Transient Tribo-Dynamics of Thermo-Elastic Compliant High-Performance Piston Skirts

Littlefair, Bryn; Cruz, Miguel De la; Theodossiades, Stephanos; Mills, Robin S.; Howell-Smith, S.J.; Rahnejat, Homer; Dwyer-Joyce, R. S.

doi:10.1007/s11249-013-0243-6

Cited by 41 publications

(28 citation statements)

References 34 publications

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“…The mechanical distortion is determined by the method used by Littlefair et al (2014). The loads applied for the estimation of the piston's mechanical distortion are as follows: (1) gas load applied on the piston crown; (2) piston inertial force due to the primary accelerative motion; and (3) piston side force acting orthogonal to the skirt surface.…”

Section: Loads For Mechanical Distortionmentioning

confidence: 99%

“…The loads applied for the estimation of the piston's mechanical distortion are as follows: (1) gas load applied on the piston crown; (2) piston inertial force due to the primary accelerative motion; and (3) piston side force acting orthogonal to the skirt surface. As shown in (Littlefair et al, 2014), these loads actually cause the skirt to deform, which in turn affect the pin boss. In this study, the multi-body dynamic motion model is established with the solid model.…”

Section: Loads For Mechanical Distortionmentioning

confidence: 99%

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Analysis of piston-pin lubrication considering the effects of structure deformation and cavitation

Yue-hui

et al. 2015

J. Zhejiang Univ. Sci. A

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Abstract:Running conditions for piston pin boss bearing have become very severe due to the high combustion pressure and piston temperature increase over the past ten years. The aim of this paper was to analyze the friction and lubrication characteristic of piston pin boss bearings and a connecting rod small end bearing. This paper provided a comprehensive analysis of piston pin based on a multi-body dynamic model which considers the oil film cavitation and structure deformation. Effects of different lubrication models, pin structures, and thermal deformation on the lubrication were discussed. The lubrication characteristics and performance parameters including oil film pressure distribution, asperity contact pressure, the minimum oil film thickness, the maximum oil film pressure, and friction power loss were listed. The results showed that the minimum oil film thickness was very different and the maximum oil film pressure was nearly the same. A parabola profile of pin bore can reduce the wear to some extent, and a flare profile intensified wear in some places and caused the wear to be concentrated on a smaller area. Reducing the inner diameters will reduce the wear of the pin boss. However, in a realistic design of the pin, avoiding high inertial force of the piston system and satisfying the demand for reliability of the pin, increasing the inner diameters and reliability is a 'trade off' problem. A suitable design of the hollow diameter is very important. The results can provide guidance for the design of the pin boss bearing.

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Section: Loads For Mechanical Distortionmentioning

confidence: 99%

Section: Loads For Mechanical Distortionmentioning

confidence: 99%

Analysis of piston-pin lubrication considering the effects of structure deformation and cavitation

Yue-hui

et al. 2015

J. Zhejiang Univ. Sci. A

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“…Hence, the study of the effects of the piston skirt profile on the secondary motion and piston dynamics is essential. Littlefair et al [16] analyzed the piston dynamics, thermoelastic distortion, and transient elastohydrodynamics of the lightweight piston with preferentially compliant short partial skirt. The greater entrainment wedge at bottom skirt and better conforming contact geometry at top skirt were achieved, and therefore, the load-carrying capacity was improved and the friction was reduced.…”

Section: Introductionmentioning

confidence: 99%

The Analysis of Secondary Motion and Lubrication Performance of Piston considering the Piston Skirt Profile

Lü

Wang

et al. 2018

Shock and Vibration

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The work performance of piston-cylinder liner system is affected by the lubrication condition and the secondary motion of the piston. Therefore, more and more attention has been paid to the secondary motion and lubrication of the piston. In this paper, the Jakobson-Floberg-Olsson (JFO) boundary condition is employed to describe the rupture and reformation of oil film. The average Reynolds equation of skirt lubrication is solved by the finite difference method (FDM). The secondary motion of pistonconnecting rod system is modeled; the trajectory of the piston is calculated by the Runge-Kutta method. By considering the inertia of the connecting rod, the influence of the longitudinal and horizontal profiles of piston skirt, the offset of the piston pin, and the thermal deformation on the secondary motion and lubrication performance is investigated. The parabolic longitudinal profile, the smaller top radial reduction and ellipticities of the middle-convex piston, and the bigger bottom radial reduction and ellipticities can effectively reduce the secondary displacement and velocity, the skirt thrust, friction, and the friction power loss. The results show that the connecting rod inertia, piston skirt profile, and thermal deformation have important influence on secondary motion and lubrication performance of the piston.

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“…VIB-16-1462 -Theodossiades is the piston rotation about its pin and it can be defined in terms of piston eccentricities ( and ) [19]. Newmark integration and predictor-corrector techniques are exploited to numerically solve equations (6).…”

Section: Piston Dynamics With the Nonlinear Absorbermentioning

confidence: 99%

“…The parameters of these elements are evaluated either experimentally [15,16] or theoretically [13]. Models combining tribology and dynamics take into account jointly the effects of piston dynamics, structural deformability and hydrodynamics of the lubricant film (Elasto-hydrodynamic lubrication) [17][18][19]. Thus, tribodynamics models are largely exploited to predict and identify piston-cylinder interactions [20,21].…”

Section: Introductionmentioning

confidence: 99%

Passive Control of Piston Secondary Motion Using Nonlinear Energy Absorbers

Dolatabadi

Theodossiades

Rothberg

2017

Journal of Vibration and Acoustics

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The impulsive behaviour of the piston in the cylinder liner plays a key role in the Noise, Vibration and Harshness (NVH) of internal combustion engines. There have been several studies on the identification and quantification of piston impact action under various operation conditions. In the current study, the dynamics of the piston secondary motion are initially explored in order to describe the aggressive oscillations, energy loss and noise generation. The control of piston secondary motion (and thus, impacts) is investigated using a new passive approach based on energy transfer of the highly transient oscillations to a nonlinear absorber. The effectiveness of this new method for improving the piston impact behaviour is discussed using a preliminary parametric study that leads to the conceptual design of a nonlinear energy absorber.

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Transient Tribo-Dynamics of Thermo-Elastic Compliant High-Performance Piston Skirts

Cited by 41 publications

References 34 publications

Analysis of piston-pin lubrication considering the effects of structure deformation and cavitation

Analysis of piston-pin lubrication considering the effects of structure deformation and cavitation

The Analysis of Secondary Motion and Lubrication Performance of Piston considering the Piston Skirt Profile

Passive Control of Piston Secondary Motion Using Nonlinear Energy Absorbers

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