Modelling of suspension components in a rail vehicle dynamics context

Bruni, Stefano; Viñolas, Jordi; Berg, Mats; Polách, Oldřich; Stichel, Sebastian

doi:10.1080/00423114.2011.586430

Cited by 204 publications

(140 citation statements)

References 85 publications

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“…During the tests of the support-axial traction drive with an elastic cog-wheel and a rubber-metal cross-arm [9,10], selfoscillations of a wheelset during boxing with frequency f 0 =80…85 Hz were followed by intensive subharmonic oscillations of an engine on a rubber-metal cross-arm with frequency (19…20 Hz) ~f 0 /4,…”

Section: The Use Of Inertia Masses Of the Drive As A Shock Absorbermentioning

confidence: 99%

Friction self-oscillation decrease in nonlinear system of locomotive traction drive

Antipin

Vorobiyov

Izmerov

et al. 2017

IOP Conf. Ser.: Mater. Sci. Eng.

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Influence of uneven distribution of coupling mass on locomotive wheel pairs, its tractive power, straight and curved sections of industrial rail tracks. A M Keropyan, L I Kantovich, B V Voronin et al. Abstract. The problems of the friction self-oscillation decrease in a nonlinear system of a locomotive traction drive are considered. It is determined that the self-oscillation amplitude decrease in a locomotive wheel pair during boxing in traction drives with an elastic linkage between an armature of a traction electric motor and gearing can be achieved due to drive damping capacity during impact vibro-damping in an axle reduction gear with a hard driven gear. The self-oscillation amplitude reduction in a wheel pair in the designs of locomotive traction drives with the location of elastic elements between a wheel pair and gearing can be obtained owing to the application of drive inertial masses as an anti-vibrator. On the basis of the carried out investigations, a design variant of a self-oscillation shock absorber of a traction electric motor framework on a reduction gear suspension with an absorber located beyond a wheel-motor unit was offered.

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Section: The Use Of Inertia Masses Of the Drive As A Shock Absorbermentioning

confidence: 99%

Friction self-oscillation decrease in nonlinear system of locomotive traction drive

Antipin

Vorobiyov

Izmerov

et al. 2017

IOP Conf. Ser.: Mater. Sci. Eng.

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“…The calculated friction torque is subsequently used in the model of dry friction in the bogies-car body connection. From the available friction models described in the literature [1][2][3][4][7][8][9][10][11]14], three groups of models were selected on the basis of the representation of popular friction models used in rail vehicle simulation. The first model represents the static smooth Coulomb approach, the second model is related to the dynamic non-smooth rheological approach, and the third one is based on the static non-smooth Coulomb approach with a defined region of stiction.…”

Section: Description Of Modelsmentioning

confidence: 99%

Evaluation of bogie centre bowl friction models in the context of safety against derailment simulation predictions

Opala

2018

Arch Appl Mech

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This paper investigates the influence of the models of dry friction suspension component used in the numerical simulation of freight car dynamics on the possible predictions related to safety against derailment. Moreover, the performance of the models is compared on the basis of simulation runtime. Three groups of static and dynamic models of friction are selected as three different approaches which are often utilized in popular multibody simulation tools. The models are used for the centre bowl friction joint between the car body and bogies. The friction torque in the centre bowl affects the rotational resistance of the bogie in motion relative to the car body and consequently influences the interaction forces between the wheels and rails. Simulation results of safety against derailment index obtained from the vehicle curving scenario suggest noticeable differences in predictions of the selected models of friction.

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“…Dynamic modeling of suspension components is well described in the reference [2]. However, depending on the speeds and axle load properties of the rail vehicle, some of the suspension elements may not be functional.…”

Section: Introductionmentioning

confidence: 99%

3D Suspension Characterization of a Rapid Transit Vehicle Using a Multi-Body Dynamic Model

Demir

2016

Urban Rail Transit

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In this work, suspension characterization of a rapid transit vehicle is performed with a multi-body dynamic model that represents full degrees of freedom of a rapid transit vehicle. The effects of lateral suspension properties on passenger ride comfort and stability are investigated by variation of critical suspension parameters using design of experiment method. The critical suspension properties are obtained for the best values of car body lateral acceleration and car body lateral stroke. The tangent track time response of the car body verified the negligible effect of both lateral viscous dampers at primary suspensions and longitudinal anti-yaw dampers at secondary suspensions on the passenger ride comfort and stability of a rapid transit vehicle.

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Modelling of suspension components in a rail vehicle dynamics context

Cited by 204 publications

References 85 publications

Friction self-oscillation decrease in nonlinear system of locomotive traction drive

Friction self-oscillation decrease in nonlinear system of locomotive traction drive

Evaluation of bogie centre bowl friction models in the context of safety against derailment simulation predictions

3D Suspension Characterization of a Rapid Transit Vehicle Using a Multi-Body Dynamic Model

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