Abstract
Improving freight axle load is the most effective method to improve railway freight capability; based on the imported technologies of railway freight bogie, the 27 t axle load side-frame cross-bracing bogie and sub-frame radial bogie are developed in China. In order to analyze and compare dynamic interactions of the two newly developed heavy-haul freight bogies, we establish a vehicle–track coupling dynamic model and use numerical calculation methods for computer simulation. The dynamic performances of the two bogies are simulated separately at various conditions. The results show that at the dipped joint and straight line running conditions, the wheel–rail dynamic interactions of both bogies are basically the same, but at the curve negotiation condition, the wear and the lateral force of the side-frame cross-bracing bogie are much higher than that of the sub-frame radial bogie, and the advantages become more obvious when the curve radius is smaller. The results also indicate that the sub-frame radial bogie has better low-wheel–rail interaction characteristics.
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1 Introduction
With its comprehensive advantages such as the large transport capacity, low energy consumption, light pollution, less occupation of the land, and high safety, the railway heavy-haul transport has developed rapidly all over the world. The side-frame cross-bracing bogie [1–3] and sub-frame radial bogie [4–9] are both main freight bogies applied in railway heavy-haul transport. In order to meet the needs of development of the Chinese railway transportation, the key technologies of both bogies were imported [10]; since then, many engineers and researchers in China began to study and investigate the technologies of the two bogies [11–26] and successfully developed a 25 t axle load side-frame cross-bracing bogie named K6 [11] and a sub-frame radial bogie named K7 [24] to meet the needs of Datong-Qinhuangdao coal transportation.
In recent years, 27 t axle load side-frame cross-bracing bogie (Fig. 1) and sub-frame radial bogie (Fig. 2) were developed in China to further enhance the railway transport capacity. The two bogies mainly consist of three parts, the bolster, the wheel sets, and the side-frame. The main difference of the two bogies is in the side-frame. The former uses an elastic crossing bar to connect the left and the right side-frame, while the latter uses a sub-frame radial appliance to connect the front and the rear wheel sets. In this paper, the dynamic performances of the two bogies are analyzed and compared at various conditions based on the theory of vehicle–track coupling dynamics [27] and a vehicle–track coupling dynamic model [28] in order to find which bogie has better low-wheel–rail dynamic interaction characteristics. The main parameters of the two bogies are shown in Table 1.
2 Vehicle–track coupling dynamic model and various calculation conditions
A vehicle–track coupling dynamic model is established according to the structural characteristics of the bogie. The degrees of freedom (DOFs) of the vehicle and track parts as well as the non-linear characteristics such as wheel–rail contact geometry, wheel–rail normal force, and wheel–rail tangential creep force are all taken into account in the vehicle–track system. In addition, the elastic cross-bracing bar of the side-frame cross-bracing bogie and the sub-frame radial appliance of the sub-frame radial bogie are simplified as three-directional stiffness separately in the model. The vehicle–track dynamic model is a complex and huge dynamic system as shown in Fig. 3 and the DOFs of the whole dynamic system are shown in Table 2. More details about Fig. 3 and Table 2 can be found in the reference [27].
In order to compare and analyze the wheel–rail interaction characteristics of the two bogies in various simulation conditions, we consider three scenarios: dipped rail joint, linear railway, and curve line. The detailed calculation conditions are shown in Table 3.
3 Analysis and comparison of wheel–rail dynamic interaction
3.1 Wheel–rail interaction at impulsive excitation
Figure 4 shows the wheel–rail dynamic response comparisons of a heavy-haul freight car equipped with the side-frame cross-bracing bogie and the sub-frame radial bogie passing through the dipped joint at a speed of 80 km/h. In Fig. 4, we can see that the diagrams of the wheel–rail dynamic interaction of both the bogies are basically the same and the amplitudes have little difference. Relatively, the wheel–rail vertical force (Fig. 4a) and the vertical displacements of rail substructures (Fig. 4d–f) of the sub-frame radial bogie are slightly larger (about 2 %) than that of the side-frame cross-bracing bogie. That is because the sub-frame radial appliance is much heavier than that of the crossing bar, which increases the unsprung mass of the bogie. Therefore, to reduce wheel–rail dynamic interactions, the sub-frame radial bogie should be lightened as much as possible.
3.2 Wheel–rail interaction at random excitation on straight line
Figure 5 shows the mean values of the wheel–rail vertical force, wheel–rail wear, and wheel–rail contact stress response as the heavy-haul freight car runs on the straight line at the speed of 80, 100, and 120 km/h, where the Chinese three-mainline spectrum excitation is considered. One can see that the mean values of the wheel–rail responses of the two bogies almost have no changes with speed variation, and the wheel–rail dynamic interactions of both bogies are basically the same.
3.3 Wheel–rail interaction on curve negotiation
Figure 6 shows the wheel–rail lateral force and the wheel–rail wear power of the external side wheel of the two bogies as the vehicle passes through a smooth curve at a speed of 55 km/h; the curve radius is 300 m. In Fig. 6, we can see that the wheel–rail lateral force and wheel–rail wear power of the side-frame cross-bracing bogie are apparently much higher than those of the sub-frame radial bogie. For example, the maximum wheel–rail lateral force of the side-frame cross-bracing bogie is 28.16 kN, while that of the sub-frame radial bogie is 15.68 kN. The former is about 1.8 times larger than the latter. The maximum wheel–rail wear power of the side-frame cross-bracing bogie is 88.89 Nm·m−1, while that of the sub-frame radial bogie is 30.16 Nm·m−1, which is about 2.95 times than the former. These indicate that the sub-frame radial bogie can reduce the wheel–rail lateral interactions and can particularly reduce the wheel–rail wear significantly when negotiating a curve.
Figure 7 shows the diagrams of the wheel–rail lateral force of the four wheel sets. Seen from the figure, the values of the four wheel sets of the side-frame cross-bracing bogie are very uneven. The maximum value of the first and the third wheel set is nearly 3 times greater than that of the second and the fourth wheel set; this means the guiding wheel sets will wear more quickly than that of the non-guiding wheel sets and cause the guiding wheel sets to repair and change, or even scrapped in advance. But, for sub-frame radial bogie, the values of the four wheel sets are basically the same, and the maximum is also much lower than that of the side-frame cross-bracing bogie; so relatively, the wheel–rail wear would be reduced and the life of the wheel set would be extended.
Figure 8 shows the comparison of the peak values of the wheel–rail lateral force and the wheel–rail wear power as the vehicle passes through smooth curved lines with different radii. As shown from Fig. 8, the peak values of the wheel–rail lateral force and the wheel–rail wear power of the side-frame cross-bracing bogie are significantly larger than those of the sub-frame radial bogie, and the difference becomes gradually larger with the reduction of the radius. For instance, when the radius is 1,500 m, both the bogies have little difference; when the radius is 1,000 m, the peak value of the wheel–rail lateral force and wheel–rail wear power of the side-frame cross-bracing bogie is, respectively, 11.24 kN and 18.44 Nm·m−1, while that of the sub-frame radial bogie is correspondingly 8.3 kN and 7.1 Nm·m−1, the former being about 1.35 times and 2.6 times larger than the latter, respectively. As the curve radius is 300 m, the peak values of the former are, respectively, 28.16 kN and 104.7 Nm·m−1, while that of the latter are 15.68 kN and 30.16 Nm·m−1, respectively, the former being about 1.8 times and 3.47 times larger than the latter, respectively.
Figure 9 shows the comparison of the mean values of wheel–rail lateral force and wheel–rail wear power as the vehicle passes through curved lines of different radii, where Chinese three-mainline spectra as the random excitation is considered. Seen from the figure, regardless of whether the mean value of the wheel–rail lateral force or the wheel–rail wear power, the values of the side-frame cross-bracing bogie are always higher than those of the sub-frame radial bogie; and, the smaller the curve radius, the greater the difference. Only when the curve radius is beyond 1,000 m do the mean values of the wheel–rail lateral force and the wheel–rail wear power of both bogies tend to be the same.
3.4 Actual wheel–rail wear comparison between two types of bogies
The 25 t axle load side-frame cross-bracing bogie named K6 and the 25 t axle load sub-frame radial bogie named K7 have been used on Datong-qinghuangdao heavy-haul line for about 2 × 105 km. Figure 10 shows the difference of the flange wear of the different bogies. One can see from the figure that the mean value of the flange wear of the K6-type bogie is 0.52 mm, while that of the K7-type bogie is 0.15 mm, less than one-third of the K6-type bogie. The mean value of tread wear of the K6-type bogie is 3.15 mm, while that of the K7-type bogie is 2.95 mm, also less than that of the K6-type bogie. These indicate that application of the sub-frame radial bogie would be more effective to decrease wheel–rail wear.
4 Conclusions
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(1)
Passing through the dipped rail joints, the vertical wheel–rail dynamic interaction of both the side-frame cross-bracing bogie and the sub-frame radial bogie is basically the same, but because of the heavier unsprung mass of the sub-frame radial bogie, the dynamic responses of the rail substructures are slightly larger.
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(2)
Running on a straight line at random excitation, the wheel–rail dynamic responses of both the bogies are basically the same with a little difference, and the running speed has almost no influence on the wheel–rail vertical dynamics performance.
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(3)
Negotiating curves, the wheel–rail lateral force and wheel–rail wear power of the side-frame cross-bracing bogie are apparently larger than those of the sub-frame radial bogie, and the smaller the curve radius, the larger the difference. Only when the curve radius is beyond 1,000 m, the wheel–rail dynamic responses of the two bogies are basically the same. These indicate that the sub-frame radial bogie has advantages on dynamic performance, especially on curve negotiation.
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Acknowledgments
This work was supported by the National Natural Science Foundation of China (No. 50975238).
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Yang, C., Li, F., Huang, Y. et al. Comparative study on wheel–rail dynamic interactions of side-frame cross-bracing bogie and sub-frame radial bogie. J. Mod. Transport. 21, 1–8 (2013). https://doi.org/10.1007/s40534-013-0001-3
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DOI: https://doi.org/10.1007/s40534-013-0001-3