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Advancements
in bioreactor techniques call for similar improvements
in modeling skills.
By
Victor O. Okereke
The full
text of this article, along with additional supporting
data and graphics, may be found in pdf format by clicking
here.
The potential
utilization of landfill gas for the generation of electricity
and other forms of energy has been the subject of great
interest during the past decade. The economic viability
of a landfill gas-to-energy (LFGTE) project is mostly
dependent on a sustainable level of gas production over
the project life. A typical LFGTE project life is 20
years, which is
long after a landfill cell has ceased operating and
gas production in the cell has declined significantly
It has been well documented by many studies, including
Pohland (1975), that optimum moisture content and the
effectiveness its distribution in the refuse matrix
has the most impact on gas production and that the artificial
addition of moisture to landfills through leachate recirculation
increases gas production rates. Therefore, the retention
and distribution of optimum moisture contents in the
landfill through the duration of an LFGTE project might
improve the economic viability of the project. Additional
effects of increased moisture content include increases
or decreases in leachate generation and accelerated
refuse stabilization rates that might help extend landfill
life and reduce postclosure liability costs.
Significant
monetary and other resources continue to be invested
in pilot and full-scale bioreactor studies. A bioreactor,
when fully operational, will provide a dynamic system
for optimum utilization of the beneficial effects of
leachate recirculation. The Solid Waste Association
of North America defines a bioreactor as “any
permitted Subtitle D landfill or landfill cell where
liquid or air is injected in a controlled fashion into
waste mass in order to accelerate or enhance biostabilization
of the waste.” This technology relies on liquids’
addition to achieve optimal moisture content of approximately
40-45% (McManus, 2002). According to a United States
Department of Energy survey, LFGTE projects currently
utilize about 10% of the potential LFG in the US, and
it estimates that the application of the controlled
bioreactor technology to 50% of the waste currently
being landfilled could provide more than 270 billion
ft.3 of methane gas per year to meet about 1% of the
electrical energy needs in the US (McManus, 2002).
The full
utilization of the benefits associated with bioreactors
is currently limited due to the difficulty in determining
the quantitative relationships between the key variables
that influence gas and leachate production, optimum
operating conditions, and the variables that control
the biochemical processes in landfills. Although gas
and leachate are produced simultaneously during biochemical
degradation reactions and moisture redistribution in
landfills and, in addition, the management of leachate
account for a significant portion of landfill operating
costs, the planning of LFGTE projects mostly rely on
gas projections with gas-only simulation models. Opportunities
for applying controlled bioreactor technology or leachate
recirculation are not commonly considered during process
planning and design of LFGTE projects. This model is
designed to allow for the cost-effective assessment
of this option.
The model discussed in this paper is an efficient tool
for the concurrent simulation of leachate and gas. The
model is significant as a cost-effective tool for evaluating
the economic viability of LFGTE projects with the application
of leachate recirculation; determining the optimum operating
conditions of a leachate recirculation facility or bioreactor,
which enhances the economic balance sheet of an LFGTE
project; and the assessment of the range of economic
benefits attainable for a broad range of leachate recirculation
rates or economic conditions.
Modeling
Approach
The model
is a one-dimensional, quasi-two-phase continuous simulation
model and is divided into two principal submodels for
engineering and economic analysis. The engineering submodel
is composed of four modules for simulating climatological
conditions, leachate and gas generation, and leachate
recirculation. The second submodel performs the economic
feasibility analysis for a specified LFGTE project with
the utilization of variable leachate recirculation regimes.
The growing
acceptance of bioreactor landfills adds urgency to a
need for better information on LFG generation. This
in turn establishes the requirement for improved modeling
techniques that will allow owners, operators, and designers
to anticipate system requirements as well as the economic
potential of these resulting increases in gas production.
References
McManus,
T. and T. Hanlon. “Strategy for Municipal Solid
Waste Landfills.” Proceedings of the 7th Annual
SWANA’s Landfill Symposium. Louisville, KY, June
17-19, 2002.
Pohland, F.G. “Sanitary Landfill Stabilization
with Leachate Recycle and Residual Treatment.”
USEPA Report No. EPA/600/2-75/043. Cincinnati, OH. 1975.
Guest
author Victor O. Okereke, Ph.D., P.E. is seniro engineer
with King County Solid Waste Division in Seattle, WA.
MSW
- July/August 2003
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