Gas turbines engine determination in act

PARISUTHAM INSTITUTE OF TECHNOLOGY
& SCIENCE
CONFCALL’19
DEPARTMENT OF AERONAUTICAL
DESIGN AND ANALYSIS OF COMBUSTION
CHAMBER IN A GAS TURBINE ENGINE
BATCH MEMBERS
C.Keerthana
D.Preethi

ABSTRACT
• The paper deals with the design of a combustion chamber
in a gas turbine engine and it has to be designed based on
the constant pressure, enthalpy process. The approach
deals with the computation of the initial design parameters
of the combustion chamber. New computational analysis
method are continuously developed in order to rectify the
problems occur in gas turbine and the various analytical
configuration of the combustor has to be calculated based
on different realistic formulas. The air-fuel mixture,
combustion turbulence ,thermal and cooling analysis is
carried out. The computational analysis of combustion
chamber performed at various scenarios and compared by
using k-€ Turbulence tool in ANSYS CFX software.

• Gas turbines are preferred over new crucial movers
for power generation due to its low specific fuel
consumption. The gas turbine power plants and
steam turbine bottoming cycle are used as co-
generation technique for refining overall efficiency of
the plant. Hence combustion chamber of gas turbine
should provide obligatory chemical kinetics and
species generation with effective cooling of flame
tube.

INTRODUCTION
• A gas turbine, also called a combustion turbine, is a type of
continuous combustion, internal combustion engine. The
main elements common to all gas turbine engines are:
• An upstream rotating gas compressor
• A combustor
• A downstream turbine on the same shaft as the compressor.
• A fourth component is often used to increase efficiency (on
turboprops and turbofans), to convert power into
mechanical or electric form (on turbo shafts and
electric generators), or to achieve greater
thrust-to-weight ratio (on afterburning engines).

operation
• The basic operation of the gas turbine is a Brayton cycle with air as
the working fluid. Atmospheric air flows through the compressor that
brings it to higher pressure. Energy is then added by spraying fuel into
the air and igniting it so the combustion generates a high-temperature
flow. This high-temperature high-pressure gas enters a turbine, where
it expands down to the exhaust pressure, producing a shaft work
output in the process. The turbine shaft work is used to drive the
compressor; the energy that is not used for compressing the working
fluid comes out in the exhaust gases that can be used to do external
work, such as directly producing thrust in a turbojet engine, or
rotating a second, independent turbine (known as a power turbine)
which can be connected to a fan, propeller, or electrical generator. The
purpose of the gas turbine determines the design so that the most
desirable split of energy between the shaft and thrust.

COMBUSTION CHAMBER
• A combustor is a component or area of engine where
combustion takes place. It is also known as a burner, combustion
chamber or flame holder. In a gas turbine engine,
the combustor or combustion chamber is fed high pressure air by
the compression system. The combustor then heats this air at
constant pressure. After heating, air passes from the combustor
through the nozzle guide vanes to the turbine. In the case of a
ramjet or scramjet engines, the air is directly fed to the nozzle.
• A combustor must contain and maintain stable combustion
despite very high air flow rates. To do so combustors are
carefully designed to first mix and ignite the air and fuel, and
then mix in more air to complete the combustion process.

TYPES AND PARTS
TYPES
• Can
• Annular
• Can annular
PARTS
• Case
• Diffuser
• Liner
• Snout
• Swirler
• Fuel injector
• Igniter

FUNDAMENTALS OF COMBUSTOR
• Completely combust the fuel. Otherwise, the engine wastes the unbent fuel and
creates unwanted emissions of unburnt hydrocarbons, carbon monoxide (CO) and
soot.
• Low pressure loss across the combustor. The turbine which the combustor feeds
needs high pressure flow to operate efficiently.
• The flame (combustion) must be held (contained) inside of the combustor. If
combustion happens further back in the engine, the turbine stages can easily be
overheated and damaged. Additionally, as turbine blades continue to grow more
advanced and are able to withstand higher temperatures, the combustors are
being designed to burn at higher temperatures and the parts of the combustor
need to be designed to withstand those higher temperatures.
• It should be capable of relighting at high altitude in an event of engine flame-out.
• Uniform exit temperature profile. If there are hot spots in the exit flow, the turbine
may be subjected to thermal stress or other types of damage. Similarly, the
temperature profile within the combustor should avoid hot spots, as those can
damage or destroy a combustor from the inside.

• Small physical size and weight. Space and weight is at a premium in
aircraft applications, so a well- designed combustor strives to be compact.
Non-aircraft applications, like power generating gas turbines, are not as
constrained by this factor.
• Wide range of operation. Most combustors must be able to operate with a
variety of inlet pressures, temperatures, and mass flows. These factors
change with both engine settings and environmental conditions (I.e., full
throttle at low altitude can be very different from idle throttle at high
altitude).
• Environmental emissions. There are strict regulations on aircraft emissions
of pollutants like carbon dioxide and nitrogen oxides, so combustors need
to be designed to minimize those emission.

AIR FLOW DISTRIBUTION PATH
Primary air
• This is the main combustion air. It is highly compressed air
from the high-pressure compressor (often decelerated via the
diffuser) that is suckled through the main channels in the dome
of the combustor and the first set of liner holes. This air is
mixed with fuel, and then combusted.
Intermediate air
• Intermediate air is the air vaccinated into the combustion zone
through the second set of liner holes (primary air goes through
the first set). This air completes the response processes, cooling
the air down and diluting the high deliberations of
carbon monoxide (CO) and hydrogen (H2).

Dilution air
• Dilution air is airflow injected through holes in the liner at the end of the
combustion chamber to help cool the air to before it reaches the turbine
stages. The air is sensibly used to produce the uniform temperature
profile preferred in the combustor. However, as turbine blade technology
improves, allowing them to tolerate higher temperatures, dilution air is
used less, permitting the use of more combustion air.
Cooling air
• Cooling air is airflow that is inoculated through small holes in the liner to
engender a layer (film) of cool air towards protect the liner from the
combustion temperatures. The enactment of cooling air has to be
carefully designed so it does not directly intermingle with the combustion
air and process. In some cases, as much as 50% of the inlet air is used as
cooling air.

AERODYNAMIC INTENTION
Preliminary design procedure
• The proposal of state-of-the-art low emission combustion chamber is
based on a multitude of design rules.
• By automating the combustor design process, the cohort of a new
preliminary combustion chamber design can be done.
Initial design parameters
• The initial design strictures are mostly the compressor exit and turbine
inlet restraints, which is typically absorbed for any combustion chamber
design. Others embrace custo-
mer specifications, constants, tentative values and limits.

Initial design parameters
Parameters values Units
M3 28.7103 Kgs
T3 743.352 K
P3 2083450 Pa
M 0.25818 kgs

Gas temperature profile
Adiabatic flame temperature:
• In the study of combustion, there are two types of adiabatic flame
temperature depending on how the process is completed: the constant
volume and constant pressure; both of which describe temperature that
combustion products theoretically can reach if no energy is lost to the
outside environment.
• The constant volume adiabatic flame temperature is the temperature that
results from a complete combustion process that occurs without any work,
heat transfer or changes in kinetic or potential energy. Its temperature is
higher than the constant pressure process because no energy is utilized to
change the volume of the system (i.e., generate work).

Analytical models
Analytical model
Velocity flow path

MODELLING DATA
Parameters Values
Discretization Finite volume method
Domain Combustor- eddy dissipation
Meshing model Advancing front
Total element 2906742
Total nodes 5921257

Velocity stream line path Total pressure delineation model

Total temperature delineation Total temperature
delineation at outlet

Radial & circumferential pattern
factor
Pressure loss

Results and discussion
• The complete combustor design using the initial parameters
has been evidently discussed in this paper.this is more
sophisticated design approach which can be used for the
preliminary design. This detailed approach is focused on
reducing design time and convolution.By using this practise
a practical design can be illustrated. It follows the optimum
values for a preliminary design. The gotten values are used
for modelling and analysis. Based on theoretical calculation
and obtained results, the design point combustor exit
temperature was achieved within 96% efficiency. Thus the
design is capable of reaching higher temperatures.

Conclusion
• The design was efficaciously calculated and modeled.
The mandatory simpler model for exploration was
also created. Then the model was aerodynamically
analyzed at design point and the geometry was
enhanced based on the results. This has delivered one
of the most efficient combustion chamber design that
can be used in the gas turbine engine.

Reference
Base papers:
• Design and analysis of a combustion chamber in a low bypass
turbofan jet engine.
• Design and analysis of gas turbine combustion chamber.
• The JET ENGINE – rolls-royce
• Aircraft propulsion-by FAROOKI
• Modeling of combustion systems
• Combustion chambers for jet propulsion engine
• Some relevant data from WIKIPEDIA
• CFD analysis of rocket engine combustion chamber by- J.
steelant

Gas turbines engine determination in act

Gas turbines engine determination in act

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