Abstract The objective of the EU project “Sensors Towards Advanced Monitoring and Control of Gas Turbine Engines (acronym STARGATE)” is the development of a suite of advanced sensors, instrumentation and related systems in order to contribute to the developing of the next generation of green and efficient gas turbine engines. One work package of the project deals with the design and development of a long wavelength infrared (LWIR) radiation thermometer for the non-contact measurement of the surface temperature of thermal barrier coatings (TBCs) during the operation of gas turbine engines. For opaque surfaces (e.g. metals or superalloys) radiation thermometers which are sensitive in the near or short wavelength infrared are used as state-of-the-art method for non-contact temperature measurements. But this is not suitable for oxide ceramic based TBCs (e.g. partially yttria stabilized zirconia) as oxide ceramics are semi-transparent in the near and short wavelength infrared spectral region. Fortunately the applied ceramic materials are non-transparent in the long wavelength infrared and additionally exhibit a high emittance in this wavelength region. Therefore, a LWIR pyrometer can be used for non-contact temperature measurements of the surfaces of TBCs as such pyrometers overcome the described limitation of existing techniques. For performing non-contact temperature measurements in gas turbines one has to know the infrared-optical properties of the applied TBCs as well as of the hot combustion gas in order to properly analyse the measurement data. For reaching a low uncertainty on the one hand the emittance of the TBC should be high (>0.9) in order to reduce reflections from the hot surrounding and on the other hand the absorbance of the hot combustion gas should be low ( This paper presents the results of the work performed by the authors with focus on the implementation of the LWIR pyrometer and the selection of the optimal wavelength band where the detector should be sensitive. Besides determining the spectral infrared-optical properties (emittance, transmittance and absorbance) of the TBCs and the hot combustion gas at high temperatures up to 1700 K, the wavelength specification of the developed LWIR pyrometer is defined. Also an overview of the LWIR radiation thermometer is given and the preliminary results for different temperatures and environmental conditions are presented. Finally the measurement uncertainty of the LWIR-pyrometer is deduced.
[1]
J. Brun,et al.
Temperature Measurement: Christiansen Wavelength and Blackbody Reference
,
2005
.
[3]
U. Schulz,et al.
Infrared-optical properties and heat transfer coefficients of semitransparent thermal barrier coatings
,
2009
.
[4]
Matthias Oechsner,et al.
Thermal-barrier coatings for more efficient gas-turbine engines
,
2012
.
[5]
Emittance of Y2O3 stabilised ZrO2 thermal barrier coatings prepared by electron-beam physical-vapour deposition
,
2000
.
[6]
L. Peluso,et al.
Role of environment deposits and operating surface temperature in spallation of air plasma sprayed thermal barrier coatings
,
1996
.
[7]
M. Arduini-Schuster,et al.
Infrared-optical characteristics of ceramics at elevated temperatures
,
2011
.
[8]
C. Levi.
Emerging materials and processes for thermal barrier systems
,
2004
.
[9]
J. Hartmann,et al.
High-temperature measurement techniques for the application in photometry, radiometry and thermometry
,
2009
.
[10]
H. Gremlich,et al.
IR Spectroscopy: An Introduction
,
2002
.
[11]
Carlos G. Levi,et al.
Environmental degradation of thermal-barrier coatings by molten deposits
,
2012
.
[12]
M. Arduini-Schuster,et al.
Newly Designed Apparatus for Measuring the Angular Dependent Surface Emittance in a Wide Wavelength Range and at Elevated Temperatures up to 1400°C
,
2012
.
[13]
S. Standard.
GUIDE TO THE EXPRESSION OF UNCERTAINTY IN MEASUREMENT
,
2006
.
[14]
L. Hanssen,et al.
Integrating-sphere system and method for absolute measurement of transmittance, reflectance, and absorptance of specular samples.
,
2001,
Applied optics.