EP1662046A1 - Railway pad - Google Patents

Abstract

A railway has rails (10) directly attached to tie-bars ('sleepers') by a clamp fittings (16, 18) to an elastic interface (12). The elastic interface outer margin (48) has higher stiffness in limited outer areas (34, 36).

Description

The invention relates to a support for a mounted on a base such as threshold over at least one holder such as clamp rail, which is supported with her foot on an elastic intermediate layer, wherein the rail is mounted harder at least in its outer rail foot edge region than in the central region. This is in particular a direct attachment of a rail on a base such as concrete sleeper.

A corresponding support is shown in GB-A-2 051 187. The intermediate layer to be designated as a pad has, in its respective longitudinal edge region, a vulcanised edge strip whose spring stiffness is greater than that of the pad per se. In this case, the rail side extending top of the edge strip is offset from the top of the pad. By forming the pad in this way it is achieved that excessive tilting of the rail supported on the pad is prevented, namely when the rail foot rests on one of the edge strips.

The fact that the pad does not extend over the entire underside of the rail foot, but ends at a distance to the Längsseitenrändem, in the periphery and depending on the effective width of the edge strips, the elastic behavior of the pad is in itself influenced and consequently are in the track Pads having corresponding edge strips to dimension differently than those that extend over the entire surface of the rail foot.

Furthermore, it is disadvantageous that the edge strips run up to the end faces of the pad, so that when passing through the rail in the transition region due to the hardness of the edge strips shock loads can occur.

DE-U-296 08 777 discloses a highly elastic rail pad comprising a hard rim and a soft and thicker central portion.

A rail pad according to GB-A-2 152 119 is softer in the middle region than in the edge region in order to prevent unwanted tilting of a rail supported on the intermediate layer.

The subject of DE-B-2 210 741 is a rubber-elastic intermediate plate for rail fasteners. On the intermediate plate a rib plate is fixed, on which in turn a rail is arranged. The intermediate plate has channels in the longitudinal edge region in order to adjust the rigidity such that the edge regions are harder than the intermediate region. Viewed in the longitudinal direction of the rail, the longitudinal edge regions of the intermediate layer have the same rigidity.

The present invention has the object, a support of the type mentioned in such a way that it is ensured that an undesirable or inadmissible tilting of the rail stops acting on this horizontal forces without the elastic behavior of the intermediate layer must be substantially changed.

According to the invention, the object is essentially achieved by the fact that the intermediate layer has a higher stiffness in its at least along the outer rail foot edge region and below this extension in a limited first region than in the remaining rail foot longitudinal edge region extending second region and / or at least in the outer rail foot longitudinal edge region has a recess in which a stop extends with a rigidity which is greater than in the remaining rail foot longitudinal edge region extending second region. Projection of the rail foot along the vertical axis of the rail cuts, at least in sections, the stop or the first area. The first area or the stop and the recess receiving this extend at a distance from the transverse edge of the intermediate layer.

In the related construction, the intermediate layer has the required rigidity over substantially all of its surface to elastically support the rail. In this case, due to the higher stiffness having first area or stopper liners are used, the depression in the range between 20 kN / mm - 25 kN / mm, ie an elasticity that is considerably larger than conventional liners, which at 50 kN / mm - 60 kN / mm. Regardless of the soft bearing of the rail is ensured that an inadmissible tilting and thus an inadmissible track width extension is omitted. If the rail should be tilted such that an impermissible change in track width could occur, then the rail rests on the second area or the stop, with the result that the pivot point of the rail is from the middle area of the rail foot to the contact area between rail foot and first area of the intermediate layer or stop of the attack. Upon further horizontal force, the tilt angle is then reduced and thus prevented an inadmissible track width change.

Since the first area or the stop extends at a distance from the respective edge extending transversely to the rail longitudinal direction, no change in the elasticity occurs in the end edge area of the intermediate layer so that a uniform "unrolling" of the rail takes place when passing through it.

The inventive construction of the intermediate layer, a displacement of the pivot point of the rail from its central region to the edge region, so that there is a Kippwinkelreduzierung with further force application.

Due to the teachings of the invention, the rail can be stored over its entire foot surface softer than in the prior art, without the risk of unacceptable track width change arises.

In particular, it is provided that the fulcrum displacement is realized by the stop, which additionally provides a hiking protection against displacement of the intermediate layer in the rail longitudinal direction. In this case, the stop of the recording of the holder like tensioning clamp emanate, so that a trouble-free mounting is given. Of the Stop can emanate, for example, from an angled guide plate z. B. can accommodate a tension clamp with a geometry of M or W. The fence can also be based on a Pandrol® clamp insert to give an example of how the insert can be mounted.

The stiffness course of the intermediate layer between edge regions and middle region can be designed in the usual way relative to one another, that is to say that there is less rigidity in the rail foot center region than in the edge region. Of course, it is also possible to design the intermediate layer over its entire surface, with the exception of the second region or the recess, in such a way that the same rigidity results.

In order to not or not substantially change the elastic behavior of the intermediate layer through the second region or the stop, a development of the invention provides that the first region or the stop has a width extension B to the rail longitudinal direction which is ≤ 10% of the width of the rail Rail foot is. In particular, the width extension of the first area or the stop should amount to ≤ 10 mm.

The second area or stop extends with its surface facing the rail foot back to the rail side extending surface of the intermediate layer, wherein at a depression of the elastic intermediate layer (total springing) of about 10% - 15% compared to the unloaded rail, the rail foot base with the second area or interacts with the attack.

In particular, in the case of a vertical force component Fv acting on the rail, from 10 kN to 20 kN, the first area or the stop should interact with the underside of the rail foot. This ensures that an impermissible tilting of the rail can not occur.

The first region or the stop should have an extension L _A in the longitudinal direction of the rail with 30 mm ≦ L _A ≦ 100 mm, wherein the length L _A to the length extension L _{z of} the intermediate layer in the rail longitudinal direction should behave like 2 ≤ L _z : L _A ≤7.

The second region or stop should preferably have a stiffness of 80 kN / mm to 400 kN / mm. Of course, the stiffness can also be greater than 400 kN / mm.

If, in principle, it is only necessary for the second region or stop to be formed or arranged in the outer rail longitudinal edge region of the intermediate layer, it is of course possible for a corresponding second region to be formed on both the outer and inner rail foot longitudinal edge region or a stopper arranged.

Further details, advantages and features of the invention will become apparent not only from the claims, the features to be taken from them-alone and / or in combination-but also from the following description of a preferred embodiment to be taken from the drawing.

Fig. 1

eine Prinzipdarstellung einer auf einer Schwelle angeordneten Schiene im Querschnitt,

Fig. 2

eine Draufsicht einer Zwischenlage,

Fig. 3

einen Ausschnitt einer vergrößerter Darstellung der Zwischenlage gemäß Fig. 2 und

Fig. 4

ein Diagramm.

Show it:

Fig. 1

a schematic representation of a arranged on a threshold rail in cross section,

Fig. 2

a top view of an intermediate layer,

Fig. 3

a section of an enlarged view of the intermediate layer according to FIG. 2 and

Fig. 4

a diagram.

In order to allow a sufficient mobility of a rail in the vertical direction in the track superstructure and to dampen a sound transmission, elastic intermediate layers are arranged between a base and a rail. To avoid inadmissible tilting movements, the rails are usually mounted on ribbed plates, which lead to an apparent Fußverbreitenvergroßerung. On the other hand, if a direct attachment is made to a support such as a threshold, the rail must be supported on a relatively stiff intermediate layer to prevent undue tilting movement and thus prevent unacceptable change in track width. As a result, the elastic behavior and the sound attenuation deteriorate.

According to the invention, a direct attachment of a rail 10 is provided, which is mounted relatively soft, without disadvantages in terms of track stability or sound absorption must be taken into account. The rail 10 is supported via an elastic intermediate layer 12 on a base such as concrete sleeper 14 and secured by tension clamps 16, 18. The clamps 16, 18 are stretched by screws 20, 22, which in turn can be screwed directly into the concrete sleeper 14. For this purpose, 14 corresponding dowels are cast in the concrete sleeper. Other types of brackets for the rail 10 are also possible. Thus, angled guide plates can be provided. Other receptacles of tension clamps, as known in the art, are also possible.

The recess 30, 32 and thus the stop 34, 36 are spaced from the transverse to the rail longitudinal edge regions arranged, as the plan view of FIG. 2 illustrates.

Independently of this, the rail 10 is supported via its rail foot 24 on the elastic intermediate layer 12 over the entire rail foot width. The intermediate layer 12 may also extend laterally over the rail foot edge. Independently of this, the effective surface of the intermediate layer 12 extends directly below the rail foot 24, ie within its vertical projection extending in the direction of the concrete sleeper 14.

In order to design the intermediate layer 12 sufficiently soft, without the risk of inadmissible tilting of the rail 10, the invention provides that in the respective longitudinal edge region 26, 28 of the intermediate layer 12, a recess 30, 32 is provided, within which a stop 34, 36 extends whose rigidity is greater than that of the intermediate layer 12. The stop 34, 36 can emanate from the holder or recording of the tensioning clamp 16, 18, to ensure a clear positioning. Also, a direct fastening on the concrete sleeper 14 can take place. A lateral connection with the elastic intermediate layer 12, for example by vulcanization is also possible.

Regardless of this, however, the top 38, 40 of the stop 34, 36, so its the bottom of the rail foot facing surface, set back to the top 42 of the liner 12. This conditionally occurs at normal force inputs into the rail 10, ie their vertical and horizontal components Fv or F _H exclusively a support on the elastic intermediate layer 12, whereby the desired elastic support and depression is made possible. If impermissibly high forces occur, which, in particular due to the horizontal components F ₁₁ , could lead to a tilting of the rail 10 to such an extent that an unacceptable change in the track width occurs, the stop 34 or 36 interacts with the rail foot underside, with the consequence that a further tilting occurs is prevented. By resting the bottom rail foot on the stop 34 and 36, a pivot point displacement of the rail 10 of the central region (reference numeral 44) in the edge region 46, in which the rail foot 24 rests on the stop 34 and 36, respectively. As a result, the tilt angle α is reduced as the force is introduced further, as illustrated by FIGS. 3 and 4.

Thus, in Fig. 3, the intermediate layer 12 is shown in section. In the outer longitudinal edge region of the rail foot 24, the intermediate layer 12 has the recess 32 in which the stop 34 is set back to the surface. In the case of normal introduction of force via the rail 10, this can be tilted up to a maximum critical angle α _GR without the stop 34 acting. Upon further introduction of force, the rail foot 24 lies with its outer edge region 48 on the stop 34, ie its Top 38 on. In this case, the otherwise running in the middle region of the rail 10 fulcrum 44 moves to the support point 46 of the rail 24, abruptly, so that upon further introduction of force, the rail 10 is tilted towards the track center, thus reducing the angle a.

This is also clear from the diagram of FIG. 4. Thus, the course of the tilt angle α at a force as a function of the elasticity of the intermediate layer 12, for example in the range between 10 kN - 20 kN on a kink, which is due to the resting of the rail 24 on the stop 34. Accordingly, an abrupt change in the track width to smaller values takes place. This is illustrated by the curve marked X, which represents the track width change as a function of the introduced force. In the further curve marked V, a break point is likewise determined when the rail foot 24 rests on the stop 34. V represents the depression of the rail as a function of the vertically introduced force. The break point, which reflects the sudden increase in stiffness, occurs when the rail foot 24 rests on the stop 34 or interacts with it.

4, the stop 34, 36 or a corresponding harder region of the elastic intermediate layer 12 in Schienenfußlängsrandbereich completely below the edge portion 48 of the rail 24 is arranged - ie the projection of the stopper 34, 36 extends completely in the direction of the vertical axis of the rail within the edge region 48, the invention will of course not be abandoned even if the stop or the corresponding harder region of the intermediate layer runs laterally outside the rail foot.

According to the invention, a direct fastening to the rail 10 directly on the support such as concrete sleeper 14 is proposed, in which it is ensured that the rail 10 is tiltable upon introduction of horizontal forces to an extent without an inadmissible track width extension takes place. At the same time, the rail 10 can be stored soft, since due to the stop 34, 36 or a trained accordingly Area is ensured in the intermediate layer 12 that at high shear forces a safe driving through the rail 10 is possible.

In this case, the stop 34, 36 or a correspondingly formed first region I of the intermediate layer 12 has a higher rigidity than adjacent longitudinal edge region 26, 28, which may be referred to as second region II.

If, in the exemplary embodiments, a stop is shown in each rail longitudinal edge region, it is basically only necessary that a corresponding stop be provided in the region of the outer longitudinal edge region.

Instead of the stop 34 or 36 may be formed in the intermediate layer 12 also connected to the intermediate layer 12 region of higher rigidity, the surface is also spaced from the plane spanned by the intermediate layer 12 level.

If, in the exemplary embodiment, the intermediate layer 12 lies directly on the threshold 14, such as concrete sleeper or slab (slab track), a further intermediate layer may run between the intermediate layer 12 and the threshold 14.

Also, the intermediate layer 12 may extend laterally beyond the rail foot edge. It is essential only that the stop 34, 36 in the rail foot longitudinal edge region and extending below it.

The stop 34, 36 or a corresponding area in the intermediate layer 12 has an extension B transverse to the rail longitudinal direction, in the range between 10% and 15% of the total width of the intermediate layer 12 in the immediate area below the rail foot 24, so the width of the rail foot 24 is located. Regardless, the width B of the stopper 34 should be equal to or less than 10 mm.

The length L of the stop should be in about 20% to 40% of the total length of the intermediate layer in the rail longitudinal direction, but preferably not more than 30 mm to 100 mm.

If the intermediate layer 12 in particular has a stiffness between 20 kN / mm - 25 kN / mm, the rigidity of the stop 34, 36 or of the correspondingly formed region of the intermediate layer 12 should amount to between 80 kN / mm and 400 kN / mm or more.

The stop 34, 36 should preferably start from a holder or receptacle of the tensioning clamp 16, 18, whose construction corresponds to that of the prior art. As a result, a clear position positioning of the stopper 34, 36 is ensured, at the same time a hiking protection for the intermediate layer 12 is given.

The fact that the stopper 34, 36 is very small in comparison to the surface dimension of the intermediate layer 12, there is the advantage that the intermediate layer 12 can also be used in bases in which corresponding stops are not provided. Thus, corresponding intermediate layers can be used universally.

Claims (11)

Support for a rail (10) fastened to a support (14), such as a threshold, via at least one support, such as a spacer clamp (16, 18), which is supported by its foot (24) on an elastic intermediate layer (12) Direct fastening of a rail to a concrete sleeper, wherein the rail is mounted harder at least in its outer rail foot longitudinal edge region (48) than in the middle region,
characterized,
that the intermediate layer (12) in the rail longitudinal direction viewed in its along at least the outer Schienenfußlängsrandbereichs (48) and below this extending extension in a limited first area (I) has a higher stiffness than extending the remaining Schienenfußlängsrandbereich second region (II) and / or the at least outer rail foot longitudinal edge region has a recess (30, 32) in which a stop (34, 36) extends with a rigidity which is greater than the remaining second region (II) extending in the rail foot longitudinal edge region. Support according to claim 1,
characterized,
in that the rigidity in the second region (II) of the rail foot longitudinal base region (48) has the same or essentially the same rigidity as the intermediate layer (12) in the middle region between the rail spring longitudinal edge regions. Support according to claim 1,
characterized,
that the first region (I) and / or the stop (34, 36) has a width extent B transverse to the longitudinal direction of the rail (10) ≤ 10% of the width of the rail foot (24), in particular the width extent B of the first region (I) and / or the stop (34, 36) amounts to B ≤ 10 mm. Support according to at least one of the preceding claims,
characterized,
that at a depression V of the elastic intermediate layer (12) of 10% - 15% compared to the unloaded rail (10) of the rail foot (24) interacts with its underside with the first region (I) or the stop (34, 36) in particular that, in the case of a vertical force component F _v acting on the rail (10) in the range between 10 kN / mm and 20 kN / mm, the rail foot (24) is connected to the first area (I) and / or the stop (34, 36) interacts. Support according to at least one of the preceding claims,
characterized,
that the first region (I) or the stop (34, 36) has an extent L in the longitudinal direction of the rail (10) with 30 mm ≤ L ≤ 100 mm has and / or that the length L of the first region (I) or, of the abutment (34, 36) behaves like the length L _{z of} the intermediate layer (12) as 2 ≦ L _z / L ≦ 7. Support according to at least one of the preceding claims,
characterized,
in that the first region (I) and / or the abutment (34, 36), with its free surface (38, 40) extending on the rail side, is set back to the surface (42) of the intermediate layer (12), Support according to at least one of the preceding claims,
characterized,
in that the first region (I) and / or the stop (34, 36) has a stiffness S of 80 kN / mm ≤ S ≤ 400 kN / mm. Support according to at least one of the preceding claims,
characterized,
that the stop (34, 36) of a receptacle of the holder for the rail (10), such as the tension clamp (16, 18), in particular the stop of an angle guide plate for a W or M-shaped clamp or a holder for a Pandrol ® terminal goes out. Support according to at least one of the preceding claims,
characterized,
in that the first region (I) and / or the stop (34, 36) runs both in the outer and in the inner rail foot longitudinal edge region (48). Support according to at least one of the preceding claims,
characterized,
that the stop (34, 36) connected with the intermediate layer (12) such as vulcanized. Support according to at least one of the preceding claims,
characterized,
in that the first region (I) or the stop (34, 36) extends at a distance from the respective edge region of the intermediate layer (12) running transversely to the rail longitudinal direction.

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