Transition of the state of the boundary layer from laminar to turbulent plays an important role in the aerodynamic loss generation on turbine airfoils. An accurate simulation of the transition process and of the state of the boundary layer is therefore crucial for prediction of the aerodynamic efficiency of components in rotating machines. A lot of the research in the past years dealt with the transition over laminar separation bubbles, especially concerning flows in low pressure turbines (LPTs) of air jet engines. Nevertheless, bypass transition is also frequent in turbomachines at higher Reynolds numbers as well as for properly designed profiles. Compared with transition over a laminar separation bubble, a bypass transition is experimentally much more difficult to detect with standard measurement techniques. In such cases it becomes necessary to use more sophisticated techniques, such as hot-film anemometry, hot wires, or Preston probes in order to obtain accurate information on the state of the boundary layer. The study presented is carried out using a linear cascade with a LPT blade profile with strong front loading and gentle flow deceleration at the rear suction side of the blade. Measurements were performed at the high-speed cascade wind tunnel of the Institute of Jet Propulsion at engine relevant Mach and Reynolds numbers. Emphasis is put on the evaluation of the different transition processes at midspan and its influence on profile losses. The data postprocessing was adapted for compressible flows, which allows a more accurate determination of the transition area as well as qualitatively better distributions of the wall shear stress. Finally, comparisons with simulations, using computational fluid dynamics (CFD) tools, are performed and fields for improvement of the turbulence and transition models are identified.
Skip Nav Destination
Article navigation
September 2015
Research-Article
Hot-Film Measurements on a Low Pressure Turbine Linear Cascade With Bypass Transition
Reinaldo A. Gomes,
Reinaldo A. Gomes
1
Mem. ASME
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: reinaldo.gomes@unibw.de
Institute of Jet Propulsion,
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: reinaldo.gomes@unibw.de
1Corresponding author.
Search for other works by this author on:
Stephan Stotz,
Stephan Stotz
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: stephan.stotz@unibw.de
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: stephan.stotz@unibw.de
Search for other works by this author on:
Franz Blaim,
Franz Blaim
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: franz.blaim@unibw.de
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: franz.blaim@unibw.de
Search for other works by this author on:
Reinhard Niehuis
Reinhard Niehuis
Professor
Mem. ASME
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: reinhard.niehuis@unibw.de
Mem. ASME
Institute of Jet Propulsion,
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: reinhard.niehuis@unibw.de
Search for other works by this author on:
Reinaldo A. Gomes
Mem. ASME
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: reinaldo.gomes@unibw.de
Institute of Jet Propulsion,
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: reinaldo.gomes@unibw.de
Stephan Stotz
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: stephan.stotz@unibw.de
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: stephan.stotz@unibw.de
Franz Blaim
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: franz.blaim@unibw.de
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: franz.blaim@unibw.de
Reinhard Niehuis
Professor
Mem. ASME
Institute of Jet Propulsion,
Federal Armed Forces Munich,
e-mail: reinhard.niehuis@unibw.de
Mem. ASME
Institute of Jet Propulsion,
University of the German
Federal Armed Forces Munich,
Neubiberg 85577
, Germany
e-mail: reinhard.niehuis@unibw.de
1Corresponding author.
Contributed by the International Gas Turbine Institute (IGTI) of ASME for publication in the JOURNAL OF TURBOMACHINERY. Manuscript received January 21, 2015; final manuscript received January 26, 2015; published online March 24, 2015. Editor: Ronald Bunker.
J. Turbomach. Sep 2015, 137(9): 091007 (11 pages)
Published Online: September 1, 2015
Article history
Received:
January 21, 2015
Revision Received:
January 26, 2015
Online:
March 24, 2015
Citation
Gomes, R. A., Stotz, S., Blaim, F., and Niehuis, R. (September 1, 2015). "Hot-Film Measurements on a Low Pressure Turbine Linear Cascade With Bypass Transition." ASME. J. Turbomach. September 2015; 137(9): 091007. https://doi.org/10.1115/1.4029967
Download citation file:
Get Email Alerts
Related Articles
Mach Number Distribution and Profile Losses for Low-Pressure Turbine Profiles With High Diffusion Factors
J. Turbomach (October,2017)
Endwall Boundary Layer Development in an Engine Representative Four-Stage Low Pressure Turbine Rig
J. Turbomach (January,2009)
Accurate Estimation of Profile Losses and Analysis of Loss Generation Mechanisms in a Turbine Cascade
J. Turbomach (December,2017)
Predicting Transition in Turbomachinery—Part II: Model Validation and Benchmarking
J. Turbomach (January,2007)
Related Proceedings Papers
Related Chapters
Cavitating Structures at Inception in Turbulent Shear Flow
Proceedings of the 10th International Symposium on Cavitation (CAV2018)
Introduction
Design and Analysis of Centrifugal Compressors
Boundary Layer Analysis
Centrifugal Compressors: A Strategy for Aerodynamic Design and Analysis