|
Once
again MSW Management is proud to pay tribute to SWANA’s
Landfill Excellence Award winners.
By
John Trotti
Gold Award:
Outer Loop Recycling and Disposal Facility, Louisville,
KY
For approximately
35 years, the Outer Loop Recycling and Disposal Facility
(Outer Loop) has served as a solid waste disposal site.
Located in Jefferson County, Louisville, KY, approximately
9 miles south of the Kentucky-Indiana state border,
the facility consists of seven individual and separate
landfill units (designated as Units 1 through 7). The
combined waste footprint is 390 acres and the total
facility area is 782 acres. Outer Loop has been owned
and operated by Waste Management of Kentucky LLC (WMK),
a subsidiary of Waste Management Inc. (WMI), since 1984.
Units 1 through
3 and Unit 6 are filled and final-capped. Unit 4 is
permitted as a construction/demolition debris landfill
and is active. Units 5 and 7 are permitted as contained
landfills and are active.
The site
also incorporates a 455-acre wetlands mitigation and
banking area, a 40,000-ton-per-year composting operation,
a landfill gas-to-energy facility, a sequential batch
reactor (SBR) leachate treatment plant, and a petroleum-contaminated-soil
treatment area. The design, construction, and operation
of this facility exceed industry standards.
The area
surrounding Outer Loop is a mix of dense industrial
to the north and northwest, commercial businesses to
the northwest and southwest, a railroad yard to the
west, residential and commercial buildings to the south,
and Interstate 65 to the east. There are no known groundwater
users within a 1-mile radius of the facility, or any
known springs, water supply wells, or water intakes
within the vicinity of the site.
Waste materials
accepted at Outer Loop include municipal solid waste,
construction demolition and debris, special waste, nonhazardous
solidified liquid/sludge and petroleum contaminated
soil. Between 600 and 700 vehicles deliver an average
waste flow of 5,500 tons per day from the Louisville
metropolitan area and 22 surrounding counties in Kentucky
and Indiana. It is the largest operating Subtitle D
landfill in Kentucky, and provides waste disposal service
for residential, commercial, and industrial customers.
As of March
2005, Outer Loop has about 40.9 million cubic yards
of remaining gross airspace. At an anticipated disposal
rate of 1 million tons per year, the landfill has about
35 years of total remaining permitted disposal capacity.
With the use of bioreactors in new cells it is thought
this will expand to at least 40 years.
Daily site
operations at Outer Loop are the responsibility of the
landfill operator/manager, Rick Barr. He is supported
by other state-licensed operators and managers including
Kevin Brown, Chad Abell, Dave Dunn, and Charles Dyer.
Kevin Mieczkowski is responsible for the composting
facility operations.
Bioreactor
Research
Outer Loop is the site of an on-going multi-year
bioreactor research project conducted by WMI, in collaboration
with the EPA, through a Cooperative Research and Development
Agreement (CRADA), and the Kentucky Department of Environmental
Protection (KDEP). The facility was selected because
of several favorable characteristics, including adequate
acreage and working space, average US climatic conditions,
permit conditions, and the opportunity for coordination
with other agencies. Filling activities in the bioreactor
cells commenced in 2001.
The landfill
research project is both unique and significant due
to its examination of emerging technologies with testing
and research variables at the field-scale level.
There are
currently two bioreactor studies and one biocover study
being conducted at Outer Loop. These include
- The “retrofit”
Facultative Landfill Bioreactor (FLB) study—being
performed within a 47.7-acre area within the western
part of active landfill Unit 5. Waste in these cells
is 4 to 5 years of age.
- The “as
constructed” Aerobic-Anaerobic Bioreactor (AALB)
study (patent number US6,283,676,B1)—being performed
within active Unit 7
- The Biologically
Active Landfill Cover (BALC) study—being performed
in Units 5 & 7.
The FLB study
evaluates the feasibility of controlling ammonia in
leachate by injecting nitrate-containing leachate. This
is important in that elevated ammonia requires treatment
before discharge to the environment or a treatment plant.
It is the only project of its kind in the US.
The FLB Study
objectives are to measure under field-scale conditions
(1) the effect that adding nitrate-containing leachate
to existing landfill waste has on the rate and extent
of waste stabilization and the nitrogen cycle, (2) the
extent that denitrification occurs in the landfill environment,
and (3) the impact that operating an FLB has on atmospheric
emissions.
Facultative
Bioreactor Test Cells
To facilitate the FLB study, Unit 5 was designed
and constructed with the approval of the Kentucky Department
for Environmental Protection (KYDEP) and the EPA. The
design and construction of Unit 5 was uncommon when
compared to the traditional Subtitle D landfill and
posed unique advantages and difficulties to overcome
during the FLB Study, as summarized below.
- The SBR
for removing the ammonia was about 1 mile from the
test cells and four easements had to be acquired prior
to construction.
- The site
contains asbestos, and special care had to be taken
during construction and drilling.
- While
the property is around 47 acres, only about 8 acres
are at level ground. Much of the trenching had to
be put on the slopes. Because of this, the trenches
had to be very deep to prevent liquid breakouts.
- Discharge
of the SBR is a batch process that happens infrequently,
but over a relatively short period of time.
Six vertical
gas extraction wells were constructed in the cells.
The gas wells serve the dual purpose of collecting landfill
gas and penetrating layers of soil cover placed during
landfilling. Probes for measuring waste moisture, oxidation-reduction
potential, and landfill gas were installed during gas
well construction. Similar installations were made for
the control cells located in Unit 7, Cell 3A, and Unit
7, Cell 3B. After treatment in the SBR, leachate is
distributed into the tanks on top of Unit 5 and then
by gravity into the array of trenches.
Preliminary
FLB Results—To date, an average of 50,000 gpd of
liquid can readily be added to the retrofit bioreactor.
The site has experimented with adding as much as 100,000
gpd and is also able to take experimental commercial
liquids from off the property. WMI believes this is
very unique in the solid waste industry.
This bioreactor
process involves specialized construction and management
techniques for measuring and controlling the amounts
of water and air in the landfill, as well as extensive
data collection and analysis.
Innovation
and Creativity
Outer Loop is one of only a handful of US
landfills conducting concurrent full-scale operations
and research and development. The WMI bioreactor program
is recognized as setting a standard in the landfill
industry and the Outer Loop site is where most of the
WMI research is taking place. Just to recap, Outer Loop
research and study efforts include
- Accelerating
the methane generation so as to make the LFG energy
from solid waste more available than would otherwise
be the case with conventional LFG collection.
- Reducing
uncaptured, fugitive air emissions associated with
landfills through trial covers, including leaf/mulch
compost.
- Achieving
stable landfill conditions more quickly than conventional
means, particularly prior to closure.
- Reducing
global warming by beneficially using the collected
methane and reducing fugitive emissions.
- Extending
the lifespan of the existing landfill cells without
increasing their size.
In addition,
Outer Loop’s project is already delivering economic
and waste recycling benefits. Several landfill cells
have re-used well over a million shredded waste tires
in trials as leachate collection media. Increased landfill
gas generation is captured with onsite wells delivering
a total of more than 1.1 trillion cubic feet of gas
to GE’s Appliance Park Facility, where the LFG
is used in place of conventional fuels to provide steam
and heat. Landfill gas is also being sent to nearby
Gohman Asphalt, which is currently using the LFG as
its primary fuel.
Clearly,
the most unique aspect of the site is working for the
last four years with the EPA under the CRADA, as discussed
previously. This cooperative approach ensures that the
resultant research and data will be released to the
landfill industry and be realized as a public benefit.
In addition,
the progress of this research has been reported at several
SWANA symposiums, and the respective SWANA technical
division members (i.e., Landfill Management and Landfill
Gas Management) are tracking and evaluating this progress.
Not only are the Outer Loop research concepts timely,
they each have the potential to make landfills more
environmentally protective and operationally efficient
in the future. The Outer Loop facility also provides
an example for the industry on how to conduct needed
research at the field-scale and demonstration-scale
while operating a large landfill site.
As Kentucky
and other states face the challenges associated with
the cleanup and remediation of old abandoned landfills,
bioreactor landfill technology like that being pioneered
at Outer Loop may provide a key to promoting improved
solid waste design and disposal techniques for yesterday’s
and today’s landfills—offering significant
environmental and economic benefits in the years to
come.
Silver
Award:
Hartland Landfill, Victoria, BC
Hartland landfill is owned and operated by
the Capital Regional District (CRD) and is located about
14 km northwest of Victoria. It is the only solid waste
disposal facility in the Capital Region, serving 340,000
people. Hartland receives about 140,000 tons of municipal
solid waste per year. The operation is a multi-purpose
facility providing recycling, HHW collection, a salvage
area, yard and garden waste collection and processing,
and controlled waste disposal and landfill service to
commercial and residential customers. Since 1985, over
$30 million has been invested in capital works, environmental
controls, and general site improvements, and the site
is now run as a state-of-the-art facility.
Hartland
has two phases: Phase 1 is closed, having received 4.5
million m3 of refuse, and Phase 2, with a capacity of
10 million m3, is expected to last until 2048. Phase
1 closure took place in 1997 and consisted of an impermeable
engineered cover designed to control surface water runoff
while preventing further production of leachate. Phase
2 has been designed with a unique leachate management
concept specific to the hydrology of the area. The bottom
of the Phase 2 area is a former lake basin that acts
as a sump with an inward flow of ground and surface
water. Leachate is collected in the sump and drained
through a microtunnel to the lower leachate lagoon.
The water table surrounding the basin is naturally higher
than that of the sump, forming a hydraulic trap ensuring
leachate is contained within the basin area. An extensive
groundwater and surface water monitoring program costing
$400,000 per year is in place to ensure no leachate
exits the site.
A comprehensive
landfill gas collection and disposal/utilization facility
manages 650 scfm of landfill gas. The system consists
of a collection network, 115 horizontal and vertical
wells, a ground flare, and a 2-MW utilization facility
commencing operation in 2004. There is a potential recovery
rate of between 1,600 scfm to 1,800 scfm in the future.
Gas collection and utilization costs are in the order
of $5 million.
Ongoing short-
and long-term planning is essential, considering that
the $12 million revenue generated from tipping fees
supports the programs of the entire solid waste division.
Financial modeling is used to assess the impact of waste
diversion programs on the division and disposal fees
are adjusted accordingly to ensure that long-term stability
and appropriate levels of service are maintained. Along
with financial planning, program performance indicators
are tracked to ensure that the entire divisional operation
is cost-effective. The CRD solid waste function is the
only agency in British Columbia that has zero requisition
for all solid waste activities.
A public
outreach program promotes community relations with the
neighbors around the landfill and educates the community
at large about solid waste operational and diversion
practices. This outreach program—including a good
neighbor policy, site tours, and environmental education—forms
part of the division’s information strategy.
Site
Development
Hartland landfill has grown to be a multi-purpose
facility providing service to residential and commercial
customers. In addition to the landfill there are four
distinct areas: (1) recycling and household hazardous
waste drop off, (2) yard and garden waste disposal,
(3) residential refuse bin drop off, and (4) controlled
waste disposal. There are also facilities that support
the administrative function of the operation such as
a weigh scale, administration office, and various operations
buildings.
Controlled
wastes are those that, because of their inherent nature,
need to be handled in a controlled manner and away from
the other disposal areas. These include liquids, animal
carcasses, solids, semi-solids, special waste (asbestos),
and contaminated soil. Customers require an appointment
and a permit to deliver these wastes, which a landfill
attendant monitors. The area is constructed of clay
cells on top of the landfill and receives about 3,000
tons of waste per year.
The landfill
has been developed as two operational areas, Phase 1
and Phase 2. Phase 1 is now closed and Phase 2 began
operating on April 30, 1997.
The Phase
1 area was the original landfill of approximately 20
hectares and had been in operation since the early 1950s.
The site was not an engineered landfill and “just
happened” like many dumps. Recognizing the significant
impact of a site of this nature, steps were taken beginning
in 1984 to put in place environmental controls.
The Phase
1 landfill was closed in 1997 with an engineered cover
consisting of aggregates, compacted clay, a PVC membrane
and a topsoil layer. The cover system was designed to
control surface water runoff while preventing the further
production of leachate.
The Phase
2 landfill is an area of about 30 hectares, partially
overlapping Phase 1, with a capacity for approximately
8 million tons of refuse. Originally, Phase 2 consisted
of a 2.5 hectare lake, which was drained, excavated,
and prepared for landfilling. The area surrounding the
basin is rugged with rock outcroppings and steep side
slopes, which by its very nature promotes an inward
flow of surface water toward the basin.
The overall
long-term site-filling plan requires approval by the
MWLAP. Approval was initially granted in 1987 and has
been updated and approved subsequently to include Phase
2. The filling plan firmly establishes the site footprint
and projects capacity to approximately 2048; subject
to the effectiveness of the region's waste reduction
programs on volumes.
A site rehabilitation
plan began in 2004, which will blend the site into the
surrounding forested area. The end-use will be for an
open space/park which will be available after the operational
uses have ended (i.e., post-closure monitoring).
A significant
landfill gas collection, monitoring, and disposal/utilization
program is underway at the Hartland site. LFG production
at Hartland landfill (Phase 1 and Phase 2) is estimated
to peak at approximately 2,200 scfm with a recovery
potential of between 1,600 scfm to 1,800 scfm. A public/private
partnership has been undertaken to develop a gas-to-electricity
plant. This project is complete and presently being
commissioned. The contractor undertook to construct
and operate a landfill gas utilization facility by using
the gas produced in the landfill. The contractor will
pay the CRD a royalty for the energy produced. At the
present time, the plant will produce 1.6 MW of electricity,
which will be sold to BC Hydro. That is enough energy
to supply about 1,600 homes.
Site
Operations
This work is administered and designed by
the CRD and its consultants, and tendered to/constructed
by private contractors. The daily site operation, landfill
repairs, and maintenance work are tendered to private
contractors.
The landfill
operation is divided into two main contracts; the contract
to place and compact the municipal solid waste (MSW)
received daily and the contract to haul refuse and recycling
bins onsite and off-site. At present, the contract to
place and compact refuse is about $650,000 per year
and the roll-off bin haul contract is approximately
$220,000 per year.
Standard
refuse is typically landfilled using the advanced terrace
method. This technique enables control of surface runoff
and leachate flow, as well as control of long-term site
settlement. It consists of an advancing active face
with vehicular access atop the preceding day’s
refuse. Alternatively, depending on site conditions,
refuse will be deposited at the toe of the active face
and pushed up to the desired elevation. The active face
advances in four meter lifts and all refuse is covered
daily with aggregate on the horizontal and sloping surfaces.
A synthetic tarp serves as nightly cover on the active
face.
A supervisory
control and data acquisition system (SCADA) is in place
to monitor the leachate management system. Leachate
levels, pumping cycles, purge well levels and some groundwater
levels are continuously monitored and operated.
The system
is fully automated and a computer with real-time read-outs
is available to office and operations staff to ensure
the system is operating as designed.
Site
Rehabilitation and Reforestation
A long-standing vision for Hartland landfill
is to restore the land to a condition that will blend
in naturally with the surrounding forest. A plan has
been developed that proposes installing a growing medium
over the existing cover system and planting a broad
variety of native species of overstory and understory
vegetation and ground cover, to provide a self-sustaining
natural ecosystem.
Planting
began in 2004 and includes Douglas fir, bigleaf maple,
and arbutus, as well as ocean spray, Indian plum, and
mock orange (all which are native to the area). Over
the course of five years, the entire Phase 1 area (approximately
10 hectares) of the Hartland site will be rehabilitated.
Over 1.4 meters of topsoil has been placed over the
cover material and membrane to allow for root growth.
In addition
to this rehabilitation, the Phase 2 area, which is under
landfill construction, is being progressively closed
as much as possible to enhance landfill gas collection,
reduce surface water infiltration (leachate production),
and to provide a higher degree of aesthetics. These
programs are funded through the annual operating budget.
Bronze
Award:
Cedar Hills Regional Landfill, King County, WA
The Cedar Hills Regional Landfill is located
near Maple Valley, WA, approximately 25 miles east of
Seattle. King County owns the landfill, which disposes
of solid waste from all of King County outside of the
City of Seattle. Currently, the landfill accepts approximately
3,500 tons per day of municipal solid waste. The site
encompasses 940 acres, with 452 acres of interior permitted
waste fill area. Waste filling began in an unlined area
of the site in the 1960s. In 1985, King County constructed
the first composite-lined expansion area with leachate
collection. The construction of the area was well ahead
of landfill lining and leachate collection requirements
imposed by the RCRA Subtitle D regulations of 1991.
King County Solid Waste Division (KCSWD) personnel operate
the landfill and all of its environmental control systems,
including the landfill gas collection system.
 |
| Cedar
Hills Regional Landfill,, King County, WA |
The development
of the Cedar Hills Regional Landfill has been planned
as a series of large expansion areas, or cells, each
designed to provide several years of filling capacity.
Surface water runoff is uniquely managed at the site.
The layout of the landfill is designed so that surface
water runoff from landfill areas that have received
final or interim final covers drain to four permanent
detention ponds. An additional temporary stormwater
detention pond is also constructed with the development
of each new cell.
Beginning
in the early 1980s, environmental protection was established
as a priority at the Cedar Hills Regional Landfill.
King County understood the importance of taking all
reasonable precautions to prevent groundwater contamination,
and effective measures were taken to reduce or eliminate
the impacts of past practices on groundwater quality.
An example is the improvements made to the “Central
Pit,” a 2.1.1-acre (final cover surface) expansion
area of the Cedar Hills Regional Landfill. The improvements
were designed in expectation of the requirements of
WAC 173-304 promulgated in 1984 and enacted in 1986.
In 1985, KCSWD constructed a composite lining system
(plastic membrane underlain by low-permeability soils)
in the Central Pit area. Although earlier parts of the
landfill were unlined, the new area in 1985 would be
closer to groundwater. Therefore, as final cover was
placed over the earlier parts of the landfill, the composite
lining was installed in the Central Pit. All successive
expansion areas of the landfill since that time have
had RCRA Subtitle-D-compliant lining.
Over the
years, King County has proactively remediated a number
of issues by investing in a large number of improvement
projects.
Landfill
Monitoring and Inspection Program
KCSWD has a trained staff of four full-time
technicians who are responsible for monitoring, inspection,
and operation of the environmental control systems at
the landfill.
The landfill
gas system technicians have implemented an aggressive,
day-to-day preventive maintenance program. Inspections
occur during monitoring sessions as well as during scheduled
quadrant inspections.
The Cedar
Hills Regional Landfill gas collection system has (at
present) nearly 500 landfill gas collection and control
stations. It consists of 276 horizontal gas collectors,
108 vertical gas collectors, 29 migration control vertical
wells, and 84 leachate control gas connections
A network
of 19 down-gradient wells and 22 up-gradient wells is
used to monitor groundwater. An aggressive approach
to landfill gas control has prevented lateral gas migration.
KCSWD also monitors ambient air and has a complete meteorological
station at the site. The Nasal Ranger program is used
to monitor odor. KCSWD hired an olfactory certification
consultant—Nasal Ranger Inc.—to train all
supervisors and leads and landfill gas operators to
recognize odors and evaluate the source and concentration
levels of reported and detected odors. Design of modifications
to the existing gas collection system to provide gas
to the generating plant is under way.
Progressive
Cover Program
KCSWD has adopted a program of placing
interim cover over all areas that will not have final
cover immediately installed and will not be covered
with additional waste lifts during wet weather months
(October through May). This program reduces water infiltration
into the landfill and minimizes gas emissions and air
breakthrough into the gas extraction system. Final cover
is placed progressively as final fill elevations are
reached in each cell.
KCSWD has
recently implemented a regular Compaction Control Program
for monitoring the compaction of recently placed waste
in the landfill. This is done through monthly measurement
of compaction densities achieved, and adjusting operating
practices as necessary to ensure consistency in the
resulting densities. In addition, annual evaluation
of effective density is completed using aerial photogrammetric
and land survey data. The tonnage placed in a defined
area, as recorded at the scales and tracked to the working
face, is compared to the fill volume in the defined
area. The compaction results are provided to disposal
equipment operators to provide feedback on performance
of ongoing operating methods with a goal of optimizing
landfill airspace consumption.
Up-To-Date
Technology
KCSWD is an earlier adopter of new landfill
technology where the new technology makes economic sense.
One example is the Supervisory Control and Data Acquisition
(SCADA) system that monitors processes at the landfill
as well as at the county’s transfer stations and
closed landfills.
ECS Engineering
Inc., of Bothell, WA, was responsible for the investigation,
study and master plan preparation for the new countywide
SCADA system for the KCSWD. The project goal was to
develop a SCADA system that would allow staff to monitor
sites throughout the Cedar Hills Regional Landfill,
remote landfills, and transfer stations for process
and security alarm conditions.
Subsequent
to the investigation, ECS Engineering worked with the
County Information Technology and Communications Departments
to investigate communications options to all of the
sites. The plan recommended using an existing countywide
fiber optic and telephone Ethernet network for most
of the locations that needed to be monitored. The remainder
of the sites were provided with Ethernet radios, which
allowed connection of remote sites to the existing network.
The resultant
system configuration recommended to the county is a
programmable logic controller-based system, communication
over the Ethernet network to a master SCADA computer
utilizing operator interface software for data gathering,
report generation, alarm generation, and graphic screens
for information display. The system has new Allen-Bradley
PLCs and a Graphical User Interface/Data acquisition
system software. Technical Systems Inc. was the prime
contractor and SCADA system hardware supplier.
To monitor
all facilities from the Cedar Hills facility, the master
SCADA computer communicates with the remote facilities
(transfer stations and closed land fills) over a combination
of the county’s existing Ethernet network, cellular
telephone modem, or leased telephone line. The type
of communication selected depended on the most economical
(initial and life cycle) option. Specifically, at Cedar
Hills all of the potable water pumps, gas flares and
blowers, and monitoring sensors in the leachate, stormwater,
and gas systems are monitored by a SCADA system that
transmits data to the site office through a fiber optic
network installed around the landfill perimeter. This
network is accessible throughout King County’s
Ethernet, including at offsite county offices.
MSW
- September/October 2005
|
