Turbomachinery Research Group
Research keywords:
· aerodynamics
· fluid mechanics
· fluid machinery
· fluid systems
· turbomachinery
· aeroacoustics
· computational fluid dynamics (CFD)
· computational aeroacoustics (CAA)
Horizon Europe keywords:
· Cities and communities
· Clean and healthy air, water and soil
· Clean, sustainable, secure and competitive energy supply
· Climate change mitigation and adaptation
· Energy efficient buildings
· European Green Deal
· Renewable energy
· Smart and sustainable transport and mobility
Introduction of the Research Group
Over the past decades, one of the main research areas of the Budapest University of Technology and Economics, Faculty of Mechanical Engineering, Department of Fluid Mechanics has been turbomachinery. The Turbomachinery Research Group brings together members of the Department of Fluid Mechanics working in this area. Our research goal is to design more efficient and quieter fluid machinery (or even complex fluid systems) and to further develop methods to facilitate this. The narrower research areas of the members of the group range from basic research on flow and acoustic phenomena in fluid systems to applied research in industrial fluid systems. In the course of the research, the infrastructure of the Theodore von Kármán Wind Tunnel Laboratory of the Department of Fluid Mechanics (wind tunnels; hotwire anemometry (CTA), Laser Doppler anemometry (LDA), and particle image velocimetry (PIV) measurement techniques; multichannel pressure, force, and torque measurement systems; acoustic measurements; vibration diagnostics; phased array microphone systems; and flow visualization) is utilized, and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects. and particle image velocimetry (PIV) measurement techniques; multichannel pressure, force, and torque measurement systems; acoustic measurements; vibration diagnostics; phased array microphone systems; and flow visualization) is utilized, and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects. and particle image velocimetry (PIV) measurement techniques; multichannel pressure, force, and torque measurement systems; acoustic measurements; vibration diagnostics; phased array microphone systems; and flow visualization) is utilized, and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects. acoustic measurements; vibration diagnostics; phased array microphone systems; and flow visualization) is utilized, and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects. acoustic measurements; vibration diagnostics; phased array microphone systems; and flow visualization) is utilized, and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects. and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects. and in addition we also rely on computational fluid dynamics (CFD) and computational aeroacoustics (CAA) simulation techniques. In the course of our work, we consider it important to support the industry. Therefore, in addition to basic research grants, we also cooperate with a number of industrial partners from the private sector. Other than research, we also focus on nurturing talented engineering students and therefore constantly strive to involve students interested in fluid mechanics and acoustics in our research projects.
Watch our 3-minute introductory video:
Achievements
- Design of multiple axial flow fan families for a wide range of industrial applications which can be characterized as being highly efficient and quiet- Providing the industry with key blade stacking design guidelines (eg sweep, dihedral, and skew)
- Explanation of the 3D flow field of turbomachinery designed using controlled vortex design methods.
- Providing the industry with design guidelines for highly efficient turbomachinery
- Development of design guidelines for quiet turbomachinery
- Extension of semi-empirical noise generation models for real axial flow fan geometry
- Explanation of noise emission reduction effect of bellmouth inlets of axial flow fans
- Development of multiple noise source localization methods for turbomachinery applications
- Providing a deeper understanding of the beamforming results of turbomachinery applications
- Explanation of turbomachinery noise sources
Publications
Vad, J. (2008). Aerodynamic effects of blade sweep and skew in low-speed axial flow rotors at the design flow rate: an overview. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 222(1), 69-85. https://doi.org/10.1243/09576509JPE471Vad, J., Kwedikha, ARA, Horváth, Cs., Balczó, M., Lohász, MM, & Régert, T. (2007). Aerodynamic effects of forward blade skew in axial flow rotors of controlled vortex design. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 221(7), 1011-1023. https://doi.org/10.1243/09576509JPE420
Horváth, Cs., Envia, E., & Podboy, GG (2014). Limitations of phased array beamforming in open rotor noise source imaging. AIAA journal, 52(8), 1810-1817. https://doi.org/10.2514/1.J052952
Vad, J. (2013), Forward blade sweep applied to low-speed axial fan rotors of controlled vortex design: an overview, JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER-TRANSACTIONS OF THE ASME 135 : 1 Paper: 012601 , 9 p. https://doi.org/10.1115%2F1.4007428
Benedek, T., & Vad, J. (2016), An industrial on-site methodology for combined acoustic-aerodynamic diagnostics of axial fans, involving the Phased Array Microphone technique, INTERNATIONAL JOURNAL OF AEROACOUSTICS 15 : 1-2 pp. 81-102. , 22 p. https://doi.org/10.1177%2F1475472X16630849
Journals
Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy; AIAA Journal; Applied Acoustics; International Journal of Aeroacoustics; International Journal of Turbomachinery, Propulsion, and Power; Journal of Sound and Vibration; Journal of TurbomachineryInfrastructure
Wind tunnels, Hotwire anemometry (CTA), Laser Doppler Anemometry (LDA), Particle Image Velocimetry (PIV), Multi-channel pressure, force, and torque measurements, Acoustic measurements, Vibration measurements, Phased array microphone systems, Flow visualization, Computational Fluid Dynamics (CFD), Computational AeroAcoustics (CAA), In-house simulation tool developmentProjects
- Concerted investigation of aerodynamic and noise generation mechanisms in highly-loaded axial flow rotor blade rows, 2011-2014, principal investigator, grant, National Research, Development and Innovation Office- Further development of a phased array microphone-based diagnostics method for aiding in the loss and noise reduction of axial flow industrial fans, 2014-2018, principal investigator, grant, National Research, Development and Innovation Office
- Aeroacoustic and aerodynamic investigation of counter-rotating open rotors, utilizing beamforming methods, 2016-2019, principal investigator, grant, National Research, Development and Innovation Office
- Elaboration of new methods for noise mapping of ducted axial fans, 2018-2022, principal investigator, grant, National Research, Development and Innovation Office
- Development of complex technologies for municipal solid waste with increased efficiency of processing and energy utilization, 2020-2022 , principal investigator, grant, National Research, Development and Innovation Office
Industry relations
AVLKnorr-Bremse
Audi
Flowserve
Grundfos
Hungaro-Ventilator
MOL
Rolls Royce
Siemens
Conferences
ASME Turbo Expo, Online, 13-17 June 2022, János Vad, Gábor Daku, participants14th European Conference on Turbomachinery Fluid dynamics & Thermodynamics, Online 12-16 April, 2021, János Vad, Estzella Balla, Gábor Daku, participants
ASME Turbo Expo , Online, 21-25 September 2020, János Vad, Gábor Daku, participants
8th Berlin Beamforming Conference (BeBeC), Berlin, Germany, 2-3 March 2020, Csaba Horváth, Bálint Kocsis, Estzella Balla participants
INTER-NOISE Congress, changing location , 2020, 2021, 2022, Csaba Horváth organizer
25th AIAA/CEAS Aeroacoustics Conference, Delft, Netherlands, 20-23 May 2019, Csaba Horváth, Kristóf Tokaji, Bálint Kocsis, participants
Conference on Modeling Fluid Flow, Budapest, Hungary, 4-7 September 2018, János Vad, Chairman of the local organizing committee, Csaba Horváth, Secretary of the scientific committee, Estzella Balla, Secretariat
International Conference on Fan Noise, Technology and Numerical Methods, Darmstadt, Germany, 18-20 April, 2018, Csaba Horváth organizer
7th Berlin Beamforming Conference (BeBeC), Berlin, Germany, 5-6 March 2018, Csaba Horváth, Kristóf Tokaji, Bálint Kocsis, Estzella Balla participants
21st Workshop of the Aeroacoustics Specialists Committee of the CEAS, Dublin, Ireland, 13-15 September, 2017, organizer Csaba Horváth