The correct computation of steam subcooling, subsequent formation of nuclei and finally droplet growth is the basic prerequisite for a quantitative assessment of the wetness losses incurred in steam turbines due to thermal and inertial relaxation. The same basically applies for the prediction of droplet deposition and the resulting threat of erosion. Despite the fact that there are many computational fluid dynamics (CFD)-packages that can deal with real-gas effects in steam flows, the accurate and reliable prediction of subcooling, condensation, and wet steam flow in steam turbines using CFD is still a demanding task. One reason for this is the lack of validation data for turbines that can be used to assess the physical models applied. Experimental data from nozzle and cascade tests can be found in the open literature; however, these measurement results are only partly useful for validation purposes for a number of reasons. With regard to steam turbine test data, there are some publications, yet always without any information about the turbine stage geometries. This publication is part of a two-part paper; whereas Part I focuses on the numerical validation of wet steam models by means of condensing nozzle and cascade flows, the focus in this part lies on the comparison of CFD results of the turbine flow to experimental data at various load conditions. In order to assess the validity and reliability of the experimental data, the method of measurement is presented in detail and discussed. The comparison of experimental and numerical results is used for a discussion about the challenges in both modeling and measuring steam turbine flows, presenting the current experience and knowledge at Institute of Thermal Turbomachinery and Machinery Laboratory (ITSM).
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April 2015
Research-Article
Two-Phase Flow Modeling and Measurements in Low-Pressure Turbines—Part II: Turbine Wetness Measurement and Comparison to Computational Fluid Dynamics-Predictions
M. Schatz,
M. Schatz
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: schatz@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: schatz@itsm.uni-stuttgart.de
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T. Eberle,
T. Eberle
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: eberle@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: eberle@itsm.uni-stuttgart.de
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M. Grübel,
M. Grübel
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: gruebel@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: gruebel@itsm.uni-stuttgart.de
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J. Starzmann,
J. Starzmann
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: starzmann@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: starzmann@itsm.uni-stuttgart.de
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D. M. Vogt,
D. M. Vogt
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: vogt@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: vogt@itsm.uni-stuttgart.de
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N. Suerken
e-mail: norbert.suerken@siemens.com
N. Suerken
Siemens AG, Energy Sector
,Rheinstrasse 100
,Mülheim (Ruhr) D-45478
, Germany
e-mail: norbert.suerken@siemens.com
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M. Schatz
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: schatz@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: schatz@itsm.uni-stuttgart.de
T. Eberle
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: eberle@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: eberle@itsm.uni-stuttgart.de
M. Grübel
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: gruebel@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: gruebel@itsm.uni-stuttgart.de
J. Starzmann
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: starzmann@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: starzmann@itsm.uni-stuttgart.de
D. M. Vogt
ITSM—Institute of Thermal Turbomachinery and
Machinery Laboratory,
e-mail: vogt@itsm.uni-stuttgart.de
Machinery Laboratory,
University of Stuttgart
,Pfaffenwaldring 6
,Stuttgart D-70569
, Germany
e-mail: vogt@itsm.uni-stuttgart.de
N. Suerken
Siemens AG, Energy Sector
,Rheinstrasse 100
,Mülheim (Ruhr) D-45478
, Germany
e-mail: norbert.suerken@siemens.com
Contributed by the Turbomachinery Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received July 28, 2014; final manuscript received August 8, 2014; published online October 28, 2014. Editor: David Wisler.
J. Eng. Gas Turbines Power. Apr 2015, 137(4): 042603 (9 pages)
Published Online: October 28, 2014
Article history
Received:
July 28, 2014
Revision Received:
August 8, 2014
Connected Content
A companion article has been published:
Two-Phase Flow Modeling and Measurements in Low-Pressure Turbines—Part I: Numerical Validation of Wet Steam Models and Turbine Modeling
Citation
Schatz, M., Eberle, T., Grübel, M., Starzmann, J., Vogt, D. M., and Suerken, N. (October 28, 2014). "Two-Phase Flow Modeling and Measurements in Low-Pressure Turbines—Part II: Turbine Wetness Measurement and Comparison to Computational Fluid Dynamics-Predictions." ASME. J. Eng. Gas Turbines Power. April 2015; 137(4): 042603. https://doi.org/10.1115/1.4028547
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