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Investigations of flow and film cooling on turbine blade edge regionsYang, Huitao 30 October 2006 (has links)
The inlet temperature of modern gas turbine engines has been increased to achieve higher thermal
efficiency and increased output. The blade edge regions, including the blade tip, the leading edge, and the
platform, are exposed to the most extreme heat loads, and therefore, must be adequately cooled to
maintain safety.
For the blade tip, there is tip leakage flow due to the pressure gradient across the tip. This leakage
flow not only reduces the blade aerodynamic performance, but also yields a high heat load due to the thin
boundary layer and high speed. Various tip configurations, such as plane tip, double side squealer tip, and
single suction side squealer tip, have been studied to find which one is the best configuration to reduce the
tip leakage flow and the heat load. In addition to the flow and heat transfer on the blade tip, film cooling
with various arrangements, including camber line, upstream, and two row configurations, have been
studied. Besides these cases of low inlet/outlet pressure ratio, low temperature, non-rotating, the high
inlet/outlet pressure ratio, high temperature, and rotating cases have been investigated, since they are
closer to real turbine working conditions.
The leading edge of the rotor blade experiences high heat transfer because of the stagnation flow.
Film cooling on the rotor leading edge in a 1-1/2 turbine stage has been numerically studied for the design
and off-design conditions. Simulations find that the increasing rotating speed shifts the stagnation line
from the pressure side, to the leading edge and the suction side, while film cooling protection moves in the
reverse direction with decreasing cooling effectiveness. Film cooling brings a high unsteady intensity of
the heat transfer coefficient, especially on the suction side. The unsteady intensity of film cooling
effectiveness is higher than that of the heat transfer coefficient.
The film cooling on the rotor platform has gained significant attention due to the usage of low-aspect
ratio and low-solidity turbine designs. Film cooling and its heat transfer are strongly influenced by the
secondary flow of the end-wall and the stator-rotor interaction. Numerical predictions have been
performed for the film cooling on the rotating platform of a whole turbine stage. The design conditions
yield a high cooling effectiveness and decrease the cooling effectiveness unsteady intensity, while the high rpm condition dramatically reduces the film cooling effectiveness. High purge flow rates provide a better
cooling protection. In addition, the impact of the turbine work process on film cooling effectiveness and
heat transfer coefficient has been investigated. The overall cooling effectiveness shows a higher value than
the adiabatic effectiveness does.
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Theoretical and Experimental Analysis of Power and Cooling Cogeneration Utilizing Low Temperature Heat SourcesDemirkaya, Gökmen 01 January 2011 (has links)
Development of innovative thermodynamic cycles is important for the efficient utilization of low-temperature heat sources such as solar, geothermal, and waste heat sources. Binary mixtures exhibit variable boiling temperatures during the boiling process, which leads to a good thermal match between the heating fluid and working fluid for efficient heat source utilization. This study presents a theoretical and an experimental analysis of a combined power/cooling cycle, which combines the Rankine and absorption refrigeration cycles, uses ammonia-water mixture as the working fluid and produces power and refrigeration, while power is the primary goal. This cycle, also known as the Goswami Cycle, can be used as a bottoming cycle using waste heat from a conventional power cycle or as an independent cycle using low to mid-temperature sources such as geothermal and solar energy. A thermodynamic analysis of power and cooling cogeneration was presented.
The performance of the cycle for a range of boiler pressures, ammonia concentrations, and isentropic turbine efficiencies were studied to find out the sensitivities of net work, amount of cooling and effective efficiencies. The thermodynamic analysis covered a broad range of boiler temperatures, from 85 °C to 350 °C. The first law efficiencies of 25-31% are achievable with the boiler temperatures of 250-350 °C. The cycle can operate at an effective exergy efficiency of 60-68% with the boiler temperature range of 200-350 °C. An experimental study was conducted to verify the predicted trends and to test the performance of a scroll type expander. The experimental results of vapor production were verified by the expected trends to some degree, due to heat transfer losses in the separator vessel. The scroll expander isentropic efficiency was between 30-50%, the expander performed better when the vapor was superheated. The small scale of the experimental cycle affected the testing conditions and cycle outputs. This cycle can be designed and scaled from a kilowatt to megawatt systems. Utilization of low temperature sources and heat recovery is definitely an active step in improving the overall energy conversion efficiency and decreasing the capital cost of energy per unit.
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Detailed Validation Assessment of Turbine Stage Disc Cavity Rotating FlowsJanuary 2016 (has links)
abstract: The subject of this thesis is concerned with the amount of cooling air assigned to seal high pressure turbine rim cavities which is critical for performance as well as component life. Insufficient air leads to excessive hot annulus gas ingestion and its penetration deep into the cavity compromising disc life. Excessive purge air, adversely affects performance. Experiments on a rotating turbine stage rig which included a rotor-stator forward disc cavity were performed at Arizona State University. The turbine rig has 22 vanes and 28 blades, while the rim cavity is composed of a single-tooth rim lab seal and a rim platform overlap seal. Time-averaged static pressures were measured in the gas path and the cavity, while mainstream gas ingestion into the cavity was determined by measuring the concentration distribution of tracer gas (carbon dioxide). Additionally, particle image velocimetry (PIV) was used to measure fluid velocity inside the rim cavity between the lab seal and the overlap. The data from the experiments were compared to an 360-degree unsteady RANS (URANS) CFD simulations. Although not able to match the time-averaged test data satisfactorily, the CFD simulations brought to light the unsteadiness present in the flow during the experiment which the slower response data did not fully capture. To interrogate the validity of URANS simulations in capturing complex rotating flow physics, the scope of this work also included to validating the CFD tool by comparing its predictions against experimental LDV data in a closed rotor-stator cavity. The enclosed cavity has a stationary shroud, a rotating hub, and mass flow does not enter or exit the system. A full 360 degree numerical simulation was performed comparing Fluent LES, with URANS turbulence models. Results from these investigations point to URANS state of art under-predicting closed cavity tangential velocity by 32% to 43%, and open rim cavity effectiveness by 50% compared to test data. The goal of this thesis is to assess the validity of URANS turbulence models in more complex rotating flows, compare accuracy with LES simulations, suggest CFD settings to better simulate turbine stage mainstream/disc cavity interaction with ingestion, and recommend experimentation techniques. / Dissertation/Thesis / Masters Thesis Mechanical Engineering 2016
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3-D Unsteady Simulation of a Modern High Pressure Turbine Stage: Analysis of Heat Transfer and FlowShyam, Vikram January 2009 (has links)
No description available.
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Aerodynamic and mechanical performance of a high-pressure turbine stage in a transient wind tunnelSheard, A. G. January 1989 (has links)
Unsteady three-dimensional flow phenomena have major effects on the aerodynamic performance of, and heat transfer to, gas-turbine blading. Investigation of the mechanisms associated with these phenomena requires an experimental facility that is capable of simulating a gas turbine, but at lower levels of temperature and pressure to allow conventional measurement techniques. This thesis reports on the design, development and commissioning of a new experimental facility that models these unsteady three-dimensional flow phenomena. The new facility, which consists of a 62%-size, high-pressure gas-turbine stage mounted in a transient wind tunnel, simulates the turbine design point of a full-stage turbine. The thesis describes the aerodynamic and mechanical design of the new facility, a rigorous stress analysis of the facility’s rotating system and the three-stage commissioning of the facility. The thesis concludes with an assessment of the turbine stage performance.
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