The invention relates to a friction-fit elastic rail fastener for track systems, comprising a tensioning element made of an elastic material, in particular hardened spring steel, that in the assembled state is fixed in place between a retaining plate provided on a sleeper and a fastening anchor such that the tensioning element exerts a retention force on the rail foot in order to hold the rail in position, and the tensioning element is symmetrically aligned with respect to a vertically oriented plane of symmetry that is perpendicular to the longitudinal axis of the rail.
A generic rail fastener-is known from DE 34 00 110 [U.S. Pat. No. 4,770,343]. In the cited document a tensioning element is used that in the assembled state-is provided between a retaining plate and a fastening anchor. The tensioning element has two legs designed as torsion elements. The torsion legs have two adjacent parallel spring bar sections that are formed one piece with a loop that forms a bracing section and is curved outward-and essentially transversely with respect to the spring bar sections. The two spring bar sections of the torsion legs are connected via the transverse connecting piece. The two outer spring bar sections of the torsion legs each have a U-shaped bend, provided at a distance behind the transverse connecting piece that at its free end section is supported on the transverse connecting piece, whereas anchor parts for the rail fastener have two support flanges for the torsion legs of the tensioning element, projecting toward opposite sides, adjacent to a center bar and respectively provided at a distance above stop bevels for the bracing sections located next to the rail foot.
A rail fastener of the above-described type is known from DE 39 18 091 [U.S. Pat. No. 5,096,119] in which sections of the outer legs of the epsilon-shaped tensioning elements widen toward the rail foot with an increase in distance between the inner legs. The mutually aligned free ends of the tensioning element end outside the inner legs. The tensioning element is also designed such that in the assembled position a center bar comes to rest a small distance above the rail foot, and in the preassembled position the inner side of the center bar contacts the shaft of the sleeper screw.
In one of the previously known embodiments, although the tensioning element fulfills its function, namely, to securely hold the rail on the sleeper, the tensioning element-is relatively large and complicated in design. This entails a correspondingly high level of manufacturing complexity-that increases the production costs for the tensioning elements.
In addition, the previously known tensioning elements do not adequately address the problem that the rail may tilt when unusually high forces impinge thereon. The torsion legs of the tensioning element and the sleeper screws may be highly stressed, i.e. overtightened or overloaded, when the rail tilts. It is therefore desirable to design the rail fastener in such a way that precautions are taken, and also that overloading of the tensioning element and of the sleeper screws is prevented even during tilting.
In one of the previously known embodiments, the tensioning torque is indirectly produced only by tightening the sleeper screws or hook screws. The tensioning force of the tensioning element also acts on the pretensioning force of the sleeper screw, thereby also subjecting the screw to load. In addition, the tensioning element can be assembled only by use of a sleeper screw or hook screw. It is desirable to achieve a universal assembly of the tensioning element, i.e. with or without screws, and, if necessary, without affecting the pretensioning force for the screw.
The object of the invention, therefore, is to refine a rail fastener of the generic type such that the above-referenced disadvantages are avoided, that in particular a simple geometric design of the tensioning element is possible, and that the associated manufacturing costs remain low. A further aim is to provide a reliable two-stage overload protection so that the tensioning element is not damagedeven when occasional, unusually high forces arise. A further aim is to provide a possibility for assembly that is universal and, if necessary, independent from the screw pretensioning.
Achievement of this object according to-the invention is characterized in that the tensioning element has two preferably parallel torsion legs that in the assembled state are at least substantially provided between the retaining plate and the fastening anchor, and the two torsion legs are connected to one another on the side facing away from the rail by means of a connecting section. In addition, a loop-shaped clamping section is provided on each end of the torsion leg facing the rail, and adjacent the torsion legs the clamping section first extends essentially perpendicular to the plane, and then extends in a looped manner until the ends of the clamping section reach the vicinity of the ends of the torsion legs, where they form a support surface on the rail foot. Furthermore, in the non-tensioned state of the tensioning element the torsion legs together with the connecting section lie essentially in a first plane, and at least a portion of the loop-shaped clamping sections lie in a second plane, whereby the second plane is rotated about an axis in relation to the first plane, the axis extending parallel to the sectional axis of the plane of symmetry containing the first plane.
In the assembled state of the tensioning element, the second plane preferably is substantially congruent with the first plane.
Under normal load on the rail, in the assembled state the loop-shaped clamping sections of the tensioning element preferably contact the rail foot. However, the ends of the clamping section. in the assembled state may also engage in recesses provided for same in the retaining plate. In this manner it is possible for the end-face ends of the clamping sections to lock in the recesses for horizontal stabilization in the final assembled position. The recesses in the retaining plate may also have locking projections or catches that enable the ends of the clamping section to engage with the retaining plate.
The loop-shaped clamping sections may also first extend from the end of the torsion legs, essentially perpendicular to the plane of symmetry, and then extend in the direction away from the rail in order to return back to the rail in a curved progression. In this case, the loop-shaped clamping sections preferably have an S-shaped curve, at least in places. This design provides a compact structure of the fastening system, as discussed further below.
In their portions facing the rail as viewed from above, the loop-shaped clamping sections preferably each have an essentially circular or oval shape. Connection transitions between the individual functional zones are provided with large radii or radius transitions to ensure optimal tension curves in the material of the tensioning element. The individual radii or radius transitions along the curve of the tensioning element may have different sizes.
The loop-shaped clamping sections adjacent the torsion is legs may first extend essentially perpendicular from the-plane of symmetry.
The angle between the above-referenced planes, i.e. between the first plane and the second plane, is preferably between 5° and 30° in the non-tensioned state of the tensioning element.
The ends of the loop-shaped clamping sections may be designed as straight sections. These straight sections preferably extend parallel to each other.
The ends of the loop-shaped clamping sections, in particular the straight sections, may have a cutout that is designed as a support surface on the corner radius of the rail foot. This allows defined and secure contact on the rail foot.
To accommodate an overload, each loop-shaped clamping section may have a first contact surface in the lateral region of the clamping section for contacting the rail foot, the first contact surface likewise contacting the rail foot when the rail tilts in the event of high horizontal forces on the rail head (first overload case), but with a greatly reduced lever arm. In addition, each loop-shaped clamping section may have a second contact surface for contacting the fastening anchor, and in a second, more intense overload case that exceeds the first overload case for the forces acting on the rail, the second contact surface contacts the fastening anchor.
The retaining plate may be integrated into a rail-bed plate.
The retaining plate and the fastening anchor may have a two-piece design. The retaining plate and the fastening anchor may be connected or held together by means of a hook screw.
The fastening anchor may be plate-shaped and fixed in placed by a screw.
The retaining plate and the fastening anchor may also have a one-piece design.
On its lower face, in its lateral end regions facing the rail, the fastening anchor may have contact surfaces for the loop-shaped clamping sections. On its lower face the fastening anchor in its lateral end regions facing away from the rail may also have a first channeled locking depression in each case for locking the tensioning element in a preassembled position. On its lower face the fastening anchor may also have a second channeled locking depression in its lateral end regions facing away from the rail for locking the tensioning element in a neutral position. Finally, on its lower face the fastening anchor may have two channeled contact surfaces for supporting the torsion legs of the tensioning element in the final assembled state.
The fastening anchor may also be formed by the sleeper screw or by a washer connected thereto.
The retaining plate may have two curved depressions, extending perpendicular to the longitudinal axis of the rail, for guiding the tensioning element during installation thereof. The retaining plate may have two contact surfaces for contacting the tensioning element in its assembled state. Furthermore, on its lower face the retaining plate may have a projection, extending in the direction of the longitudinal axis of the rail, for engaging with a corresponding recess in the sleeper.
The tensioning element may be economically produced by use of the proposed design. The tensioning element is relatively compact, so that the proposed rail fastener may be used for a number of applications.
In addition, two-stage overload protection of the rail fastener is provided in the event of overload, thereby reliably preventing excessive tilting of the rail and avoiding plastic deformation of the clamp.
Illustrated embodiments of the invention are shown in the drawings that show the following:
As shown in
The specific design of the tensioning element 1 is shown in
As shown most clearly in
This end regions 1e′ and 1e″ are designed as straight sections 1f′ and 1f″, and are provided for pressing on the top side of the rail foot 5 in normal operation. As shown in
As shown most clearly in
As a result of this design, after the tensioning element 1 is assembled, it makes defined contact only in the region of the straight sections 1f′ and 1f″. The tensioning element 1 otherwise does not contact the rail foot 5 in normal operation.
As shown in
The following precautions are taken to prevent damage or overload of the tensioning element 1 in the event of an excessive lateral, horizontal force on the head of the rail 6, i.e. when the rail 6 undergoes a tilting motion about its longitudinal axis 8.
First contact surfaces 1h′ and 1h″ are provided on the tensioning element, i.e. in the region of the loop-shaped clamping sections 1d′ and 1d″, in lateral regions 1i′ and 1i″ of the clamping sections 1d′ and 1d″. In the event of extreme tilting of the rail 6, the rail foot 5 also presses on these contact surfaces 1h′ and 1h″, thereby increasing the elastic force of the tensioning element 1 on the rail foot 5. Thus, the first stage of an overload protection is provided by the first contact surfaces 1h′ and 1h″.
If the tilting motion of the rail 6 should increase even more, second contact surfaces 1k′ and 1k″ are provided on the clamping sections 1d′ and 1d″ that upon further lifting of the clamping sections 1d′ and 1d″ are also lifted and press against contact surfaces 15′ and 15″ (see
The fastening anchor 4 is shown in
During assembly the tensioning element 1 is first pushed in the direction of the rail until it rests against first channeled locking depressions 17′ and 17″ that are provided, i.e. integrally molded, in lateral end regions 16′ and 16″. When the tensioning element 1 is advanced further in the direction of the rail 6, and thus in the direction of the final position of the tensioning element after assembly, the tensioning element 1 comes to rest in second channeled locking depressions 18′ and 18″. In the final assembled position the tensioning element 1 then makes contact in channeled contact surfaces 19′ and 19″.
The assembly sequence for the rail fastener is shown in
The first stage of installation in the preassembled position is shown in
In the third stage of installation, the intermediate stage as shown in
The measures for protection against overload of the tensioning element 1 are shown in
In the first stage of overload protection the first contact surfaces 1h′ and 1h″ of the loop-shaped clamping section 1d′ and 1d″ of the tensioning element 1 rest on the rail foot 5.
In the first stage of overload protection the first distance, denoted by reference numeral s1 in
In the second stage of overload protection the loop-shaped clamping sections 1d′ and 1d″ together with the second contact surfaces 1k′ and 1k″ are supported on the contact surfaces 15′ and 15″ of the fastening anchor 4.
In the second stage of overload protection the second distance, denoted by reference numeral s2 in
In the illustrated embodiment the loop-shaped clamping sections 1d′ and 1d″ adjacent the torsion legs 1e′ and 1e″ extend away from the plane of symmetry 7. In principle, the clamping sections 1d′ and 1d″ may extend toward the plane of symmetry 7.
In the illustrated embodiment the retaining plate 4 [sic; 3] is designed as a separate component. The plate 4 [sic; 3] may be a component of a ribbed plate, or may be fixedly connected to the fastening anchor 4.
The illustrated assembly procedure is based on the fact that the sleeper screw 12 is tightened with final torque before the tensioning element 1 is installed. It is also possible for the sleeper screw 12 to not be (completely) tightened until the tensioning element 1 is installed, specifically, in the sleeper unit, for example; i.e. in the preassembled position before the rail is assembled, or in the neutral or final tensioned position after the rail is assembled.
Such recesses 25 may also be provided for an embodiment as illustrated in
One variant of the tensioning element is shown in
The above-mentioned illustrated embodiments show that all relevant fastener variants of rail tensioning elements in use hitherto may be replaced by a tensioning element of one shape by means of the system according to the invention.
In all of the above illustrated embodiments the sleeper screw 12 fixes the fastening anchor 4 in place. However, this is not absolutely necessary. The fastening anchor 4 may be omitted, so that the sleeper screw 12 acts directly on the tensioning element and fixes same in place. To this end,
An alternative design of the tensioning element 1 is shown in
The difference between the embodiment of the tensioning element 1 shown by way of example in
A further difference in the embodiment illustrated in
In the embodiment described above according to
In the embodiment according to
In the embodiment according to
The variant of the tensioning element 1 illustrated in
A further modified variant of the tensioning element 1 is shown in
Number | Date | Country | Kind |
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102004059536.4 | Dec 2004 | DE | national |
2005048829.3 | Oct 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP05/13211 | 12/9/2005 | WO | 00 | 6/7/2007 |