An Investigation Of Gas Turbine Combustors With High Inlet Air Temperatures Part I Combustor Modelling

An Investigation of Gas Turbine Combustors with High Inlet Air Temperatures. Part I: Combustor Modelling

Author : Dean C Hammond (Jr)

Publisher :

Page : 119 pages

File Size : 27,76 MB

Release : 1971

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ISBN :

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Book Description

An analytical model has been developed which will predict the performance and pollutant emissions of gas turbine combustors. The entire gas turbine combustor is approximated as a collection of perfectly stirred zones. Within each zone a general hydrocarbon combustion mechanism is used to predict the gas composition and temperature. The zone volumes and sizes are assigned from consideration of the theoretically predicted gas flows thereby approximating the mixing behavior of the system. Selected predictions of the overall model for a 'typical' aircraft combustor are presented. These results are seen to be qualitatively accurate and fall in the range of values typically observed in practical systems.



An Investigation of Gas Turbine Combustors with High Inlet Air Temperatures. Part 3: Experimental Developments

Author : Richard D. Anderson

Publisher :

Page : 64 pages

File Size : 21,63 MB

Release : 1971

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ISBN :

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Book Description

Current gas turbine combustor design philosophy must reflect consideration of both emission control and high inlet air temperature effects on flame stability, combustor performance, and flame tube life. An experimental facility has been designed for the detailed, systematic study of gas turbine combustion as a function of realistic inlet parameters. In an attempt to provide fundamental gas turbine measurements are described. In addition to a detailed description of the experimental facility, internal gas temperature and gas sampling probing techniques, facility instrumentation, and future engine parameter settings are discussed.



An Investigation of Gas Turbine Combustors with High Inlet Air Temperatures. Part 2; Heat Transfer

Author : Clifton W. Owens

Publisher :

Page : 111 pages

File Size : 14,17 MB

Release : 1971

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ISBN :

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Book Description

The wall temperature distribution of a combustion chamber is a function of the various heat transfer processes existing in the chamber and annulus. The basic turbulent conservation equations of mass, momentum, species, and energy are developed in an effort to provide an analytical rather than empirical method of determining the temperature distribution. However, the inclusion of radiation energy exchange using the radiative transport theory and the fact that the chamber flow is not one dimensional makes a closed form solution to the problem mathematically impossible.



Flow and Combustion in Advanced Gas Turbine Combustors

Author : Johannes Janicka

Publisher : Springer Science & Business Media

Page : 495 pages

File Size : 30,65 MB

Release : 2012-10-29

Category : Technology & Engineering

ISBN : 9400753209

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Book Description

With regard to both the environmental sustainability and operating efficiency demands, modern combustion research has to face two main objectives, the optimization of combustion efficiency and the reduction of pollutants. This book reports on the combustion research activities carried out within the Collaborative Research Center (SFB) 568 “Flow and Combustion in Future Gas Turbine Combustion Chambers” funded by the German Research Foundation (DFG). This aimed at designing a completely integrated modeling and numerical simulation of the occurring very complex, coupled and interacting physico-chemical processes, such as turbulent heat and mass transport, single or multi-phase flows phenomena, chemical reactions/combustion and radiation, able to support the development of advanced gas turbine chamber concepts



An Experimental and Numerical Investigation of a Gas Turbine Research Combustor

Author : Reuben Montresor Morris

Publisher :

Page : pages

File Size : 34,74 MB

Release : 2013

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ISBN :

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Book Description

Gas turbine engineering faces many challenges in the constant strive to increase not only the efficiency of engines but also the various stages of development and design. Development of combustors have primarily consisted of empirical or semi-empirical modelling combined with experimental investigations. Due to the associated costs and development time a need exists for an alternative method of development. Although experimental investigations can never be substituted completely, mathematical models incorporating numerical methods have shown to be an attractive alternative to conventional combustor design methods. The purpose of this study is twofold: firstly, to experimentally investigate the physical properties associated with a research combustor that is geometrically representative of practical combustors: and secondly, to use the experimental measurements for the validation of a computational fluids dynamic model that was developed to simulate the research combustor using a commercial code. The combustor was tested at atmospheric conditions and is representative of practical combustors that are characterized by a turbulent, three-dimensional flow field. The single can combustor is divided into a primary, secondary and dilution zone, incorporating film cooling air through stacked rings and an axial swirler centred around the fuel atomizer. Measurements at different air/fuel ratios captured the thermal field during operating conditions and consisted of inside gas, liner wall and exit gas temperatures. An investigation of the different combustion models available, led to the implementation of the presumed-PDF model of unpremixed turbulent reaction. The computational grid included the external and internal flow field with velocity boundary conditions prescribed at the various inlets. Two-phase flow was not accounted for with the assumption made that the liquid fuel is introduced into the combustion chamber in a gas phase. Experimental results showed that incomplete combustion occurs in the primary zone, thereby reducing the overall efficiency. Also evident from the results obtained are the incorrect flow splits at the various inlets. Evaluation of the numerical model showed that gas temperatures inside the combustor are overpredicted. However, the numerical model is capable of capturing the correct distributions of temperatures and trends obtained experimentally. This study is successful in capturing detail temperature measurements that will be used for validation purposes to assist the development of a numerical model that can accurately predict combustion properties.







Gas Turbine Emissions

Author : Tim C. Lieuwen

Publisher : Cambridge University Press

Page : 385 pages

File Size : 41,26 MB

Release : 2013-07-08

Category : Technology & Engineering

ISBN : 1107244242

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Book Description

The development of clean, sustainable energy systems is one of the pre-eminent issues of our time. Most projections indicate that combustion-based energy conversion systems will continue to be the predominant approach for the majority of our energy usage, and gas turbines will continue to be important combustion-based energy conversion devices for many decades to come, used for aircraft propulsion, ground-based power generation, and mechanical-drive applications. This book compiles the key scientific and technological knowledge associated with gas turbine emissions into a single authoritative source. The book has three sections: the first section reviews major issues with gas turbine combustion, including design approaches and constraints, within the context of emissions. The second section addresses fundamental issues associated with pollutant formation, modeling, and prediction. The third section features case studies from manufacturers and technology developers, emphasizing the system-level and practical issues that must be addressed in developing different types of gas turbines that emit pollutants at acceptable levels.



Gas Turbine Combustion Modeling for a Parametric Emissions Monitoring System

Author :

Publisher :

Page : pages

File Size : 13,30 MB

Release : 2007

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ISBN :

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Book Description

Oxides of nitrogen (NO[subscript x]), carbon monoxide (CO) and other combustion by-products of gas turbines have long been identified as harmful atmospheric pollutants to the environment and humans. Various government agencies place restrictions on emissions and often require some sort of emissions monitoring even for new low emission gas turbines. Predicting actual emissions from operating parameters that affect the formation of pollutants, called parametric emissions monitoring system (PEMS), has potential economic advantages compared to a continuous emissions monitoring system (CEMS). The problem is that a simple applicable PEMS does not exist. During this study, a gas turbine combustor model applying first engineering principles was developed to predict the emission formation of NO[subscript x]and CO in a gas turbine. The model is based on a lean-premixed combustor with a main and pilot burner including the function of a bleeding air valve. The model relies on ambient condition and load. The load is expressed as a percentage of the target speed of the gas producer turbine. Air flow and fuel flow for the main and pilot burner are calculated by the model based on the load through a set of measured input data for a specific gas turbine. To find the combustion temperature characteristics, the combustor is divided into several zones. The temperature for each zone is calculated by applying an energy balance. To predict NO[subscript x] and CO, several correlations explored by various researchers are used and compared against each other, using the calculated temperatures, pressures and equivalence ratios. A comparison between collected emissions examples from a turbine test cell data spreadsheet and predicted emissions by the developed model under the same conditions show a highly accurate match for NO[subscript x] emission at any load. Because of the high variation of CO at part load, the model predictions only match the CO data set at full load.



Performance of a Turbojet Combustor Using Natural Gas Fuel Heated to 12000 F (922 K)

Author : James S. Fear

Publisher :

Page : 28 pages

File Size : 14,47 MB

Release : 1970

Category : Airplanes

ISBN :

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Book Description

Combustion efficiency was determined using natural gas fuel over a range of injection temperatures from ambient to 1200' F (922 K). The combustor was comprised of three U-gutter flameholders mounted downstream of a trumpet-shaped diffuser in a rectangulai housing. A simple film-cooled liner was used. Tests were conducted at ambient pressure over a range of fuel-air ratios and combustor reference velocities. Increases in efficiency of more than 40 percentage points were achieved at the higher fuel temperatures. The results are applicable to natural gas afterburner design and to the design of advanced low-pressure-loss primary combustors.