2010
DOI: 10.1080/00423111003668211
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The influence of the condition of three-piece freight bogies on wheel flange wear: simulation and operation monitoring

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Cited by 13 publications
(6 citation statements)
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“…When predicting the wheel wear, the value of the wear coefficient is crucial as it determines the rate of wear. Jendel provided the relationship between the wear coefficient, contact pressure and sliding speed refer to Orlova and Boronenko (2010). The wear process is shown in Figure 3(a).…”
Section: Wheel Wear Prediction Modelmentioning
confidence: 99%
See 1 more Smart Citation
“…When predicting the wheel wear, the value of the wear coefficient is crucial as it determines the rate of wear. Jendel provided the relationship between the wear coefficient, contact pressure and sliding speed refer to Orlova and Boronenko (2010). The wear process is shown in Figure 3(a).…”
Section: Wheel Wear Prediction Modelmentioning
confidence: 99%
“…Li et al (2017) analyzed the causes of the wear and the influencing factors of wheel wear of heavy-haul freight vehicles by establishing two steering bogie models. Orlova and Boronenko (2010) analyzed the effect of the three major components of the steering bogie on the wheel flange by a dynamic model. Fergusson et al (2008) reduced flange wear by optimizing suspension parameters.…”
Section: Introductionmentioning
confidence: 99%
“…Many different wedge suspension models are available in the open literature [35][36][37][38][39][40]. The model used in this paper has the structure shown in Figure 4 and can be expressed as where F N1 is the normal force between side frame and wedge; F N2 is the normal force between wedge and bolster; z b is the vertical displacement of bolster; γ is the toe angle or the vertical inclination angle of the wedge-side frame contact surface; μ 1 is the coefficient of friction on wedge-side frame contact surface; α is the wedge angle; μ 2 is the coefficient of friction on wedge-bolster contact surface; m w is the wedge mass; m b is the bolster mass; G w is the weight of the wedge; G b is the weight of the bolster; F kb is the bolster spring force; F cp is the centre plate force; and F kw is the wedge spring force.…”
Section: D Wagon Modellingmentioning
confidence: 99%
“…The measurement data were used as reference when choosing the wear model parameters as far as it refers to the well-determined test conditions compared with experimental data available from field tests [6] of freight wagons. Data for wear coefficients and friction coefficients, obtained by tests of wheel and rail materials on special rigs, were not available.…”
Section: Available Experimental Datamentioning
confidence: 99%