passive and semi-active treatment
systems to treat acid rock drainage (ARD) associated with metal
mines.” A stated limitation of the study is that although
they spoke with system designers and operators of passive treatment
systems, usually URS was unable to obtain information on why the
systems failed, either because an evaluation had not been done,
or the information not available.
The study reviewed 7 passive treatment systems: aerobic wetlands,
anoxic limestone drains (ALD), open limestone channels (OLC),
settling ponds, successive alkalinity producing systems (SAPS),
solid-reactant anaerobic or sulfate reducing bacteria (SRB) bioreactors
and liquid-Reactant SRB Bio-reactors. The liquid SRB is a semi-active
system that requires inputs of two liquids regularly. The study
involved a literature review that included other more comprehensive
literature reviews including a 1996 paper from Canada that reviewed
over 100 papers.
URS reviewed 5 case studies using SRB’s. There were no case
studies for treatment methods other than SRB’s. The Elizabeth
Mine has flows of up to 2000 gpm (SLERA). The majority of the
load to the WBOR is iron and aluminum, and the water is acidic.
Previous studies have designed for flows of up to 135 gpm from
TP1. The 5 case studies in general did not address sites with
similar chemistry and flows. The 5 case studies reviewed were:
1) The Burleigh tunnel treated 7 gallons per minute (gpm) of neutral
pH water. These SRB’s failed due to spring runoff which
‘appeared to have changed the microbial ecology of the reactor”.
2) The Brewer Pad 5 operated for 18 months, design flow dropped
from 5 gpm to 0.75 gpm (due to changes in water chemistry), and
after maintenance and re-building due to invasive plants, it operated
effectively for another 3 months until it was closed.
3) The Ferris-Haggerty mine has neutral pH and high copper concentrations.
A pilot cell treated 3 – 5 gpm for 2 years, and it was de-commissioned.
4) Doe Run mine treated 1200 gpm of high pH (8) water with high
lead concentrations since 1996. The substrate in the SRB’s
has been completely removed and replaced twice.
5) A liquid SRB at Leviathan Mine treats up to 16 gpm of pH 4
water with relatively low concentrations of copper, nickel and
zinc (1 mg/l each), 100 mg/l of iron and 25 mg/l of aluminum.
The water from TP3 has a similar pH, but has higher average concentrations
of copper (21 mg/l), zinc (5 mg/l) and aluminum (30 mg/l) and
higher flows.
The study summarizes the geology and geochemistry of the Elizabeth
Mine and presented both a conceptual design for treatment on TP1
and TP3.
The conceptual plan for TP3 recommends an open limestone channel
(OLC) that flows to oxidation and settling ponds to remove iron
and aluminum, which lead to a liquid sulfate reducing bacteria
(SRB) system to remove heavy metals and a final step of aerobic
wetlands.
The conceptual plan for TP1 recommends an anoxic limestone drain
(ALD) leading to oxidation and settling ponds to remove iron and
aluminum and aerobic wetlands with an algal mat.
The study included a literature review of costs and an initial
cost estimates for both conceptual plans. TP1 has capital costs
of $268,500 and TP-3 has costs ranging from $1,400,000 to $1,700,000
for solid and liquid SRB’s respectively. Operation and maintenance
costs are estimated at $48,500 annually for TP1, and $120,000
- $132,000 for TP3.
General comments:
1. Most case studies did not address flows or chemistry that are
similar to E-Mine. Particularly waters with high iron and aluminum
concentrations and variable flows.
2. Many case studies reviewed were for pilot projects and/or short
periods of time and only reviewed systems using sulfate reducing
bacteria systems (either liquid or solid).
3. There were no reviews of case studies of other passive treatment
systems (ALD’s, SAP’s, OLC’s, wetlands etc.)
4. Conclusion on a strong recommendation of liquid sulfate reducing
bacteria systems (SRB) seems premature. The data is insufficient
to strongly recommend the technology. The literature referenced
note that SRB’s are not tested for large sudden changes
in load, flow, concentration and temperature (similar to E-Mine).
The liquid SRB is a semi-active system that requires alcohol and
sodium hydroxide at a combined cost of $1 for every thousand gallons
treated.
5. State of the practice review neglected to look at ‘aluminator’
flushing system, or constructed wetlands (combined aerobic and
anaerobic wetlands). There are gaps in literature review.
6. Oldest SAPS installed prior to 1991, have 12 years of data
or more, no reviews of long-term systems.
7. The “treatment train” approach taken in both conceptual
plans is a good one. Aluminum is easily precipitated by raising
the pH over 4.5, iron can be precipitated out by exposure to oxygen
if there is enough alkalinity to maintain a pH higher than 6.
These two metals are the major part of the load to the West Branch
of the Ompompanoosuc. The metals (copper, zinc….etc) can
be removed in wetlands, SAPS, ALD’s, SRB’s or by other
treatment methods.
8. Treatment recommendations for TP1 and TP3 do not agree with
the Figure 1 flow chart, based on flows and chemistry of E-Mine
(see below).
9. The chemistry and flows of the E-mine do not appear to support
the use of ALD’s. OLC’s may work for conveying water,
but will probably not do much for treatment due to the low slopes
and inability to flush. SRB’s, are best used after iron
and aluminum are removed from the flows. Initial treatment would
be with SAP’s and aluminators.
CONCEPTUAL APPROACHES FOR TP1 AND TP3.
The conceptual approaches to treatment do not agree with the flow
chart on Figure 1.
TP3
TP3 has water with lots of oxygen (DO >5 mg/l), flows of <200
liters per minute, pH of <4.5. Figure 1 would recommend an
anaerobic wetland or SAP’s for treatment based on this chemistry
and flow. Anaerobic wetlands require a larger land area for treatment
than SAPS.
There are problems with both the OLC’s and liquid SRB’s
recommended for this site. As URS states, OLC’s are best
on slopes of 45 – 60%, or according to the literature, slopes
that exceed 20% where suspended sediment can be kept in suspension
and precipitates flushed from the system to keep the limestone
from being armored. They do not provide treatment on slopes that
are less than 8%. Although some treatment occurs even when the
limestone is armored. Channel slopes and flows in the upper watershed
are not sufficient to allow the exposed limestone to self-scour.
The liquid SRB’s are microbial systems that have not been
tested for and have been found to fail with changes in flow, chemistry,
temperature and load as are found at the Elizabeth Mine. SRB’s
are a better technology for dealing with metal acidity (like from
copper and zinc), although they can treat iron and aluminum, there
are better technologies for removal of iron and aluminum.The changeable
flows and chemistry of TP3 and the flow chart do not seem to support
the conceptual plan for remediation.
TP1:
The conceptual plan for TP1 seems to address seeps only. Seeps
are a relatively small and steady flow, but the streams below
TP1 are a bigger problem, and during most months are the primary
source of loading to the WBOR. There is much more water and load
below TP1 than just the seeps. (If seeps are defined as small
seeps at base of TP1 with high concentrations of reduced iron,
low dissolved oxygen and relatively steady low flow).
WON'T DIVERSION GREATLY AFFECT THIS, REDUCING THE FLOW AND METAL
LOADING IN THE STREAM?
The plan for TP1 needs to address the major source of load. High
iron and aluminum are the primary contributors to acidity d/s
of TP1. Treatment downstream of TP1 will probably need to treat
relatively large volumes of water with high concentrations of
dissolved oxygen, iron and aluminum. It is critical that the design
address variable flow, as well as varying load, chemistry and
temperature. The dissolved oxygen concentrations in streams below
TP1 were quite high (over 8 mg/l). The installation of channel
diversions, the horizontal drains at the base of TP1 and the removal
of the pond on TP1 will effect both the chemistry and flow of
the surface water downstream of TP1. Surface water flows will
be reduced, and the seeps could change chemistry due to reduced
residence time within the pile and reduced recharge because the
pond will be drained and a cap of some sort put on the pile. Both
flows and metal loading will be reduced by the three actions mentioned
(diversion, draining of pond, installation of horizontal drains.)
ALD’s function with anoxic water with dissolved oxygen concentrations
of <2 mg/l. The many small seeps at the base of TP1 are anoxic
and need to be collected without exposing to oxygen. ALD’s
are prone to clogging if aluminum concentrations exceed 25 mg/l
and can clog with even very low aluminum concentrations (1 mg/l).
Skousen states: “Longevity of treatment is a concern for
ALD’s especially in terms of water flow through the limestone.
If appreciable dissolved iron and aluminum are present, clogging
of limestone pores with precipitated Al and Fe hydroxides has
been observed. The maximum alkalinity that ALD’s can generate
is about 300 mg/l” The groundwater seeps at the base of
TP1 had a measured acidity of 1900 mg/l in calcium carbonate equivalents.
ALD’s are likely to clog with this chemistry, and not function
well because of the high acid neutralizing capacity required.
At the Elizabeth Mine, ALD’s do not have the capacity to
generate enough alkalinity to treat the flows. Acid mine drainage
(AMD) that does not contain high concentrations of iron and aluminum
can be effectively treated with ALD’s.
Figure 1 recommends open limestone channels for this location,
but this is not appropriate technology due to usual lack of high
enough flows and the low slopes.. Figure 1 recommends anaerobic
wetland or SAPS as treatment alternative for chemistry of streams
downstream of base of TP1.
CHANGES IN CHEMISTRY/FLOW
It is important to remember that the chemistry and flow will change
with the removal of the pond, the installation of the horizontal
drains in TP1 and the construction of diversion ditches. Upon
removal of pond, more iron will stay in suspension in the stream,
as it will not be able to precipitate out into the pond. The proposed
systems should be designed for the flows and chemistry specific
to the area. Diversion is the first step that will change flows
and chemistry.
ECONOMICS
Economics should be re-worked with appropriate designs for each
area. The selection of treatment systems is not consistent with
Figure 1 on the basis of the chemistry and flows of the E-mine.
Capital costs are low for the seeps at TP1 (unless it is only
to treat seeps immediately at base of TP1 and not surface water).
The semi-active treatment system proposed for TP3 is very expensive.
Figure 1 recommends SAP’s or anaerobic wetlands. Capital
costs using SAPs as part of treatment trains for TP1 and TP3 were
calculated in 1999 and found to be $750,000 $950,000 with estimated
annual operation and maintenance costs of $11,000 $17,000 for
TP1 with a design flow of 125 gpm. TP3 had capital costs of $245,000
$299,000, with estimated annual operation and maintenance costs
of $4,000 $8,000 For tp3 with a design flow of 35 gpm and design
lives of 20 years. These costs are in 1999 dollars and would need
to be updated with changes in both design, and capital and O and
M costs.
The cost estimates in the report are for systems that are inappropriate
according to Figure 1 of URS’s report. They should be refined
as design is refined.
MISSING INFORMATION
Two passive treatment systems were not reviewed:
1) Constructed wetlands that combine both aerobic and anaerobic
treatment
The Canadian literature review that was referenced examined constructed
wetlands. Constructed wetlands combine both aerobic and anaerobic
processes. In the aerobic portion, they remove metals either by
precipitation, attachment to another compound or exchange with
another compound (one ion replaces another on a molecule). In
the anaerobic portion, sulfate reducing bacteria and chemical
and micro-biological activity in the underground limestone beds
are used to reduce acidity.
2) A design that combines the use of successive alkalinity producing
systems (SAPs) with a flushing system to remove precipitates from
the system called the “aluminator” by the designer
of the SAP’s (Kepler and McLeary).
SAPs are intended to generate alkalinity and increase pH. SAP’s
treatment is in an anaerobic environment. Iron is removed in a
downstream oxidation and settling pond. Aluminators© are
similar to saps, but intended to precipitate the aluminum within
the limestone of the (modified SAPs). The periodic flushing of
the aluminum precipitates from the system will keep the SAP from
being plugged. Experience in Oven Run, Pennsylvania shows that
“Long duration, high volume flushing performed on a regular
schedule has maintained hydraulic conductivity through the Oven
Run Site F system. The system has continued to produce high quality
water since construction” (Milavec and Seibert, 2002). The
use of SAP’s combined with an aluminator, or similar system
to remove precipitated metals should be reviewed. The literature
review mentions the need for quarterly flushing, but says initial
monitoring should be done during the first year to determine the
operation and maintenance schedule.
CASE STUDIES OF SAPS/ALUMINATOR
Although the literature reviewed contained case studies of SAP’s
from the references (Skousen), this was not mentioned in the report.
A 2003 paper by Damariscotta, the inventor of SAP’s was
not referenced in URS’s review. It is available on-line
and was presented at the 2003 West Virginia Surface Mine Drainage
Task Force Symposium and contains information on treatment effectiveness
of SAP’s/Aluminator combination treatment systems . The
following two tables were excerpted from that paper and characterize
results from two different mines with flows and chemistry somewhat
similar to the E-mine.
| Table 1. Coal Run Treatment
System Characterization. Design flow; 300 gpm |
| |
|
|
|
|
|
| Sample Point |
pH¹ |
alkalinity² |
acidity² |
iron³ |
aluminum³ |
| Raw4 |
2.8 |
0 |
400 |
50 |
40 |
| Raw5 |
3.2 |
0 |
220 |
20 |
15 |
| Aluminator© |
6.2 |
55 |
75 |
18 |
2 |
| Settling Basin |
6.1 |
30 |
40 |
1.5 |
0.8 |
| SAPS |
7.1 |
65 |
0 |
<0.3 |
<0.2 |
| Final Discharge |
7.0 |
60 |
0 |
<0.3 |
<0.2 |
| |
|
|
|
|
|
| 1s.u.;
2as mg/L CaCO3; 3total mg/L; 4design
values; 5more recent quality developed from additional mine
drainage treatment in the watershed |
| Table 2. Metro (M1) and (M2) Treatment System
Characterizations |
| |
| Sample Point |
pH¹ |
alkalinity² |
acidity² |
iron³ |
aluminum³ |
| M1 Raw |
2.8 |
0 |
1,300 |
270 |
90 |
| M1 Aluminator© |
5.8 |
90 |
240 |
140 |
20 |
| M2 Raw |
2.7 |
0 |
1,400 |
290 |
110 |
| M2 Aluminator© |
5.8 |
100 |
410 |
170 |
25 |
| |
| 1s.u.; 2as
mg/L CaCO3; 3total mg/L |
The Metro was designed for flows of 30 gpm, but treats flows of
up to 200 gpm.
Earlier SAP’s systems were reviewed by Skousen and are found
in the appendices of URS’s report
“A 1022 m 2 surface flow wetland was constructed in KY to
treat 37 L/min of AMD with a pH of 3.3,acidity of 2280 mg/L as
CaCO 3 , Fe of 962 mg/L, Mn of 11 mg/L, and Al of 14 mg/L (Karathanasis
and Barton 1997). After construction in 1989, metal concentrations
in the effluent were reduced during the first six months of treatment,
however, the system failed thereafter due to insufficient wetland
area and metal overloading. In 1995, a two-phase renovation project
began incorporating the use of an ALD, and a series of anaerobic
drains that promote vertical flow through limestone beds overlain
by organic compost (much like a SAPS). Results to date indicate
a pH of 6.4, slightly net alkaline water (15 mg/L as CaCO 3 ),
Fe reduction of 96%, Mn removal of 50%, and Al by 100%.
Kepler and McCleary (1994) reported on initial successes for three
SAPS in PA. The Howe Bridge SAPS reduced acidity from 320 mg/L
to 93 mg/L as CaCO 3 , and removed 2 mg/L ferric iron. The REM
SAPS decreased acidity from 173 to 88 mg/L as CaCO 3 , and exported
more ferrous iron than entered. The Schnepp Road SAPS decreased
acidity from 84 to 5 mg/L as CaCO 3 , but removed all 19 mg/L
ferric iron, with only 1 mg/L ferrous iron exiting the wetland.
Kepler and McCleary (1997) reported the use of SAPs in OH, PA,
and WV. In all cases, Al in AMD precipitated in their systems.
Their drainage design incorporates a flushing system called the
'Aluminator' (Picture 10). This allows for the precipitated Al
to be flushed from the pipes thereby maintaining hydraulic conductivity
through the limestone and pipes. One SAPS, Buckeye, received 3
L/min of very acid water (pH of 4.0, acidity of 1989 mg/L as CaCO
3 ), Fe of 1005 mg/L, and Al of 41 mg/L. Over a two-year period,
the effluent had a pH of 5.9, net acidity concentration of about
1000 mg/L, Fe of 866 mg/L, and <1 mg/L Al. A second site, Greendale,
treated a 25-L/min flow, and increased the pH from 2.8 to 6.5,
changed the water from a net acid water (925 mg/L as CaCO 3 )
to a net alkaline water (150 mg/L as CaCO 3 ), Fe from 40 to 35
mg/L, and Al from 140 to <1 mg/L.”.(Skousen)
SAPs and Aluminator combinations have been designed for variable
flow 4 – 9000 gpm and 5 – 6000 mg/l of acidity with
flows of 130 gpm.
SAPs require less residence time than anaerobic wetlands (they
can be sized smaller). Iron concentrations are still high as water
exits the SAP. Settling pond(s) downstream of the SAP can be used
to remove iron and aluminum precipitates
Vertical flow ponds are essentially an imitator of a SAP. Some
of the systems reviewed were poorly designed vertical flow ponds.
One of the systems reviewed by Demchak et. al, was subsequently
dug up, the compost layer 12 years into a system designed with
a 15 year design life was found to be intact. The designers of
SAP’s have found that systems that were 60% or 100% effective
10 years ago have the same removal capacity if they are maintained
properly. Kepler and McCleary have reported on over 100 SAPS systems
that they have installed. They say it is critical to use the Aluminator
to flush the system where aluminum is present, and to install
flow controls to adjust for variable flow.
SETTLING PONDS AND AEROBIC WETLANDS
All of the systems designed to date include settling ponds. The
EMSG study includes aerobic and anaerobic wetlands, and URS recommends
aerobic wetlands and SRB’s which are essentially anaerobic
wetlands. The use of both of these technologies is well documented.
Iron precipitates out upon exposure to oxygen. The settling ponds
allow a large enough area for the velocities to slow down, the
water to oxidize, and a still enough environment (a pond) that
will allow the iron to settle to the bottom. While the water is
in the settling pond the pH is increased and metals drop out.
Settling ponds can be used to remove iron prior to entry into
an anaerobic wetland or SAPS, and to remove iron from the effluent
of an anaerobic wetland or SAPS. This precipitate needs to be
cleaned out on a regular basis. Some work has been done in the
past on recycling these metals from the settling ponds, but no
information was given in the study about metal recycling. Pilot
studies on resource recovery from settling ponds have been undertaken,
but the results are not cited. The costs could be used to offset
O and M costs.
Aerobic wetlands do a lot of what settling ponds do, they allow
the iron to contact with the air and precipitate as metal oxides
and metal hydroxides. Settling ponds are better for large concentrations
of metals and aerobic wetlands are best for small concentrations
of metal. A down-side of aerobic wetlands is that they increase
acidity (decrease pH) when the available alkalinity is used up.
Most wetlands have both an aerobic and anaerobic component. The
Canadian study stated that wetlands that treat acid mine drainage
“will reach toxic levels much sooner [than constructed wetlands
that treat sewage waste], rendering their long-term applicability
(>100 years) doubtful.”
URS recommends algal mats. Algal mats remove dissolved metals,
but pass suspended metals. They require a back-up settling area
and do not function in winter when frozen.
