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Experiments with gas and liquid-fuelled flamesOrain, Mikaël January 2001 (has links)
No description available.
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Characteristics of non slagging cyclone combustors for solid fuelsMorgan, D. J. January 1990 (has links)
No description available.
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Opposed jets in crossflowKhan, Zafar Ayub January 1982 (has links)
No description available.
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Flow and combustion characteristics of model annular and can-type combustorsTse, David Gar Nile January 1988 (has links)
No description available.
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Developing and Testing a Combustor Simulator For Investigating High Pressure Turbine Aerodynamics and Heat TransferBarringer, Michael David 02 August 2006 (has links)
Within a gas turbine engine, the turbine nozzle guide vanes are subjected to very harsh conditions from the highly turbulent and hot gases exiting the combustor. The temperature and pressure fields exiting combustors are highly nonuniform and dictate the heat transfer and aero losses that occur in the turbine passages. To better understand these effects, the goal of this work was to develop an adjustable combustor exit profile simulator for the Turbine Research Facility (TRF) at the Air Force Research Laboratory. The TRF is a high temperature, high pressure, short duration blow-down test facility that is capable of matching several aerodynamic and thermal nondimensional engine parameters including Reynolds number, Mach number, pressure ratio, corrected mass flow, gas to metal temperature ratio, and corrected speed.
The primary research objective was to design, install, and verify a non-reacting simulator device that can provide representative combustor exit total pressure and temperature profiles to the inlet of the TRF turbine test section. This required the upstream section of the facility to be redesigned into multiple concentric annuli that serve the purpose of injecting high momentum dilution jets and low momentum film cooling jets into a central annular chamber, similar to a turbine engine combustor. The design of the section allows for variations in injection levels to generate different pressure profiles with elevated turbulence. The dilution and film cooling temperatures can also be varied to create a variety of exit temperature profiles similar to real combustors. The impact of the generated temperature and pressure profiles on turbine heat transfer and secondary flow development was ultimately investigated. Proposed optimal inlet conditions for the turbine tested in this research effort were determined based on the measured data corresponding to the combustor simulator exit profiles that minimized vane heat transfer and total pressure loss. / Ph. D.
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Development of gas turbine combustor preliminary design methodologies and preliminary assessments of advanced low emission combustor conceptsKhandelwal, Bhupendra January 2012 (has links)
It is widely accepted that climate change is a very serious environmental concern. Levels of carbon dioxide (CO2) and other emissions in the global atmosphere have increased substantially since the industrial revolution and now increasing faster than ever before. There is a thought that this has already led to dangerous warming in the Earth’s atmosphere and relevant changes around. Emissions legislations are going to be stringent as the years will pass. Hydro carbon fuel cost is also increasing substantially; more over this is non- renewable source of energy. There is an urgent need for novel combustor technologies for reducing emission as well as exploring alternative renewable fuels without effecting combustor performance. Development of novel combustors needs comprehensive understanding of conventional combustors. The design and development of gas turbine combustors is a crucial but uncertain part of an engine development process. At present, the design process relies upon a wealth of experimental data and correlations. Some major engine manufacturers have addressed the above problem by developing computer programs based on tests and empirical data to assist combustor designers, but such programs are proprietary. There is a need of developing design methodologies for combustors which would lead to substantial contribution to knowledge in field of combustors. Developed design methodologies would be useful for researchers for preliminary design assessments of a gas turbine combustor. In this study, step by step design methodologies of dual annular radial and axial combustor, triple annular combustor and reverse flow combustor have been developed. Design methodologies developed could be used to carry out preliminary design along with performance analysis for conventional combustion chambers. In this study the author has also proposed and undertaken preliminary studies of some novel combustor concepts. A novel concept of a dilution zone less combustor has been proposed in this study. According to this concept dilution air would be introduced through nozzle guide vanes to provide an optimum temperature traverse for turbine blades. Preliminary study on novel dilution zone less combustor predicts that the length of this combustor would be shorter compared to conventional case, resulting in reduced weight, fuel burn and vibrations. Reduced fuel burn eventually leads to lower emissions. Another novel concept of combustor with hydrogen synthesis from kerosene reformation has been proposed and a preliminary studies has been undertaken in this work. Addition of hydrogen as an additive in gas turbine combustor shows large benefits to the performance of gas turbine engines in addition to reduction in NOx levels. The novel combustor would have two stages, combustion of ~5% of the hydrocarbon fuel would occur in the first stage at higher equivalence ratios in the presence of a catalyst, which would eventually lead to the formation of hydrogen rich flue gases. In the subsequent stage the hydrogen rich flue gases from the first stage would act as an additive to combustion of the hydrocarbon fuel. It has been preliminary estimated that the mixture of the hydrocarbon fuel and air could subsequently be burned at much lower equivalence ratios than conventional cases, giving better temperature profiles, flame stability limits and lower NOx emissions. The effect of different geometrical parameters on the performance of vortex controlled hybrid diffuser has also been studied. It has been predicted that vortex chamber in vortex controlled hybrid diffuser does not play any role in altering the performance of diffuser. The overall contribution to knowledge of this study is development of combustor preliminary design methodologies with different variants. The other contribution to knowledge is related to novel combustors with a capability to produce low emissions. Study on novel combustor and diffuser has yielded application of two patent applications with several other publications which has resulted in a contribution to knowledge. A list of research articles, two patents, awards and achievements are presented in Appendix C.
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Development of gas turbine combustor preliminary design methodologies and preliminary assessments of advanced low emission combustor conceptsKhandelwal, Bhupendra 07 1900 (has links)
It is widely accepted that climate change is a very serious environmental
concern. Levels of carbon dioxide (CO2) and other emissions in the global
atmosphere have increased substantially since the industrial revolution and now
increasing faster than ever before. There is a thought that this has already led
to dangerous warming in the Earth’s atmosphere and relevant changes around.
Emissions legislations are going to be stringent as the years will pass. Hydro
carbon fuel cost is also increasing substantially; more over this is non-
renewable source of energy.
There is an urgent need for novel combustor technologies for reducing emission
as well as exploring alternative renewable fuels without effecting combustor
performance. Development of novel combustors needs comprehensive
understanding of conventional combustors. The design and development of gas
turbine combustors is a crucial but uncertain part of an engine development
process. At present, the design process relies upon a wealth of experimental
data and correlations. Some major engine manufacturers have addressed the
above problem by developing computer programs based on tests and empirical
data to assist combustor designers, but such programs are proprietary. There is
a need of developing design methodologies for combustors which would lead to
substantial contribution to knowledge in field of combustors. Developed design
methodologies would be useful for researchers for preliminary design
assessments of a gas turbine combustor.
In this study, step by step design methodologies of dual annular radial and axial
combustor, triple annular combustor and reverse flow combustor have been
developed. Design methodologies developed could be used to carry out
preliminary design along with performance analysis for conventional combustion
chambers. In this study the author has also proposed and undertaken
preliminary studies of some novel combustor concepts.
A novel concept of a dilution zone less combustor has been proposed in this
study. According to this concept dilution air would be introduced through nozzle
guide vanes to provide an optimum temperature traverse for turbine blades.
Preliminary study on novel dilution zone less combustor predicts that the length
of this combustor would be shorter compared to conventional case, resulting in
reduced weight, fuel burn and vibrations. Reduced fuel burn eventually leads to
lower emissions.
Another novel concept of combustor with hydrogen synthesis from kerosene
reformation has been proposed and a preliminary studies has been undertaken
in this work. Addition of hydrogen as an additive in gas turbine combustor
shows large benefits to the performance of gas turbine engines in addition to
reduction in NOx levels. The novel combustor would have two stages,
combustion of ~5% of the hydrocarbon fuel would occur in the first stage at
higher equivalence ratios in the presence of a catalyst, which would eventually
lead to the formation of hydrogen rich flue gases. In the subsequent stage the
hydrogen rich flue gases from the first stage would act as an additive to
combustion of the hydrocarbon fuel. It has been preliminary estimated that the
mixture of the hydrocarbon fuel and air could subsequently be burned at much
lower equivalence ratios than conventional cases, giving better temperature
profiles, flame stability limits and lower NOx emissions.
The effect of different geometrical parameters on the performance of vortex
controlled hybrid diffuser has also been studied. It has been predicted that
vortex chamber in vortex controlled hybrid diffuser does not play any role in
altering the performance of diffuser.
The overall contribution to knowledge of this study is development of combustor
preliminary design methodologies with different variants. The other contribution
to knowledge is related to novel combustors with a capability to produce low
emissions. Study on novel combustor and diffuser has yielded application of two
patent applications with several other publications which has resulted in a
contribution to knowledge. A list of research articles, two patents, awards and
achievements are presented in Appendix C.
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Flame Interactions and Thermoacoustics in Multiple-Nozzle CombustorsDolan, Brian January 2016 (has links)
No description available.
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Heat Transfer and Flow Measurements on a One-Scale Gas Turbine Can Combustor ModelAbraham, Santosh 05 November 2008 (has links)
Combustion designers have considered back-side impingement cooling as the solution for modern DLE combustors. The idea is to provide more cooling to the deserved local hot spots and reserve unnecessary coolant air from local cold spots. Therefore, if accurate heat load distribution on the liners can be obtained, then an intelligent cooling system can be designed to focus more on the localized hot spots. The goal of this study is to determine the heat transfer and pressure distribution inside a typical can-annular gas turbine combustor. This is one of the first efforts in the public domain to investigate the convective heat load to combustor liner due to swirling flow generated by swirler nozzles. An experimental combustor test model was designed and fitted with a swirler nozzle provided by Solar Turbines Inc. Heat transfer and pressure distribution measurements were carried out along the combustor wall to determine the thermo-fluid dynamic effects inside a combustor. The temperature and heat transfer profile along the length of the combustor liner were determined and a heat transfer peak region was established.
Constant-heat-flux boundary condition was established using two identical surface heaters, and the Infrared Thermal Imaging system was used to capture the real-time steady-state temperature distribution at the combustor liner wall. Analysis on the flow characteristics was also performed to compare the pressure distributions with the heat transfer results. The experiment was conducted at two different Reynolds numbers (Re 50,000 and Re 80,000), to investigate the effect of Reynolds Number on the heat transfer peak locations and pressure distributions. The results reveal that the heat transfer peak regions at both the Reynolds numbers occur at approximately the same location. The results from this study on a broader scale will help in understanding and predicting swirling flow effects on the local convective heat load to the combustor liner, thereby enabling the combustion engineer to design more effective cooling systems to improve combustor durability and performance. / Master of Science
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Heat Transfer and Flow Measurements in Gas Turbine Engine Can and Annular CombustorsCarmack, Andrew Cardin 31 May 2012 (has links)
A comparison study between axial and radial swirler performance in a gas turbine can combustor was conducted by investigating the correlation between combustor flow field geometry and convective heat transfer at cold flow conditions for Reynolds numbers of 50,000 and 80,000. Flow velocities were measured using Particle Image Velocimetry (PIV) along the center axial plane and radial cross sections of the flow. It was observed that both swirlers produced a strong rotating flow with a reverse flow core. The axial swirler induced larger recirculation zones at both the backside wall and the central area as the flow exits the swirler, and created a much more uniform rotational velocity distribution. The radial swirler however, produced greater rotational velocity as well as a thicker and higher velocity reverse flow core. Wall heat transfer and temperature measurements were also taken. Peak heat transfer regions directly correspond to the location of the flow as it exits each swirler and impinges on the combustor liner wall.
Convective heat transfer was also measured along the liner wall of a gas turbine annular combustor fitted with radial swirlers for Reynolds numbers 210000, 420000, and 840000. The impingement location of the flow exiting from the radial swirler resulted in peak heat transfer regions along the concave wall of the annular combustor. The convex side showed peak heat transfer regions above and below the impingement area. This behavior is due to the recirculation zones caused by the interaction between the swirlers inside the annulus. / Master of Science
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