EATEEM | Experimental Aero- and Thermal investigation for a next generation Engine Exit Module

Summary
A unique facility for experimental testing of engine exit modules (EEM) at engine-realistic flow conditions is currently available at Chalmers University of Technology and will be used to address this JTP action. The unique design of the facility includes an open test section which permits investigation of the complete EEM assemblies consisting of a turbine rear structure (TRS) and a core exhaust nozzle. The facility is equipped with a 1.5 stage shrouded low-pressure turbine (LPT) providing realistic inflow to the tested EEM. The parameters of the facility completely fulfil the requirements specified in the topic description. Thus, the LPT blade height, the flow Reynolds number range, the LPT flow coefficient, the LPT load coefficient, the LPT exit swirl angle range, the LPT hub-to-tip ratio and the purge flow are as specified. The instrumentation of the facility also completely fulfils the topic requirements. Multi-hole pressure probes are available upstream and downstream of the tested EEM. Both traversing systems are covering an entire 360-degree sector of the test section from hub to shroud. Furthermore, in practically all modern techniques of the flow and heat transfer diagnostics are available in the facility. This includes a complete set of equipment and software for PIV (particle image velocimetry) including high-speed stereo-PIV, tomographic-PIV, long-distance micro-PIV and endoscopic micro-PIV. Furthermore, equipment and software for surface oil-flow visualisation and oil-film interferometry, hot-wire and hot-film interferometry, pressure- and temperature-sensitive paints, digital image correlation (DIC), naphthalene sublimation, liquid-crystal thermography and IR-thermography are available as well. Personnel in the workgroup is highly skilled in using all these measurement techniques and has many years of experience in innovation turbomachinery research programs at national and European level.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/821398
Start date: 01-10-2018
End date: 30-06-2022
Total budget - Public funding: 799 608,00 Euro - 799 608,00 Euro
Cordis data

Original description

A unique facility for experimental testing of engine exit modules (EEM) at engine-realistic flow conditions is currently available at Chalmers University of Technology and will be used to address this JTP action. The unique design of the facility includes an open test section which permits investigation of the complete EEM assemblies consisting of a turbine rear structure (TRS) and a core exhaust nozzle. The facility is equipped with a 1.5 stage shrouded low-pressure turbine (LPT) providing realistic inflow to the tested EEM. The parameters of the facility completely fulfil the requirements specified in the topic description. Thus, the LPT blade height, the flow Reynolds number range, the LPT flow coefficient, the LPT load coefficient, the LPT exit swirl angle range, the LPT hub-to-tip ratio and the purge flow are as specified. The instrumentation of the facility also completely fulfils the topic requirements. Multi-hole pressure probes are available upstream and downstream of the tested EEM. Both traversing systems are covering an entire 360-degree sector of the test section from hub to shroud. Furthermore, in practically all modern techniques of the flow and heat transfer diagnostics are available in the facility. This includes a complete set of equipment and software for PIV (particle image velocimetry) including high-speed stereo-PIV, tomographic-PIV, long-distance micro-PIV and endoscopic micro-PIV. Furthermore, equipment and software for surface oil-flow visualisation and oil-film interferometry, hot-wire and hot-film interferometry, pressure- and temperature-sensitive paints, digital image correlation (DIC), naphthalene sublimation, liquid-crystal thermography and IR-thermography are available as well. Personnel in the workgroup is highly skilled in using all these measurement techniques and has many years of experience in innovation turbomachinery research programs at national and European level.

Status

CLOSED

Call topic

JTI-CS2-2017-CfP07-ENG-02-06

Update Date

26-10-2022
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Horizon 2020
H2020-EU.3. SOCIETAL CHALLENGES
H2020-EU.3.4. SOCIETAL CHALLENGES - Smart, Green And Integrated Transport
H2020-EU.3.4.5. CLEANSKY2
H2020-EU.3.4.5.5. ITD Engines
H2020-CS2-CFP07-2017-02
JTI-CS2-2017-CfP07-ENG-02-06 Experimental investigation of aerodynamic and heat transfer properties for a next generation turbine frame and nozzle