Experimental and Numerical Study of Laminar-Turbulent Transition on a Low-Pressure Turbine Outlet Guide Vane
Paper i proceeding, 2020
There are several available transition models in RANS simulations and most of them need parameter tuning when introduced to new conditions. Evaluation of these models for different turbomachinery components is relatively well covered in the literature even though the model specifics often is a classified property of engine manufacturers. However, there are no cases in the literature of transition prediction with experimental verification in the TRS at engine-realistic conditions.
This work presents the first experimental verification of laminar-turbulent transition in a TRS module tested in the LPT-OGV experimental facility at Chalmers Laboratory of Thermal and Fluid Science. The facility is a semi-closed rig using a rotating 1.5 stage shrouded low-pressure turbine stage to create engine representative inlet conditions for the TRS downstream of the LPT stage. Transition was measured using differential IR-thermography (DIT) which is a non-intrusive two-dimensional measurement technique. The technique was specially developed at Chalmers for this particular purpose and validated by boundary layer hot-wire measurements. The numerical analysis was done using commercially available transition models in Fluent and Ansys CFX. Gamma-theta transition model was used with the k-omega SST turbulence model. Experiments and numerical simulations were performed at a chord Reynold number of 235000 and with LPT outlet swirl angles covering both the design point (ADP) and relevant off-design points.
Numerical and experimental results show that agreement between transition models and experiments can be achieved at these conditions. Boundary layers on the pressure side and suction side undergo laminar-turbulent transition for the selected test range. At decreased OGV aerodynamic load, the boundary layer on the pressure side near the leading edge is laminar along most of the span. At higher OGV loads the secondary flow is influencing the region near the shroud on the pressure side as well as near the hub on the suction side. The transition on the suction side midspan is significantly influenced by the vane load. The numerical analysis was used to better understand the involved flow mechanisms.
Turbine Exhaust Casing
Engine Exit Structure
Turbine Rear Structure
Secondary Flow
Low Pressure Turbine
Transition
Turbine Rear Frame.
Tail Bearing Housing
Experimental
Författare
Isak Jonsson
Chalmers, Mekanik och maritima vetenskaper, Strömningslära
Srikanth Deshpande
GKN Aerospace Sweden
Valery Chernoray
Chalmers, Mekanik och maritima vetenskaper, Strömningslära
Oskar Thulin
GKN Aerospace Sweden
Jonas Larsson
GKN Aerospace Sweden
Proceedings of the ASME Turbo Expo
Vol. 2B-2020 V02BT33A014
9780791884072 (ISBN)
Online, United Kingdom,
Aerotermoutveckling för effektiva jetmotorutlopp (AT3E)
VINNOVA (2017-04861), 2017-11-10 -- 2022-06-30.
VINNOVA (2023-01203), 2023-07-01 -- 2024-06-30.
Experimentell aerotermisk studie av nästa generations flygmotorkomponenter
Europeiska kommissionen (EU) (EC/H2020/821398), 2018-10-01 -- 2021-03-31.
Ämneskategorier
Rymd- och flygteknik
Teknisk mekanik
Strömningsmekanik och akustik
DOI
10.1115/GT2020-14990