Development of an innovative wheel–rail contact model for the analysis of degraded adhesion in railway systems

Allotta, Benedetto; Meli, Enrico; Ridolfi, Alessandro; Rindi, Andrea

doi:10.1016/j.triboint.2013.09.013

Cited by 52 publications

(45 citation statements)

References 29 publications

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“…This 2D multibody model simulates the longitudinal dynamics of the vehicle while an innovative 2D adhesion model especially developed [16,17] to accurately reproduce the real behaviour of the adhesion coefficient during braking phases under degraded adhesion conditions. The inputs are the estimated torques on the wheelsets and the outputs are the simulated wheelset angular velocities and the tangential contact forces on the wheelsets; the innovative controllers (software) reproduce on the roller-rig the same dynamical behaviour of the virtual train model (through the roller control torques) in terms of wheelset angular velocities, applied torques and, consequently, tangential forces [8].…”

Section: General Architecture Of the Hil Systemmentioning

confidence: 99%

“…The WSP device installed on the UIC-Z1 coach [12,17] allows the control of the torques applied to the wheelsets, to prevent macrosliding during the braking phase.…”

Section: The Wheel Slide Protection System Modelmentioning

confidence: 99%

“…In Fig x w and accelerations _ x w ; the computation of the logical sliding state state WSP (equal to 1 if sliding occurs and 0 otherwise) and the consequent torque modulation, through a speed and an accelerometric criterion and by means of a suitable logical table [17]; the periodic braking release to bring back the perceived adhesion coefficient to the original value (often used when degraded adhesion conditions are very persistent and the WSP logic tends to drift).…”

Section: The Wheel Slide Protection System Modelmentioning

confidence: 99%

“…The adhesion model has been especially developed to describe degraded adhesion conditions [17,[32][33][34] and calculates, for all the 4 wheelset-rail pair, the tangential contact forces T sim starting from the wheelset kinematic variables v ws ; x ws and the normal contact forces N cs (see Fig. 12).…”

Section: The Adhesion Modelmentioning

confidence: 99%

“…The direct comparison between the experimental and simulated train velocities v sp ; v s is illustrated in Fig. 16 [17][18][19][20].…”

Section: The Model Validationmentioning

confidence: 99%

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An innovative hardware in the loop architecture for the analysis of railway braking under degraded adhesion conditions through roller-rigs

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This article appeared in a journal published by Elsevier. The attached copy is furnished to the author for internal non-commercial research and education use, including for instruction at the authors institution and sharing with colleagues.Other uses, including reproduction and distribution, or selling or licensing copies, or posting to personal, institutional or third party websites are prohibited. Nowadays, the longitudinal train dynamical behaviour is almost totally controlled by braking on board subsystems, such as Wheel Slide Protection (WSP) devices. The study and the development of these systems are fundamental for the vehicle safety, especially at high speeds and under degraded adhesion conditions. Traditionally, the performance of braking subsystems is tested on full-scale roller-rigs, to save time and to avoid expensive on-track tests. However, the study of the subsystem behaviour under degraded adhesion conditions on roller-rigs is still limited to few applications since high slidings among rollers and wheelsets generate wear of the rolling surfaces. This event is not acceptable because of the effects on the maintenance costs (the rollers have to be turned or substituted), on the system dynamical stability and on the safety. In this work the authors present an innovative Hardware In the Loop (HIL) approach for testing braking on board subsystems on full-scale roller-rigs. The new approach permits the reproduction on the rollerrig of a generic wheel-rail adhesion pattern and, in particular, of degraded adhesion conditions. The described strategy is the same implemented on the innovative full-scale roller-rig, recently built by Trenitalia and owned by SIMPRO, in the Railway Research and Approval Center of Firenze-Osmannoro (Italy). To validate the proposed approach, a complete model of the HIL system has been developed; the results provided by the simulation model have been compared to the experimental data provided by Trenitalia and relative to the on-track tests performed in Velim, Czech Republic, with a UIC-Z1 coach equipped with a fully-working WSP system. The complete model is based on the real characteristics of the components provided by Trenitalia. The preliminary validation performed with the HIL model highlighted the good performance of the HIL strategy in reproducing on the roller-rig the complex behaviour of the degraded adhesion during the braking of a railway vehicle. The next steps of the research activity will be the implementation both of the controller and the virtual vehicle model on the real Firenze-Osmannoro roller-rig.

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Section: General Architecture Of the Hil Systemmentioning

confidence: 99%

“…The WSP device installed on the UIC-Z1 coach [12,17] allows the control of the torques applied to the wheelsets, to prevent macrosliding during the braking phase.…”

Section: The Wheel Slide Protection System Modelmentioning

confidence: 99%

Section: The Wheel Slide Protection System Modelmentioning

confidence: 99%

Section: The Adhesion Modelmentioning

confidence: 99%

“…The direct comparison between the experimental and simulated train velocities v sp ; v s is illustrated in Fig. 16 [17][18][19][20].…”

Section: The Model Validationmentioning

confidence: 99%

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An innovative hardware in the loop architecture for the analysis of railway braking under degraded adhesion conditions through roller-rigs

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An innovative degraded adhesion model for railway vehicles: development and experimental validation

2013

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The realistic description of the wheel-rail interaction is crucial in railway systems because the contact forces deeply influence the vehicle dynamics, the wear of the contact surfaces and the vehicle safety. In the modelling of the wheel-rail contact, the degraded adhesion represents a fundamental open problem. In fact an accurate adhesion model is quite hard to be developed due to the presence of external unknown contaminants (the third body) and the complex and highly non-linear behaviour of the adhesion coefficient; the problem becomes even more complicated when degraded adhesion and large sliding between the contact bodies (wheel and rail) occur.In this work the authors describe an innovative adhesion model aimed at increasing the accuracy in reproducing degraded adhesion conditions. The new approach has to be suitable to be used inside the wheelrail contact models usually employed in the multibody applications. Consequently the contact model, comprising the new adhesion model, has to assure both a good accuracy and a high numerical efficiency to be implemented directly online within more general ve- The model studied in the work considers some of the main phenomena behind the degraded adhesion: the large sliding at the contact interface, the high energy dissipation, the consequent cleaning effect on the contact surfaces and, finally, the adhesion recovery due to the external unknown contaminant removal.The new adhesion model has been validated through experimental data provided by Trenitalia S. p. A. and coming from on-track tests carried out in Velim (Czech Republic) on a straight railway track characterised by degraded adhesion conditions. The tests have been performed with the railway vehicle UIC-Z1 equipped with a fully-working Wheel Slide Protection (WSP) system.The validation showed the good performances of the adhesion model both in terms of accuracy and in terms of numerical efficiency. In conclusion, the adhesion model highlighted the capability of well reproducing the complex phenomena behind the degraded adhesion.

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An innovative wheel–rail contact model for railway vehicles under degraded adhesion conditions

Meli

Ridolfi

2013

Multibody Syst Dyn

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The accurate modelling of the wheel-rail contact plays a fundamental role in the railway field since the contact forces heavily affect the vehicle dynamics, the wear of the contact surfaces and the vehicle safety. Concerning the wheel-rail contact, an important open problem is represented by the degraded adhesion. A realistic adhesion model is quite difficult to obtain because of the complex and highly nonlinear behaviour of the adhesion coefficient and the presence of external unknown contaminants (the third body); this is especially true when degraded adhesion and large sliding between the wheel and rail contact surfaces occur. In this work the authors present an adhesion model particularly developed to describe degraded adhesion conditions. The new approach will have to be suitable to be employed within the wheel-rail contact models typical of the multibody applications. In other words the contact model, comprising the new adhesion model, will have to guarantee a good accuracy and, at the same time, a high numerical efficiency to be implemented directly online inside the general multibody model of the vehicles (e.g. in Matlab-Simulink or Simpack environments). [1][2] The model analysed in the paper is based on some of the main phenomena characterising the degraded adhesion, such as large sliding at the contact interface, high energy dissipation, the consequent cleaning effect on the contact surfaces and the final adhesion recovery due to the removal of external unknown contaminants. The adhesion model has been validated thanks to the experimental data provided by Trenitalia S. p. A. coming from on-track tests performed in Velim (Czech Republic).

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Development of an innovative wheel–rail contact model for the analysis of degraded adhesion in railway systems

Cited by 52 publications

References 29 publications

An innovative hardware in the loop architecture for the analysis of railway braking under degraded adhesion conditions through roller-rigs

An innovative hardware in the loop architecture for the analysis of railway braking under degraded adhesion conditions through roller-rigs

An innovative degraded adhesion model for railway vehicles: development and experimental validation

An innovative wheel–rail contact model for railway vehicles under degraded adhesion conditions

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