Coupler device for a coupling, in particular of a rail vehicle

Abstract

Coupler device for a coupling, in particular of a rail vehicle, is provided with a drawbar with spring elements mounted thereon in order to dampen the tension and pressure forces incurred, with a plate arranged between these, and a support flange secured to the rail vehicle. The plate bears the drawbar and is held on the support flange and connected at its outer circumference in each case with a carrier disk, each in an opening of the support flange, by overload elements arranged adjacent to one another. The overload elements are sheared off in the event of an overload in the pressure or tension direction of the drawbar. Accordingly, a secure connection is formed between the support flange and the plate, which, in the event of a crash or an overload, can be detached in a functionally reliable manner, but which in normal operation ensures a perfect coupling linkage.

Claims

1. Coupler device for a coupling, in particular of a rail vehicle, comprising: a drawbar, a plurality of spring elements mounted on the drawbar for damping the tension and pressure forces incurred, a plate arranged between the spring elements, a support flange configured to be secured to the rail vehicle, wherein the plate is mounted on the drawbar and held on the support flange, and a carrier disk, the plate being connected at its outer circumference to the carrier disk in each case in an opening of the support flange by means of at least two overload elements arranged next to one another, wherein the overload elements can be sheared off in the event of an overload in the pressure or tension direction of the drawbar, and wherein in each case at least one spring element is arranged on both sides of the plate.

2. Coupler device according to claim 1, wherein in the axis (A) of the carrier disks, arranged coaxially to one another, in each case a securing means is provided for fixing them to the plate, wherein the plane formed by the overload elements arranged in pairs is located at a distance interval from the axis (A) of the carrier disks.

3. Coupler device according to claim 2, further comprising overload elements for the connection of the respective carrier disk to the plate, which are arranged in pairs with their axes parallel to one another, and are arranged in the plane in the direction of the drawbar.

4. Coupler device according to claim 1, wherein the drawbar is additionally mounted in the plate by means of a swivel joint in such a way that it can be deflected.

5. Coupler device according to claim 1, wherein the support flange comprises on both sides a projection with the respective opening for the carrier disks, which can be closed on the outside by a cover with a number of securing means.

6. Coupler device according to claim 1, wherein the plate and the support flange are dimensioned on the outside and the inside respectively in such a way that the drawbar, with the spring elements mounted on it and the plate arranged between them, can be pushed as one unit into the support flange, and the plate can be connected by way of the securing means and the overload elements to the carrier disks placed in the openings.

7. Coupler device according to claim 1, wherein a mid-centring element is assigned to the support flange, which interacts with the unit formed by the drawbar and the plate in such a way that the drawbar is adjusted with its longitudinal axis, in the unloaded state, in the horizontal alignment always approximately in the longitudinal direction of the rail vehicle.

8. Coupler device according to claim 7, wherein the mid-centring element comprises, at the support flange, at least one centring means, consisting of a spring pressure body with a sliding element and a guide rail interacting with this body, wherein the guide rail runs parallel to the longitudinal axis of the drawbar.

9. Coupler device according to claim 1, wherein arranged at the support flange is a connection arm, aligned preferably parallel to the drawbar, at a bearing in the extension of one of the projections, which is held by the support flange on one side and by the drawbar on the other, and has the effect of producing a supporting pressure force onto the drawbar, and therefore, at least, a certain centring height position of the coupling head is incurred.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] The invention is explained in greater detail hereinafter on the basis of exemplary embodiments and making reference to the drawings, wherein:

[0013] FIG. 1 shows a coupler device according to the invention in a longitudinal section through the axes of the overload elements;

[0014] FIG. 2 shows the coupler device according to FIG. 1 in a longitudinal section offset at an angle to the longitudinal axis of the drawbar; and

[0015] FIG. 3 is a view from above of the coupler device according to FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

[0016] The coupler device shown in FIG. 1 includes or consists essentially of a drawbar 1, which can be connected to a connecting rod, a coupling head, a spacer pipe, a spiral sleeve, an energy absorption element, or the like, with a plurality of spring elements 2 mounted on it for damping the pressure and tension forces incurred when in the coupled state. In addition, provision is made for a support flange 3, which can be secured to a vehicle box or the like of the rail vehicle, these not being shown in any greater detail, which is provided with openings 3′ for its securing. The drawbar 1 is mounted in this situation in a plate 5 arranged between these spring elements 2. Such a coupler device is well-suited for rail vehicles of all kinds, such as for passenger coaches, goods wagons, locomotives, or vehicles for other purposes.

[0017] According to the invention, the plate 5 is connected on its outer circumference in each case to a carrier disk 10, 11, in each case in an opening 8′, 9′ of the support flange 3, by means of at least two adjacently arranged overload elements 14a, 14b, wherein these overload elements 14a, 14b are arranged with their axes 14 parallel to one another in one plane in the direction of the drawbar 1, and which can be sheared off in the event of an overload in the pressure or tension direction of the drawbar. These overload elements could, however, also be arranged as parallel and in one plane.

[0018] The sectional plane shown along the axes 14 of the overload elements 14a, 14b arranged in pairs is arranged at a distance interval from the rotation axis A of the carrier disks 10, 11, and the longitudinal axis of the drawbar respectively.

[0019] According to FIG. 2, the coaxially arranged carrier disks 10, 11, and the plate 5, which are located in these openings 8′ of projections 8, 9 of the support flange 3, are provided with a central hole 4 in the axial direction A, in which in each case a detachable securing means 4a is provided for fixing them to the plate 5. This securing means 4a is preferably a screw, and serves primarily as a fitting aid. It could also be screwed in at another position than that represented, and it would be possible for several of these to be used per carrier disk 10, 11. In the event of an overload, these securing means 4a are likewise sheared off.

[0020] The spring elements 2, arranged in rows on both sides of the plate 5, are fitted on one side with five pads in the pressure direction, and on the other with three pads in the tension direction. This number can be varied, depending on the circumstances, between, in front of, and behind the plate, in each case by at least one spring element 2, or, as represented, more than two.

[0021] Accordingly, the drawbar 1, preassembled to form one unit, can be pushed together with the spring elements 2 and the plate 5 located between them, into the support flange 3 secured to the rail vehicle, and then secured in it by these overload elements 14a, 14b, by being secured in the holes in the plate 5.

[0022] These overload elements 14a, 14b are preferably configured as shear bolts or shear screws. They could also be configured, however, as disks, slot nuts, or other forms, and are provided with predetermined break points in the form of grooves, and are dimensioned in such a way that, in the event of the occurrence of a predetermined overload, they are sheared off. The drawbar 1, together with the spring elements 2 and the plate 5 are pushed backwards in the event of an excessive impact force. Depending on the force of an impact, this can be overcome without significant damage to the coupling or the vehicle. Accordingly, it is possible for the number and/or dimensions of the overload elements used to be varied from case to case, such that their effectiveness can be optimally configured under the respective requirements to meet the maximum impact or tension forces.

[0023] The plate 5 comprises two diametrically arranged peripheral surfaces 6, 7, which are guided close to free of any play in projections 8, 9, flattened on the inner side, of the support flange 3. In principle, these flat peripheral surfaces could also be configured as cylindrical or similar.

[0024] Moreover, it is also possible for a closable cover 12 to be secured on the projections 8, 9, closing an opening 8′, 9′ in each case, which can be closed by a number of securing means 12′, such as screws. With this robust securing of the cover 12, the situation is attained that, in the event of shearing, the carrier disks are securely held in the support flange, and that they can easily be replaced.

[0025] The coupler device according to the invention makes provision that the plate 5 and the carrier disk 10, 11, arranged coaxially on both sides of it are mounted such as to pivot about a perpendicular axis A in the openings 8′, 9′ of the projections 8, 9 of the support flange 3. The drawbar 1 is also preferably mounted in the plate 3 so as to deflect by means of a rotary joint 13. By way of indication, the rotary joint 13 is represented as a spherical sleeve at the outer circumference. Accordingly, the drawbar 1 can be pivoted both horizontally as well as vertically about a limited angle.

[0026] The spring elements 2, with the plate 5 located between them, are installed on the drawbar 1 between a front sleeve 19 and a rear locking disk 15. They can be fixed and pretensioned against the sleeve 19 by means of a nut 16 or the like, which can be screwed in at the rear end of the drawbar.

[0027] Within the framework of the invention, a mid-centering element is assigned to the support flange 3, which, at the support flange 3, comprises on at least side, or preferably on both sides, in each case a centering means 20, which consists of a spring pressure body 21 with a slide element 22 and, interacting with this, a guide rail 23, with a guide track 23′. This spring pressure body 21 comprises a pressure spring 21′, a piston element 24, which moves when subjected to pressure from the spring, and mounted on which is a slide element 22, provided for preference in the form of a roller. This slide element 22 is pressed by the spring pressure body 21 onto the guide rail 23, which is secured laterally by the plate 5, and runs parallel to the longitudinal axis of the drawbar 1. This guide rail 23 could also be located directly at the plate, and its shape could be configured, depending on the desired characteristics of the mid-centering element as cylindrical, curved, or some other form.

[0028] This mid-centering element, with the two centering means 20 on both sides of the plate 5, therefore interact in such a way with the unit formed by the drawbar 1 and the plate 5 in such a way that the drawbar 1 is positioned with its longitudinal axis, in the unloaded state, in a horizontal alignment always approximately in the longitudinal direction of the rail vehicle. Purposefully, these sliding elements 23 engage, in relation to the longitudinal axis of the drawbar 1, offset to the rotation axis A on the guide rail 23, such that a torque force takes effect on the plate.

[0029] In the coupled state of the device and the deflections which occur on the drawbar in travel operation, or with a rotation of the plate 5, the guide rails 23 are pivoted in opposite directions, and in consequence the spring pressure bodies 21 are in each case pressed further together on one side by the slide element 22, and relaxed on the other side. When the coupler device is released, the drawbar 1 is again adjusted horizontally into the middle.

[0030] The support flange 3 can comprise, in the radial elongation of the projection 9, a connection arm, connected to it in a bearing 17 and aligned preferably parallel to the drawbar, with a pressure spring exerting pressure on it in the longitudinal direction, which is not represented in any greater detail. This couples the support flange 3 to the drawbar 1 in such a way that a supporting pressure force is produced, by means of which it, and the coupling head connected to it, are centered at a predetermined height position. Such a connection arm is explained in detail in the European Application No. 19 214 224.8, and is therefore not described in any greater detail hereinafter.

[0031] In the event of a collision with an obstacle or another vehicle, the drawbar 1 is subjected to overload forces, which, on reaching a predetermined intensity, cause the overload elements to shear off. As a result, the drawbar 1, together with the spring package 2 and plate 5, are pushed backwards through the opening in the support flange 3, which is flush with the outer profile of the plate, into a vehicle box of the rail vehicle. As a result, after a crash the spring package can be taken back into use without any great effort, inasmuch as no irreversible damage has been incurred.

[0032] According to FIG. 3, for the connection of the carrier disks 10, 11 to the plate 5, in each case four overload elements 14a, 14b are provided, which are arranged in pairs with their axes 14 parallel to one another and in the plane in the direction of the drawbar. Advantageously, these four overload elements 14a, 14b are arranged symmetrically and at the same distance interval from the axis A. In addition, the centric arrangement of the securing means 4a, the cover 12, and the number of its securing means 12′ can be seen.

[0033] The invention has been adequately disclosed by the foregoing exemplary embodiments. It could, however, also be disclosed by further variants. For example, the carrier disks could be fixed in the respective opening of the support flange. The number of the overload elements with a respective carrier disk amounts to at least two. These could in principle be arranged on the plane of the longitudinal axis of the drawbar.