EP2199174A2 - Vehicle, especially of the railway type, with anti-roll supports - Google Patents

Abstract

The vehicle (101) has anti-roll devices (108, 109) each countering roll moments between vehicle bodies (102, 103, 104) around a vehicle longitudinal axis (101.6). The anti-roll devices are coupled with each other by a coupling device (110) for counter mutual interaction. The vehicle body (102) has a length smaller than lengths of the vehicle bodies (103, 104). The vehicle bodies (102, 103) are connected by the vehicle body (104), and the vehicle bodies (102, 104) are connected by the vehicle body (103). Vehicle modules (101.2, 101.3) are adjacently arranged in a direction of the axis.

Description

The present invention relates to a vehicle, in particular a rail vehicle, with a vehicle longitudinal axis, a first vehicle module with a first car body, a second vehicle module with a second car body and a third vehicle module with a third car body. The second vehicle module and the third vehicle module are arranged adjacent to the first vehicle module in the direction of the vehicle longitudinal axis in each case one of the two ends of the first vehicle module. The first car body and the second car body are connected via a first anti-roll device, while the first car body and the third car body are connected via a second anti-roll device, wherein the respective anti-roll device counteracts rolling movements about the vehicle longitudinal axis between the connected car body. The first anti-roll device and the second anti-roll device are coupled to one another via a coupling device for opposing mutual influencing.

Such a design is often used in vehicles in urban transport, especially trams, their application and is for example from the DE 10 2005 041 162 A1 the applicant known. The first vehicle module is a chassis-less module with a car body, which is supported on the two vehicle longitudinally adjacent vehicle modules, which in turn are provided with trolleys. Because of the two-sided suspension of the adjacent vehicle modules, the middle, first vehicle module is often referred to as litter.

The anti-roll bars between the vehicle modules ensure, on the one hand, that undesirable high relative roll movements (around a rolling axis parallel to the vehicle longitudinal axis) do not occur when passing through unbroken straight track sections or track curves. In contrast, the opposite coupling of the anti-roll bars ensures that it can not come to the initiation of undesirably high torsional loads of the car bodies by the opposite rolling movements of the adjacent to the (middle) first car body car bodies when driving over track.

The disadvantage here, however, is the fact that the coupling device between the two anti-roll bars must bridge a comparatively large distance because of the usually relatively large length of the radiating litter. This results in a comparatively complex and complex design of the coupling device (ultimately irrespective of the operating principle of the coupling device used).

The present invention is therefore based on the object to provide a vehicle of the type mentioned above, which does not have the abovementioned disadvantages or at least to a lesser extent and in particular with a simpler design of the coupling device, a reliable reduction of the torsional load of the vehicle modules in twisted track sections allows.

The present invention solves this problem starting from a vehicle according to the preamble of claim 1 by the features stated in the characterizing part of claim 1.

The present invention is based on the technical teaching that allows a simple and reliable way to reduce the torsional load of the vehicle components in twisted track sections when the two anti-roll devices on the coupling device (instead of the two anti-roll devices at both ends of the comparatively long wheelless litter) the ends of an optionally provided with a chassis, in relation to at least one of the two adjacent vehicle modules short vehicle module are connected. It has been found that on the one hand also a significant reduction of the torsional loads of the car bodies, in particular wheelless litter, can be achieved, while on the other hand, the coupling device possibly even considerably simplified, since the short (possibly provided with a chassis) vehicle module in usually even shorter (possibly even many times shorter) can be designed and will. Correspondingly shorter is thus also the distance to be bridged by the coupling device between the two anti-roll bars, so that their design is simplified.

Incidentally, it has been shown that in the design according to the invention, a reduction of the constructive effort for the vehicle can be achieved, for example, in a five-car vehicle with two sedan chairs, the number of coupling devices can be reduced from two to one, namely the one short, middle support module.

According to one aspect of the invention, therefore, this relates to a vehicle, in particular a rail vehicle, having a vehicle longitudinal axis, a first vehicle module having a first vehicle body, a second vehicle module having a second vehicle body and a third vehicle module having a third vehicle body, wherein the second vehicle module and the third vehicle module the first vehicle module in the direction of the vehicle longitudinal axis respectively adjacent to one of the two ends of the first vehicle module are arranged. The first car body and the second car body are connected via a first anti-roll device, while the first car body and the third car body are connected via a second anti-roll device, wherein the respective anti-roll device counteracts rolling movements about the vehicle longitudinal axis between the connected car body. The first anti-roll device and the second anti-roll device are coupled to one another via a coupling device for opposing mutual influencing. Seen in the direction of the vehicle longitudinal axis, the first carbody has a first length, the second carbody a second length and the third carbody a third length, wherein the first length is small compared to the second length and / or the third length.

Preferably, the first vehicle module is significantly shorter than the second or third vehicle module formed, since this way particularly advantageous designs can be achieved. In this case, any length ratios between the vehicle modules can be selected as long as there is a noticeable difference in length. It is preferably provided that the first length is at most 60%, preferably at most 40%, more preferably at most 25% of the second length and / or the third length.

The invention can basically be used in connection with any vehicle configurations. In particular, both the first car body and at least one of the two adjacent car bodies can be supported on at least one other chassis. Particularly advantageous designs result when the first vehicle body is supported on a chassis, while the second vehicle module and / or the third vehicle module is formed without a vehicle.

The opposing coupling of the two anti-roll devices can in principle be designed in any suitable manner, which avoids the introduction of excessive torsional moments in the car bodies. Preferably, the coupling device is designed such that a first change in state of the first anti-roll device, the counterforce (thus without external, counteracting restoring forces) under a first rolling motion of the second car body with respect to the first car body takes place, via the coupling device causes a second state change of the second anti-roll device, which takes place under a counter to the first rolling motion second rolling motion of the third car body with respect to the first car body. In this way, even in cases where there is a rigidly rolling in the roll direction to another vehicle module with chassis on the first vehicle module end remote from the second or third vehicle module, are reliably prevented with a single coupling device that excessive Torsionsmomente be introduced into the car bodies ,

The opposing state change (displacement and / or length change, etc.) of the two anti-roll devices achieves the positive reduction of the torsional load of the first vehicle component, already described above, on the one hand. This is due to the fact that, in the case of a twisted or otherwise deformed track plane course, the two anti-rotation state changes achieved thanks to the coupling device can possibly even completely follow the deformed track plane course without being actuated, ie. H. without exerting a force acting on the first vehicle component restoring force, which could then lead to the described torsional load of the first vehicle component.

However, if such a counter-displacement due to a non-deformed track plane course does not take place, the anti-roll devices can unfold their rolling motion limiting effect to the full extent. In other words, the effectiveness of the anti-roll devices is not compromised in cases where they are actually to be used.

The opposite coupling of the two anti-roll devices can basically be done in any suitable manner. The two anti-roll devices can also experience different state changes. For example, one of the roll supports may experience a change in length while the other undergoes a displacement. Preferably, the coupling device is designed such that a counterforce-free first state change, in particular a first displacement and / or a first change in length of the first anti-roll device, causes a reverse second state change of the second anti-roll device.

The connection of the coupling device to respective anti-roll device can basically be done in any suitable manner. For example, if you have one in yourself Adjusting device (for example, a working cylinder or an adjusting spindle, etc.) be provided adjustable anti-roll device, that the coupling device attaches to this adjusting device and makes the coupling via an influence on the adjusting device (for example via the hydraulic coupling of the working spaces of the working cylinder).

However, the coupling is preferably carried out in the region of articulation of the respective anti-roll device to the relevant body, so that a change in state of the respective anti-roll device a simple shift in the region of the articulation point can be selected. It is therefore preferably provided that the first anti-roll device is articulated in a first articulation point on the coupling device, the second anti-roll device is articulated in a second articulation point on the coupling device. The coupling device is designed in this case such that a counterforce-free first displacement of the first coupling point causes an opposite second displacement of the second coupling point.

An advantage of this solution is that no definition of the design and design of the anti-roll devices is given by the achieved over the articulation points on the coupling device displacement of the anti-rolling devices. Thus, in the solution according to the invention, anti-roll devices of any type (hydraulic, mechanical, etc.) can be used and possibly combined with each other as desired.

In particularly simple variants of the vehicle according to the invention, the coupling device is designed such that a counterforce-free first displacement of the first pivot point causes an opposite second displacement of the second pivot point. As a result, in particular the coupling device can be made particularly simple, since such counter-rotating movement of the two articulation points can optionally be realized simply via a single pivotally mounted lever arm with two free ends, on each of which one of the articulation points is located.

The motion translation achieved by the coupling device can in principle be chosen arbitrarily and adapted to the construction and design of the anti-roll device connected to the respective side of the coupling device. In particularly simple variants of the vehicle according to the invention, in particular in variants with identically constructed anti-roll devices, it is provided that the first displacement and the second displacement are essentially the same amount have divergent directions, in particular substantially opposite direction.

Because of the simple, space-saving design is preferably provided that the coupling device on the same side of the vehicle longitudinal axis located parts of the first anti-roll device and the second anti-roll device connects. The coupling device preferably also connects components of the first anti-roll device and the second anti-roll device, which have the same function and / or position within the respective anti-roll device. This makes it possible to achieve particularly simple construction variants with simple kinematics.

Because of the particularly simple design, the coupling device preferably comprises at least one first lever arm pivotably connected to the first carriage body about a first pivot point, wherein the first pivot point is arranged in the kinematic chain between the first anti-roll device and the second anti-roll device. Preferably, the first lever arm comprises a free first end and a free second end, wherein the first end is directly connected to the first anti-roll device and the second end is connected directly or via further intermediate elements with the second anti-roll device. At the free ends of such a first lever arm, as set out above, one of the articulation points can then be arranged in each case.

In further advantageous variants of the vehicle according to the invention, provision is made for the coupling device to comprise at least one second lever arm pivotably connected to the first carriage body about a second pivot point, wherein the second pivot point is arranged in the kinematic chain between the first anti-roll device and the second anti-roll device and the second Lever with the first lever arm via at least one coupling element, in particular a push rod is connected. By such an arrangement, favorable movement translations can be achieved in an advantageous manner, so that even larger distances between the anti-roll devices can be bridged without the coupling device having to perform large deflections.

As mentioned, the coupling device can be designed in any suitable manner in order to achieve the above-mentioned opposite state changes of the anti-rolling devices or on the anti-roll devices. So it can be formed purely mechanically by a lever mechanism or the like. Likewise, it can also be wholly or partially realized via a fluidic transmission, for example a hydraulic transmission be. In further preferred variants of the vehicle according to the invention it is therefore provided that the coupling device comprises at least one first working cylinder connected to the first anti-roll device, in particular a first hydraulic cylinder, the coupling device comprises at least one second working cylinder, in particular a second hydraulic cylinder, connected to the second anti-roll device the coupling device comprises at least one connecting line for a working medium, in particular a hydraulic fluid, connecting the first working cylinder and the second working cylinder.

As mentioned, it can also be provided that the first working cylinder is part of the first anti-roll device and / or the second working cylinder is part of the second anti-roll device so that eventually only one connecting line for the medium is ultimately required in addition to the respective anti-roll device.

In preferred variants of the vehicle according to the invention, it is additionally provided that the coupling device comprises a damping device and / or an adjusting device in order to dampen the movements occurring in the arrangement (and so for example to reduce dynamic loads) and / or to generate active actuating forces (and the like) for example, to actively generate desired rolling movements between the car bodies).

Figur 1

eine schematische Draufsicht auf einen Teil einer bevorzugten Ausführungsform des erfindungsgemäßen Fahrzeugs in Neutralstellung;

Figur 2

eine schematische Draufsicht den Teil des Fahrzeugs aus Figur 4 in Verwindungsstellung;

Figur 3

eine schematische Draufsicht auf einen Teil einer weiteren bevorzugten Ausführungsform des erfindungsgemäßen Fahrzeugs in Neutralstellung.

Figur 4

eine schematische Draufsicht auf einen Teil einer weiteren bevorzugten Ausführungsform des erfindungsgemäßen Fahrzeugs in Neutralstellung.

Further preferred embodiments of the invention will become apparent from the subclaims or the following description of preferred embodiments, which refers to the accompanying drawings. Show it:

FIG. 1

a schematic plan view of a portion of a preferred embodiment of the vehicle according to the invention in neutral position;

FIG. 2

a schematic plan view of the part of the vehicle FIG. 4 in a twisting position;

FIG. 3

a schematic plan view of a part of another preferred embodiment of the vehicle according to the invention in neutral position.

FIG. 4

a schematic plan view of a part of another preferred embodiment of the vehicle according to the invention in neutral position.

First embodiment

The FIGS. 1 and 2 show schematic plan views of a five-part vehicle 101 according to the invention ( FIG. 1 ) or a part of the vehicle 101, which has a first vehicle module 101.1, a second vehicle module 101.2, a third vehicle module 101.3, a fourth vehicle module 101.4, a fifth vehicle module 101.5, and a vehicle longitudinal axis 101.6. The middle, first vehicle module 101.1 comprises a first vehicle body 102 which is supported on a chassis 102.1 via corresponding spring devices. At the two ends of the first vehicle module 101.1 adjoin the second vehicle module 101.2 and third vehicle module 101.3, which are each designed without a chassis.

The second vehicle module 101.2 in this case has a second car body 103, while the third vehicle module 101.3 has a third car body 104. The second car body 103 is supported on the one hand on the first car body 102 and on the other hand on a fourth car body 105 of the fourth vehicle module 101.4, which in turn is supported via corresponding spring devices on a chassis 105.1. The third car body 104 is supported on the one hand on the first car body 102 and on the other hand on a fifth car body 106 of the fifth vehicle module 101.5, which in turn is supported via corresponding spring devices on a chassis 106.1. Thus, therefore, the second car body 103 and the third car body 104 are designed in the manner of a so-called wheelless litter.

The vehicle modules 101.1 to 101.5 are, as will be explained in more detail below, coupled to each other to ensure the power transmission between them. In this case, in a conventional manner in the height direction of the vehicle spaced hinge means may be provided which typically provide additional functions in addition to the pivotal movements between the coupled car bodies in at least one direction. In the following, mainly the joints are to be discussed, which have significant influence on the reciprocal rolling movements (about the vehicle longitudinal axis 101.6) between the car bodies, while the other joints are not mentioned in more detail and are not shown in the figures for reasons of clarity.

While excessive roll differences between the car bodies 102 to 106 are to be prevented, due to the passage of deformed track sections, in particular track distortions, adjusting staggered inclinations of the successive following car bodies 102, 103 and 104 are allowed to their respective longitudinal axis.

Known solutions have for this purpose, for example, in the roof area between adjacent car bodies arranged in the transverse direction and this articulated connecting rods, as in FIG. 1 are indicated by the dotted contours 107. The car bodies 102, 103 and 104 are further articulated to each other, for example, by a articulation (not shown) in the floor area. During roll motions of a car body 102, 103 and 104, ie a transverse movement in the roof area relative to the lower rolling pole, this transverse movement is transmitted via the rigidity of the rods 107 to the adjacent car body of the articulated train. The rods 107 thus prevent the car bodies 102, 103 and 104 from swaying relative to one another while at the same time allowing relative pitching movements of the car bodies 102, 103 and 104, as may occur when driving on track sills or bumps.

When traversing track distortions, however, these rods 110 try to keep the adjacent bodies 102, 103 and 104 parallel to each other, in particular in the vertical direction parallel to each other, resulting in strong constraining forces in the articulation points of these rods 110 and thus the structure of the bodies 102,103 and 104 leads.

To overcome this disadvantage, an inventive decoupling of the dynamic and undesired rolling motion of the by driving on a deformed track sections, z. As a track warp, generated relative bank of successive segments of a articulated train required.

This will be at the in FIG. 1 and 2 schematically illustrated vehicle 101 achieved as follows, wherein the FIG. 1 in plan view the situation on a flat track and the FIG. 2 the situation on a twisted track represents:

Between the respective second car body 103, 104 and the first car body 102 a respective rolling support means 108 and 109 is arranged. Thus, between the second car body 103 and the first car body 102, a first anti-roll device 108 is provided, while between the third car body 104 and the first car body 102, a second anti-roll device 109 is provided.

The first anti-roll device is designed in the form of a first pull-push rod 108 which, on the one hand, is articulated pivotably on a bracket on the second vehicle body 103. At its end facing the first vehicle body 102, the first rod 108 is rotatably mounted in a first articulation point 108.1 in a first free end of a first lever arm 110.1 of a coupling device 110, the function of which will be explained in more detail below.

In an analogous manner, the second anti-roll device 109 is designed in the form of a second pull-push rod 109, which is articulated on the one hand pivotally on a console on the third car body 104. At its end facing the first carriage body 102, the second rod 109 is rotatably mounted in a second articulation point 109.1 in a first free end of a second lever arm 110.2 of the coupling device 110. The first lever arm 110.1 and the second lever arm 110.2 are mechanically connected via a coupling rod 110.3, so that the first anti-roll device 108 is mechanically coupled via the coupling device 110 to the second anti-roll device 109.

The first lever arm 110.1 designed as a short angle lever is pivotably connected to the first car body 102 in the vicinity of the first anti-roll device 108 about a first pivot point 110.4 with a first pivot axis. The first pivot axis is located in the region of the bend of the first lever arm 110.1 and is fixedly connected to the first carriage body 102.

At the first free end of the first lever arm 110.1 is the first articulation point 108.1 of the first anti-roll device 108, while at the second free end of the first lever arm 110.1 the coupling rod 110.3 is articulated.

The second lever arm 110.2, which is likewise designed as a short angle lever, is pivotably connected to the first vehicle body 102 in the vicinity of the second anti-roll device 109 about a second pivot point 110.5 with a second pivot axis. The second pivot axis is located in the region of the bend of the second lever arm 110.2 and is fixedly connected to the body 102.

At the first free end of the second lever arm 110.2 is the second pivot point 109.1 of the second anti-roll device 109, while at the second free end of the second lever arm 110.2, the coupling rod 110.3 is articulated.

The first articulation point 108.1 and the second articulation point 109.1 in turn form bearing points of the respective anti-roll device 108 or 109 with respect to the first vehicle body 102, ie a bearing point of the anti-roll device 108 or 109, the non-actuation or fixation of the coupling device 110 and upon actuation of the anti-roll device 108 or 109 with respect to the first vehicle component, that is, the first car body 102, is stationary.

The first lever arm 110.1 and the second lever arm 110.2 preferably have identical dimensions and are arranged symmetrically to the transverse center plane of the first car body 102. In this case, the coupling rod 110.3 extends continuously on one side of the connecting straight line of the pivot points 110.4 and 110.5, so that a counter-force-free deflection of the first free end of the first lever arm 110.1 generates an opposite deflection of the first free end of the second lever arm 110.2 and vice versa.

Because of the position of the first articulation point 108.1 at the first free end of the first lever arm 110.1 and the position of the second articulation point 109.1 at the first free end of the second lever arm 110.2, the coupling device 110 causes opposing deflections of the first articulation point 108.1 and the second articulation point 109.1 of the respective anti-roll device 108 and 109 and thus in the context of the present invention, an opposite state change of the respective anti-roll device 108 and 109. The amount of the deflections is the same, while the directions are respectively opposite.

It should be mentioned at this point for the sake of completeness that in other variants of the invention can also be provided that the first lever arm and the second lever arm need not necessarily be articulated in the on the first car body. Rather, at least one of the two can also be articulated to the respectively adjacent to the first car body second or third car body (which then, of course, the respective lever arm remote from the other end of the anti-roll device is hinged to the first car body).

The mode of operation of the coupling device 110 and the first anti-roll device 108 and second anti-roll device 109 coupled via it will be explained below.

Does the first car body 102, z. B. due to a rough running and its high center of gravity, a pure rolling moment about a roll axis parallel to Vehicle longitudinal axis 101.1, the first articulation point 108.1 and the second articulation point 109.1 move at its two car body ends opposite the adjacent vehicle bodies 103, 104 in the same relative direction. As a result, the first free ends of the two angle levers 110.1 and 110.2 are loaded symmetrically, ie, a force of essentially the same direction and the same amount is exerted on them in each case. Due to their own rigidity and the rigidity of the coupling rod 110.3, the angle levers 110.1 and 110.2 are prevented from rotating so that the arrangement, like the known rods 107, counteracts the rolling movement.

When twisting the track, the car bodies 102, 103, 104, etc. are successively deflected in the direction of travel from the vertical direction, like this FIG. 2 can be seen. The relative horizontal movement between the first car body 102 and the preceding third car body 104 and between the first car body 102 and the subsequent second car body 103 now takes place in the opposite direction. As a result, the two angle levers 110.1 and 110.2 can rotate about their respective pivot point 110.4 or 110.5 in the same direction. The coupling rod 110.3 undergoes no appreciable force, but also moves almost without resistance in the vehicle longitudinal direction 101.1 Thus, the brackets on the car bodies 102, 103, 104 and the car bodies 102, 103, 104 themselves not as in the conventional case with the rods 107 with constraining forces loaded.

In a mixed form of both movements, d. H. with simultaneous rolling of a car body during the crossing over a piece of deformed track, only the actual rolling of a single car body relative to the car bodies adjacent to him differential forces are absorbed by the brackets of Wankstützeinrichtungen 108, 109, while caused by the track warping increasing inclination of the car bodies 102, 103, 104 does not cause undesirable constraining forces in the transverse direction.

As FIG. 1 can be seen, the supported on the chassis 102.1 first car body 102 in the direction of the longitudinal axis 101.6 (first) length, which is significantly smaller than the (second) length of the second car body 103 and the (third) length of the third car body 104th of the two adjacent vehicle-less vehicle modules 101.2 and 101.3. This has the advantage that the coupling device 110 can be made significantly shorter and therefore simpler than in conventional solutions in which the coupling device is arranged on the usually much longer trolley-less sedan chairs.

In the present example, the first length is about 25% of the second length and the third length. It is understood, however, that the other variants of the invention may be provided that the first length is at most 60%, preferably at most 40%, the second length and / or the third length. This can be achieved in any case, the advantages described above.

Again FIG. 1 It can also be seen that the second vehicle body 103 and the fourth vehicle body 105 are coupled at least by means of a simple joint 111, which optionally does not allow rolling movements between the second vehicle body 103 and the fourth vehicle body 105. However, this is not critical, since in the present example, the fourth car body 105 (preferably the same extent as the first car body 102) in the longitudinal direction of the vehicle 101 is significantly shorter than the second car body 103, so that the unit of the second car body 103 and the fourth car body 105 in terms of rolling movements ultimately behaves like a conventional long car body in which thanks to the coupling device 110 but in particular the torsional loads (about the longitudinal axis 101.6) are significantly reduced.

Again FIG. 1 The third car body 104 and the fifth car body 106 are also coupled at least via a simple joint 111, which optionally no rolling movements between the third car body 104 and the fifth Car body 106 allows.

Again FIG. 1 Finally, it can be seen, the coupling device 110 may be provided with a damping device and / or an active actuating device, as indicated by the dashed contour 112. About this damping device and / or actuator 112 may be an attenuation or (controlled by a corresponding control device) an active adjustment of the coupling of the rolling movements between the first, second and third car body 102 to 104. In particular, an active adjustment of the motion ratio of the coupling device 110 can optionally be undertaken.

Second embodiment

A further advantageous embodiment of the vehicle 201 according to the invention with the car bodies 202, 211, 212 is in FIG. 3 shown. The vehicle 201 corresponds to in its basic design and operation of the vehicle 101 FIG. 1 , so that only the differences should be discussed here.

The only difference from the execution FIG. 1 consists in the design of the two anti-roll devices 208 and 209 and the coupling device 210, via which the two anti-roll devices 208 and 209 are coupled together.

Thus, on the one hand, the two anti-roll devices 208 and 209 are each fixed in position to the respective first vehicle body 202 and second or third vehicle body 203 or 204, respectively. In addition, the two anti-roll devices 208 and 209 are not formed as rigid rods, but each comprise a working cylinder 208.1 and 209.1, by means of which the length of the anti-roll device 208 and 209 can be adjusted via a working fluid.

Instead of the coupling rod 110.3, the coupling device 210 comprises a hydraulic coupling in the form of a hydraulic line 210.3 via which the working spaces of the working cylinders 208.1 and 209.9 (in any suitable manner) are connected in order to achieve the opposite coupling of the two anti-rolling devices 208 and 209.

It is understood that in other variants of the vehicle according to the invention, the hydraulic coupling device described above may also be provided with an active actuating device and / or a damping device, as shown in FIG. 3 is indicated by the contour 212. Thus, for example, a corresponding pump and control unit or the like may be provided, which modifies the degree of filling of the working spaces of the hydraulic cylinders in accordance with the specifications of a control device.

Third embodiment

A further advantageous embodiment of the vehicle 301 according to the invention with the car bodies 302, 311, 312 is shown in FIG FIG. 4 shown. The vehicle 301 corresponds in its basic design and operation of the vehicle 101 from FIG. 1 , so that only the differences should be discussed here.

The only difference from the execution FIG. 1 consists in the design of the anti-roll device 308 and the coupling device 310, via which the two anti-roll devices 308 and 309 are coupled together.

Thus, on the one hand, the anti-roll device 308 is designed as a swivel fixed to the second car body 303. It is understood, however, that in other variants of the invention, a design with a rigid rod may be provided, as in FIG. 4 is indicated by the contour 313.

In place of the angle levers 101.1 and 101.2 and the coupling rod 110.3, the coupling device 310 further comprises simply a first lever 310.1, at the ends of which the two anti-roll devices 308 and 309 are articulated and at an articulation point 310.4 (in the center region of the car body 302) on the vehicle body 302 (Rotatable about the vertical axis of the car body 302) is articulated. As a result, the opposite coupling of the rolling movements can be achieved in a particularly simple manner. It should be mentioned that in particular the (in the longitudinal direction) comparatively short design of the first carbody 302 and thus the short distance to be bridged between the anti-roll devices 308 and 309 are of particular advantage for the simplicity of the design.

It is understood that in other variants of the vehicle according to the invention, the above-described or other coupling mechanisms can be used individually or in combination in order to realize the inventive coupling between the anti-rolling devices.

The present invention has been described above solely by means of examples of rail vehicles with a central support module with chassis and two wheelless litter adjacent thereto. It should be mentioned again, however, that the invention can also be used in conjunction with any other vehicle constellations in which at least one of the two adjacent to the short first vehicle module vehicle modules is also supported on at least one chassis.

The present invention has been described above solely by means of examples of rail vehicles. Finally, it goes without saying that the invention can also be used in conjunction with any other vehicles.

Claims (16)

Vehicle, in particular rail vehicle, with a vehicle longitudinal axis (101.6), - A first vehicle module (101.1) with a first car body (102, 202, 302), a second vehicle module (101.2) with a second car body (103, 203, 303) and a third vehicle module (101.3) with a third car body (104; 204, 304), where - the second vehicle module (101.2) and the third vehicle module (101.3) are arranged adjacent to the first vehicle module (101.1) in the direction of the vehicle longitudinal axis (101.6) in each case one of the two ends of the first vehicle module (101.1), the first carbody (102, 202, 302) and the second carbody (103, 203, 303) are connected via a first anti-roll device (108, 208, 308), the first carbody (102; 202; 302) and the third carbody (104; 204; 304) are connected via a second anti-roll device (109; 209; 309), wherein - The respective anti-roll device (108, 109; 208, 209; 308, 309) counteracts rolling movements about the vehicle longitudinal axis (101.6) between the connected vehicle bodies, and - the first anti-roll device (108; 208; 308) and the second anti-roll device (109; 209; 309) are coupled to each other via a coupling device (110; 210; 310) for counteracting each other, characterized in that in the direction of the vehicle longitudinal axis, the first carbody (102, 202, 302) has a first length, the second carbody (103, 203, 303) has a second length, and the third carbody (104, 204, 304) has a third length, wherein - The first length is small compared to the second length and / or the third length. Vehicle according to claim 1, characterized in that the first length is at most 60%, preferably at most 40%, more preferably at most 25% of the second length and / or the third length. Vehicle according to claim 1 or 2, characterized in that - The first car body (102, 202, 302) is supported on a chassis (105.1), while the second vehicle module (101.2) and / or the third vehicle module (101.3) is formed without a chassis. and or - The first car body (102, 202, 302) is supported on a chassis (105.1), while the second vehicle module and / or the third vehicle module is supported on at least one other chassis. Vehicle according to one of the preceding claims, characterized in that the coupling device (110; 210; 310) is designed such that a counterforce-free movement under a first rolling movement of the second car body (103; 203; 303) with respect to the first car body (102; 202; 302) shows a second state change of the second anti-roll device (109; 209; 309) under a second rolling movement of the third car body (104; 204; 304) opposite to the first rolling movement with respect to the first vehicle body (102; 202; 302). Vehicle according to one of the preceding claims, characterized in that the coupling device (110; 210; 310) is designed such that a first state change, in particular a first displacement and / or a first change in length, of the first anti-friction device (108; 208; 308) causes a reverse second state change of the second anti-roll device (109; 209; 309). Vehicle according to one of the preceding claims, characterized in that the first anti-roll device (108, 308) is articulated on the coupling device (110, 310) in a first articulation point (108.1), - The second anti-roll device (109, 309) is articulated in a second articulation point (109.1) on the coupling device (110, 310), and - The coupling device (110, 310) is designed such that a counterforce-free first displacement of the first linkage point (108.1) causes a counter-rotating second displacement of the second linkage point (109.1). Vehicle according to claim 6, characterized in that the first displacement and the second displacement have substantially the same amount but divergent directions, in particular substantially opposite directions. Vehicle according to one of the preceding claims, characterized in that the coupling device (110; 210; 310) connects parts of the first anti-roll device (108; 208; 308) and the second anti-roll device (109; 209; 309) located on the same side of the vehicle longitudinal axis. Vehicle according to one of the preceding claims, characterized in that the coupling device (110; 210; 310) connects components of the first anti-roll device (108; 208; 308) and the second anti-roll device (109; 209; 309) which have the same function and / or Have location within the respective anti-roll device. Vehicle according to one of the preceding claims, characterized in that - The coupling device (110, 310) at least one about a first pivot point (110.4, 310.4) pivotally connected to the first car body (102, 302) hinged first lever arm (110.1, 310.1), wherein - The first pivot point (110.4; 310.4) in the kinematic chain between the first anti-roll device (108; 308) and the second anti-roll device (109; 309) is arranged. Vehicle according to claim 10, characterized in that - The first lever arm (110.1; 310.1) comprises a free first end and a free second end, wherein - The first end is directly connected to the first anti-roll device (108, 308) and - The second end is connected directly or via further intermediate elements with the second anti-roll device (109; 309). Vehicle according to claim 7 or 8, characterized in that - The coupling device (110) at least one about a second pivot point (110.5) pivotally mounted on the first car body (102) hinged second lever arm (110.2), wherein - The second pivot point (110.5) in the kinematic chain between the first anti-roll device (108) and the second anti-roll device (109) is arranged and - The second lever arm (110.2) with the first lever arm (110.1) via at least one coupling element (110.3), in particular a push rod, is connected. Vehicle according to one of the preceding claims, characterized in that the coupling device (210) comprises at least one first working cylinder (208.1), in particular a first hydraulic cylinder, connected to the first anti-roll device (208), - The coupling device (210) at least one with the second anti-roll device (209) connected second working cylinder (209.1), in particular a second hydraulic cylinder comprises, and - The coupling device (210) at least one of the first working cylinder (208.1) and the second working cylinder (209.1) connecting connecting line (210.3) for a working fluid, in particular a hydraulic fluid comprises. Vehicle according to claim 13, characterized in that - the first working cylinder (208.1) is part of the first anti-roll device (208), and or - The second cylinder (209.1) is part of the second anti-roll device (209). Vehicle according to one of the preceding claims, characterized in that the coupling device (110; 210; 310) comprises a damping device (112; 212). Vehicle according to one of the preceding claims, characterized in that the coupling device (110; 210; 310) comprises an adjusting device (112; 212).

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