Ball bearing turbocharger vibration management: application on high speed balancer
Today's modern internal combustion engines are increasingly focused on downsizing, high fuel efficiency and low emissions, which requires appropriate design and technology of turbocharger bearing systems. Automotive turbochargers operate faster and with strong engine excitation; vibration manag...
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| Veröffentlicht in: | Mechanics & industry : an international journal on mechanical sciences and engineering applications 2020, Vol.21 (6), p.619 |
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| creator | Gjika, Kostandin Costeux, Antoine LaRue, Gerry Wilson, John |
| description | Today's modern internal combustion engines are increasingly focused on downsizing, high fuel efficiency and low emissions, which requires appropriate design and technology of turbocharger bearing systems. Automotive turbochargers operate faster and with strong engine excitation; vibration management is becoming a challenge and manufacturers are increasingly focusing on the design of low vibration and high-performance balancing technology. This paper discusses the synchronous vibration management of the ball bearing cartridge turbocharger on high-speed balancer and it is a continuation of papers [1–3]. In a first step, the synchronous rotordynamics behavior is identified. A prediction code is developed to calculate the static and dynamic performance of “ball bearing cartridge-squeeze film damper”. The dynamic behavior of balls is modeled by a spring with stiffness calculated from Tedric Harris formulas and the damping is considered null. The squeeze film damper model is derived from the Osborne Reynolds equation for incompressible and synchronous fluid loading; the stiffness and damping coefficients are calculated assuming that the bearing is infinitely short, and the oil film pressure is modeled as a cavitated π film model. The stiffness and damping coefficients are integrated on a rotordynamics code and the bearing loads are calculated by converging with the bearing eccentricity ratio. In a second step, a finite element structural dynamics model is built for the system “turbocharger housing-high speed balancer fixture” and validated by experimental frequency response functions. In the last step, the rotating dynamic bearing loads on the squeeze film damper are coupled with transfer functions and the vibration on the housings is predicted. The vibration response under single and multi-plane unbalances correlates very well with test data from turbocharger unbalance masters. The prediction model allows a thorough understanding of ball bearing turbocharger vibration on a high speed balancer, thus optimizing the dynamic behavior of the “turbocharger-high speed balancer” structural system for better rotordynamics performance identification and selection of the appropriate balancing process at the development stage of the turbocharger. |
| doi_str_mv | 10.1051/meca/2020091 |
| format | Article |
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Automotive turbochargers operate faster and with strong engine excitation; vibration management is becoming a challenge and manufacturers are increasingly focusing on the design of low vibration and high-performance balancing technology. This paper discusses the synchronous vibration management of the ball bearing cartridge turbocharger on high-speed balancer and it is a continuation of papers [1–3]. In a first step, the synchronous rotordynamics behavior is identified. A prediction code is developed to calculate the static and dynamic performance of “ball bearing cartridge-squeeze film damper”. The dynamic behavior of balls is modeled by a spring with stiffness calculated from Tedric Harris formulas and the damping is considered null. The squeeze film damper model is derived from the Osborne Reynolds equation for incompressible and synchronous fluid loading; the stiffness and damping coefficients are calculated assuming that the bearing is infinitely short, and the oil film pressure is modeled as a cavitated π film model. The stiffness and damping coefficients are integrated on a rotordynamics code and the bearing loads are calculated by converging with the bearing eccentricity ratio. In a second step, a finite element structural dynamics model is built for the system “turbocharger housing-high speed balancer fixture” and validated by experimental frequency response functions. In the last step, the rotating dynamic bearing loads on the squeeze film damper are coupled with transfer functions and the vibration on the housings is predicted. The vibration response under single and multi-plane unbalances correlates very well with test data from turbocharger unbalance masters. The prediction model allows a thorough understanding of ball bearing turbocharger vibration on a high speed balancer, thus optimizing the dynamic behavior of the “turbocharger-high speed balancer” structural system for better rotordynamics performance identification and selection of the appropriate balancing process at the development stage of the turbocharger.</description><identifier>ISSN: 2257-7777</identifier><identifier>EISSN: 2257-7750</identifier><identifier>DOI: 10.1051/meca/2020091</identifier><language>eng</language><publisher>Villeurbanne: EDP Sciences</publisher><subject>Acoustics ; Automotive engines ; Balancing ; Ball bearings ; Cartridges ; Computational fluid dynamics ; Contact angle ; Damping ; Downsizing ; Finite element method ; Fluid flow ; Frequency response functions ; Gas turbine engines ; High speed ; Housings ; Incompressible flow ; Internal combustion engines ; Load ; Mathematical models ; Prediction models ; Reynolds equation ; Rotor dynamics ; Squeeze films ; Stiffness ; Superchargers ; Thrust bearings ; Transfer functions ; Vibration response ; Viscosity</subject><ispartof>Mechanics & industry : an international journal on mechanical sciences and engineering applications, 2020, Vol.21 (6), p.619</ispartof><rights>2020. 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The squeeze film damper model is derived from the Osborne Reynolds equation for incompressible and synchronous fluid loading; the stiffness and damping coefficients are calculated assuming that the bearing is infinitely short, and the oil film pressure is modeled as a cavitated π film model. The stiffness and damping coefficients are integrated on a rotordynamics code and the bearing loads are calculated by converging with the bearing eccentricity ratio. In a second step, a finite element structural dynamics model is built for the system “turbocharger housing-high speed balancer fixture” and validated by experimental frequency response functions. In the last step, the rotating dynamic bearing loads on the squeeze film damper are coupled with transfer functions and the vibration on the housings is predicted. The vibration response under single and multi-plane unbalances correlates very well with test data from turbocharger unbalance masters. The prediction model allows a thorough understanding of ball bearing turbocharger vibration on a high speed balancer, thus optimizing the dynamic behavior of the “turbocharger-high speed balancer” structural system for better rotordynamics performance identification and selection of the appropriate balancing process at the development stage of the turbocharger.</description><subject>Acoustics</subject><subject>Automotive engines</subject><subject>Balancing</subject><subject>Ball bearings</subject><subject>Cartridges</subject><subject>Computational fluid dynamics</subject><subject>Contact angle</subject><subject>Damping</subject><subject>Downsizing</subject><subject>Finite element method</subject><subject>Fluid flow</subject><subject>Frequency response functions</subject><subject>Gas turbine engines</subject><subject>High speed</subject><subject>Housings</subject><subject>Incompressible flow</subject><subject>Internal combustion engines</subject><subject>Load</subject><subject>Mathematical models</subject><subject>Prediction models</subject><subject>Reynolds equation</subject><subject>Rotor dynamics</subject><subject>Squeeze films</subject><subject>Stiffness</subject><subject>Superchargers</subject><subject>Thrust bearings</subject><subject>Transfer functions</subject><subject>Vibration response</subject><subject>Viscosity</subject><issn>2257-7777</issn><issn>2257-7750</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><sourceid>BENPR</sourceid><recordid>eNo9kNtKAzEQhoMoWGrvfICAt66dZDeH9U6LJygIotdhks0eyp5MtoJv75YW4Yf5GT5m4CPkmsEdA8HWnXe45sABcnZGFpwLlSgl4Py_K3VJVjHuAIDJPM8yuSAfj9i21HoMTV_RaR_s4GoMlQ_0p7EBp2boaYc9Vr7z_XRPcRzbxh33c-qmqmkcvS-oxRZ758MVuSixjX51mkvy9fz0uXlNtu8vb5uHbeJSYFOSSl1y1MiYK1jhnVDWaWYFaBBecQuicABSSWuVsErm1gkhLOfISlakebokN8e7Yxi-9z5OZjfsQz-_NDzTGZdap3qmbo-UC0OMwZdmDE2H4dcwMAdx5iDOnMSlf6g_YPI</recordid><startdate>2020</startdate><enddate>2020</enddate><creator>Gjika, Kostandin</creator><creator>Costeux, Antoine</creator><creator>LaRue, Gerry</creator><creator>Wilson, John</creator><general>EDP Sciences</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>8FE</scope><scope>8FG</scope><scope>ABJCF</scope><scope>AFKRA</scope><scope>BENPR</scope><scope>BGLVJ</scope><scope>CCPQU</scope><scope>DWQXO</scope><scope>FR3</scope><scope>HCIFZ</scope><scope>L6V</scope><scope>M7S</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PRINS</scope><scope>PTHSS</scope><scope>S0W</scope></search><sort><creationdate>2020</creationdate><title>Ball bearing turbocharger vibration management: application on high speed balancer</title><author>Gjika, Kostandin ; 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Automotive turbochargers operate faster and with strong engine excitation; vibration management is becoming a challenge and manufacturers are increasingly focusing on the design of low vibration and high-performance balancing technology. This paper discusses the synchronous vibration management of the ball bearing cartridge turbocharger on high-speed balancer and it is a continuation of papers [1–3]. In a first step, the synchronous rotordynamics behavior is identified. A prediction code is developed to calculate the static and dynamic performance of “ball bearing cartridge-squeeze film damper”. The dynamic behavior of balls is modeled by a spring with stiffness calculated from Tedric Harris formulas and the damping is considered null. The squeeze film damper model is derived from the Osborne Reynolds equation for incompressible and synchronous fluid loading; the stiffness and damping coefficients are calculated assuming that the bearing is infinitely short, and the oil film pressure is modeled as a cavitated π film model. The stiffness and damping coefficients are integrated on a rotordynamics code and the bearing loads are calculated by converging with the bearing eccentricity ratio. In a second step, a finite element structural dynamics model is built for the system “turbocharger housing-high speed balancer fixture” and validated by experimental frequency response functions. In the last step, the rotating dynamic bearing loads on the squeeze film damper are coupled with transfer functions and the vibration on the housings is predicted. The vibration response under single and multi-plane unbalances correlates very well with test data from turbocharger unbalance masters. 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| subjects | Acoustics Automotive engines Balancing Ball bearings Cartridges Computational fluid dynamics Contact angle Damping Downsizing Finite element method Fluid flow Frequency response functions Gas turbine engines High speed Housings Incompressible flow Internal combustion engines Load Mathematical models Prediction models Reynolds equation Rotor dynamics Squeeze films Stiffness Superchargers Thrust bearings Transfer functions Vibration response Viscosity |
| title | Ball bearing turbocharger vibration management: application on high speed balancer |
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