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1	DESIGN OF A HIGH FIDELITY WAKE SIMULATOR FOR RESEARCH USING LINEAR CASCADES Pluim, Jonathon Douglas 08 September 2009 (has links) No description available. Wake Simulation Low pressure turbine wake generator
2	A STUDY OF SEPARATED FLOW THROUGH A LOW-PRESSURE TURBINE CASCADE SINGH, NAVTEJ 27 May 2005 (has links) No description available. Low-Pressure Turbine Flow Separation Filtering Compact Difference Schemes
3	EXPERIMENTAL INVESTIGATION OF SEPARATION IN A LOW PRESSURE TURBINE BLADE CASCADE MODEL Hollon, Brian 01 January 2003 (has links) The flow field around a low pressure turbine blade is examined using smoke-wire flow visualization, static surface pressure measurements, and particle image velocimetry (PIV). The purpose of the experimental study is to investigate the transition and separation characteristics on low pressure turbine blades under low Reynolds number (Re) and varying freestream turbulence intensity (FSTI). A cascade model consisting of 6 Pratt andamp; Whitney PAK-B low pressure turbine blades was examined in a wind tunnel using PIV and flow visualization. Smoke-wire visualization was performed for test section exit angles of 93°, 95°, and 97°, in the range Re = 3 · 104 to 9 · 104 and three levels of FSTI varied with a passive grid. The locations of separation and transition were determined to be approximately 45% and 77% of the suction surface length, respectively, based upon the smoke stream lines observed in the images, and appear to be independent of Re, turning angle, and FSTI. The maximum size of the separation bubble was found to decrease with increasing Re, turning angle, and FSTI. PIV images from three camera views were processed for an exit angle of 95° and a Re range of 3:0 · 104 to 30:0 · 104 and three levels of FSTI. Velocity, vorticity, and reversed flow probability field plots were generated along with velocity, vorticity, and RMS velocity profiles. The point of separation point was determined to be from 63% SSL to 67% SSL. The area of reversed flow was computed for each image pair from camera views 1 and 3, as an approxiamtion of the relative size of the separation region. For low Re and FSTI cases the area was much larger than for higher FSTI cases at any Re. The raw PIV images include some of the rst clear pictures of the turbulent flow structures forming in the unsteady shear layer over the suction surface of low pressure turbine blades. Several movies are compiled that show how the geometry and location of the shear layer evolve in time for a given set of flow conditions. Engineering Mechanical Engineering
4	EXPERIMENTAL STUDY OF ACTIVE SEPARATION FLOW CONTROL IN A LOW PRESSURE TURBINE BLADE CASCADE MODEL McQuilling, Mark 01 January 2004 (has links) The flow field around a low pressure turbine (LPT) blade cascade model with and without flow control is examined using ejector nozzle (EN) and vortex generator jet (VGJ) geometries for separation control. The cascade model consists of 6 Pak-B Pratt andamp; Whitney low pressure turbine blades with Re = 30,000-50,000 at a free-stream turbulence intensity of 0.6%. The EN geometry consists of combined suction and blowing slots near the point of separation. The VGJs consist of a row of holes placed at an angle to the free-stream, and are tested at two locations of 69% and 10.5% of the suction surface length (SSL). Results are compared between flow control on and flow control off states, as well as between the EN, VGJs, and a baseline cascade with no flow control geometry for steady and pulsatile blowing. The EN geometry is shown to control separation with both steady and pulsatile blowing. The VGJs at 69% SSL are shown to be much more aggressive than the EN geometry, achieving the same level of separation control with lower energy input. Pulsed VGJs (PVGJ) have been shown to be just as effective as steady VGJs, and results show that a 10% duty cycle is almost as effective as a 50% duty cycle. The VGJs at 10.5% SSL are shown to be inefficient at controlling separation. No combination of duty cycle and pulsing frequency tested can eliminate the separation region, with only higher steady blowing rates achieving separation control. Thus, the VGJs at 69% SSL are shown to be the most effective in controlling separation. Engineering Mechanical Engineering
5	Unsteady Effects of a Pulsed Blowing System on an Endwall Vortex Donovan, Molly Hope 04 June 2019 (has links) No description available. Mechanical Engineering turbomachinery fluid mechanics low-pressure turbine endwall vortex wall-bounded flows LPT turbine engine
6	Turbine Passage Vortex Response to Upstream Periodic Disturbances Scott, Mitchell Lee January 2020 (has links) No description available. Mechanical Engineering Passage Vortex Vortex Dynamics Low-pressure turbine Endwall Secondary Flow PIV SPIV
7	HIGHER-ORDER ACCURATE SOLUTION FOR FLOW THROUGH A TURBINE LINEAR CASCADE AYYALASOMAYAJULA, HARITHA 30 June 2003 (has links) No description available. Engineering, Mechanical low-pressure turbine high-order accurate method filtering flow separation Navier-stokes equations
8	SIMULATION OF FLOW THROUGH LOW-PRESSURE LINEAR TURBINE CASCADE, USING MULTI-BLOCK STRUCTURED GRID MUTNURI, PAVAN KUMAR January 2003 (has links) No description available. Engineering, Mechanical low-pressure turbine multi-block structured grid higher-order schemes flow separation
9	DESIGN AND VALIDATION OF A HIGH-LIFT LOW-PRESSURE TURBINE BLADE McQuilling, Mark W. 28 September 2007 (has links) No description available. low-pressure turbine high lift L2F L1M transition zweifel surface stress shear S3F
10	PHASE-LOCKED PIV INVESTIGATION OF THE EFFECTS OF THE BLOWING RATIO OF A PULSED VORTEX GENERATOR JET IN A LOW-PRESSURE TURBINE Woods, Nathan Michael 02 October 2007 (has links) No description available. Turbine Pack-B Pak-B separation Low Pressure Turbine Vortex Generator Jets PIV

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