Application of a miniaturized solid state electrolyte sensor for tracer gas measurements in a two-stage low pressure turbine
- Submitting institution
-
University of Sussex
- Unit of assessment
- 12 - Engineering
- Output identifier
- 356515_76080
- Type
- D - Journal article
- DOI
-
10.1016/j.expthermflusci.2016.11.035
- Title of journal
- Experimental Thermal and Fluid Science
- Article number
- -
- First page
- 367
- Volume
- 82
- Issue
- -
- ISSN
- 0894-1777
- Open access status
- Not compliant
- Month of publication
- November
- Year of publication
- 2016
- URL
-
https://doi.org/10.1016/j.expthermflusci.2016.11.035
- Supplementary information
-
-
- Request cross-referral to
- -
- Output has been delayed by COVID-19
- No
- COVID-19 affected output statement
- -
- Forensic science
- No
- Criminology
- No
- Interdisciplinary
- No
- Number of additional authors
-
5
- Research group(s)
-
-
- Proposed double-weighted
- No
- Reserve for an output with double weighting
- No
- Additional information
- Elsewhere we have compared the diffusion of the tracer gas in the turbine from the paper to the distribution of temperature as influenced by turbulent heat transfer. This article has facilitated a deeper understanding of turbulent heat transfer inside a turbine. Today's industrial CFD codes have very crude models involving isotropic eddy viscosity and a constant turbulent Prandtl number. Both of these assumptions have been shown to be weak, through DNS solution comparisons. The evidence from the paper is encouraging and validating improved heat transfer modelling in CFD codes.
- Author contribution statement
- -
- Non-English
- No
- English abstract
- -
