Numerical Investigation of the Influence of Air Contaminants on the Interfacial Heat Transfer in Transonic Flow in a Compressor Rotor

Atmospheric air is a commonly used working fluid in turbomachinery. The air typically contains a certain amount of suspended solid particles, as well as water in the form of vapor or droplets. In the current paper, we focus on the numerical modeling of humid air transonic flow in turbomachinery. In...

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Published inEnergies (Basel) Vol. 15; no. 12; p. 4330
Main Authors Wiśniewski, Piotr, Zhang, Guojie, Dykas, Sławomir
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2022
Subjects
Air flow
Air pollution
Analysis
Compression
Compressor rotors
computational fluid dynamics
Condensation
Contaminants
Droplets
Efficiency
Evaporation
Gas turbines
Heat
Heat transfer
Humidity
Investigations
Mach number
Moisture content
Numerical analysis
Outdoor air quality
Parameters
pollution
relative humidity
Rotors
Solid suspensions
Suspended solids
Transonic flow
Turbines
Turbofan engines
Turbomachinery
Turbulence models
Velocity
Water
Water content
Water drops
Water pollution
Working fluids
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Summary:Atmospheric air is a commonly used working fluid in turbomachinery. The air typically contains a certain amount of suspended solid particles, as well as water in the form of vapor or droplets. In the current paper, we focus on the numerical modeling of humid air transonic flow in turbomachinery. In this paper we demonstrate a rarely considered, but as presented herein important influence of air humidity, pollution and liquid water content on the performance of the first stage of the gas turbine compressor and turbofan engine fan (NASA rotors 37 and 67). We also discuss the impact of the interfacial heat transfer associated with steam condensation or water evaporation on the distribution of stagnation parameters at the rotor outlet, the rotor performance, and flow conditions, as well as losses. Results demonstrate the impact of the number of pollution particles and water droplets on the compression process in the analyzed rotors, especially on the Mach number distribution in the blade-to-blade channel. In this paper we highlight that the air pollution and liquid water content, together with such physical phenomena as steam condensation or water droplets evaporation, exert a significant influence on work parameters, losses and efficiency, and thus should be considered in high-velocity airflow simulations.
ISSN:1996-1073
1996-1073
DOI:10.3390/en15124330