SE445632B - BIKE VEHICLE WITH DRIVING DEVICE IN BOGGI - Google Patents

Description

15 20 25 30 35 40 7906787-2 2 stability in the aisle of the vehicle. The drive units, such as a bogie motor and associated transmission gears, are stored in the known rail-driven vehicles via spring elements in such a way that only vertical shocks from the bogie frame against the drive unit are mitigated.

In the transverse direction, however, these spring elements are almost rigid, which is why the masses of the drive unit or the drive units are directly connected from the transverse direction of the bogie frame from a pivotal technical point of view.

To eliminate these faults, the drive motors of other known rail-bound vehicles are stored in the body. With such a solution, the mass conditions in the bogie are improved from an angular point of view, however, due to the large relative movements between body and wheel sets when driving in curves, the transfer of torque from the drive units to the wheel sets is conditionally constructive and also resource-intensive and also resource-intensive. to error. In addition, this solution can often not be carried out without serious other disadvantages, since the space for the drive units in or under the vehicle body is first available by extending the vehicle.

Furthermore, even with these known rail vehicles, a part of the drive unit, namely the axle drive, must necessarily remain in the bogie.

The object of the invention is to provide a rail vehicle of the type mentioned in the introduction, in which a great stability is achieved during walking and in which the critical speed, which is characterized by periodic wheel flange bearings for the wheel sets of approximately 1-5Hz when driving on straight lines, to speed ranges substantially above 200 km / h.

In doing so, the mentioned disadvantages of the known rail-driven vehicles must be avoided.

This object is solved in accordance with the invention in that the drive unit and the drive units inside the bogie in the transverse direction are substantially translatable about the same deflection and about a vertical axis substantially around the same angle of rotation as the bogie frame on the rails, the drive units and the drive units in the transverse direction. a spring and a damping element are connected to the bogie frame. In this case, it is essential that the spring stiffness of the spring element and the spring elements, respectively, is dimensioned so small that the translational oscillations of the drive unit and the drive units directed perpendicular to the direction of movement in relation to the bogie frame and the corresponding rotational angles about a vertical axis 7 206787-2 to a maximum of approximately 5 Hz and that the attenuation characteristics of the attenuation element and the attenuation elements at the frequencies of the oscillations and amplitudes for the respective drive units or the drive units are adapted in such a way that the overall system for the bogie is technically oscillatingly stable to a pre-given maximum speed. With the features described in claim 5, an advantageous suspension of the drive unit is indicated. The feature described in claim 6 entails a substantial simplification of the drive problems, while the features described in claims 4 and 8 enable a dimensioning of the spring stiffness for the translational movement of a drive unit in the transverse direction and that of the rotational movement around a vertical axis independently.

The invention will be described in more detail below in the form of several exemplary embodiments in connection with the drawings. Fig. 1 shows a two-axle bogie for a rail-borne vehicle in accordance with the invention with a drive block for both axles, Fig. 2 a two-axle bogie with two different drive units one for each axle, Fig. 3 a bogie with two different operating angles Fig. 4 shows a bogie with a drive block suspended from a pivot rod-pendulum pair with two shaft drives, Fig. 4a shows a damping link between the drive block and the frame of the bogie in the embodiment according to Fig. 4. Figs. 1-4 are perspective views while Fig. 4a is a top view. The drawings are partly greatly simplified to show the essentials.

The bogie frame 1 consists of two longitudinal beams Z at the outer sides and two cross-connections 3 at the ends. Boggín has two axles 4 with wheels 5 each running on the rails 6.

As can be seen from Fig. 1, the shaft bearings 7 for the shafts 4 are each via a spring 8 in the longitudinal direction - i.e. in the rails and the direction of movement, respectively - and via a suspension and damping element 9 and 10, respectively, in the vertical direction and via a spring and damping elements 11 and 12, respectively, in the transverse direction - i.e. perpendicular to the rail and vehicle direction - are connected to the bogie frame 1. In Figs. 2-4 the spring elements 8 and the pairs of spring and damping elements 9, 10 and 11, 12, respectively, are for simplicity only indicated by dotted lines. To absorb the vertical forces, each shaft bearing 7 is assigned a bracket 13 to the longitudinal beams 2.

The drive for the two shafts 4 is in the exemplary embodiment shown in Fig. 1 summarized in a single drive block 14. The drive block 14 is substantially symmetrical with respect to a vertical shaft 15. In the transverse direction, the drive block 14 is connected on each side via a spring element 16 and a damping element 17 to the longitudinal beams 2 of the bogie 1, the units of a spring and a damping element 16 and 17, respectively, consisting of the vertical shaft 15 in the longitudinal direction has a distance 1 and below each other also has a distance 21, as shown in Fig. 1.

For the power or torque transmission from the drive block 14 to the shafts 5, in principle any suitable solution can be used, insofar as it has the suspension and damping characteristics required for an optimal dimensioning. In the exemplary embodiment shown in Figs. 1-4, a hollow shaft 18 known for its design is arranged, which on the one side of the drive block 14 and at the gear 22 and 30, respectively, and on the other side at the shaft 4 and the wheel S, respectively, is universal jointed. The axially effective spring and damping properties for the universal joint of the hollow or tubular shaft 18 are indicated in Fig. 1 by a replacement system, each consisting of a suspension and damping element 19 and 20, respectively. By the described arrangement of spring and damping elements 16 , 17 and 18, 19, respectively, the drive block 14 is movably mounted around the vertical axis 15 relative to the bogie frame 1 both translationally in the transverse direction as well as the angle of rotation or rotation.

The drive block 14 is in the longitudinal direction and with respect to its own longitudinal axis via (not shown) known rubber-elastic elements stored in the bogie frame 1, by means of which the drive block 14 opposite the bogie frame 1 in the mentioned movement relations provides only little movement possibilities. The vertical storage of the drive block 14 in the bogie frame 1 can take place in a known manner by means of pendulum links, as shown in Figs. 2 and 3, so that the movements described above in the horizontal plane are possible.

In the exemplary embodiment shown in Fig. Z, each wheel set 4,5 has a separate drive. Each drive consists of a motor 21, the drive 22 and the pipe shaft 18. The motors 21 are suspended via pendulums 23 in the beam 24 for a bridge-like cross-connection 25 for the bogie frame 1 and by means of torque supports 26 via a bolt 27 I articulated in the longitudinal direction at the cross-connections 3 for the bogie frame 1. Through the pendulum suspension a movement of the motors in the transverse direction is possible, by means of the bolts 27 a vertical axis of rotation is each determined for each drive block 21, 22. The cylinders The units shown consist each of a spring element 16 and a damping element 17, and are arranged on both sides between the motors 21 and the longitudinal beams 2 of the bogie frame 1.

In the exemplary embodiment shown in Fig. 3, two different drives, consisting of a motor 21, a gear 22 and a pipe shaft 18, are provided. These drives are summarized into a drive block by means of a frame frame 28 - pivoting technically. The frame frame 28 is in the manner already described suspended via pendulum 23 in the bogie frame 1 and relieved transversely via units shown as cylinders, each consisting of a spring element 16 and a damping element 17 opposite the bogie frame 1. The drive assembled on the frame frame 28 can thereby moving both transversely in the transverse direction and also rotationally about the vertical axis 15 given through the center of the frame frame 28. In the exemplary embodiment shown in Figs. 4 and 4a, again a single drive block, consisting of a motor 29 and two shaft drives 30 is arranged. . The motor 29 is again suspended via pendulums 31 in the bogie frame 1. In contrast to the above embodiments, the pendulum 31 is at its upper end, however, via torsionally rigid connections 32 attached to torsion springs 33, these being rotatable in the cross-connection 25 arranged layers. The units of each spring and a damping element 16 and 17, respectively, consisting as a cylinder, are arranged in the transverse direction centrally between the axes in line with each other. This device enables the advantage that the spring and the damping elements of the translational movement of the drive blocks 29, 30 in the transverse direction and the rotational movement about the vertical axis 15 can be dimensioned separately.

During the translational movement, the torsion springs 33 rotate with the pendulums 31 in their original unaffected state in the bearings 34.

The suspension and damping properties are given by the properties determined by the suspension and damping elements 16 and 17, respectively. During the rotational movement, the two pendulums on each side make opposite turns, so that the torsion springs 33 are rotated and a restoring force is exerted on the drive blocks 29,50. The damping arranged for the rotational movement of the drive block is realized by means of at least one damping element 35, as shown in Fig. 4a. During the rotational movement of the drive block, the units consisting of the spring and damping elements 16 and 17, respectively, remain practically unaffected, while during translational movement the torsion springs 33 and the damping element and the elements 35, respectively, are inactive. .... ... w .- _....-____.....-,.-... ~ .. u. _ .. 7906787-2 For an oscillation model corresponding to the embodiment according to Fig. 1 carried out calculations have, after optimization of suspension and damping characteristics at predetermined masses, given critical speeds, which are far above those for rail-bound vehicles, which are equipped with bogies of hitherto known type. k-c-u- * ß-u-w-m-v -... ny e. "_. i v ..

Claims (6)

7906787-2 P a t e n t k r a v A bogie vehicle with at least one drive unit, which is movably mounted to the bogie in the transverse direction and which is connected to the bogie frame via at least one spring element, is characterized in that the drive unit and the drive units (14; 21; 29) in the transverse direction also via at least one damping element (16; 17) are connected to the bogie frame (1) and that the drive unit and the drive units (14; 21; 29) inside the bogie frame (1) in the transverse direction are movable substantially over the same deflection translationally and about a perpendicular axis (15) substantially around the same angle of rotation rotationally as the bogie frame (1) on the rails (6). Towing vehicle according to claim 1, characterized in that the drive unit or units (14; 21; 29) in relation to the wheel sets (4, 5) are movable in the transverse direction substantially to the same extent as they - in relation to an imaginary vertical plane through the axle (4) of the wheel sets in relation to the bogie frame (1). A towing vehicle according to claim 2, characterized in that the pivoting system consisting of the drive unit and the drive units (14; 21; 29) and the transversely arranged suspension and damping elements (16; 17) in relation to the bogie frame (1) in the transverse direction and around the perpendicular axis (15) has limited natural oscillations of approximately 5 hetz. A bogie vehicle according to any one of claims 2 or 3, wherein each bogie has only a single drive block (longitudinal motor with angular gears), characterized in that the transversely directed suspension and damping elements (16; 17) between the drive block (14 ; 29) and the bogie frame (1) are hinged at bearing points, which - seen in the longitudinal direction of the bogie - have a distance (21) from each other and are arranged symmetrically with respect to the vertical axis of rotation (15) of the drive block. A bogie vehicle according to claim 2 or 3, characterized in that for the translational movement of the drive unit or the drive units (14; 21; 29) and for the rotational movement about this and their vertical axis of rotation (15), respectively, are separate systems of spring and damping elements ( 16; 17; 33; 35) arranged. Bogie rail vehicle according to Claim 5, characterized in that the drive unit or the drive units (30) are suspended in pendulums (31) in the bogie frame in a manner known per se and that the drive units (31) holding the drive unit and the drive units (30), respectively. are mounted in pairs via torsionally rigid connections (32) are attached to longitudinal torsion springs (33), which in turn are mounted in the bogie frame (1), wherein in the transverse direction between the drive assembly (30) and the bogie frame (1) aligned, each of a spring and units of a damping element (16; 17) are arranged in line centrally with the drive block (29, 30).