Unsteady 1-Way Coupling of Combustor and High-Pressure Turbine II

Unsteady 1-Way Coupling of Combustor and High-Pressure Turbine II

Jonathan_Gründler_Unsteady 1-Way Coupling of Combustor and High-Pressure Turbine II_Figure1Jonathan_Gründler_Unsteady 1-Way Coupling of Combustor and High-Pressure Turbine II_Figure1

Figure 1: Vortex structures in NGV passage on 50 % span height.

Jonathan Gründler
Jonathan_Gründler_Unsteady 1-Way Coupling of Combustor and High-Pressure Turbine II_Figure2Jonathan_Gründler_Unsteady 1-Way Coupling of Combustor and High-Pressure Turbine II_Figure2

Figure 2: Velocity contour on CTI in the combined combustor-turbine simulation of research turbine LSTR.

Jonathan Gründler

Introduction

The flow conditions at the combustor turbine interface (CTI) have a significant role in the development process of modern gas turbines and turbo engines. At this location, the relevant information is transferred from the combustor to the turbine, and a deep understanding of the flow there is critical for a robust turbine design. The high-pressure turbine and especially its first stage is strongly affected by the flow in the combustor upstream. To design the turbine to specific life requirements and optimum efficiency, it is very important to understand the interaction mechanisms between the combustor and turbine and to take all the important combustor-related effects into account.

Methods

To enable scale-resolving simulation in the turbine context, it is essential to formulate an appropriate set of time-accurate inlet boundary conditions. A novel method for the unsteady 1-way coupling of combustor and turbine was developed. This method enables Proper Orthogonal Decomposition and Fourier Series (PODFS) to compress the full unsteady snapshot data at the CTI and uses it as inlet conditions for the turbine simulation. 

Results

Within this project period the PODFS method was applied to two combustor-turbine cases. First, the behavior of the first NGV of a high-pressure turbine under realistic inlet conditions has been investigated. For this purpose, the snapshot data of a combustor simulation was used in the PODFS method to create unsteady inlet boundary conditions for the NGV simulation. The simulations have been conducted on different meshes to evaluate the influence of mesh resolution on the results of the scale-resolving simulations. Also, a comparison between SAS and SBES turbulence models has been done. The main findings of these simulations are:

a. Mesh resolution has no significant effect on the aerodynamic parameter of the vanes but is affecting the thermal load of the NGV.

b. SBES turbulence model resolves more turbulence than SAS.

c. Appropriate inlet boundary conditions are very important for the thermal analysis of turbine vanes.

In the second simulation setup, the combustor simulator and the first NGV of the Large-Scale Turbine Rig (LSTR) were simulated. The integrated simulation of both in one domain could be used to generate the unsteady boundary conditions for a stand-alone turbine simulation. Furthermore, this simulation could serve as a comparison case for the stand-alone simulation. In future steps, the simulation setup needs to be improved and the simulation results can be compared with measurement data. By doing so, a comprehensive comparison with experimental data will be possible

Discussion

The developed method for the unsteady 1-way coupling of the combustor and turbine could be applied to an actual combustor-turbine case. The results are very promising and show the importance of the description of time-accurate inlet boundary conditions when doing scale-resolving turbine simulations. in a prolongation project, more simulations of the LSTR high-pressure turbine case need to be conducted to validate the method against experimental data.

Last Update

  • Last Update: 2023-09-11 17:26

Participating Universities