RU217800U1 - RAIL VEHICLE UNDERCARRIAGE - Google Patents

Abstract

The utility model relates to the undercarriage of a rail vehicle, with at least a frame (2) of the undercarriage, to which are connected at least the first wheelset (8) and the second wheelset (9) and to which are attached, by at least the first drive unit (17) and the second drive unit (18). To create preferred structural conditions, it is proposed that the first connecting rod (24) is pivotally connected to at least the first drive unit (17) and is intended for elastic connection with the body (1) of the rail vehicle car.

Description

The utility model relates to a rail vehicle undercarriage with at least one undercarriage frame, to which at least the first wheel pair and the second wheel pair are connected and to which at least the first drive unit and the second drive unit are connected. node.

Tension rods or tension/compression rods as traction links can hardly be connected to the end beams of the undercarriage frames of rail vehicles, since, on the one hand, the lengths of the tension rods or tension/compression rods would be too small and, consequently, the angles due to the turning and rolling processes of the undercarriage would be too large, and on the other hand, the free space for guiding the tension rods or tension/compression rods under the drive unit to the cross members of the undercarriage frame is only available to a limited extent due to dimensional limitations.

In addition, it is often difficult to properly position the tension rods or tension/compression rods to reduce the redistribution of the load between the undercarriage and the car body when starting or braking rail vehicles.

For example, from the prior art, traction links are known, implemented by means of pivots.

The disadvantage of such traction links is that they must be made massive and that due to the relatively high force application points between the car body and the undercarriage, a strong redistribution of the load occurs. In order to also be able to transfer the high starting traction forces of the rail vehicle to the rails with a strong load redistribution, the different load states on the wheelsets of the undercarriage must be compensated electrically, for example by control of the drive unit, or by means of actuating means. In the case of electrical compensation for load redistribution, it is necessary to increase the dimensions of motors, power converters, cabling, shafts of wheel sets, etc. accordingly.

From the prior art, for example, the document WO 2015/117678 A1 is known, which shows a rail vehicle with a traction link of the car body through the undercarriage using a kingpin.

In addition, WO 2011/141510 A1 describes the drive of a rail vehicle. The drive is articulated on one side with the undercarriage or the body of the rail vehicle, and on the other side with the wheel pair of the undercarriage. Due to its gimbal support, the drive has the ability to rotate about two mutually perpendicular axes of rotation, which, in turn, are oriented perpendicular to the axis of rotation of the drive rotor.

In addition, EP 3 272 614 A1 discloses a rail vehicle undercarriage, the wheelsets of which have a smooth running, which is achieved due to ball-and-socket joints of the rail vehicle drive with the frame of the undercarriage.

In their known forms, the last two approaches have in particular the disadvantage of excessive mobility of the drives relative to the undercarriage frames, wheelsets and/or rail vehicle car bodies for certain categories of rail vehicles or undercarriages and/or for certain ranges of travel speeds.

The present solution is based on the problem of offering a bogie which is a further improvement over the prior art, and whose traction link and drive bearing provide acceleration and deceleration with little load redistribution.

According to the present solution, this object is achieved by means of a bogie of the type mentioned above, in which the first connecting rod is pivotally connected to at least the first drive unit and is intended to be resiliently connected to the car body of the rail vehicle. Due to this, the transmission of longitudinal forces with mechanical decoupling is realized, in which, on the one hand, moderate forces are introduced into the undercarriage and the car body, and on the other hand, the turning movements, as well as the compression and rebound movements of the undercarriage under the car body, are not hindered, and largely shock-free starting and braking is also guaranteed. The spring rate of one or more springs of the first tie rod can be selected to suit the required ranges of traction force and the required resistance to rotation and make-up of the undercarriage.

It is possible to dispense with heavy and expensive power transmission components that require a lot of space, which cause a strong redistribution of the load when starting and braking a rail vehicle, for example, from a central beam (traverse) mounted centrally on the undercarriage.

Preferably, if at least the first assembly is connected to at least the first wheel pair through a coupling with the possibility of displacement in the direction of the transverse axis of the undercarriage, by means of the first support device, elastically and with the possibility of movement in the direction of the transverse axis of the undercarriage is connected to the first cross member at least one frame of the undercarriage, and by means of the second support device is elastically and movably connected in the direction of the transverse axis of the undercarriage to the second cross member of at least one frame of the undercarriage, while at least the first drive unit is installed in the support with the possibility of rotation around the vertical axis of the drive, which is made movable in the direction of the transverse axis of the undercarriage.

This measure provides the support of the drive, coordinated with the traction link through the first connecting rod. Movements of the first drive unit that interfere with the traction link are avoided (for example, turning or tipping movements around the longitudinal axis of the undercarriage and around the transverse axis of the undercarriage). Only minor rotational movements are possible around the vertical axis of the drive, which, due to the translational mobility of the first drive, can move together with the first drive in the direction of the transverse axis of the undercarriage.

Despite the limited rotational mobility, a transverse elastic support of the first drive unit is possible, with the first drive unit acting as a vibration damper transverse to the direction of travel of the rail vehicle.

A preferred configuration is provided if the first stiffeners of the first support device and the second support device in the plane formed by the longitudinal axis of the undercarriage and the vertical axis of the undercarriage and the second stiffnesses of the first support device and the second support device in the direction of the transverse axis of the undercarriage can be set independently of each other .

This makes it possible to provide a rigid characteristic of the drive support in the direction of the longitudinal axis of the undercarriage and the vertical axis of the undercarriage and a soft characteristic in the direction of the transverse axis of the undercarriage.

The preferred solution, in which the first rigidity of the first support device and the second support device in the plane formed by the longitudinal axis of the undercarriage and the vertical axis of the undercarriage is greater than the second rigidity of the first support device and the second support device in the direction of the transverse axis of the undercarriage causes, with on the one hand, the coordinated behavior of the transmission, the clutch and the first connecting rod, and on the other hand, contributes to the damping of vibrations of the transverse elasticity of the first drive unit. As a result, on the one hand, a safe, comfortable and low wear running of the undercarriage is achieved, and on the other hand, only moderate mechanical loading of the undercarriage and the car body is caused.

Particularly large variation in the rigidity of the first support device and the second support device and, as a result, high resistance to rotational or overturning movements of the first drive unit relative to the longitudinal axis of the undercarriage and the transverse axis of the undercarriage, as well as smooth translational mobility of the first drive unit in the direction of the transverse axis of the undercarriage bogies are achieved if the stiffness ratio between the first stiffness and the second stiffness is set to at least 1 to 40.

In addition, it may be useful if the first connecting rod is pivotally connected to at least the first drive unit through the second support device, and the first connecting rod through the hinge, which is located closer to the second cross member than to the first cross member, is connected to the second support device. On the one hand, this measure effectively compensates for the relative movements between the undercarriage and the car body, and on the other hand, the angle of installation of the first tie rod remains moderate even during strong turns and swings, or the first tie rod remains long enough even for strong turns and rolls. . In addition, the first connecting rod may have a simple geometric shape, since it is not necessary to lead the first connecting rod to the first cross member.

An advantageous solution is achieved if the first support device is positioned so that it protrudes into at least one recess in the first cross member. This measure provides a certain degree of environmental protection for the first support device and a space-saving arrangement.

In addition, it is expedient if at least the first spring device of the first support device is connected to the first cross member, the first longitudinal axis of the spring of which is located parallel to the vertical axis of the undercarriage. This measure contributes to a rigid response of the drive support in the direction of the vertical axis of the undercarriage and a soft response in the direction of the transverse axis of the undercarriage.

An advantageous configuration is also provided if the second spring device of the second support device is connected to the second cross member, the second longitudinal axis of the spring of which is parallel to the longitudinal axis of the undercarriage, the third spring device of the second support device, the third longitudinal axis of the spring of which is parallel to the vertical axis of the undercarriage, and also the fourth spring device of the second support device, the fourth longitudinal axis of the spring of which is parallel to the vertical axis of the undercarriage. As a result, simple or standardized machine elements, such as rubber-metal elements or helical springs, etc., can be used to realize the drive support and its special rigidity characteristics. for the second spring device, the third spring device and the fourth spring device.

It is further preferred if the second support device has a recess for the spring, wherein the second spring device is positioned so that it protrudes into the recess for the spring.

On the one hand, the spring recess reduces the mass of the second support device, and on the other hand, the spring recess acts as a mounting hole for the second spring device, thereby facilitating mounting and dismounting of the second spring device.

An advantageous solution is provided if the second support device has a through hole through which the axle of the wheelset of at least the first wheelset passes, the through hole being closed from below by means of a plug detachably connected to the second support device. This measure also implements the principle of lightweight construction with respect to the second support device. At the same time, the plug allows assembly and disassembly of the first wheelset with the second support device mounted.

It may also be useful if the second drive unit is connected to the first cross member through a third support device, wherein the first support device and the third support device are arranged in a fork-like manner and extend into each other. As a result of this measure, the first support device and the third support device are compactly connected to the first cross member, or the installation space available on the first cross member is effectively used.

The adaptive spring behavior of the traction link becomes possible if a connecting spring device is connected to the first connecting rod, by means of which the first connecting rod can be connected to the car body, while the connecting spring device has at least a first spring stiffness and a second spring stiffness, which set to be different from each other.

The first spring rate may be calculated, for example, considering the high tractive forces of the rail vehicle, the second spring rate may be calculated taking into account low tractive forces and low resistance to rotation and compression or rebound. As a result, suitable spring forces are available for different pull force ranges.

In addition, preferably, if the second connecting rod is pivotally connected to the second drive unit and is intended for elastic connection with the car body of the rail vehicle. This measure distributes the loads between the first connecting rod and the second connecting rod. Depending on the direction of travel or the traction force of the rail vehicle, either the first connecting rod or the second connecting rod is subjected to a tensile load. Pressure on the first connecting rod and the second connecting rod is prevented. The first connecting rod and the second connecting rod can only be designed as tension rods, i.e. they should not be performed as tension/compression pulls.

The connection of the first drive unit and the second drive unit to each other is achieved by providing a horizontal pendulum between at least the first drive unit and the second drive unit. This measure results in the reaction forces from the first drive unit and the second drive unit being distributed to the drive bearings of the first drive unit and the second drive unit.

Drive bearings and traction links are partially unloaded. In the case of reaction forces in the direction of the longitudinal axis of the undercarriage, a partial increase in the reaction force in the opposite direction is achieved.

Next, the decision is explained in more detail on exemplary embodiments. This shows:

Fig. 1: Top view of an exemplary embodiment of the rail vehicle undercarriage according to the present solution with two drive units which are spring-mounted to the undercarriage frame by the undercarriage frame cross member and connected to the rail vehicle body by tie rods,

Fig. 2 is a side view of a fragment of an exemplary embodiment of the undercarriage according to the present solution, showing the support device between the drive unit and the cross member, and

Fig. 3 is a side view of a detail of a frame cross member of an undercarriage of an exemplary embodiment of the undercarriage according to the present solution, the cross member having a support recess into which the support device of the drive unit of the undercarriage protrudes.

In FIG. 1 shows the undercarriage and the car body 1 of a rail vehicle in plan view.

The undercarriage has a frame 2 of the undercarriage, which includes the first spar 3, the second spar 4, the first crossbar 5, the second crossbar 6 and the third crossbar 7. The first crossbar 5 is made as the central crossbar of the undercarriage, the second crossbar 6 and the third crossbar 7 are made as end beams of the undercarriage.

The first wheelset 8 and the second wheelset 9 are connected to the frame 2 of the undercarriage. The first wheel pair 8 includes the first wheel 10, the second wheel 11 and the shaft 12 of the wheel pair.

The first wheel pair 8 by means of the first wheel pair bearing, the bearing housing of the first wheel pair, the first wheel pair guide, which in FIG. 1 are not shown, and is connected to the first side member 3 by means of the first main spring 13, and by means of the second wheel set bearing, the second wheel set bearing housing, the second wheel set guide, which in FIG. 1 is not shown, and is connected by means of a second mainspring 14 to the second spar 4. The second wheelset 9 is made in the same way as the first wheelset 8 in terms of its design and connection technique with the frame 2 of the undercarriage. The body of 1 car is located above the undercarriage. The first secondary spring 15 and the second secondary spring 16 are located between the first cross member 5 and the underside of the car body 1.

The first drive unit 17 and the second drive unit 18 are mounted resiliently in the undercarriage in the transverse direction, i. e. in such a way as to damp vibrations relative to movements in the direction of the transverse axis 19 of the undercarriage. The first drive unit 17 is connected to the first cross member 5 via the first support device 20 and to the second cross member 6 via the second support device 21. The second drive unit 18 is connected to the first cross member 5 and to the third cross member 7 via two additional support devices. The first support device 20, the second support device 21 and two additional support devices are aligned parallel to the longitudinal axis 23 of the undercarriage.

The first connecting rod 24 is located between the first drive unit 17 and the underside of the car body 1, and the second connecting rod 25 is located between the second drive unit 18 and the underside of the car body 1. The first connecting rod 24 is pivotally connected to the first drive unit 17 through the second support device 21 connected to it, while a hinge 26 is provided between the first connecting rod 24. The hinge 26 is located closer to the second cross member 6 than to the first cross member 5. 27 of the hinge shown in FIG. 2, which is rotated about parallel to the transverse axis 19 of the undercarriage from parallel to that projected in FIG. 1 virtual vertical axis 28 undercarriage. The first connecting rod 24 is rotatable about said hinge axis 27 . Connected to the first connecting rod 24 is a connecting spring device 29, through which the first connecting rod 24 is connected to the car body 1 . The connecting spring device 29 has a first connecting spring element 30 with a first spring stiffness k ₁ , a second connecting spring element 31 with a second spring stiffness k ₂ and a third connecting spring element 32 with a third spring stiffness k ₃ , the first spring stiffness k ₁ , the second stiffness k ₂ springs and the third stiffness k ₃ springs are different from each other.

The first connecting spring element 30 and the second connecting spring element 31 are made in the form of multilayer rubber-metal springs, the third connecting spring element 32 is in the form of a metal helical spring. The third connecting spring element 32 is connected to the welded bracket 33 of the car body 1, whereby the first connecting rod 24 is connected to the car body 1. The connecting spring device 29 is pretensioned between the spring holder 34 of the first connecting rod 24 and the welded bracket 33.

The first spring stiffness k ₁ is greater than the second spring stiffness k ₂ , the second spring stiffness k ₂ is greater than the third spring stiffness k ₃ . The first spring stiffness k ₁ is 37 kN/mm, the first connecting spring element 30 allows a maximum spring travel of 12 mm. The second spring stiffness k ₂ is 6 kN/mm, the second connecting spring element 31 allows a maximum spring travel of 7 mm. The third stiffness k ₃ of the spring is 0.2 kN/mm. The third connecting spring element 32 is prestressed by 25 mm and can deflect a maximum of 3 mm.

In the case of transmission of longitudinal force or transmission of traction force (transmission of force in the direction of the longitudinal axis 23 of the undercarriage) between the car body 1 and the undercarriage, when the traction forces are small, the softest, the third connecting spring element 32 comes into action as the first spring stage. Due to its pretension, the connecting spring device 29 is not weakened by relative movements of the car body 1 and the undercarriage in the direction of the longitudinal axis 23 of the undercarriage, i.e. remains clamped between the spring holder 34 and the welded bracket 33. Due to the low third spring constant k ₃ , the welded bracket 33 and the undercarriage frame 2 are only lightly loaded when the third connecting spring element 32 is actuated.

If the first stop (not shown in FIG. 1) of the third connecting spring element 32 is actuated, the third connecting spring element 32 is blocked and the second connecting spring element 31 takes over the springing function as the stiffer second spring stage. Thus, medium tractive forces are transmitted between the car body 1 and the undercarriage. The second connecting spring element 31 is made sufficiently soft so that the turning movements of the undercarriage during cornering, as well as the compression and rebound processes of the undercarriage, are not affected, and a substantially shock-free starting is possible.

If the second stop (not shown in Fig. 1) of the second connecting spring element 31 is activated during the springing process of the second connecting spring element 31, the second connecting spring element 31 is blocked, and the first connecting spring element 30 assumes the springing function as the third spring stage. Traction forces from high to maximum are transmitted between the car body 1 and the undercarriage through the first connecting spring element 30 or the third spring stage.

The second connecting rod 25 is made in the same way as the first connecting rod 24 in terms of its design and connecting properties. Depending on the direction of the pulling forces, either the first connecting rod 24 or the second connecting rod 25 is subjected to a tensile load. Pressure loading of the first connecting rod 24 and the second connecting rod 25 is excluded, so the first connecting rod 24 and the second connecting rod 25 are made in the form of tension rods.

The first drive unit 17 is also connected with the possibility of displacement in the direction of the transverse axis 19 of the undercarriage with the first wheelset 8 through the clutch 35, made in the form of a clutch with curved teeth, and the transmission 36. The clutch 35 is located between the drive shaft of the first drive unit 17 (not shown in Fig. 1) and a transmission shaft 36 (also not shown in Fig. 1). The transmission shaft, in turn, is connected to the shaft 12 of the wheelset.

The relative movements between the drive shaft and the transmission shaft in the direction of the transverse axis 19 of the undercarriage are compensated in the clutch 35, and the relative movements in the direction of the longitudinal axis 23 of the undercarriage due to the ability of the transmission shaft to tilt.

Between the transmission 36 and the second wheel 11, as a continuation of the transmission housing, a protective tube 37 is provided, which has a flange-shaped expanding section 38 towards the second wheel 11. to be able, for example, to connect the brake disk of the wheel to the wheel 11.

The first drive unit 17 is connected through the first support device 20 resiliently and movably in the direction of the transverse axis 19 of the undercarriage with the first crossbar 5 and through the second support device 21 elastically and movably in the direction of the transverse axis of the undercarriage 19 with the second crossbar 6.

The first drive unit 17 is mounted so that it can rotate to a limited extent about the vertical drive axis 39, which can be displaced in the direction of the transverse axis 19 of the undercarriage.

The first support device 20 has a first support bracket 40 and a second support bracket 41, which are screwed to the first drive unit 17 at a distance from each other.

The first support bracket 40 and the second support bracket 41 are positioned so that they protrude into the support recesses of the first cross member 5, the support recess 66 being shown in FIG. The first support device 20 has a first spring device 42, which in turn comprises a first spring system 46 and a second spring system 47. The first spring system 46 is located between the first cross member 5 and the first support bracket 40, the second spring system 47 is provided between the first cross member 5 and the second support bracket 41.

Projected in FIG. 1 the virtual first longitudinal axis 48 of the spring of the first spring system 46 is parallel to the vertical axis 28 of the undercarriage.

The first spring system 46 comprises a first multilayer spring 52 and a second multilayer spring 53 shown in FIG. 3. The second spring system 47 corresponds to the first spring system 46 in terms of its structural properties and arrangement.

The first spring system 46 and the second spring system 47 are located in the support recesses of the first cross member 5.

The second support device 21 is made in the form of a lightweight support and is screwed to the first drive unit 17.

Connected to the second cross member 6 is a second spring device 43, the second longitudinal spring axis 49 of which, shown in FIG. 2, is located parallel to the longitudinal axis 23 of the undercarriage, the third spring device 44, the third virtual longitudinal axis 50 of which is projected in FIG. 51 whose springs are located parallel to the vertical axis of the undercarriage. 28. The second spring device 43, the third spring device 44 and the fourth spring device 45 are parts of the second support device 21.

The second spring device 43 is located in the middle between the third spring device 44 and the fourth spring device 45 and offset relative to the third spring device 44 and the fourth spring device 45 in the direction of the longitudinal axis 23 of the undercarriage.

The second spring device 43 is located in the first spring cup 58, the third spring device 44 is in the second spring cup 59, and the fourth spring device 45 is in or connected to the third spring cup 60. The first cup 58 of the spring, the second cup 59 of the spring and the third cup 60 of the spring are screwed to the second cross member 6.

The second spring device 43 includes a third multilayer spring 54 and a fourth multilayer spring 55, which are separated from each other by a flat neck section of the second support device 21. The third multilayer spring 54 is connected to the first spring cup 58, the fourth multilayer spring 55 is connected to the second cross member 6. Between the third multilayer spring 54 and the fourth multilayer spring 55 is a flat neck-shaped section of the second support device 21.

The third spring device 44 and the fourth spring device 45 are designed in the same way as the second spring device 43 in terms of their structural properties, but are rotated by 90° relative to the second spring device 43.

The second spring device 43 is provided in the region of the spring recess 61 of the second support device 21, the second spring device 43 being positioned so that it protrudes into the spring recess 61. In the region of the recess 61 for the spring, a flat neck-shaped section of the second support device 21 is provided, with which the third multilayer spring 54 and the fourth multilayer spring 55 are in contact. The third multilayer spring 54 is located inside the recess 61 for the spring, and the fourth multilayer spring 55 is located outside the recess 61 for the spring .

By means of the first spring device 42, the second spring device 43, the third spring device 44 and the fourth spring device 45, the first overall stiffness of the first support device 20 and the second support device 21 can be precisely and independently adjusted in the plane formed by the longitudinal axis 23 of the undercarriage and the vertical axis 28 undercarriage, and the second overall rigidity of the first support device 20 and the second support device 21 in the direction of the transverse axis 19 of the undercarriage.

The first total stiffness of the first support device 20 and the second support device 21 is greater than the second total stiffness of the first support device 20 and the second support device 21.

The stiffness ratio between the first total hardness and the second total hardness is set to about 1:50.

Appropriate design and arrangement of the first support device 20 and the second support device 21 essentially eliminates the rotational movements of the first drive unit 17 about the first parallels of the longitudinal axis 23 of the undercarriage and around the second parallels of the transverse axis 19 of the undercarriage.

The second support device 21 has a through hole 62 through which the shaft 12 of the wheelset of the first wheelset 8 passes.

The second drive unit 18 is made in the same way as the first drive unit 17 and its connection with the first beam 5, the second beam 6 and the first wheel pair 8 from the point of view of the technique of connection with the first cross member 5, the third cross member 7 and the second wheel pair 9. The second drive unit the assembly 18 is connected to the first cross member 5 via a third support device 22 which, like the first support device 20, comprises two support brackets to which the spring devices are connected. The first support bracket 40 with the first spring system 46 and the second support bracket 41 with the second spring system 47 of the first support device 20, on the one hand, and on the other hand, the support brackets and the spring devices of the third support device 22 are arranged so that they fit into each other. friend like a fork.

A horizontal pendulum 64 is located between the first drive unit 17 and the second drive unit 18 and is pivotally connected to the first drive unit 17 on the one hand and the second drive unit 18 on the other hand.

FIG. 2 shows a side view of a fragment of the same exemplary embodiment of the undercarriage of a rail vehicle according to the present solution, which is also shown in FIG.

The first drive unit 17 of the undercarriage is connected through the first support device 20 to the first spring device 42, which includes the first spring system 46 with the first multilayer spring 52 and the second multilayer spring 53, as well as the second spring system 47, made similar to the first spring system 46, which is shown in Fig. 1 and 3 is connected to the first cross member 5 of the frame 2 of the undercarriage shown in FIG. In addition, the first drive unit 17 is connected through the second support device 21, which includes the second spring device 43, the third spring device 44 and the fourth spring device 45, shown in Fig.1, is connected to the second cross member 6 of the frame 2 made in the form of an end beam. running cart.

The second support device 21 is made in the form of a light steel beam, screwed to the first drive unit 17, and has a through hole 62 and recess 61 for the spring.

The shaft 12 of the wheelset of the first wheelset 8 of the undercarriage passes through the through hole 62. The through hole 62 is closed at the bottom by a plug 63 which is screwed to the second support device 21 and is thus releasably connected. When the plug 63 is dismantled, the first wheelset 8 can be withdrawn from the through hole 62 downwards or inserted into the through hole 62 upwards for dismantling or mounting.

The second support device 21 has a flat neck section.

The third multi-layer spring 54 and the fourth multi-layer spring 55 of the second spring device 43, in which the second longitudinal axis 49 of the spring is parallel to the longitudinal axis 23 of the undercarriage shown in FIG. The third multilayer spring 54 is connected to the first spring cup 58, shown in section in FIG. 2, and the fourth multi-layer spring 55 is laterally connected to the removable insert 65 of the second cross member 6. The third multi-layer spring 54 is located inside the spring recess 61. The first cup 58 of the spring is screwed to the side of the second cross member 6, enclosing the second support device 21 in the area of the recess 61 for the spring. The insert 65, which is also screwed to the side of the second cross member 6, covers the mounting hole for the second spring device 43. The fourth multilayer spring 55 is located between the insert 65 and the flat neck section of the second support device 21.

The third spring device 44 has a third longitudinal spring axis 50 which is parallel to the vertical axis 28 of the undercarriage shown in FIG. The fifth multilayer spring 56 and the sixth multilayer spring 57 are located in the second spring sleeve 59, which is screwed to the lower side of the second cross member 6. pressure plate and the underside of the second cross member 6.

The pressure plate of the second support device 21 is located between the fifth multilayer spring 56 and the sixth multilayer spring 57.

The fourth spring device 45 and the third spring sleeve 60 shown in FIG. 1 are designed in the same way as the third spring device 44 and the second spring sleeve 59 in terms of their structural properties and the technology of their connection with the second cross member 6.

With the second connecting device 21 through the hinge 26 is connected shown fragmentarily in Fig. 2, the first connecting rod 24, which in turn is connected to the one shown in FIG. 1 body of 1 wagon of a rail vehicle. The hinge 26 is made in the form of a rotary hinge and has a hinge axis 27, which is inclined relative to the longitudinal axis 23 of the undercarriage, parallel to the plane formed by the longitudinal axis 23 of the undercarriage and the vertical axis 28 of the undercarriage. Accordingly, the first connecting rod 24 extends from the second support device 21 upwards to the car body 1 and is rotatably mounted on the second support device 21 about the hinge axis 27 .

Figure 3 shows a side view of a fragment of the first cross member 5 of the frame 2 of the undercarriage, which is the bogie of the exemplary embodiment of the undercarriage of the rail vehicle according to the present solution shown in Fig.1.

The first cross member 5 has a support recess 66 which is formed by a first leg 67 configured as an upper leg, a second leg 68 configured as a lower leg, and a first side wall 69 and a second side wall 70 of the first cross member 5. The first side wall 69 and the second the side wall 70 is welded to the first shelf 67, the second shelf 68 and to the jumper 71 of the first cross member 5. The jumper 71 is made with an interruption in the area of the support recess 66.

The first support bracket 40 of the first support device 20, which is connected to the first drive unit 17 of the undercarriage shown in FIG. 1 is located so that it protrudes into the support recess 66, and is connected through the pressure plate of the first support bracket 40 to the first multi-layer spring 52 and the second multi-layer spring 53 of the first spring system 46 of the first spring device 42, while the pressure plate is located between the first multi-layer spring 52 and the second multi-layer spring 53. The first multi-layer spring 52 and the second multi-layer spring 53 are made in the form of multi-layer rubber-metal springs. The first multilayer spring 52 is connected to the first shelf 67, the second multilayer spring 53 to the second shelf 68. The first spring device 42 is part of the first support device 20 and has the first longitudinal axis 48 of the spring.

The first cross member 5 has a cylindrical hole in the area of the support recess 66, closed by a cover 72.

An opening provided in the second leg 68 extends in the vertical direction and extends the support recess 66 down and forward. The second multilayer spring 53 protrudes into said hole and is in contact with the cover 72. The cover 72 is bolted to the second shelf 68.

In the support recess 66 between the first cross member 5 and the side surface of the second multi-layer spring 53 there is an annular stop 73 made of rubber, covering the second multi-layer spring 53 and connected to the screws provided for connecting the cover 72 to the second shelf 68. As a result, lateral deviations of the first support bracket are limited. 40.

Also shown in FIG. 1, the second spring system 47 of the first spring device 42 connected to the second support bracket 41 of the first support device 20 shown in FIG.

List of symbols

1 car body

2 undercarriage frame

3 first spar

4 second spar

5 first cross member

6 second cross member

7 third bar

8 first wheelset

9 second wheelset

10 first wheel

11 second wheel

12 wheel pair shaft

13 first mainspring

14 second mainspring

15 first secondary spring

16 second secondary spring

17 first drive unit

18 second drive unit

19 transverse axle of the undercarriage

20 first support device

21 second support device

22 third support device

23 longitudinal axis of the undercarriage

24 first connecting rod

25 second connecting rod

26 hinge

27 hinge pin

28 vertical axle undercarriage

29 connecting spring device

30 first connecting spring element

31 second connecting spring element

32 third connecting spring element

33 welding bracket

34 spring holder

35 clutch

36 gear

37 protective tube

38 expanding plot

39 vertical axis drive

40 first support bracket

41 second support bracket

42 first spring device

43 second spring device

44 third spring device

45 fourth spring device

46 first spring system

47 second spring system

48 first longitudinal axis of the spring

49 second longitudinal axis of the spring

50 third longitudinal axis spring

51 fourth longitudinal axis of the spring

52 first multilayer spring

53 second multilayer spring

54 third multilayer spring

55 fourth layered spring

56 fifth multilayer spring

57 sixth multilayer spring

58 first spring cup

59 second spring cup

60 third spring cup

61 recess for spring

62 through hole

63 plug

64 pendulum

65 insert

66 support notch

67 first regiment

68 second regiment

69 first side wall

70 Second side wall

71 jumpers

72 cover

73 emphasis

k ₁ first spring rate

k ₂ second spring rate

k ₃ third spring rate .

Claims (15)

1. Undercarriage of a rail vehicle with a frame (2) of the undercarriage, to which at least the first wheelset (8) and the second wheelset (9) are connected and to which at least the first drive unit (17) and the second drive unit are connected. assembly (18), characterized in that the first connecting rod (24) is pivotally connected to at least the first drive assembly (17) and is intended for elastic connection with the body (1) of the rail vehicle car, and the said at least first drive assembly the assembly (17) is connected to at least the first wheel pair (8) through the clutch (35) with the possibility of displacement in the direction of the transverse axis (19) of the undercarriage, by means of the first support device (20) resiliently and with the possibility of displacement in the direction of the transverse axis (19) of the undercarriage is connected to the first cross member (5) of the frame (2) of the undercarriage and by means of the second support device (21) is elastically and movably connected in the direction of the transverse axis (19) of the undercarriage to the second cross member (6) of the frame (2) of the undercarriage bogies, and moreover, at least the first drive unit (17) is mounted for rotation around the vertical axis (39) of the drive, which is made movable in the direction of the transverse axis of the undercarriage (19). 2. Undercarriage according to claim 1, characterized in that the first stiffness of the first support device (20) and the second support device (21) in the plane formed by the longitudinal axis (23) of the undercarriage and the vertical axis (28) of the undercarriage, and the second the stiffness of the first support device (20) and the second support device (21) in the direction of the transverse axis (19) of the undercarriage are set independently of each other. 3. Undercarriage according to claim 1 or 2, characterized in that the first rigidity of the first support device (20) and the second support device (21) in the plane formed by the longitudinal axis (23) of the undercarriage and the vertical axis (28) of the undercarriage, is greater than the second rigidity of the first support device (20) and the second support device (21) in the direction of the transverse axis (19) of the undercarriage. 4. Undercarriage according to claim 3, characterized in that the stiffness ratio between the first stiffness and the second stiffness is set to at least 1 to 40. 5. Undercarriage according to any one of claims 1 to 4, characterized in that the first support device (20) and the second support device (21) are configured to substantially prevent rotational movements of said at least first drive unit (17) around the first parallels of the longitudinal axis (23) of the undercarriage and around the second parallels of the transverse axis (19) of the undercarriage. 6. Undercarriage according to any one of claims 1 to 5, characterized in that the first connecting rod (24) is pivotally connected to at least the first drive unit (17) mentioned through the second support device (21), and the first connecting rod (24 ) through the hinge (26), which is located closer to the second crossbar (6) than to the first crossbar (5), is connected to the second support device (21). 7. Undercarriage according to any one of claims 1 to 6, characterized in that the first support device (20) is positioned so that it protrudes into at least one recess (66) of the first cross member (5). 8. Undercarriage according to any one of claims 1 to 7, characterized in that at least one first spring device (42) of the first support device (20) is connected to the first cross member (5), the first longitudinal axis (48) of the spring of which is located parallel to the vertical axis (28) of the undercarriage. 9. Undercarriage according to any one of claims 1 to 8, characterized in that the second spring device (43) of the second support device (21) is connected to the second cross member (6), the second longitudinal axis (49) of the spring of which is located parallel to the longitudinal axis ( 23) undercarriage, the third spring device (44) of the second support device (21), the third longitudinal axis (50) of the spring of which is parallel to the vertical axis (28) of the undercarriage, as well as the fourth spring device (45) of the second support device (21) , the fourth longitudinal axis (51) of the spring of which is parallel to the vertical axis (28) of the undercarriage. 10. Undercarriage according to claim 9, characterized in that the second support device (21) has a recess (61) for the spring, while the second spring device (43) is located so that it protrudes into the recess (61) for the spring. 11. Undercarriage according to any one of claims 1 to 10, characterized in that the second support device (21) has a through hole (62) through which the axle (12) of the wheelset passes at least the first wheelset (8), moreover, the through hole (62) is closed from below with the help of a plug (63) releasably connected to the second support device (21). 12. Undercarriage according to any one of claims 1 to 11, characterized in that the second drive unit (18) is connected to the first cross member (5) through the third support device (22), wherein the first support device (20) and the third support device ( 22) are arranged in a fork-like protrusion into each other. 13. Undercarriage according to any one of claims 1 to 12, characterized in that a connecting spring device (29) is connected to the first connecting rod (24), through which the first connecting rod (24) is able to communicate with the car body (1), wherein the connecting spring device (29) has at least a first spring stiffness (k ₁ ) and a second spring stiffness (k ₂ ) which are different from each other. 14. Undercarriage according to any one of claims 1 to 13, characterized in that the second connecting rod (25) is pivotally connected to the second drive unit (18) and is designed for elastic connection with the body (1) of the rail vehicle car. 15. Undercarriage according to any one of claims 1 to 14, characterized in that between said at least the first drive unit (17) and the second drive unit (18) a horizontal pendulum (64) is provided.

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