EP1114221A1

EP1114221A1 - Sleeper frame for a rail system for rail-mounted vehicles, especially for a ballasted track

Info

Publication number: EP1114221A1
Application number: EP99969131A
Authority: EP
Inventors: Peter Dr. Ing. Plica
Original assignee: Individual
Current assignee: Individual
Priority date: 1998-09-16
Filing date: 1999-09-16
Publication date: 2001-07-11
Anticipated expiration: 2019-09-16
Also published as: EP1114221B1; DE19917179C1; AU1150200A; US6581848B1; ES2195660T3; ATE233845T1; JP2002525457A; DE59904476D1; WO2000015908A1; DE19981826D2

Abstract

The invention relates to a sleeper frame for a track system for railborne vehicles, particularly for a ballasted track, consisting of several cross-ties (1) provided in the direction transverse to the track, and one or several longitudinal supports (2) connected with the cross-ties, wherein one cross-tie (1), respectively, substantially forms the outer delimitation of the sleeper frame in the longitudinal direction, with outer bearings (4) and fixtures (3) for the rails (6) being provided on the outer cross-ties, and with a continuous or quasi-continuous bearing for the rails (6) being provided between the outer rail bearings (4).

Description

Threshold frame for a track system for rail-bound vehicles, in particular for a ballast track

The invention relates to a sleeper frame for a track system for rail-bound vehicles, in particular for a ballast track, with the features of the preamble of claim 1.

Such a component is known from CH 545 376. Compared to the common ballast track with cross sleepers, sleeper frames have the

Advantages of a more uniform bedding in the ballast, a lower ballast pressure under the wheel loads and an increased transverse displacement resistance.

However, the greater length of the sleeper frames in the longitudinal direction also leads to disadvantages: The transverse joints between the sleeper frames must be non-positively connected to avoid damaging joint movements. The necessary elastic, vertical depression of the rail under the rolling wheel requires additional, highly elastic support structures between the rail and sleeper frame due to the small frame deformations in the ballast, but which, on the other hand, prevents the undesired tilting of the

Favor the rail in the rail fastening. Furthermore, the uniform and comparatively small distance between cross ties and rail fastenings in the longitudinal direction of the track under the rolling load leads to vibrations in the ballast, which considerably impair the stability of the superstructure.

The main drawbacks of this construction are the high technical and economic outlay for the joint connection. Furthermore, a railway superstructure is known from AT-PS 377 806, in which individual frame elements are strung together, each rail being mounted on a frame element by means of a plurality of supports. The frame elements can be connected by means of dowels on the end faces to absorb larger transverse forces. The reinforcement of these elements, which are made of prestressed concrete, is carried out by tendons, each of which runs in a straight line between two opposite end faces of the element.

This construction has the disadvantage that a connection of the frame elements is also required to absorb high transverse forces, which requires a corresponding manufacturing and assembly effort. In addition, the relatively large spacing of the rail supports within an element when subjected to a load on a wheel of a rail vehicle results in corresponding vibrations as a result of the different deflection behavior of the rail. The production as a prestressed concrete part with reinforcement elements running in the longitudinal and transverse directions requires the tensioning in two directions perpendicular to each other. This also means a considerable manufacturing effort.

The present invention is therefore based on the object of creating a sleeper frame for a track system for rail-bound vehicles, in particular for a ballast superstructure, in which no complex connection of the sleeper frames in the transverse joints or highly elastic rail supports in the area of the rail fastenings is necessary, even with high transverse forces, and a decrease in the frequency of those generated in the rail vehicle

Allows vibrations. Furthermore, a simple and inexpensive method for producing such threshold frames is to be created. This object is solved by the features of claim 1.

The particular advantages of the sleeper frame according to the invention consist in that the rail fastenings placed on the outside of the frame edge on the one hand reduce the vertical gap in the transverse joint to such an extent that a connection between the sleeper frames can be dispensed with; In addition, the distance between the rail fastenings is considerably increased in this way, with the result that the frequency of vibrations is reduced accordingly.

According to one embodiment of the invention, the outer rail supports in the area of the rail fastenings have a high stiffness and the middle rail supports have a low stiffness, the surface of the middle rail support being significantly higher than that of the outer rail supports before the rail assembly, so that the rail fastenings are tightened the middle rail support is compressed to the level of the outer rail support and receives a compressive prestress.

This has the advantage that the so-called lifting shaft of the rail, which adjusts itself behind a wheel of the rail vehicle in the direction of travel, is nevertheless supported by the middle support and thus the rail does not lift off the support in the region of the lifting shaft. The cushioning effect of the elastic middle support is retained.

According to a further embodiment of the invention, the

Transverse sleepers (1) and / or the side members (2) are provided with an elastic material, preferably an elastic mat. This ensures that the elastic mat arranged under the sleeper frame largely takes on the required vertical rail depression and therefore the rail can be firmly connected to the sleeper frame by the rigid, outer rail supports and secured against tipping. The vertical rail deformation between the rail fastenings remains almost unhindered thanks to the soft middle rail support.

The pre-compression in the middle rail support can be adjusted depending on its rigidity and pre-compression height so that the vertical rail depression under the wheel load becomes the same in both the frame center and in the rail fastenings and thus corresponds to a continuous rail support. This also further improves the vibration damping of the system.

According to another embodiment of the invention is in each case one

Rail axis provided a side member. As a result, a continuous or quasi-continuous mounting of the rail can be achieved in a simple manner without having to provide the cross ties very closely to one another, for example. The number of cross sleepers can in particular be reduced to two. At this point, it should be pointed out that a quasi-continuous mounting of the rail is to be understood as storage in points or areas lying close to one another, without one of the desired bending line of the rail under load being essential in the areas in which no storage is provided Deviation is generated.

The position of the outer rail supports and / or the rail fastenings is selected such that the central plane of the rail fastenings is at a distance of less than or equal to 15 cm, preferably less than or equal to 10, transverse to the course of the rails cm from the outer boundary of the threshold frame in the longitudinal direction. With an appropriate dimension of the transverse sleepers in the longitudinal direction, these elements can be arranged centrally with respect to this dimension.

According to the preferred embodiment of the invention, the cross sleepers and the at least one longitudinal beam are formed in one piece, preferably as a prestressed concrete element. This results in a simple, rational possibility of production.

The sleeper frame can be designed as a whole as a prestressed concrete part or it can be connected to a connecting rod in the form of a metal profile outer regions of the cross sleepers (and possibly the longitudinal beams) produced as normal concrete parts or prestressed concrete parts.

According to one embodiment of the invention, tensioning elements are used as reinforcement of the sleeper frame, which are anchored on the end faces of a transverse sleeper. The tensioning elements are guided with arches from this cross sleeper via a longitudinal beam to a second cross sleeper and anchored on their front sides. This has the advantage that the pre-tension can be applied from only two opposite sides of the frame and both pre-tension in the longitudinal and transverse directions can be generated in one operation.

In this case, at least two U-shaped clamping elements rotated relative to one another by 180 ° can be provided, the ends of which are anchored on opposite end faces of two transverse sleepers. The arches of the tensioning elements can run through the same side member or, in the case of two or more side members, through one side member each, which is closer to that End faces of the cross sleepers, in which the ends of the other clamping element are anchored.

However, the tensioning elements can also be essentially Z-shaped, the ends of a tensioning element being anchored at opposite ends of different transverse sleepers. In the case of a sleeper frame which has at least two longitudinal beams, at least four Z-shaped clamping elements can be provided, two Z-shaped clamping elements crossing each other in the same longitudinal beam.

To produce such a sleeper frame, it can first be produced with expansion joints in the side members. The clamping elements are then pre-stressed by widening the joints. The expansion joints are finally closed with a suitable hardenable building material, so that there is a positive and non-positive connection in the expansion joints.

Of course, a different type of suitable fixation of the prestressed position of the threshold frame can also be carried out.

These features relating to the special reinforcement of the sleeper frame and the tensioning method can of course also be used independently of the features relating to the positioning of the rail fastening and the design of the supports. Conventional sleeper frames, which consist of at least two transverse sleepers and one or more longitudinal beams, can also be produced easily and inexpensively in this way.

Further embodiments of the invention result from the subclaims. The invention is explained in more detail below with reference to the drawings. The drawing shows:

Figure 1 is a partial schematic plan view of a track system with threshold frame according to the invention.

Fig. 2 is a side view of the illustration in Fig. 1;

Fig. 3 is a plan view of an embodiment of a threshold frame according to the invention, illustrating the U-shaped clamping elements used and

4 shows a plan view of a further embodiment of a sleeper frame according to the invention, illustrating the Z-shaped tensioning elements used.

The section of a track system shown schematically in FIG. 1 shows an embodiment of a sleeper frame with two cross sleepers 1, which preferably have one piece with two longitudinal beams 2

Component are connected. The formation of rail fastenings 3 with associated outer rail supports 4 correspond to the known prior art.

The provision of the rail fastenings 3 on the transverse sleepers forming the outer boundary of the sleeper frame means that adjacent sleeper frames can be lined up with only a relatively small gap, and thus the rails 6 at the interfaces between them two threshold frames can be fixed at a short distance from each other. This improves the absorption of transverse forces, in particular forces vertical to the course of the rails when loaded by the wheels of a rail-bound vehicle (to a lesser extent, of course, transverse forces also occur in the plane formed by the rails 6, for example in

Curves). This results in a smaller deviation from the desired course of the practically unavoidable deflection at the interfaces of adjacent threshold frames when the rails are loaded.

The limitation of the frame size in the longitudinal direction to only two near the

Transverse joint arranged rail fastenings 3 with the two outer rail supports 4 has the advantage that the frame can follow the rail depression occurring under the wheel load without constraint and only slight differences in depression occur at the transverse joints. As a result, the transverse forces to be transmitted in the transverse joint also remain so low that they are transmitted via the rails 6 without any significant additional stress. An additional connection in the transverse joint is no longer necessary.

The middle rail support 5 between the outer rail supports 4 has the task, on the one hand, of the rail 6, which is more self-supporting than usual

To support wheel loads vertically and on the other hand to dampen vibrations in the rail 6.

Since the rail 6 bends between the outer rail supports 4 in the center of the frame both downwards as a result of the wheel load located directly above it and upwards as a result of the so-called lifting shaft, the central rail support 5 must be able to follow these movements without detaching from the rail 6. This is achieved in that the surface of the middle rail support 5 before the rail assembly is clearly, preferably between 2 to 5 mm, higher than the surface of the outer rail supports 4. When the rail 6 is placed on and the elastic rail fastenings 3 are tightened, the middle becomes Rail support 5 compressed to the height of the outer rail support 4 and thereby receives a compressive prestress, which is maintained in the order of 0.1 mm even with a rail deflection upwards.

The mode of operation of the middle rail support 5 described here is particularly useful with large dimensional tolerances in the gap between the rail 6 and the side member 2.

The distance between the individual threshold frames, i.e. between the closely adjacent outer transverse sleepers 1 and 1 'should be as low as possible. On the one hand, a changing gap width is required when laying in curves; on the other hand, the laying must not be hindered by individual gravel stones in the gap. In this respect, a distance of about 5 cm seems appropriate.

In a further constructive embodiment of the invention, the threshold frame described monolithically as a prestressed concrete component is shaped in such a way that it is suitable for production as a reinforced concrete component according to the principles known for two-block sleepers. The advantages of the threshold frame according to the invention are thus transferred to a further area of application. For a preferred embodiment of the reinforcement according to the invention, the prestressing reinforcement shown in FIG. 3 shows two U-shaped tensioning elements 10 and 11, which are anchored with end plates 12 on the adjacent end faces 9 and on the adjacent end faces 8.

Because of the curvatures in the tensioning elements 10 and 11, the prestressing can only be applied after the concrete has hardened. In order not to hinder the expansion in the tensioning elements 10 and 11, they are slidably guided in cladding tubes or separated from the concrete by a coat of paint.

The prestressing forces are preferably entered into the tensioning elements 10 and 11 on the end faces 8 and 9 using 4 presses operating simultaneously.

Thanks to the curved guidance of the tensioning elements 10 and 11, both the cross sleepers 1 and the side members 2 thus receive the longitudinal pretension necessary to accommodate dynamic loads.

Due to the number of at least 2 clamping elements 10 and 11, the pretensioning force in the central region of the cross ties 1 is twice as large as in FIGS

End regions and in the longitudinal beams 2. Since the sleeper frame is also most heavily stressed by the wheel loads in the central region of the cross sleepers 1, this reinforcement guide is to be regarded as economically very advantageous.

The use of the U-shaped clamping elements 10 and 11 is particularly suitable for large and few tendons because of the relatively large bending radii of the clamping elements and the small number of plate anchors 12. On the other hand, if thin wires are to be used for technical and economic reasons, the reinforcement form shown in FIG. 4 is expedient, for which at least four Z-shaped tensioning elements 13, 14, 15 and 16 are required.

These tensioning elements are anchored to the end by bonding the wires to the concrete. Outside the end anchorages, the wires can slide through cladding tubes or thanks to a coat of paint in the concrete.

The prestressing of this prestressing reinforcement is generated by widening the tension joints 17 in the longitudinal beams 2. The two cross sleepers 1 are pressed apart and thus pretensioned by four prestressing presses, which act close to the side members 2 on both sides. The opened expansion joints 17 are then filled with mortar, which is compacted by intensive vibration. As soon as the mortar has reached the necessary load-bearing capacity, the prestressing presses are lowered. This also gives the side members the intended preload.

The clamping joints 17 arranged offset in the longitudinal beams 2 have the

Purpose to prevent the frame parts from twisting each other during pretensioning.

The advantages of this form of reinforcement lie in the fact that the usual anchoring openings to be closed on the end faces 8 and 9 of the sleeper frame after prestressing are eliminated. Furthermore, because of the larger number of tensioning elements, the prestressing force in the longitudinal beams 2 increases to such an extent that the tensioning joints 17 are sufficiently bridged.

Claims

claims

1. sleeper frame for a track system for rail-bound vehicles, in particular for a ballast track,

a) consisting of several transverse sleepers (1) provided in the transverse direction of the track and one or more longitudinal beams (2) connected to the transverse sleepers,

characterized,

b) that in each case one transverse threshold (1) essentially forms the outer boundary of the threshold frame in the longitudinal direction,

c) that outer supports (4) and fastenings (3) for the rails (6) are provided on the outer transverse sleepers and

d) that a continuous or quasi-continuous support for the rails (6) is provided between the outer rail supports (4).

2. Threshold frame according to claim 1, characterized in that the outer rail supports (4) in the area of the rail fastenings (3) have a high level of rigidity and the middle rail supports (5) have a low level of rigidity, the support surface of the central rail support (5) before the rail assembly is significantly higher than that of the outer one Rail support (4), so that when the rail fastenings (3) are tightened, the middle rail support (5) is compressed to the level of the outer rail supports (4) and receives a compressive prestress.

3. Threshold frame according to one of the preceding claims, characterized in that an elastic material, preferably an elastic mat, is provided on the underside of the transverse sleepers (1) and / or the longitudinal beams (2).

4. Threshold frame according to one of the preceding claims, characterized in that exactly two transverse sleepers (1) are provided which represent the outer transverse sleepers (1).

5. Threshold frame according to one of the preceding claims, characterized in that a longitudinal beam (2) is provided in each case under a rail axis.

6. Threshold frame according to one of the preceding claims, characterized in that the outer rail supports (4) and or the rail fastenings (3) are provided centrally on the outer cross sleepers (1).

7. threshold frame according to one of the preceding claims, characterized in that the central plane of the rail fastenings (3) transversely to the course of the rails has a distance of less than or equal to 15 cm, preferably less than or equal to 10 cm from the outer boundary of the threshold frame in the longitudinal direction.

8. Threshold frame according to one of the preceding claims, characterized in that the transverse sleepers (1) and the at least one longitudinal beam (2) are formed in one piece, preferably as a prestressed concrete element.

9. threshold frame according to claim 8, characterized in that in a threshold frame designed as a reinforced concrete component, the central region of each crossbar (1) is formed by a connecting rod in the form of a metal profile.

10. Sleeper frame according to claim 8, characterized in that one or more tensioning elements serve as reinforcement, which are anchored on the end faces (8, 9) of a transverse sleeper (1), with arches from this transverse sleeper (1) via a longitudinal member ( 2) led to a second crossbar (1) and anchored on the end faces (8, 9).

11. Threshold frame according to claim 10, characterized in that at least two U-shaped clamping elements (10, 11) rotated relative to one another by 180 ° are provided, the ends of which are anchored on opposite end faces of two transverse sleepers (1).

12. Threshold frame according to claim 11, characterized in that the arches of the tensioning elements (10, 11) run through the same longitudinal beam (2) or, in the case of two or more longitudinal beams (2), through one each

Side member (2), which is closer to those end faces of the cross sleepers (1) in which the ends of the respective other tensioning element (11, 10) are anchored.

13. Threshold frame according to claim 10, characterized in that the tensioning elements (13, 14, 15, 16) are Z-shaped, the ends of a tensioning element being anchored at opposite ends of different transverse sleepers (1).

14. Threshold frame according to claim 13, characterized in that the threshold frame has at least two longitudinal beams (2) and at least four Z-shaped clamping elements (13, 14, 15, 16) are provided, two Z-shaped clamping elements in each case always the same

Cross the side members (2).

15. A method for producing a sleeper frame, in particular according to one of claims 8 to 12, characterized in that the prestressing of the reinforcement on the end faces (8, 8) after the concrete has hardened.

9) the cross sleepers (1) is applied.

16. A method for producing a sleeper frame according to one of claims 8 to 12, characterized in that the sleeper frame is first produced with expansion joints (17) in the longitudinal members (2), that the tensioning elements (13, 14, 15 , 16) are prestressed by expansion of the joint and that a positive and non-positive connection is then created in the expansion joints (17) by means of joint sealing with a suitable hardenable building material or that the prestressed position of the threshold frame is fixed in a different manner.