EP1719684A1 - Central buffer coupling for railway vehicles - Google Patents

Abstract

The coupling has a coupling-shaft (1) and a linkage (2), which includes a bearing case (4), where the rear end of the shaft is connected with the linkage. The rear end of the shaft is horizontally pivotable by the bearing case at a wagon body of the railway vehicle. A shock proof unit (5) integrated in the linkage is designed such that a connection between the shaft and the linkage is released when a critical impact force transmitted by the shaft to the linkage exceeds, and the shaft partially absorbs the force transmitted to the linkage.

Description

The present invention relates to a central buffer coupling for rail vehicles with a coupling shaft and a bearing block having articulation, wherein the rear end of the coupling shaft connected to the articulation and is articulated horizontally pivotable about the bearing block of the articulation on the car body of the rail vehicle.

Such a clutch assembly is well known in the railroad industry and is used to make a positive mechanical connection between two adjacent bodies of a multi-unit train. Thus, the coupling shaft can also perform pivotal movements, which occur for example when cornering of the train, the articulation is designed so that a horizontal and vertical swinging and axial rotation of the coupling rod is made possible. It is known that in a rigidly supported coupling device, for example, occurring during the coupling process or during braking shocks and vibrations to damage the vehicle or: the clutch assembly itself can lead. To avoid such damage, it is necessary to limit the transmission of such shocks, vibrations and the like as possible. This is preferably achieved by providing the coupling assembly with elastic damping means, such as pull / push devices, for absorbing such impacts. For example, the linkage may consist of a bearing block with a pull / push device, the pull / push device tensile and compressive forces up to a defined size elastically passes over the bearing block in the vehicle untergestellt. The aim is to absorb energy with an elastic deformation and thus prevent overstressing of the undercarriage.

From rail vehicle technology, it is also known to use multi-stage energy dissipation facilities. These generally have as a primary stage a reversible energy dissipation device, which is integrated, for example, as a train / shock device in the articulation or as a clutch spring in the coupling shaft of the central buffer, and which should absorb the shock forces occurring in driving, maneuvering and coupling operation. In addition, a second, secondary energy dissipation device for absorbing impact energy resulting from excessive camber impulses is often arranged in the form of two side buffers on the outer edge of the end face of the respective car body. In this case, the energy dissipation devices are designed so that the implementation of the resulting from shunting accidents Aufstoßenergie is accomplished in two merging stages, the first stage is integrated in the central buffer and the second stage of the supporting body structure is preceded.

Another approach provides, after exhaustion of the coupling side energy dissipation device, the residual energy via a predetermined breaking point in the clutch assembly on carriage body side energy absorption elements, such as friction elements redirect. However, this presupposes that the coupling shaft is taken to the coupling head at a defined level of force from the force transmitted by the clutch assembly force flow, and thus allows the collision of the car bodies and the use of the car side energy absorbing elements. As a rule, the coupling shaft with the coupling head is removed from the power flow by the coupling shears off at predetermined breaking points in such a way that larger parts of the coupling arrangement are pushed by a backward movement of these in a space provided for this purpose in the undercarriage of the vehicle. A shearing function of the clutch is usually achieved in that the coupling shaft itself is fastened to the lower frame of the car body via the bearing block of the articulation or a joint and via an Abscherfunktion enabling, external shear element. However, this structure, in which the bearing block is fastened with external shear elements on the base of the car body, requires, however, that for the assembly of the linkage and belonging to the articulation bearing block at the respective end face of the car body, a contact surface of the bearing block corresponding opening must be provided the external shearing elements with respect to the mounting plate of the car body of the To attach the back to the undercarriage of the car body. This has the consequence that the installation of external shear elements is very expensive and expensive. Furthermore, in principle, a relatively large opening must be formed in the mounting plate of the car body. The same difficulties occur even when the linkage and belonging to the linkage bearing block are not mounted directly but via an adapter plate on the mounting plate of the car body.

FIG. 1 shows a perspective view of an articulation 102, known from the prior art, of a central buffer coupling for rail vehicles. FIG. 2 shows the linkage 102 according to FIG. 1 in a side sectional view. This linkage 102 belongs to a central buffer coupling, in which in the articulation 102 an existing from an elastomeric spring element pull / shock protection 110 is integrated. It is provided that the elastomeric spring element 110 receives tensile and compressive forces up to a defined size. As a result, the occurring during normal driving between the individual car bodies tensile and impact forces are absorbed. However, when the operating load is exceeded, for example when the vehicle collides with an obstacle, it is possible that the envisaged energy consumption of the pull / shock protection 110 provided in the articulation 102 is insufficient. So that this excess impact energy is not transmitted directly to the vehicle undercarriage and this is exposed to extreme loads, the bearing block 104 of the linkage 102 is attached via external shear elements 108 on the car body or on the subframe of the car body. This is particularly apparent from Fig. 3, which shows a plan view of the linkage 102 of FIG. 1 in a mounted on the undercarriage of the car body state. The external shearing elements 108 respond when the critical impact forces provided for the shock / shock protection 110 are exceeded, as a result of which they lose their function as fastening elements, and the entire coupling arrangement is removed from the transmitted force flow.

In addition to the disadvantage that in the mounting plate 117 of the car body a relatively large opening 107 must be provided to secure the bearing block 104 of the linkage 102 on the vehicle undercarriage, the solution shown in FIG. 3 has the further disadvantage that the bearing block 104th can only be attached from the back of the mounting plate 117 via external shear elements 108 on the vehicle body. In clutch assemblies in which, for example, by the immediate vicinity of a bogie, a screwing the linkage from the back is not possible, such a shearing solution of the coupling can not be used.

The present invention is therefore based on the object, a middle buffer coupling of the type mentioned in such a way that in a crash, i. upon impact of extreme impact energies, the coupled clutches are shortened such that the car side energy absorbing elements of the respective car bodies consume the impact energy transmitted in the impact between the adjacent car bodies without external shearing elements being employed in the space behind the clutch to force the clutch out of the power flow to take.

This object is achieved in a central buffer coupling for rail vehicles of the type mentioned in that the linkage itself has a shock absorber, wherein the shock absorber is designed such that when a transmitted over the coupling shaft on the linkage, definable critical impact force, the connection between linkage and Clutch shaft solved and the coupling shaft is at least partially taken from the transferred to the linkage power flow.

The solution according to the invention has a number of significant advantages over the known from rail vehicle technology and explained above central buffer coupling. By using a shock absorber provided in the articulation itself, which responds when a certain force transmitted to the coupling shaft is exceeded, the connection between the articulation and the coupling shaft is released, which allows the coupling shaft to be transferred from the force flow transmitted to the articulation can be pressed, in which case the respective carcass side energy absorbing elements are used and reliably reduce the transmitted impact energy. Thus, a maximum achievable and in particular calculable energy consumption is achieved in a predictable event sequence. Due to the fact that according to the invention the shock absorber is integrated in the articulation itself, it is no longer necessary to use external shearing elements, with which the bearing block of the articulation is fastened to the vehicle body, and which fulfill the shock protection function. Accordingly, it is no longer necessary with the clutch assembly according to the invention that in the mounting plate of the car body, an opening is provided through which passes through the bearing block to be fastened from the back of the mounting plate via external shear elements on the car body. Rather, it is now possible that the bearing block of the articulation is attached directly from the front of the mounting plate ago on the car body, for example with screws.

Advantageous developments of the invention are specified in the subclaims.

For example, it is provided that the shock absorber has an opening formed in the bearing block of the car body towards the central buffer coupling through which, after the critical impact force has been exceeded, the coupling shaft is at least partially pressed and thus removed from the force flow. The opening formed in the bearing block ensures that the coupling shaft released after the shock absorber has responded can move backwards into a space outside the coupling plane in order to be taken out of the power flow. This solution is particularly advantageous because thus the impact protection function or Abscherfunktion having linkage can be mounted from the front of the mounting plate, while in the mounting plate of the car body no opening must be provided. It is also conceivable that an opening corresponding to the opening formed in the bearing block is already provided in the screw-on plate by which the coupling shaft is at least partially pressed and thus removed from the force flow after the critical impact force has been exceeded, after the coupling shaft has been provided in the bearing block Opening happened. Instead of an opening already provided in the mounting plate of the car body, the material of the mounting plate or the mounting plate itself (for example, by a perforation corresponding to the opening) can be designed accordingly so that the coupling shaft after exceeding the critical impact force and after the response in the articulation provided shock protection as easy as possible, ie pierce the material of the mounting plate with little resistance and can be pressed by the thus resulting in the mounting plate opening.

In an advantageous further development of the aforementioned embodiment, it is provided that the bearing block of the articulation is not mounted directly but via an additional support plate or adapter plate on the mounting plate of the car body, wherein the support plate may further comprise an opening corresponding to the opening provided in the bearing block. This embodiment has the advantage that the central buffer coupling is designed to be modular with the shock absorber according to the invention and thus can be mounted without elaborate conversion measures on differently designed screw-on plates. As indicated in the previous embodiment, it is again conceivable that in the support plate itself originally no own opening is provided, but that a corresponding opening is formed only after the coupling shaft has passed through the opening provided in the bearing block.

In a particularly advantageous realization of the central buffer coupling according to the invention, it is further provided that the articulation can have a guide to at least partially guide the movement of the coupling shaft from the force flow transmitted to the articulation when the critical impact force is exceeded. This guide allows a very predictable event sequence, since the coupling shaft can be taken in a guided manner from the power flow when exceeding a defined level of force in a guided manner and thus allows the collision of the car bodies and the use of the car side energy absorbing elements.

In a particularly advantageous realization of the latter embodiment, it is provided that the guide has a run-on slope in the direction of the opening provided in the bearing block, wherein the guide is designed such that when the critical impact force is exceeded, the coupling shaft is pressed through the opening in the bearing block. This is a particularly simple to implement, maintenance-free and reliable functioning design of the guide. Of course, however, other embodiments of the leadership are conceivable.

Particularly preferably it is provided that the shock absorber has at least one shearing element, by means of which the coupling shaft is connected to the articulation, wherein the shearing element is designed such that it shears at a transmitted from the coupling shaft to the articulation critical impact force, and thus the connection between coupling shaft and linkage is released. Here, the term "shear element" is to be understood as a connecting member which breaks or shears when a certain force in the longitudinal and / or transverse direction of the coupling shaft is exceeded and thereby loses its function as a connecting member. It is conceivable to perform the shearing element such that only moments of force about a certain axis, for example, the longitudinal axis of the coupling shaft, a response of the shock protection will cause. Of course, other embodiments of the shearing element are also conceivable here. Thus, for example, the shearing element can also be designed so that it responds when a certain force is exceeded both in the longitudinal and in the transverse direction of the coupling shaft and thereby loses its function as a connecting member. It is also conceivable to design the shearing element so that it only responds to impact forces and not even to tensile forces.

In a special embodiment, the shock absorber has a shearing element with at least one predetermined breaking point, which breaks at a definable critical impact force, so that the shear element loses its function as a link and thus the connection between the coupling shaft and linkage is released. The advantage of a predetermined breaking point is that such a shearing element is particularly easy to implement, whereby the response of the shearing element is still very reliably adjustable. In other words, this means that in advance the critical impact force at which the shearing element of the shock absorber is activated and loses its function as a connecting member, can be accurately determined.

It is particularly preferred that the central buffer coupling according to the invention can be used in a coupling device in which the articulation is an eye bolt articulation, in which case the shearing element of the pin of the eye bolt articulation, and wherein the coupling shaft with the eye of the eye bolt articulation when exceeded the specified critical impact force is taken from the force flow transmitted to the linkage. Conceivable here would be that serving as Abscherelement bolt breaks when exceeding the specified critical impact force and thus loses its function as a link, as a result, the coupling shaft is taken with the provided at its rear end eye from the power flow, for example, by the in the bearing block of the Wagenkastens trained opening is pushed through.

In a further, although partially known from the rail vehicle technology solution, it is provided that the central buffer coupling further comprises an elastomeric spring device for damping transmitted via the coupling shaft on the linkage tensile and impact forces. It is envisaged that the elastomeric spring device includes an open towards the coupling head housing, in which the rear end of the coupling shaft protrudes co-axially with a radial distance from the inner peripheral surface of the housing, whereby thus the rear end of the coupling shaft on the housing with the Linkage is connected. In an elastomeric spring device containing integrated elastomer springs, resiliently prestressed resilient rings of an elastic material are advantageously provided between the inner peripheral surface of the housing, which are aligned vertically with their center planes and arranged one behind the other at a mutual distance in the longitudinal direction of the coupling shaft. However, it is also conceivable here to use a single cylindrical elastomer element (elastomer cylinder) instead of a plurality of individual rings arranged one behind the other, on the outer peripheral surface of which annular elastomer beads are provided. In a possible realization of the elastomeric spring means further include both the rear end of the coupling shaft and the Inside the housing to each other directed circumferential annular beads, wherein the made of an elastic material resilient rings or the said elastomeric cylinders are held with the annular beads in each case in spaces between two adjacent annular beads against the rear end of the coupling shaft and the housing, each resilient Ring rests directly on both the peripheral surface of the coupling shaft and on the inner peripheral surface of the housing, and wherein in relation to tensile and impact forces unloaded state of the elastomeric spring device, the annular ridges of the coupling shaft are aligned with the associated annular ridges of the housing. According to the invention, it is now provided that with the aid of the at least one shearing element, the housing of the elastomeric spring device is connected to the articulation, so that when exceeding the specified critical impact force of the coupling shaft with the housing and the elastomeric spring device provided therein from the transmitted to the articulation Power flow is taken. This solution is allowed that the invention provided in the articulation shock protection can also be used in linkages in which an elastomer-spring joint (EFG) is provided. It should be noted that this embodiment is of course not limited to elastomer spring devices but also in other integrated in the articulation train / shock devices is applicable. For example, such a pull / push device may also be implemented with hollow rubber springs, friction springs, hydraulic devices, and combinations thereof. It is also conceivable to use destructive impact elements in addition to regenerative impact elements. Another advantage of this embodiment is that after exceeding the critical impact force by separating the connection between linkage and coupling shaft not only the coupling shaft but also the housing of the bearing block are taken from the power flow, so that the housing remains in its original position on the car body , In particular, it is no longer pushed the housing of the bearing block together with the articulation in a space provided in the undercarriage of the car body space, as was the case with conventional central buffer couplings. Instead, the housing remains on the car body and takes over with regard to the coupling shaft detached from the coupling function of a "guide profile" or a "collecting element", since the coupling shaft can be supported in or on the housing and thus prevents the separated coupling shaft the track can fall down.

It is particularly preferred that the central buffer coupling according to the invention according to the latter embodiment, ie the central buffer coupling with the Elastomer spring device is designed so that the transmitted from the coupling shaft on the linkage tensile and impact forces are dampened by regenerative deformation of the rings or provided in the articulation Zug- / Stoßeinrichtung up to a festdefined size, the fixed-defined size is set to a value smaller than the response of the at least one shearing element. This ensures that the pull / push device absorbs tension and pressure up to the firmly defined size and thus absorbs and thus eliminates minor shocks, such as shocks and vibrations occurring during driving and braking. The beyond forces, such as the impact of the vehicle on an obstacle, cause the integrated shock absorber in the articulation and in particular the shearing element responds, thereby solving the connection between the linkage and the coupling shaft and the coupling shaft at least partially transferred from the articulation Power flow is taken, whereby after exhaustion of the provided in the articulation energy dissipation device, the residual energy is transferred to wagenkastenseitige energy absorption elements, such as friction elements. The advantage of this is that the greatest possible calculable energy consumption can be achieved in a predictable event sequence in an accident, since the central buffer coupling is removed from the power flow when a defined force level is exceeded, and thus allows the collision of the car bodies and the use of the carcass side energy absorption elements.

Advantageously, in the inventive central buffer coupling, which has the elastomeric spring device, it is provided that the articulation has at least one vertically extending pivot with which the housing is connected by means of the at least one shearing element and horizontally pivotally mounted on the bearing block of the car body. Here, in a preferred manner, the shearing element between the at least one pivot and the housing is provided. It would also be conceivable to connect the trunnion directly to the housing, this connection having a predetermined breaking point. In order to ensure the most stable horizontally pivotable articulation of the housing on the bearing block, a plurality of vertically extending pivot pins are provided in a preferred manner, wherein a shearing element may be provided on each pivot.

In order to achieve an elastomer spring device which is as simple as possible to realize and particularly easy to assemble, it is preferably provided that the housing of the elastomer spring device, which is hinged horizontally with the aid of the at least one shearing element on the bearing block of the car body, consists of two half-shells, which can be detachably connected to each other. As a connection, for example, bolts come into question. Of course, it is also conceivable not to use two, but a plurality of housing parts. This facilitates the installation of the rings. In addition, the rings at a certain excess on the bolts or screws with bias perpendicular to the longitudinal direction of the coupling shaft can be installed, whereby a tight fit of the rings between the coupling shaft and housing can be produced.

In a further development of the elastomeric spring device having inventive central buffer coupling is provided that the coupling shaft has at its opening facing the housing opening a collar against which on the one hand a biasing ring with its rear side and on the other hand the closest to the opening of the housing ring with its front wherein the biasing ring biases the rings in the unloaded state of the elastomeric spring means in the longitudinal direction of the coupling shaft. This ensures that the elastomeric spring device a targeted, reproducible bias voltage can be impressed in terms of magnitude and direction. Furthermore, the generation and the adjustability of the bias of the spring device is simplified.

A more accurate and finer adjustment of the bias of the elastomer spring means is achieved in a preferred manner by a type in which the generation and adjustment of the biasing force in the longitudinal direction of the coupling shaft via a pressure piece, which is fastened and supported on the housing by means of screws.

In the following the invention will be described in more detail with reference to the drawings.

Show it:

Fig. 1:

a perspective view of a known from the prior art articulation of a central buffer coupling;

Fig. 2:

the linkage of Figure 1 in a side sectional view.

3:

the linkage of Figure 1 in a plan view.

4:

a side view of an articulation of a preferred embodiment of the central buffer coupling according to the invention;

Fig. 5:

a partial sectional view of the linkage of FIG. 4;

Fig. 6:

a complete sectional view of the linkage of FIG. 4; and

Fig. 7A-F:

Representations of the articulation of the central buffer coupling according to FIG. 4 in different states.

FIG. 1 shows a perspective view of an articulation 102 used in a middle buffer coupling known from the prior art. FIG. 2 shows the articulation 102 according to FIG. 1 in a side sectional view. As shown, an elastomer spring element 110 is integrated as a pull / push device in the linkage 102. This spring element 110 is designed in such a way that tension and pressure are absorbed up to a defined size and further forces are transmitted via the bearing block 104 into the vehicle undercarriage. The linkage 102 shown in FIGS. 1 and 2 comprises the rear part of the coupling arrangement and serves to pivot the coupling shaft 101 horizontally in a pivotable manner via the bearing block 104 on the screw-on plate of the car body (not explicitly shown here).

Fig. 3 shows the known from the prior art and shown in Fig. 1 and 2 linkage 102 in a plan view. In the illustration chosen in Fig. 3, the bearing block 104 of the linkage 102 is attached to the mounting plate 117 of the car body. For this purpose, a corresponding opening 107 is provided in the mounting plate 117, through which the bearing block 104 partially protrudes. The bearing block 104 itself is attached via external Abscherelemente 108 to the base of the car body. From Fig. 3 it can be seen that the attachment of the bearing block 104 by means of the external Abscherelemente 108 can be made only from the back of the mounting plate 117. The external shearing elements 108 are designed such that they respond in the event of a crash, ie when extreme impact energies impinge, and thereby lose their function as fastening elements for the bearing block 104. In such a case, the bearing block 104 can be pushed together with the linkage 102 and the coupling shaft 101 hinged thereto in a provided in the undercarriage of the car body (not explicitly shown) space and thus at least partially taken from the transferred with the clutch assembly power flow.

As already explained, the solution known from the state of the art, in which external shearing elements 108 are provided in order, on the one hand, to fasten the bearing block 104 of the articulation 102 to the vehicle body and, on the other hand, to assume the function of shock protection, has various disadvantages, which are described below To avoid repetition only briefly be addressed. On the one hand, it has proven to be disadvantageous that a relatively large opening 107 must be provided in the mounting plate 117 of the car body in order to fasten the bearing block 104 of the linkage 102 via external shear elements 108 to the vehicle undercarriage. In addition, the bearing block 104 (or the external shear elements 108) can only be attached to the car body from the rear side of the screw plate 117. These disadvantages are of great importance, in particular with regard to a cost-effective solution for a linkage having a shock-absorbing function, since hereby the assembly of the linkage 102 on the vehicle body is extremely time-consuming and expensive.

4 shows the side view of a linkage 2 of a preferred embodiment of the central buffer coupling according to the invention. Fig. 5 shows a partial sectional view of the linkage 2 of FIG. 4, while FIG. 6 is a complete sectional view thereof.

The linkage 2 of the preferred embodiment according to the present invention comprises an elastomeric spring device 10 for damping tensile and impact forces transmitted via the coupling shaft 1 to the linkage 2. It is provided that the elastomer spring device 10 has a (not explicitly shown) coupling head open towards housing 11, in which the rear end 3 of the coupling shaft 1 projects co-axially with a radial distance from the inner peripheral surface of the housing 11. The rear end 3 of the coupling shaft 1 is connected via the housing 11 with the linkage 2. In the embodiment shown in FIGS. 4 to 6, this connection is made via vertically extending pivot pins 16, to which the housing 11 is connected by means of shearing elements 8 and hinged horizontally pivotably on the bearing block 4 of the car body.

Between the inner peripheral surface of the housing 11 prestressed spring rings 13 are provided made of an elastic material, which are aligned vertically with their center planes and arranged at a mutual distance in the longitudinal direction of the coupling shaft 1, wherein both the rear end 3 of the coupling shaft 1 and the inside of the housing 11 facing each other, circumferential annular beads 14, 15 have. These annular beads 14, 15 are designed such that the resilient rings 13 in each case at intervals between two adjacent annular beads 14, 15 opposite the rear end 3 of the coupling shaft 1 and the housing 11 are held. Characterized in that each resilient ring 13 rests directly on both the peripheral surface of the coupling shaft 1 and on the inner peripheral surface 12 of the housing 11, wherein in relation to tensile and impact forces unloaded state of the elastomeric spring device 10, the annular beads 14 of the coupling shaft 1 with the associated annular beads 15 of the housing 11 are aligned, that on the one hand a gimbal movement of the coupling shaft 1 is made possible, and that on the other hand to a defined size tensile and compressive forces can be absorbed and absorbed.

As already mentioned, the housing 11 of the elastomeric spring device 10 is connected to the articulation 2 with the aid of at least one shearing element 8. In the preferred embodiment according to FIGS. 4 to 6, the linkage 2 has an upper and a lower vertical pivot pin 16, on which the housing 11 is connected in each case by means of a shear element 8 and pivoted horizontally on the bearing block 4 of the carriage body. In a preferred manner, it is provided that the response force of the shearing elements 8 is greater than the amount of force that the elastomer spring device 10 can transmit by regenerative deformation of the resilient rings 13.

The housing 11 of the elastomeric spring device 10 is designed to be split in a preferred manner in order to ensure a particularly simple assembly of the spring device 10. Furthermore, this allows the bias of the elastomeric spring means 10 in the longitudinal direction of the coupling shaft 1 are particularly easily adjusted. Conceivable here would also be that the rear end 3 of the coupling shaft 1 has a (not explicitly shown) collar against the one hand, a (not shown) biasing ring with its rear side and on the other hand to the opening of the housing 11 closest resilient ring 13 with the front is applied, wherein the biasing ring biases the resilient rings 13 in the unloaded state of the elastomeric spring device 10 in the longitudinal direction of the coupling shaft 1.

The shock absorber 5, 8 of the articulation 2 shown in Figures 4 to 6 consists of an opening provided in the bearing block 4 opening 5 and the Abscherelementen already mentioned 8 and is designed such that when exceeding a transmitted via the coupling shaft 1 to the linkage 2, definable critical impact force, the connection between articulation 2 and coupling shaft 1 solved and the coupling shaft 1 at least partially transferred from the articulation 2 Power flow is taken. On the one hand, this is achieved in that the housing 11 is connected to the articulation 2 with the aid of the at least one shearing element 8, and on the other hand, that the opening 5 designed for the central buffer coupling is provided in the bearing block 4, through which the critical impact force and beyond are exceeded Response of shear elements 8 of the coupling shaft 1 is at least partially pressed and thus removed from the power flow.

The solution according to the invention, in which the shock absorber 5, 8 is contained in the articulation 2, makes it possible that the linkage 2 can be mounted with the bearing block 4 directly to the mounting plate 6 of the car body, without provided in this a corresponding opening for mounting must be, and without the bearing block 4 must be secured via external shear elements from the back of the mounting plate 6 of the car body ago. However, as shown in Fig. 4 to 6, in addition to the opening provided in the bearing block 4 5 also in the Anschraubplatte 6 an opening 7 may be provided, in an advantageous manner both Öffnurigen 5, 7 correspond to each other. In the event of a crash, after the shearing elements 8 have addressed and lost their fastening function, in such a structure the coupling shaft 1 would first be pushed through the opening 5 provided in the bearing block 4 and then through the opening 7 provided in the mounting plate 6 and thus be removed from the force flow , It is also conceivable, instead of an additional opening 7 in the Anschraubplatte 6, the material of the Anschraubplatte perform 6 accordingly, so that the coupling shaft 1 can be pushed after response of the shear elements 8 without too much resistance in a space provided behind the mounting plate 6 space. Of course, but it is also conceivable that the bearing block 4 is initially formed without opening 5, and that at the intended position of the opening 5, the material of the bearing block 4 is designed or designed accordingly that when exceeding the critical impact force a slight puncture of the coupling rod is possible.

In contrast to the linkages known from the prior art, in which a shock absorber is provided via external shearing elements, and in which the entire articulation shears off with the associated bearing block when the critical impact force is exceeded and is removed from the force flow, the solution according to the invention leads to this in that in the event of a crash only the coupling shaft 1 leaves without articulation 2 and without bearing block 4 and is removed from the power flow.

In the preferred embodiment shown in Figs. 4 to 6, a guide 9 is further provided to exceed the critical impact force and response of the shearing elements 8, the movement of the coupling shaft 1 with the housing 11 and the elastomeric spring element 10 provided therein by the Opening 5 of the bearing block 4 and then through the opening 7 of the support plate 6 to lead. This guide 9 thus allows a very predictable event sequence.

FIGS. 7A to 7F show the linkage according to FIGS. 4 to 6 in different states. Fig. 7A shows the linkage in an unloaded state. In this state, the annular ridges of the coupling shaft are aligned with the associated annular ridges of the housing. Fig. 7B shows a loaded with respect to tensile and impact forces state of the elastomeric spring device. As shown, the coupling shaft with the elastomeric spring means provided at its end is slightly displaced in the direction of the carriage body as compared with the state of FIG. 7A. However, the impact force acting on the coupling shaft in the state shown in Fig. 7B is still below the critical impact force at which the shearing elements are responsive. Fig. 7C shows a loaded state of the linkage after the shock absorber has responded, in which the shearing elements have already been activated and have lost their function as fastening means, so that the coupling shaft (in the figures, only the rear part is shown) together with the housing, in which the elastomer spring device is contained, is pressed from the power flow. Figures 7D to 7F show the further movement of the rear end of the coupling shaft after the response of the shock absorber, the coupling shaft in its course pushed completely out of the coupling plane in a space provided behind the mounting plate of the car body (not explicitly shown) space and thus from the power flow is finally taken until the state shown in Fig. 7F is reached.

It should be noted that in Fig. 4 to 7, the clutch assembly according to the invention has been explained with reference to a central buffer coupling having an elastomeric spring device. However, the idea according to the invention, namely to integrate a shock absorber in the articulation, is also possible with other coupling arrangements, for example an eye bolt articulation.

LIST OF REFERENCE NUMBERS

1

coupling shaft

2

linkage

3

Rear end of the coupling shaft

4

bearing block

5

Opening in the bearing block

6

screwing

7

Opening in the carrier plate

8th

shearing

9

guide

10

Elastomeric spring mechanism

11

casing

11A

Half shells of the housing

13

spring washer

14, 15

torus

16

pivot

101

Coupling shaft (prior art)

102

Linkage (prior art)

104

Bearing block (prior art)

107

Opening in the mounting plate (prior art)

108

external shearing element (prior art)

110

Elastomer spring device (prior art)

117

Screw-on plate (prior art)

Claims (14)

Central buffer coupling for rail vehicles with a coupling shaft (1) and a linkage (2) having a bearing block (4), the rear end (3) of the coupling shaft (1) being connected to the linkage (2) and via the bearing block (4) of the linkage (2) is pivoted horizontally on the car body of the rail vehicle,
characterized in that
in the articulation (2) a shock protection (5, 8) is provided, wherein the shock absorber (5, 8) is designed such that when exceeding a on the coupling shaft (1) on the linkage (2) transmitted, definable critical impact force the Connection between articulation (2) and coupling shaft (1) dissolved and the coupling shaft (1) is at least partially taken from the power flow transmitted to the articulation (2). Central buffer coupling according to claim 1,
characterized in that
the shock absorber (5, 8) has an opening (5) formed in the bearing block (4) towards the central buffer coupling, through which the coupling shaft (1) is at least partially pressed and thus removed from the force flow when the critical impact force is exceeded. Central buffer coupling according to claim 2, wherein the articulation (2) via the bearing block (4) on a screw-on (6) of the car body is mounted, wherein the screw-on (6) with one in the bearing block (4) provided opening (5) corresponding opening ( 7). Central buffer coupling according to one of the preceding claims,
characterized in that
the linkage (2) further comprises a guide (9) to at least partially guide the movement of the coupling shaft (1) from the power flow transmitted to the linkage (2) when the critical impact force is exceeded. Central buffer coupling according to claim 4 and claim 2 or 3,
characterized in that
the guide (9) has a run-on slope in the direction of the bearing block (4) provided opening (5) which is designed such that when exceeding the critical impact force of the coupling shaft (1) through the opening (5) in the bearing block (4) pressed becomes. Central buffer coupling according to one of the preceding claims,
characterized in that
the shock absorber (5, 8) has at least one shearing element (8), with the aid of which the coupling shank (1) is connected to the articulation (2), wherein the shearing element (8) is designed such that it is in one of the coupling shank ( 1) sheared on the articulation (2) transmitted critical impact force, and thus the connection between the coupling shaft (1) and linkage (2) is released. Central buffer coupling according to claim 6,
characterized in that
the at least one shearing element (8) has at least one predetermined breaking point, which breaks at a definable critical impact force, so that thus the connection between the coupling shaft (1) and linkage (2) is released. Central buffer coupling according to claim 6 or 7, wherein the articulation (2) is an eye bolt articulation, and wherein the shear element (8) is the bolt of the eye bolt articulation, and wherein the coupling shaft (1) with the eye of the eye bolt articulation when exceeded the specified critical impact force is taken from the force flow transmitted to the linkage. Central buffer coupling according to claim 6 or 7, further comprising an elastomeric spring means (10) for damping of the coupling shaft (1) on the linkage (2) transmitted tensile and impact forces, wherein the elastomeric spring means (10) towards the coupling head open housing (11) into which the rear end (3) of the coupling shaft (1) protrudes coaxially with a radial distance from the inner peripheral surface of the housing (11), wherein the rear end (3) of the coupling shaft (1) via the housing (11) is connected to the linkage (2), wherein between the inner peripheral surface of the housing (11) prestressed resilient rings (13) are provided made of an elastic material which is aligned with their center planes vertically and at a mutual distance in the longitudinal direction of the coupling shaft (1 ) are arranged one behind the other, wherein both the rear end (3) of the coupling shaft (1) and the inside of the housing (11) facing each other encircling Ring beads (14, 15), and wherein the resilient rings (13) are each held in spaces between two adjacent annular beads (14, 15) opposite the rear end (3) of the coupling shaft (1) and the housing (11), wherein each ring (13) abuts directly on both the peripheral surface of the coupling barrel (1) and the inner circumferential surface of the housing (11), and wherein in the unloaded state of the elastomeric spring means (10) with respect to tensile and impact forces, the annular beads (14 ) of the coupling shaft (1) with the associated annular beads (15) of the housing (11) are aligned,
characterized in that
the housing (11) is connected to the articulation (2) with the aid of the at least one shearing element (8), so that when the definable critical impact force is exceeded, the coupling shank (1) with the housing (11) and the elastomer spring device (8) provided therein ( 10) is taken from the on the linkage (2) transmitted power flow. Central buffer coupling according to claim 9, wherein the elastomer spring device (10) attenuates the tensile and impact forces transmitted via the coupling shaft (1) to the linkage (2) by regenerative deformation of the rings (13) to a defined size, and wherein the firmly defined size is set to a value smaller than the response of the at least one shear element (8). Central buffer coupling according to claim 9 or 10,
characterized in that
the linkage (2) has at least one vertically extending pivot pin (16) to which the housing (11) is connected by means of the at least one shearing element (8) and hinged horizontally to the bearing block (4) of the car body. Central buffer coupling according to one of claims 9, 10 or 11,
characterized in that
the housing (11) is formed divided and consists of detachably connected to each other half-shells (11a). Central buffer coupling according to one of claims 9 to 12,
characterized in that
the rear end (3) of the coupling shaft (1) has a collar against which on the one hand a biasing ring with its rear side and on the other hand to the opening of the housing (11) nearest resilient ring (13) rests with the front, wherein the biasing ring, the resilient Rings (13) in the unloaded state of the elastomeric spring device (10) in the longitudinal direction of the coupling shaft (1) biases. Central buffer coupling according to claim 13, wherein the housing (11) is formed divided and consists of detachably interconnected half shells (11a), and wherein the bias of the elastomer spring means (10) in the longitudinal direction of Coupling shaft (1) by connecting the half shells (11 a) of the split housing (11) takes place.

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