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Product
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| Graduate
Students |
Students trained in combustion technology are one of the most important
products resulting from the activities in ACERC. The students can
receive training in experimental and theoretical combustion research
from leading experts in combustion technology. These students go
on to be successful employees in a variety of combustion-related
industries, and provide one of the most effective means available
to transfer the technology developed in ACERC to industry. |
97-COSMO-GT
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A three-dimensional computer code specifically developed for the
simulation of gas turbine combustors. The chemical kinetics and
coupling of the turbulence and chemistry are incorporated through
a submodel for lean, pre-mixed combustion of natural gas (LEPRECON).
This approach is applicable for both premixed and non-premixed systems.
A mixing-limited, pdf approach to the chemical reactions is also
available for non-premixed systems. The flow field is solved in
an Eulerian framework using an unstructured, tetrahedral mesh. The
unstructured grid approach is well suited for simulation of the
complex geometries associated with gas turbines. The Control Volume
Finite Element Method (CVEFM) coupled with a variation of the SIMPLE
technique is used for solution of the resulting equations resulting
from discretization of the Navier-Stokes equations. |
96-FBED-1
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A generalized, one-dimensional, heterogeneous, steady-state analysis
and design tool that can be used to simulate a variety of fixed
or moving bed gasification, combustion, and devolatilization processes.
The model considers separate gas and solid temperatures, axially
variable solid and gas flow rates, variable bed void fraction, coal
drying, devolatilization based on chemical functional group composition,
oxidation and gasification of char, and partial equilibrium in the
gas phase. Plug flow is assumed in both the solid and gas phase.
A set of 44 highly non-linear, stiff, coupled ordinary differential
equations are used to describe the physical and chemical processes
occurring within the reactor. Options for partial or complete chemical
equilibrium are available. The code is written in FORTRAN 77, and
the source code is provided with a comprehensive usersmanual for
a one-time licensing fee. |
CPD
Model
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The Chemical Percolation Devolatilization (CPD) model describes
the devolatilization behavior of rapidly heated coal, based on the
chemical structure of the parent coal. The CPD model has been developed
to function either as a standalone code or as a submodel in a comprehensive
combustion code. It includes treatment of vapor-liquid equilibrium
and a crosslinking mechanism. The CPD model successfully predicts
the effects of pressure on tar and total volatiles yields observed
in heated grid experiments for both bituminous and lignite coals.
Predictions of the amount and characteristics of gas and tar from
many different coals compare well with available data. The code
is written in FORTRAN, and is available for free; however, no support
is available from ACERC on use of the CPD model. |
| SLW
Model |
A radiative property model for H2O-CO2
mixtures, which accounts for non-gray radiative transfer in gases
in an efficient manner. The Spectral-Line Weighted-Sum-of-Gray-Gases
(SLW) model predicts radiative transfer in high temperature gases
with accuracy approaching that of much more costly line-by-line
techniques. The model may be applied using any arbitrary solution
method for the Radiative Transfer Equation (RTE), which requires
a locally defined absorption coefficient. The SLW model can be used
in multi-dimensional, irregular geometries where scattering must
be accounted for. The model has also been extended to high pressures.
The code is written in FORTRAN, and is available for a one-time
license fee, which includes the source code and a brief user's manual.
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Product
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