Multimethod aerodynamic research of engine-realistic turbine rear structures
Doktorsavhandling, 2024
Despite the significant advancements in aircraft engine technology over the past years, the aerodynamics of engine-realistic turbine rear structures (TRS) remain largely unexplored. The TRS, a structural and aerodynamic component situated downstream of the low-pressure turbine (LPT), plays a pivotal role in engine aerodynamic performance, deswirling the LPT flow to maximize the engine thrust. However, there is a significant gap in available experimental aerodynamic data on state-of-the-art TRS configurations under engine-relevant conditions.
The thesis closes this critical knowledge gap and provides the first comprehensive aerodynamic analysis of the latest and most advanced TRS configurations. Prior studies on the TRS were limited to simplified models. In contrast, this thesis is focused on two TRS types used in all state-of-the-art turbofan engines: with radial and leaned outlet guide vanes (OGVs). For the first time, aerodynamic tests of engine-realistic TRSs have been carried out under engine-relevant Reynolds numbers and flow coefficients, facilitated by a unique annular 1.5 stage LPT-OGV facility at Chalmers University of Technology, established in 2015.
For the experimental investigation of the TRS flow, a multimethod approach was applied and involved an array of advanced measurement techniques to provide insights into various aspects of TRS flow. This included the use of pressure probes and static pressure taps for acquiring total and static pressure distributions, crucial for estimating pressure losses. The oil-film method was employed to capture flow-visualization patterns, serving to indicate laminar-turbulent transition and loss-generating structures. Moreover, for the first time in the context of TRS flow, hot-wire anemometry (HWA) and PIV techniques were employed to provide time-resolved and instantaneous velocity field data, effectively capturing the unsteady phenomena.
The central focus of this thesis is detailed examination of pressure loss mechanisms within TRS, focusing on the impact of different OGV designs and operating conditions on TRS aerodynamics. This involves an in-depth aerodynamic evaluation of multiple OGV types commonly found in real engines, such as regular OGVs, those with increased thickness, and OGVs with integrated engine mount recesses (bumps). For the first time, this study aerodynamically evaluated and compared two engine-realistic TRSs with simultaneously mounted OGVs of different types. The experimental data for the radial TRS was compared with preliminary CFD results, obtained using current industrial tools. The insights obtained from the PIV and HWA campaign were instrumental, allowing for a thorough examination of the structure and propagation of LPT rotor and stator wakes into TRS.
particle image velocimetry
vane lean
pressure taps
enginerealistic
engine-mount recess
European Union (EU)
hot-wire anemometry
outlet guide vanes
oil-film visualization
multi-hole probe
turbine exhaust case
bump
turbine rear frame
computational fluid dynamics.
Clean Sky 2
experimental multimethod approach
Horizon 2020
EATEEM
turbine rear structure
low-pressure turbine
Författare
Valentin Vikhorev
Chalmers, Mekanik och maritima vetenskaper, Strömningslära
The Influence of the Vane Lean on the Flow In a Turbine Rear Structure
33rd Congress of the International Council of the Aeronautical Sciences, ICAS 2022,;Vol. 7(2022)p. 4819-4825
Paper i proceeding
Experimental and Numerical Flow Analysis of an Engine-Realistic State-of-the-Art Turbine Rear Structure
Journal of Engineering for Gas Turbines and Power,;Vol. 144(2022)
Artikel i vetenskaplig tidskrift
Experimental Flow Analysis in a Modern Turbine Rear Structure with 3D Polygonal Shroud Under Realistic Flow Conditions
European Conference on Turbomachinery Fluid Dynamics and Thermodynamics, ETC,;(2021)
Paper i proceeding
Detailed Experimental Study of the Flow in a Turbine Rear Structure at Engine-Realistic Flow Conditions
Journal of Turbomachinery,;Vol. 143(2021)
Artikel i vetenskaplig tidskrift
Experimental study on the low-pressure turbine wake interaction and development in the turbine rear structure
9TH EUROPEAN CONFERENCE FOR AERONAUTICS AND SPACE SCIENCES,;(2022)
Paper i proceeding
Detailed Experimental Study of the Flow in a Turbine Rear Structure at Engine Realistic Flow Conditions
Proceedings of the ASME Turbo Expo,;Vol. 2B(2020)
Paper i proceeding
Experimental and numerical flow analysis of an engine-realistic state-of-the-art turbine rear structure
Proceedings of the ASME Turbo Expo,;Vol. 2B-2021(2021)
Paper i proceeding
Experimental investigation of waste heat recovery concept in turbine rear structure for a Liquid Hydrogen Gas-Turbine
Proceedings of the International Symposium on Turbulence, Heat and Mass Transfer,;Vol. 1(2023)p. 725-728
Paper i proceeding
In support of this, Chalmers University of Technology offers a state-of-the-art facility specifically designed for testing one of the internal engine structures, known as the Turbine Rear Structure (TRS). TRS is a structural component positioned at the aft end of the engine, which transfers mechanical loads from the engine to the aircraft. Moreover, it has aerodynamic function: to deswirl the flow from the last stage of turbine. Such flow management significantly enhances aerodynamic efficiency and engine thrust.
Concerning TRS research, many studies have reached up astage involving laboratory studies to physically validate the analytical predictionsof TRS separate elements. However, these studies were often constrained either bythe lack of engine relevant conditions or relied on simplified models. This reflects alimited experimental database on TRS and highlights the need for comprehensiveTRS validation.
The thesis closes the critical knowledge gap and provides the first comprehensive aerodynamic analysis of the latest and most advanced TRS configurations. This thesis is focused on two TRS types used in all state-of-the-art turbofan engines: with radial and leaned outlet guide vanes (OGVs). For the experimental investigation of the TRS, a multimethod approach was applied and involved an array of advanced measurement techniques to provide insights into various aspects of TRS flow. The experimental results from this work not only offer a valuable database for future CFD simulations but also underscore the need for continued refinement of current industrial CFD tools essential for development of aerodynamically efficient TRS designs.
Aerotermoutveckling för effektiva jetmotorutlopp (AT3E)
VINNOVA (2023-01203), 2023-07-01 -- 2024-06-30.
VINNOVA (2017-04861), 2017-11-10 -- 2022-06-30.
Experimentell aerotermisk studie av nästa generations flygmotorkomponenter
Europeiska kommissionen (EU) (EC/H2020/821398), 2018-10-01 -- 2021-03-31.
Ämneskategorier
Rymd- och flygteknik
Strömningsmekanik och akustik
Infrastruktur
Chalmers strömningslaboratorium
ISBN
978-91-7905-988-0
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 2024:5454
Utgivare
Chalmers
HA4, Hörsalsvägen 4, Campus Johanneberg, Chalmers.
Opponent: Dr. Lars Ellbrant, Technology Demonstrator Director, GKN Aerospace