Thermal management for gas lubricated, high-speed turbomachinery

High-speed turbomachinery is commonly designed to achieve high power densities. Limited space for active cooling results in a challenging thermal management. A thermal modeling approach leveraging modern declarative programming capabilities is presented, yielding an efficient dynamic model capable o...

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Vydáno v:Applied thermal engineering Ročník 218; s. 119229
Hlavní autoři: Olmedo, L.E., Liu, W., Gjika, K., Schiffmann, J.
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Ltd 05.01.2023
Témata:
1D-networks
Declarative programming
Dynamic modeling
Gas lubricated bearings
Thermal management
Turbomachinery
Turbomachinery
Thermal management
Declarative programming
1D-networks
Gas lubricated bearings
Dynamic modeling
ISSN:1359-4311
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Abstract High-speed turbomachinery is commonly designed to achieve high power densities. Limited space for active cooling results in a challenging thermal management. A thermal modeling approach leveraging modern declarative programming capabilities is presented, yielding an efficient dynamic model capable of real-time simulation while achieving accurate results. These properties enable the inclusion of thermal management strategies in an early stage of the design process. Further, the effect of varying thermal and transport properties of materials and fluids during transient conditions is included and is suggested to yield a high impact on thermal loads and heat evacuation capabilities. The often neglected fluid advection within the system is modeled by integrating a 1D fluid network from MatlabTM SimscapeTM to the thermal model, displaying a significant impact on the temperature estimation for critical parts. The accuracy of the presented model is verified against three gas-bearing supported high-speed turbomachinery experiments for stationary and transient operation. •Dynamic thermal simulation for gas lubricated, high-speed turbomachinery.•Accurate and efficient multi-domain models based on 1D physical networks.•Modeling flexibility with declarative programming paradigm.•Experimental validation from three different gas-lubricated turbomachines.
AbstractList High-speed turbomachinery is commonly designed to achieve high power densities. Limited space for active cooling results in a challenging thermal management. A thermal modeling approach leveraging modern declarative programming capabilities is presented, yielding an efficient dynamic model capable of real-time simulation while achieving accurate results. These properties enable the inclusion of thermal management strategies in an early stage of the design process. Further, the effect of varying thermal and transport properties of materials and fluids during transient conditions is included and is suggested to yield a high impact on thermal loads and heat evacuation capabilities. The often neglected fluid advection within the system is modeled by integrating a 1D fluid network from MatlabTM SimscapeTM to the thermal model, displaying a significant impact on the temperature estimation for critical parts. The accuracy of the presented model is verified against three gas-bearing supported high-speed turbomachinery experiments for stationary and transient operation. •Dynamic thermal simulation for gas lubricated, high-speed turbomachinery.•Accurate and efficient multi-domain models based on 1D physical networks.•Modeling flexibility with declarative programming paradigm.•Experimental validation from three different gas-lubricated turbomachines.
ArticleNumber 119229
Author Olmedo, L.E.
Liu, W.
Schiffmann, J.
Gjika, K.
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  givenname: K.
  surname: Gjika
  fullname: Gjika, K.
  email: kostandin.gjika@kgturbomachinery.com
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  orcidid: 0000-0001-8822-9974
  surname: Schiffmann
  fullname: Schiffmann, J.
  email: jurg.schiffmann@epfl.ch
  organization: Ecole Polytechnique Fédérale de Lausanne, EPFL STI IGM LAMD, CH-2002, Neuchâtel, Switzerland
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Keywords Turbomachinery
Thermal management
Declarative programming
1D-networks
Gas lubricated bearings
Dynamic modeling
Language English
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Snippet High-speed turbomachinery is commonly designed to achieve high power densities. Limited space for active cooling results in a challenging thermal management. A...
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StartPage 119229
SubjectTerms 1D-networks
Declarative programming
Dynamic modeling
Gas lubricated bearings
Thermal management
Turbomachinery
Title Thermal management for gas lubricated, high-speed turbomachinery
URI https://dx.doi.org/10.1016/j.applthermaleng.2022.119229
Volume 218
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