EP4283040A1 - Assembly for retaining a rail - Google Patents

Abstract

The invention relates to an arrangement for holding down a rail (14) having a rail base (20), such as a stock rail, comprising a base (18), such as a sliding chair, tongue roller or wheel control plate, a plate element (16) detachably arranged on the base, such as Sliding chair or counter bearing, a spring element (10) holding the plate element on the base and a first and a second abutment for tensioning the spring element. In order to enable the rail to be held down using structurally simple measures and at the same time to achieve ease of maintenance and servicing, it is provided that the first abutment is a section (78) of the plate element (16) or extends from it, which runs in the area away from the rail foot, that the second abutment is an eccentric element (12) which preferably extends in the longitudinal direction of the rail (14) and is rotatably arranged in a receptacle (46) extending from the base (18) between the rail foot (20) and the first abutment, and that the spring element is designed to be supported on the rail base (20).

Description

The invention relates to an arrangement for holding down a rail having a rail base, such as a stock rail, comprising a base, such as a sliding chair, tongue roller or wheel control plate, a plate element releasably arranged on the base, such as a sliding chair or counter bearing, and the plate element on the base holding spring element and a first and a second abutment for tensioning the spring element.

In order to fix a stock rail, it is known that a sliding chair is supported on the rail foot to hold it down, which is braced against a base, such as a sliding chair or tongue roller plate, by means of a spring element. Alternatively, the holding down can be done using springs themselves. The spring element is tensioned by means of a sliding chair, which is integrally formed with a base. The sliding chair and the sliding chair or ribbed plate are therefore designed to be monolithic. A corresponding solution is this DE 22 59 683 A1 refer to.

After DE 103 38 421 A1 A sliding chair is braced via a spring element with a sliding chair or ribbed plate in order to hold down a stock rail by means of the sliding chair. For this purpose, the spring element is supported in a channel-shaped receptacle on the rail foot side of the sliding chair and on an eccentric bolt away from the foot. The sliding chair itself is detachably arranged on the sliding chair or rib plate.

In order to hold down a stock rail by means of a sliding chair detachably arranged on a sliding chair plate, according to the EP 0 778 372 A1 a rod-shaped eccentric spring element is provided, which is supported on the one hand on an abutment formed on the sliding chair and on the other hand in receptacles that extend from the sliding chair or ribbed plate.

If the stock rails are held down by means of the sliding chair, the wheel force is transferred to the stock rail base via the sliding chair, so that stock rail breaks can occur due to the concentration of stress under the sliding chair.

The present invention is based on the object of developing an arrangement of the type mentioned in such a way that the rail can be held down using structurally simple measures, while at the same time being easy to maintain and service. It should be possible to tension the spring safely using simple measures.

To solve one or more of these aspects, it is essentially proposed that the first abutment is a section of the plate element or extends from it, which runs in the area remote from the rail foot, that the second abutment is an eccentric element which preferably extends in the longitudinal direction of the rail and which is in a between the rail foot and the first abutment and extending from the base is rotatably arranged, and that the spring element is designed to support on the rail foot, as a third abutment.

The first and third abutments could also be referred to as first and second supports, between which the abutment formed by the eccentric element runs.

According to the invention, an arrangement for holding down a rail, in particular a stock rail, is proposed, in which the plate element, such as a sliding chair or counter bearing, in particular a sliding chair, does not hold down the rail foot, i.e. runs at a distance from it, but can extend beyond its edge, but rather a spring element , which is tensioned by means of an eccentric element in order to hold down the rail base and to hold the plate element on the base.

The plate element, which is detachably supported on the base, and the rail are clamped depending on the position of the eccentric element and are thus held down.

In particular, it is provided that the spring element encompasses the first abutment formed in the plate element or extending from it in such a way that displacement of the plate element is no longer possible. This is particularly important it is provided that a contact area of the first abutment has a cylindrical section geometry and that the spring element rests with a geometrically adapted end area on the first abutment and surrounds it in areas. This ensures, among other things, that at least in the tensioned state of the spring element it cannot be displaced in its longitudinal direction.

Preferably, the eccentric element is a rod-shaped element which has an eccentric geometry in cross section in the contact area with the spring element such that in a first position of the eccentric element the spring element can be positioned without tension and in a second position of the eccentric element the spring element is tensioned in such a way that both the rail foot and the plate element and the spring element are held down.

In the contact area with the spring element, the eccentric element should have a circular segment or circular segment-shaped geometry in section, whereby the distance of the contact area from the base is changed depending on the rotational position of the eccentric element and thus the spring element can be tensioned or relaxed.

It is preferably provided that the receptacle has two bearing elements through which the eccentric element extends in sections into recesses in the plate element.

The bearing elements have through openings through which the eccentric element passes, which in turn also penetrates sections of the plate element, thereby preventing the plate element from tipping.

Preferably, the spring element extends in the central region of the plate element and in its longitudinal direction.

The plate element should have a longitudinal recess that extends from the first abutment to the end region facing the rail and is delimited by side walls. In order to create a positive connection between the plate element and the base (anti-tip protection), the side walls and the bearing elements are of the Eccentric element penetrates. At the same time, the eccentric element is easily accessible for operation on the outside of the plate element.

The bearing elements themselves should be partially surrounded by the side legs and connected via a particularly plate-shaped leg extending above the eccentric element.

In other words, it is preferably provided that the bearing elements are side legs of the receptacle, which has a U-shape in section, the cross leg of which extends above the eccentric element.

The eccentric element should have an actuating head, such as a polygonal head, in particular a square head, at least in one of its ends in order to enable problem-free rotation of the eccentric element and thus tensioning and relaxing of the spring element. No special tools are required. Rather, an open-end wrench can be used, for example.

The spring element that should be mentioned in particular is a leaf spring, the largest cross section of which runs like an eccentric bolt in the contact area with the eccentric element. In the relaxed state, the top side, i.e. the surface facing the eccentric element, should have a concave shape and a convex shape on the underside, with the radius of curvature of the convex shape being smaller than that of the concave shape in the contact area.

The sections of the eccentric element, which are rotatably arranged in the bearing elements, have a circular geometry in section.

Further details, advantages and features of the invention result not only from the claims, the features to be found therefrom - individually and/or in combination - but also from the following description of the exemplary embodiments which can be found in the drawing.

Fig. 1

eine erste Ausführungsfonn einer Anordnung zum Niederhalten einer Schiene in Explosionsdarstellung,

Fig. 2

eine zweite Ausführungsform einer entsprechenden Anordnung,

Fig. 3

eine Schnittdarstellung einer Anordnung zum Niederhalten einer Schiene mit entspanntem Federelement und

Fig. 4

die Anordnung gemäß Fig. 3 mit gespanntem Federelement.

Show it:

Fig. 1

a first embodiment of an arrangement for holding down a rail in an exploded view,

Fig. 2

a second embodiment of a corresponding arrangement,

Fig. 3

a sectional view of an arrangement for holding down a rail with a relaxed spring element and

Fig. 4

according to the order Fig. 3 with a tensioned spring element.

Using the figures, the teaching according to the invention for fastening a rail to a base is explained using a stock rail, which is first secured via a spring element and then via a sliding chair, which in turn can be based on a sliding chair or tongue roller plate. However, this does not limit the fundamentals of the teaching according to the invention. Rather, this can be used anywhere to fasten a rail, especially in the area of a frog tip, whereby a counter bearing can also be used instead of a sliding chair.

In the figures that explain the invention purely by way of example, basically the same elements are provided with the same reference numerals.

The characteristic feature of the invention is the tensioning of a spring element 10 by means of an eccentric element 12, whereby both a stock rail 14 and a sliding chair 16 are held down on a base 18 (rib plate/sliding chair plate), as well as the spring itself.

The stock rail 14 is supported on the base 18 via an elastic intermediate layer 19, which is also referred to below as a sliding chair or ribbed plate. To avoid uncontrolled adjustment, the foot 20 of the stock rail 14 is perpendicular to its longitudinal direction via ribs 22, 24, 26 extending from the base 18 secured, with a holder of a rail fastening such as a tension clamp 28 or clamping plate being fixed between the ribs 24, 26 in a known manner. In the drawing, the clamping clamp 28 is tensioned as a fastening means by means of a clamping screw 30 in order to form the external fastening for the stock rail 14. For this purpose, in the exemplary embodiment, a section of the tension clamp 28 is supported on the left section of the rail base 20 in the drawing.

The internal fastening of the stock rail 14 is carried out by supporting the spring element 10, which can be referred to as a leaf spring, which is supported with its edge region 32 on the left in the drawing on the right section of the rail foot 20.

The base 18 can be according to the embodiment of Fig. 1 can be fastened directly to a concrete sleeper, wooden sleeper, artificial wood sleeper or to a solid road surface by means of screws 34, 36, with disc springs 38, 40 being able to be provided between the respective screw head and the surface of the base.

A tongue rail 42, which is adjusted on the surface of the sliding chair 16, is adjusted to the stock rail 14.

The sliding chair 16 is a component manufactured independently of the base 18 and can be manufactured, for example, by forging or casting or milling. If the sliding chair 16 is a cast component, cast iron with spheroidal graphite or cast steel should be used.

The same manufacturing processes and materials should also be used for the sliding chair plate 18

Like a comparison of the Fig. 1 and 2 on the one hand and the Fig. 3 and 4 On the other hand, clarified, the sliding chair 16 has a recess 44 running in its longitudinal direction and in particular in the central region, in which the spring element 10 extends. In the front area 46 of the sliding chair, the recess 44 is covered to form a closed sliding surface for the tongue rail 42.

The recess 44 is delimited by side walls 48, 50, between which the leaf spring 10 runs. Approximately in the middle area between the back and front of the sliding chair 16, the side walls 48, 50 have recesses 52, 54, which pass through the sliding chair 16 over its entire height in order to provide a space for a recording or storage 56, which is of the document 18 starts. The bearing 56 is, so to speak, a bearing block, which in the exemplary embodiment has an average U-shape with side legs 58, 60 and cross legs 62.

The recesses 52, 54 preferably have a rectangular shape in plan view.

The side legs 58, 60 have openings or bores 64, 66 aligned with one another, through which the eccentric element 12, referred to as a shaft or rod, passes through in order to be able to rotate it. For this purpose, the eccentric element 12 has an actuating head 68, such as a square head, in one end region in order to rotate the eccentric shaft 12, which is geometrically designed in the contact region 70 with the spring element in such a way that the desired eccentric effect is given, that is, it is dependent depending on the position of the shaft 12, the spring element 10 is either tensioned ( Fig. 4 ) or relaxed ( Fig. 3 ).

For this purpose, the eccentric region 70 in particular has the geometry in the section of a circle segment. Other geometries that allow the spring 10 to be bent to tension it can also be used.

If the sliding chair 16 is arranged on the base 18, the through openings 64, 66 of the bearing block 56 are aligned with openings 72, 74 in the side walls 48, 50 of the sliding chair 16, so that the eccentric element 12 passes through all of the holes and extends from the outside of the Leg 48 can be rotated using a tool such as an open-end wrench.

Since the eccentric element 12 passes through the side walls 48, 50, the eccentric element 12 simultaneously forms a tilt protection for the stock rail 14 and the sliding chair 16. Another advantage of attaching the eccentric element in the middle area is that if the spring element breaks, the plate element continues to prevent tipping , lifting and moving is held securely in position. That's it too ensures that the rail to be fastened is held in the desired position. Special precautions such as projections or notched nails extending from a base plate that get caught on the plate element can be omitted, which enables a simpler design.

In the figures, recesses 49, 51 extending from the backs of the side walls 48, 50 can also be seen, into which projections 53, 55 extending from the base 18 engage (see Fig. 2 ) to provide protection against displacement.

Otherwise, the figures are self-explanatory in terms of the components and construction.

After arranging the sliding chair 16 on the base 18, the eccentric element 12, i.e. the eccentric shaft, is first pushed through the openings 72, 64, 66, 74 and secured via a split pin 75. The spring is then pushed from the back of the sliding chair 16 into the recess 44, with the spring 10 running between the base 18 and the eccentric element 12.

The eccentric element 12 is arranged or rotated in such a way that it can be pushed through unhindered or without tension to such an extent that, on the one hand, the front end 32 of the spring 10 comes to rest on the rail foot 20 and, on the other hand, the rear end 76 rests a first abutment of the plate element 16, in particular on an elevation 78 of the plate element 16 extending between the side walls 48, 50.

In general terms, the ends of the spring element 10 are supported, on the one hand, on a first support formed by the rail foot 20 and, on the other hand, on a section of the plate element 16 or ribbed or sliding chair plate, namely in the exemplary embodiment on the elevation 78, as a second support . The adjustable or rotatable eccentric element 12 acts as an abutment between the supports.

The end section 76, which is curved in section, surrounds the section 78, which preferably has a circular geometry in section, to such an extent that uncontrolled displacement is excluded. At the same time, a sufficient contact surface is created for a material-friendly force transmission. The adjustment of the end region 76 of the spring element 10 and the holding section 78 extending between the side walls 48, 50 is also from the Fig. 3 and 4 clearly visible.

It can also be seen from this that the stock rail 10 is held down exclusively by supporting the spring element 10 on the rail foot 20 and not - as is provided in designs of the prior art - via the sliding plate 16.

Is the spring element 10 correctly positioned, i.e. the front edge region 32 lies on the rail foot 20 and the rear edge region 76 positively surrounds the section 78, the eccentric element 12 is rotated in order to tension the spring element 10, whereby both the stock rail 14 and the sliding chair 16 are held down by tension at the same time . The head of the eccentric element is secured, for example, in a groove to prevent uncontrolled rotation when the spring is to be tensioned.

The two positions of the eccentric element 12 in this regard are Fig. 3 and 4 refer to. In Fig. 3 the spring element 10 is located in a contact area 70 of the eccentric element 12, in which the spring element 10 is not tensioned. There should be no contact between the eccentric element 12 and the spring element 10. If the eccentric element 12 is rotated - in the exemplary embodiment by 180 ° - then pressure is exerted via the eccentric element 12 to tension the spring element 10.

The spring element 10 should essentially consist of two outer legs 11, 13, which are connected to one another by an arch 15. This enables tension-free introduction and positioning of the spring element 10 on the supports provided for this purpose.

The spring element 10 has the greatest moment of resistance in the area of the arch 15, preferably in the contact area 70 with the eccentric element 12, i.e. under the claimed second abutment. Due to a corresponding change in cross-section of the legs, the moment of resistance starting from the arch 15 decreases along the legs 11, 13.

In order to keep the overall height low or to enable a high moment of resistance in the area of the arch 15 of the spring element 10, there is an area for bracing downwards is not hindered by the base 18, which in turn has an advantageous effect on a low overall height. The recessed area

The contact area 70 should run closer to the lower support level of the base 18 than the highest ends A1, A2 of the legs 11, 13 of the spring element 10 facing away from the base in order to achieve a low overall height.

In the Fig. 2 an elastic storage is shown purely in principle.

The static stiffness of the elastic bearing should be greater than 30 kN/mm and up to 100 kN/mm. With a highly elastic bearing, the static stiffness should be in the range between 4 kN/mm and 27.5 kN/mm.

In the Fig. 2 a sliding chair plate (support 118) is elastically supported on a support, such as a threshold, via a plate 120. To fasten the base 118, such as a sliding chair or tongue roller plate, and the plate 120 running underneath it, forming the elastic layer, these are penetrated by preferably hexagonal screws 134, 136, with a disc spring 138, 140 and one on the base side between the respective screw head and the base 118 extending pressure washer 142, 144 is located.

Furthermore, the screw 134, 136 passes through an insert 146, 148, which is inserted into a corresponding recess 150, 152 in the base 118, which in turn merges flush into a corresponding recess 154, 156 in the plate 120.

The spring element 10 can be one that is made of alloyed tempered steel, preferably with a strength of between 1150 to 1450 N/mm ² . in particular between 1200 and 1350 N/mm ² . The hardness HRC should be between 35 and 40, especially between 38 and 42.

Preferably, the spring element 10 is galvanized.

The width of the spring element 10 can be between 45 mm and 50 mm and/or the length between 225 mm and 275 mm and/or the thickness in the contact area with the eccentric element 12 between 16 mm and 22 mm, to give numerical values purely by way of example.

The course of the resistance moment over the length of the tension spring is dimensioned such that the vertical tensioning path exerted by the eccentric element in the second position on the tension spring in the contact area is between 1 mm and 5 mm, with a required hold-down force of the tension spring on the rail base, for example 12kN, is effected.

The bracing described can also be applied to monolithic sliding chairs in which the base and the plate element are made in one piece. Therefore, the subject of the invention is also an arrangement for holding down a rail having a rail base, such as a stock rail, comprising a base, such as a sliding chair, tongue roller or wheel control plate, a plate element extending from the base, such as a sliding chair or counter bearing, a spring element and a first and a second abutment for tensioning the spring element, the first abutment being a section of the plate element or extending from it, which runs in the area remote from the rail foot, and the second abutment is an eccentric element which preferably extends in the longitudinal direction of the rail and which is located between the rail foot and the first abutment is rotatably arranged, the spring element being designed to be supported on the rail foot.

The receptacle can originate from the base or be formed in the plate element.

Refinements result from the claims for both the detachably arranged plate element and for the monolithic construction.

Claims (15)

Arrangement for holding down a rail (14) having a rail base (20), such as a stock rail, comprising a base (18, 118), such as a sliding chair, tongue roller or wheel control plate, a plate element (16) detachably arranged on the base, such as a sliding chair or Counter bearing, a spring element (10) holding the plate element on the base and a first and a second abutment for tensioning the spring element,
characterized,
that the first abutment is a section (78) of the plate element (16) or extends from it, which runs in the area remote from the rail foot, that the second abutment is an eccentric element (12) which preferably extends in the longitudinal direction of the rail (14) and which is in a The receptacle (46) extending from the base (18, 118) is rotatably arranged between the rail foot (20) and the first abutment, and that the spring element is designed to be supported on the rail foot (20). Arrangement according to claim 1,
characterized,
in that the eccentric element (12) is a rod-shaped element, such as a shaft, which has an eccentric geometry in cross section in the contact area (70) with the spring element (10) such that in a first position of the eccentric element, the spring element (10) is unstressed and in a second position is tensioned in such a way that both the rail base (20) and the plate element (16) are held down. Arrangement according to at least one of the preceding claims,
characterized,
that the eccentric element (12) in the contact area (70) has, on average, a geometry in the shape of a segment of a circle or a segment of a circle. Arrangement according to at least one of the preceding claims,
characterized,
that the receptacle (56) has two bearing elements (58, 60) which extend in sections into recesses (52, 54) in the plate element (16). Arrangement according to at least one of the preceding claims,
characterized,
that the spring element (10) extends in the central region of the plate element (16) and in its longitudinal direction. Arrangement according to at least one of the preceding claims,
characterized,
in that the first abutment (78) has a cylindrical section geometry and that the spring element (10) rests on the first abutment with a geometrically adapted end region (76) in such a way that a longitudinal displacement of the spring element is prevented in the tensioned state. Arrangement according to at least one of the preceding claims,
characterized,
that the cross-sectional area or moment of resistance of the spring element (10) in the contact area (70) with the eccentric element (12) is larger than in the contact area with both the rail foot (20) and with the first abutment (78). Arrangement according to at least one of the preceding claims,
characterized,
in that the plate element (16) for receiving the spring element (10) has a longitudinal recess (44) which preferably extends from the first abutment (78) and extends in the longitudinal direction of the plate element and is delimited by side walls (48, 50), and that the side walls of the Eccentric element (12) is penetrated. Arrangement according to at least one of the preceding claims,
characterized,
that the bearing elements (58, 60) of the eccentric element (12) are partially surrounded by the side walls (48, 50). Arrangement according to at least one of the preceding claims,
characterized,
that the bearing elements (58, 60) are side legs of the receptacle (56), which has a U-shape in section, the cross leg (72) of which extends above the eccentric element (12). Arrangement according to at least one of the preceding claims,
characterized,
that the eccentric element (12) is designed at least in one of its ends as an actuating head (68), such as a polygonal head, in particular a square head, which is located in the area of an outside of one of the legs (48, 50). Arrangement according to at least one of the preceding claims,
characterized,
that the plate element (16) extends with its end region running on the rail side above the rail foot (20) and at a distance from it. Arrangement according to at least one of the preceding claims,
characterized,
that contact area (70) between the eccentric element (12) and the spring element (10) runs closer to the lower support level of the base (18) than ends (A1, A2) of the legs (11, 13) of the spring element facing away from the base with their respective smallest distance to the lower support level of the base. Arrangement for holding down a rail (14) having a rail foot (20), such as a stock rail, comprising a base (18, 118), such as a sliding chair, tongue roller or wheel control plate, a plate element (16) extending from the base, such as a sliding chair or counter bearing , a spring element (10) and a first and a second abutment for tensioning the spring element, the first abutment being a section (78) of the plate element (16) or extending from it, which runs in the area remote from the rail foot, and the second abutment is preferably in the longitudinal direction of the rail (14 ) is an extending eccentric element (12) which is rotatably arranged in a receptacle (46) located between the rail foot (20) and the first abutment, the spring element being designed to be supported on the rail foot (20). Arrangement according to claim 14,
marked by
Features of one or more features of claims 2 to 12.

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