A high-speed infrared camera is used to measure the temperature of blade tips in a cooled high-pressure turbine operating at corrected engine conditions in The Ohio State University Turbine Test Facility. These experiments create a challenging problem for infrared imaging since the rotor turns at over 13,000 rpm with tip speeds on the order of 300 m/s, and the surface temperature of the airfoils is on the order of 350 K. This means that the camera needs to capture a low intensity signal in a short time period. This paper will review the design and operation of a measurement procedure to accomplish this difficult task along with the post-processing steps necessary to extract useful data. Raw infrared images are processed by deblurring the images using a non-blind Wiener filter and mapping the two-dimensional data onto the three-dimensional blade. This paper also describes experiments covering a range of cooling flow rates and main flow temperatures. In addition, several tests with no main flow and only cooling flow were performed at lower speeds to reduce motion blur and enable the separation of internal and external heat transfer information. Results show that the infrared data is consistent and can provide quantitative comparisons of cooling performance even at the high rotation speed. This paper presents the lessons learned for high-speed infrared measurement along with representative data to illustrate the repeatability and capability of the measurement scheme as well as suggested improvements to guide further development.
This paper presents the development and implementation of a new generation of double-sided heat-flux gauges at The Ohio State University Gas Turbine Laboratory (GTL) along with heat transfer measurements for film-cooled airfoils in a single-stage high-pressure transonic turbine operating at design corrected conditions. Double-sided heat flux gauges are a critical part of turbine cooling studies, and the new generation improves upon the durability and stability of previous designs while also introducing high-density layouts that provide better spatial resolution. These new customizable high-density double-sided heat flux gauges allow for multiple heat transfer measurements in a small geometric area such as immediately downstream of a row of cooling holes on an airfoil. Two high-density designs are utilized: Type A consists of 9 gauges laid out within a 5 mm by 2.6 mm (0.20 inch by 0.10 inch) area on the pressure surface of an airfoil, and Type B consists of 7 gauges located at points of predicted interest on the suction surface. Both individual and high-density heat flux gauges are installed on the blades of a transonic turbine experiment for the second build of the High-Pressure Turbine Innovative Cooling program (HPTIC2). Run in a short duration facility, the single-stage high-pressure turbine operated at design-corrected conditions (matching corrected speed, flow function, and pressure ratio) with forward and aft purge flow and film-cooled blades. Gauges are placed at repeated locations across different cooling schemes in a rainbow rotor configuration. Airfoil film-cooling schemes include round, fan, and advanced shaped cooling holes in addition to uncooled airfoils. Both the pressure and suction surfaces of the airfoils are instrumented at multiple wetted distance locations and percent spans from roughly 10% to 90%. Results from these tests are presented as both time-average values and time-accurate ensemble averages in order to capture unsteady motion and heat transfer distribution created by strong secondary flows and cooling flows.
Axial gas turbines set up highly complex unsteady flow fields, and the incorporation of cooling further complicates the flow. Due to time and computational resource constraints, the design cycle for modern gas turbines relies heavily on steady-state computational fluid dynamics simulations, which approximate time-averaged unsteady turbine flows as steady. Steady modeling provides good predictions of pressure loading but struggles with heat transfer predictions for cooled turbines. The present study incorporates experimental and computational research on a modern gas turbine stage to provide a detailed assessment of steady gas turbine modeling techniques. Comparisons are performed among steady simulation and unsteady simulation results and time-averaged experimental data to examine the quality of computational predictions. While steady results provide good agreement with experimental pressure data, heat transfer results are less satisfactory. The largest areas of discrepancy between experiment and steady simulation are on the suction surface near the leading edge and on the pressure surface near film cooling hole rows. Unsteady simulations narrow disagreements to within unsteadiness limits. Analysis of the main gas path identifies elements of main flow unsteadiness causing augmentation in time-averaged heat transfer. Results of this research provide a unique perspective on modeling techniques for gas turbines. The results indicate steady approximations of time-averaged heat transfer are of limited use for much of the turbine blade due to a large amount of unsteadiness in the main gas path. However, a characterization of the unsteadiness in the turbine in both experimental and computational results can help engineers to better represent the time-averaged performance with steady simulations.
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