EP2177417A1 - Railway vehicle with a frontal communication passage - Google Patents

Abstract

The railway vehicle has a front passage (F), which has a passage frame (2). The passage frame is mounted on a supporting element outgoing from a vehicle body. The passage frame is pivot-mounted such that the passage frame is displaced between a retracted position and an extended position. The passage frame captures a state parallel to a front of the railway vehicle under folding of bellows (B) of the front passage by the retracted position. The passage frame captures a vertical position by the extended position.

Description

The invention relates to a rail vehicle with a front transition, which has a transition frame, which is mounted on an outgoing from the vehicle body support member.

Such a rail vehicle, for example, under the name "Desiro UK" for several years in use. In this case, front links are used to connect trainsets, each forming one half of a total transition and have transitional frames, which are mounted on a serving as a support element central buffer coupling. The transitional frames are aligned and pressed together only by engaging the central buffer coupling. A walk-in connection between two adjacent train units is thus produced solely by the coupling of the trainsets, so that no additional downtime arises in operation compared to rail vehicles without front transition.

In such rail vehicles, however, it is considered disadvantageous that the transition frames protrude far in front of the front of the driver's cab, so that a stretch view is hindered for the driver. In addition, a appearance of a vehicle front is affected.

Proceeding from this, the present invention seeks to develop a rail vehicle of the type mentioned in such a way that the transition frame hindered less the track view for the driver.

This object is achieved in that the transition frame is pivotally mounted so that it is between a retracted position in which the transition frame under Folding a bellows of the front transition assumes a position substantially parallel to a front of the rail vehicle, and an extended position in which the transition frame occupies a substantially vertical position, is movable.

Due to the pivotability of the transition frame, it is possible that the front transition can be spent when not in use in a position that is less disturbing for the operation of the rail vehicle. In particular, the field of vision of a rail vehicle driver is significantly increased compared with the prior art.

Preferably, the support element is formed by an arm extending from the vehicle body. At the free end of the arm of the transition frame is articulated, so that the transition frame between the retracted and the extended position can be pivoted / moved. Alternatively, the transitional frame can also be pivotably supported on a central buffer coupling.

Preferably, an actuator is provided for moving the transition frame between the retracted and extended positions. This makes it possible, in particular automatically to move the transition frame between the two positions.

The actuator may be configured such that the transition frame is locked in both the retracted and extended positions. This has the advantage that transition frame maintains its respective assumed end position even when subjected to external forces.

The actuator may comprise an actuator which rotates, via a gear member, a rotary member having a radially extending lever whose free end is applied to one end of a rod whose other end is hinged to the transient frame. The like configured actuator allows to move by rotating the rotary member. In this case, the rotational movement of the rotary member is translated into a translational movement of the transition frame, with the interposition of the lever and the rod, which can act both as a pressure and as a pull rod.

It is advantageous if the transmission element, the lever and the rod are arranged in one plane. This plane may be preferred, based on the rail vehicle, a horizontally extending plane.

To realize the locking of the transition frame in its retracted or extended position, it is advantageous if these positions are each assigned a stop for the lever. The stops can advantageously be arranged such that a unit of lever and rod occupy an over-center position both in the retracted and in the extended position of the transition frame. This causes the exercise of external forces on the transition frame in the retracting or extension direction remain ineffective, since a respective stop limits the movement of the transition frame.

The lever may be biased towards the stops. This has the advantage that an assumed Übertotpunktlage for the lever and the rod is securely maintained.

The lever may be biased by means of a spring element, which is preferably formed by a tension spring, one end of which is articulated to the lever and the other end is fixed.

For the above-mentioned actuator, including translation element, both translational drives, such as pneumatic cylinders with piston rod or piston rodless cylinders, as well as rotary drives, as an electric gear motor with, for example, belt / chain drive or worm or planetary gear, implemented. These allow a particularly compact design for the actuator.

Preferably, a further outer transition frame is provided, which is connected via a further bellows with the transition frame. This transitional framework is then not driven.

Figur 1

eine Seitenansicht eines Schienenfahrzeugkopfes mit Frontübergang, mit einem Übergangsrahmen in eingefahrener Position,

Figur 2

eine Seitenansicht eines Schienenfahrzeugkopfes mit Frontübergang nach Figur 1, mit dem Übergangsrahmen in ausgefahrener Position,

Figur 3

eine schematische Darstellung einer Betätigungsvorrichtung für den Übergangsrahmen von Fig. 1, mit dem Übergangsrahmen in eingefahrener Position,

Figur 4

eine schematische Darstellung der Betätigungsvorrichtung von Figur 3, mit dem Übergangsrahmen in ausgefahrener Position, und

Figur 5

eine Seitenansicht eines Schienenfahrzeugkopfes mit gegenüber Figur 1 modifiziertem Frontübergang.

Embodiments of the invention will be explained in more detail with reference to the drawings. Show it:

FIG. 1

a side view of a rail vehicle head with front transition, with a transition frame in the retracted position,

FIG. 2

a side view of a rail vehicle head with front transition to FIG. 1 with the transition frame in the extended position,

FIG. 3

a schematic representation of an actuator for the transition frame of Fig. 1 , with the transition frame in retracted position,

FIG. 4

a schematic representation of the actuator of FIG. 3 , with the transition frame in the extended position, and

FIG. 5

a side view of a rail vehicle head with opposite FIG. 1 modified front transition.

Out FIG. 1 is the general configuration of a rail vehicle head K, equipped with a front transition F removable. The front transition has a first transition frame 1 and a second transition frame 2 on, which are each hinged to support elements hinged, which are connected to the head K. The first, outer transitional frame 1 is articulated to a central buffer coupling 3, which in turn is fastened to an underside of the rail vehicle head K. The second transitional frame 2, which is located further inwards relative to the first transitional frame 1, is pivotably mounted on the head K via an arm 4.

While FIG. 1 shows the retracted position of the front transition F goes out FIG. 2 the extended position. It can be seen that, retracted, both transitional frames 1, 2 are aligned substantially parallel to a front of the traction vehicle head K, ie at an angle to a vertical transverse plane. It is also in FIG. 1 a respective bellows B, here in two parts, in a folded state, while in FIG. 2 the bellows B is deployed.

In the Figures 1 and 2 In each case schematically a mechanical actuator V is shown, which serves for moving the second transition frame 2 between the retracted and the extended position of the front transition.

The detailed structure of the mechanical actuator is based on the Figures 3 and 4 explained. FIG. 3 shows the mechanical actuator V for the retracted position of the front transition F, while FIG. 4 a corresponding representation for its extended position shows.

In Fig. 3 . 4 in each case an actuator 6 is shown, which is operated by way of example pneumatically. A longitudinally displaceable piston rod 7 merges into a transmission element 8, which engages radially in a rotary element 9 and is mounted on the side opposite the rotary element 9.

The rotation element 9 may for example be equipped with a toothing on its outer circumference, in which engages a rack portion of the transmission element 8.

The rotation element 9 has a lever 10 which extends radially from it. The lever 10 is rigidly connected to the rotary member 9. A movement angle for the rotary member 9 is limited by two stops 11, 12, against which the lever 10 comes when taking a retracted or extended position of the front transition F to the plant. The lever 10 is articulated on a rod 13. An articulation point of the rod 13 on the lever 10 is located directly inwardly of the against the stops 11, 12, reaching the abutting free end of the lever 10th

At a distance from the outer circumference of the rotary member 9, a tension spring 14 is hinged, which biases the lever 10 for both the retracted and extended position of the front transition in the direction of either the stop 11 or the stop 12. The second end of the spring 14 is fixed and is, relative to the rotary member 9, the translation element 8 opposite.

For closer illustration is in the Figures 3 and 4 a dead center axis for the system of lever 10 and rod 13 located. It can be seen that both locking positions for the front transition F each correspond to an over-center position. The maintenance of the respective locking position of the lever 10 on the stop 11 or the stop 12 is secured by the spring 14. How out FIG. 3 shows the system of the Übertotpunktverriegelung, consisting of the rotary member 9, the lever 10, the rod 13 and the spring 14 is pulled by the spring 14 against the stop 11. An outwardly acting on the transition frame 2 force pulls the dead center over only further against the stop 11. An inwardly on the Transition frame 2 acting force is taken up by design by the folded front half of the transition with stops 15 and by the tension spring 14. Due to the chosen geometry, an inward external force can not cause the dead center of the system to be reached because the lever 10 and rod 13 are maximally congruent.

With regard to the locking position according to FIG. 4 the following is to be noted: in this case, the system of the over-center locking is pulled by the spring 14 against the stop 12. An outwardly directed external force acting on the transitional frame 2 now pushes the over-center interlock further against the stop 12. An inwardly acting external force acting on the transitional frame 2 is provided by the coupled, opposite front transition half, here illustrated by stops 16, and received by the spring 14. Due to the selected geometry, the dead center of the system can not be achieved by the action of such a force, because the lever 10 and the rod 13 are maximally congruent.

In both locking positions, an angle between the lever 10 and the rod 13 remains greater than zero.

For swinging the front transition F of the actuator 6 is driven. This rotates about the translation element 8, the rotation element 9 and thus the lever 10. Until reaching the dead center, the actuator 6 has to apply the force for pivoting the transition frame 2 and the force for tensioning the spring 14. With the crossing of the dead center, the system is additionally pulled by the spring 14 in the end position, in which the lever 10 comes to rest on the stop 12.

FIG. 5 shows a further embodiment with only one transition frame 16 which is driven and supported on the central buffer coupling.

Claims (14)

A rail vehicle having a front transition (F), which has a transition frame (2) which is mounted on a support element emanating from the vehicle body,
characterized in that
the transitional frame (2) is pivotally mounted so as to assume a position substantially parallel to a front of the rail vehicle between a retracted position where the transitional frame (2) folds together a bellows (B) of the front transition (F); an extended position in which the transition frame (2) occupies a substantially vertical position, is movable. 2. Rail vehicle according to claim 1,
characterized in that
the support member is formed by an arm (4) extending from the vehicle body. 3. Rail vehicle according to claim 1,
characterized in that
the support element is formed by a central buffer coupling (3). 3. Rail vehicle according to one of claims 1 or 2,
characterized in that
an actuator (V) is provided for moving the transitional frame (2) between the retracted and extended positions. 4. Rail vehicle according to claim 3,
characterized in that
the actuating device (V) is designed such that the transition frame (2) is locked both in the retracted and in the extended position. 5. Rail vehicle according to one of claims 3 or 4,
characterized in that
the actuating device (V) has an actuator (6) which rotates via a transmission element (8) a rotary element (9) which has a radially extending lever (10) whose free end is articulated on one end of a rod (13), whose other end is hinged to the transition frame (2). 6. Rail vehicle according to claim 5,
characterized in that
the translation element (8), the lever (10) and the rod (13) are arranged in a plane. 7. Rail vehicle according to claim 6,
characterized in that
the plane, relative to the rail vehicle, is a horizontal plane. 8. Rail vehicle according to claim 7,
characterized in that
the retracted and the extended position of the transition frame (2) is associated with a respective stop (11, 12) for the lever (10). 9. Rail vehicle according to claim 8,
characterized in that
the stops (11 12) are arranged such
a unit consisting of lever (10) and rod (13) assumes an over-center position both in the retracted and in the extended position of the transitional frame (2). 10. Rail vehicle according to claim 9,
characterized in that
the lever (10) is biased in the direction of the stops (11, 12). 11. Rail vehicle according to claim 10,
characterized in that
the lever (10) is biased by means of a spring element (14). 12. Rail vehicle according to claim 11,
characterized in that
the spring element (14) is formed by a tension spring, whose one end is articulated to the lever (10) and whose other end is fixed. 13. Rail vehicle according to one of claims 1 to 12,
characterized in that
a further, outer transitional frame (16) is provided, which is connected via a further bellows with the transition frame (2).

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