Patent Application
20240110339
The invention relates to a frog, comprising a frog tip adjustably arranged between wing rails, whereby a wheel transfer zone extends in the area of the frog point.
A frog as part of a railway switch allows a transition between crossing tracks. An essential characteristic of a resiliently movable frog tip is that the running edge is being closed, so that the wheel in the corresponding region is always guided and supported. In this, locking elements bring the frog tip into contact in a force fitting and form fitting manner against the respective wing rail. For this, actuating pull-rods originate from a railway switch drive, which are connected to the frog tip in order to move the latter and to bring it into contact with a wing rail.
The wing rails usually are rolled standard rails from standard track cross sections such as 60E1. However, the standard rail cross section and constraints posed by the rail-building materials limit the design options with respect to the embodiment of the wing rails.
Frogs with resiliently movable frog tips are disclosed for example in EP 1 455 016 A2 or EP 1 455 017 A2.
In addition to resiliently movable frog tips, there exist frogs with an inflexible frog tip, i.e. a frog tip that is not adjustable relative to the wing rails.
It is the objective of the present invention to further develop a frog with a movable frog tip in such a way as to enable a nearly optimal geometric design in the wheel transfer zone between the wing rails and the frog tip.
In addition, travel comfort while traversing the frog is to be increased, in particular jolts are to be avoided or reduced.
Wear and tear and the load on the component parts employed in the frog are to be reduced relative to the state of the art components.
In order to find a solution to one or several of these aspects, the invention essentially intends that each wing rail comprises a section that extends separately from the frog tip at least along the length of the wheel transfer zone, each of which is produced from a forged block.
The invention makes available a frog, in which in the wheel transfer region a section of the wing rail is replaced by a pre-forged steel block, which has been subjected to metal cutting. According to the state of the art, the wing rails of movable frogs along their entire length generally consist of a rolled standard track cross section, which results in limitations with respect to geometric properties.
The section produced from the forged block in particular is joined to sections of standard rails, extending in front and behind the section consisting of the forged steel block, by a flash butt welding method.
The advantage of the block section present in the respective wing rails is to be seen in that this area with respect to geometric layout and the employed material can be designed with more freedom in comparison to the state of the art, since the standard profile being employed in accordance with the state of the art has limitations with respect to its constructional options due to its standard cross-section und the constraints of limited rail-building materials.
In comparison to standard rail profiles it is possible to achieve a greater moment of inertia and moment of resistance, which results in lower flexural stresses.
It is in particular intended that the separately produced section has a length between 1.2 m und 12 m, without this placing a restriction on the teaching of the invention.
As material for the section are employed steels with a tensile strength Rm with 1175 MPa≤Rm≤1500 MPa, an elongation at break A with 9%≤A≤12% and a Brinell hardness HBW with 350 HB≤HBW≤500 HB. An example should be mentioned chromium bainitic steel. The Brinell hardness is measured with a ball diameter of d=2.5 mm, a test load of F=1.839 kN, and an exposure time of 10-15 s.
As a result of using a forged block, also to be referred to as a slab, and the wing rail section being produced by metal cutting processes, a high precision with respect to geometric requirements is facilitated. Simultaneously, critical residual stresses are avoided, which originate when employing standard rails as a result of bending or folding.
Since the frog tip can itself consist of a material with the above-mentioned material characteristics, in particular may also be a forged component, the wheel transfer zone possesses high resilience, as a result of which wear and tear is low.
Because the desired constructive developments are achievable by subjecting the block to metal cutting processes, the mass of the section, i.e. of the wing rail block, can selectively be matched to the dynamic loads, which for example result from characteristic vehicle behaviour or vehicle speeds. In comparison to standard rails, the cross sections may be chosen in a manner so that when e.g. openings, such as bores, are to be provided, in order to guide through these passages elements to move the frog tip, such as locking rods and detector rods, a weakening will not take place to such a degree that requires—as it does in the state of the art—implementing additional measures in order to achieve the required strength, as is the case for standard rails that comprise in their webs bores for effecting actuation. To be mentioned as an example are edge reinforcements of the openings.
Consequently, the invention is also characterized in that the section that comprises a rail head, a rail foot, and a web extending between the latter two, also comprises a passage opening for a rod element, such as locking rods or detector rods, whereby the web of the wing rail section at least in the area of the passage opening possesses a thickness D with D>30 mm, in particular D>40 mm, especially preferred 40 mm≤D≤60 mm, very especially preferred 45 mm≤D≤50 mm.
It has to be particularly emphasized that the contact surface of the tip region of the frog tip to the wing rail section is a section of an area that is extending recessed relative to the wing rail section's running edge, such as a milled cutout, in the flank of the wing rail section.
In the recessed regions originates the frog tip, which is lowered and approached laterally. Wheels do not contact the upper surface yet.
The functional frog tip is the start of the frog tip, starting from where the frog tip is used or can be used as a lateral guide.
Starting at the beginning of the functional frog tip, the frog tip performs a technical track function. Lateral forces can be absorbed. In front of the functional frog tip, this function is not performed by the still present region of the frog tip that extends to the free end of the frog tip.
In accordance with the invention, the contact surface between the wing rail section and the movable frog tip can be selectively shaped in a manner to facilitate an as short as possible disruption to the running edge, without having to consider any dependency on the rail profile.
In this, it is particularly intended that corresponding to the mass of the material removed to form the recessed region, more material will remain on the wing rail section, in particular on the wing rail section facing away from the frog tip.
In this, “more material” comprises a mass that corresponds to the mass of the material removed to form the recessed region. Consequently, the section machined out of the block that forms a step does not or not substantially result in a change in the moment of inertia.
The term substantially is to mean that the area moment of inertia does not change by more than ±20%, preferably by not more than ±10%. This applies both for an application of force from the direction of the flank (area moment of inertia ly) as well as for a force application in the direction of the head surface (area moment of inertia lx).
In accordance with a feature of the invention to be emphasized, the identical or substantially identical moment of inertia irrespective of geometry changes in the section of the wing rail that can be achieved on account of the invention's teaching, is principally present in the area extending between the functional frog tip and the region where the frog tip detaches from the section, i.e. is spaced apart from the section. The length LT of the region of identical or substantially identical moment of inertia preferably is 250 mm≤LT≤9,000 mm.
In other words, the wing rail section is machined out of the block in such a way, in particular by milling, so that in some areas, in which deviations from the basic geometry are formed, such as a cant or a recessed area, in which the tip of the frog tip engages in a force-fitting contact with the wing rail section, additional masses will be removed or will remain in excess in adjacent areas, equivalent to the masses resulting from the changes to the course of the geometry.
The region that extends recessed relative to the running edge and is embodied in accordance with the invention's teaching presents a further advantage of the invention's teaching to be emphasized, in particular with respect to the point of the frog tip in its starting region. Consequently, the frog tip, at the point of the functional frog tip, where the frog tip is lowered and is approached laterally so that in this area no wheel is traveling along the head surface, may on its head surface possesses a width between 8 mm and 12 mm, whereas the state of the art typically allows widths of less than 5 mm.
In this, the head surface is the area that develops in the running surface of the frog tip and is bordered by the flanks. The width of the head surface is defined by extending the left and the right flanks up to the height of the running edge. The running edge is the line along the longitudinal direction of the frog tip, which extends at some distance in parallel and below the common travel surface tangent. The common travel surface tangent is a straight line that extends tangentially to the travel surfaces of both rails of the track.
The distance normally is 14 mm, but can also assume values between 10 mm and 16 mm (depending on the railway operator or the set of regulations).
For the above stated width of 8 mm to 12 mm we used a distance of 14 mm.
In this area, the head surface possesses a plateau-like course, i.e. extends horizontally or slightly curved relative to the horizontal.
In particular it is also intended that in the transition region between the frog tip and the wing rail section in the latter a cant has been produced from the block by metal cutting processes.
It should be particularly emphasized that as one piece with the first spacer elements—also referred to as distance blocks—an anti-derail device for the frog tip is machined out of the block.
In this, it is in particular intended that machined out of the blocks as one piece together with the wing rail sections are the first distance blocks, each of which possesses a cutout, whereby in the assembled wing rail sections the cutouts merge together to form an open chamber, in which is adjustably arranged the frontmost free end, i.e. the foremost region, of the frog tip. This region is not traveled on and hereinafter will be referred to as nose.
As a further development, the invention intends that the frog tip comprises an in particular cuboid base body, and originating from the latter a tip body with a triangular cross section, and that the width B of the base body in the wheel transfer zone is B>60 mm, in particular B>70 mm, preferably 75 mm≤B≤85 mm.
The base body transitions into the tip body, whereby the tip body may possess in the transition region to the base body a width BS with 40 mm≤BS≤60 mm, preferably 45≤BS≤55 mm.
In the region of the functional tip, the frog tip is composed of the base body and the tip body, which is laterally bordered by the flanks, which can be run into, and the plateau-like extending top surface (head surface) of the front end of the functional frog tip.
The fact that using the block as starting material allows producing the desired constructive designs and consequently geometries of the section, facilitates the option that the distance between the running edge and the surface extending on the running-edge side of the web is greater than said distance when using a standard rail profile, which makes available more space and consequently the component tip with its base body can extend to a larger degree in the area below the railhead when the frog tip is in contact, i.e. the base body may be embodied with a greater width than would be the case when employing standard rail profiles.
Irrespective of this, the required strength is achieved, since the web area of the rail wing section can be embodied with a sufficient thickness. In this, the invention particularly intends that the web of the wing rail section in the wheel transfer zone possesses a thickness D with D>30 mm, in particular D>40 mm, especially preferred 40 mm≤D≤60 mm, very especially preferred 45 mm≤D≤50 mm.
For the wheel transfer it is possible to mill into the block precisely and with low tolerances an optimal geometry, including the cant of the running surface, without the need to apply the additional and complex bending and grinding processes required according to the state of the art. In contrast to the state of the art, the manufacturing process is not dependent on the large tolerances of the rolled profile employed when using standard rails.
A cant is known in the art, in order to prevent a wheel experiencing descent during a transition from the frog to the wing rail, and in reverse, if the running surfaces of the wing rail and the frog tip area in the transition region would extend on the same level, in particular because of the conical profile of the vehicle wheels and the geometric course of the wing rails towards the outer side of the rail.
According to the state of the art, the cant is produced by way of underlayers or relining below the wing rail and by bending the latter. According to the invention, this is not necessary, since the cant is machined out of the block, so that the lower surface of the rail wing section along its entire length extends in a two-dimensional plane.
Outside of the frog tip, the sections may be supported against each other via distance blocks machined integrally out of the block, which may be connected to each other via high-strength screw connections.
The invention for producing wing rails for a frog with a movable frog tip is further characterized in that the wing rail sections outside of the frog tip are supported against each other by second distance blocks that are machined out of the block as one piece together with the wing rails.
In this, it is in particular intended that at least one section of each wing rail is produced from a forged steel block by metal cutting processes, whereby a cant of the running surface of the rail can be machined integrally in an area where the frog tip is in contact with the wing rail section.
Preferably the invention intends that an anti-derail device is embodied integrally in the first distance blocks, via which the wing rails are supported against each other.
It is also intended that machined from the block is a cutout to form a contact surface for the frog tip.
It is further intended that in the flank of the wing rail section extending on the side of the frog tip is machined from the block an area that is recessed relative to the basic track trajectory of the running edge, with a contact surface for the frog tip.
Also with inventive merit it is intended that the wing rail section is machined from the block in a manner so that areas, in which the geometry of the wing rail section deviates from its base geometry, such as a cant or the region recessed relative to the running edge, corresponding to the mass of material that results from the change of the geometric course, an equivalent material mass in an adjacent area in the wing rail section is removed from the block or remains in excess relative to the basic geometry, so that the moment of inertia of the wing rail section remains unchanged or substantially unchanged.
It is known in the art to produce wing rail sections from a forged block, as is disclosed in EP 3 312 341 B1. However, the corresponding wing rail sections are intended for frogs with a fixed frog tip. There are no problems with respect to the forming of openings as passage way for actuating elements or with respect to dimensioning the frog tip, in order to achieve an adequate strength in particular under high dynamic loads.
According to the invention, the frog design with each respective wing rail comprising a section that consists of a forged block and is arranged within the wheel transfer zone between the wing rail and the frog tip, whereby each block is produced separately, i.e. with respect to the frog tip is a separate component, can in particular be installed in a track, in which high dynamic axle loads are to be absorbed, i.e. tracks that are intended for vehicle speeds of 250 km/h and higher. Typical dynamic axle loads range between 30 t and 40 t. The value of the dynamic axle load is calculated from the static axle load multiplied by a speed-dependent factor. E.g., for a velocity of 250 km/h this factor is 1.675 and for a velocity of 350 km/h the factor is 1.79.
Further details, advantages, and features of the invention are not only detailed in the claims, the characteristic features disclosed therein—individually and/or in combination—but also in the following description of preferred embodiment examples shown in the figures.
The figures show:
In the following, the invention's teaching about a frog with movable frog tip will be explained with the help of the figures, whereby in general the same reference labels are used for identical components.
The frog 10 is a frog with a resiliently movable frog tip 12, which is adjustably mounted on slide plates 14 between wing rails 16, 18. In this, in accordance with the invention's teaching, the wing rails 16, 18, in the wheel transfer zone between the frog tip 12 and the wing rails 16, 18 comprise a section 20, 22 of a length L that respectively has been produced from a forged steel block by metal cutting processing. The length of the section 20, 22 may for example be between 1500 mm and 12000 mm, without this placing any restriction on the teaching of the invention. In
In front and behind section 20,22 the sections are connected to standard rails in particular by flash butt welding.
The forged block is produced from steel with a tensile strength Rm with 1175 MPa≤Rm≤1500 MPa, an elongation at break A with 9%≤A≤12% and a hardness HBW with 350 HB≤HBW≤500 HB. Chromium bainitic steel is mentioned as an example. The Brinell hardness HBW is measured with a ball diameter of d=2.5 mm, a test load of F=1.839 kN, and an exposure time of 10 s-15 s.
From the same material may be manufactured the frog tip 12, which via railway switch drives is selectively brought into contact with one of the sections 20, 22, so that the railway switch directs to the desired track. Just like the frog tip 12, the sections 20, 22 are produced by metal cutting processes from a forged block, also referred to as a slab. In particular milling should be mentioned.
The sectional view A-A in
The form-fitting element 37 serves as a position aid, as a bolt stress relief, and to absorb rail longitudinal loads.
Each of the sections 20, 22 possesses a foot section 42, 44, which are secured via tension clamps 48, 50 on a ribbed base plate 46 or another suitable support. An elastic interlayer 52 may be arranged between the foot 42, 44 and the ribbed base plate 46. In this regard we refer to designs known in the art. The rest of the graphic representations are self-explanatory in this regard.
The section A-A is located at a distance from the frog tip 12, in particular in front of it. A sectional view C-C in the area of the frog tip 12 is shown in
As is the case in standard designs, the head 62, 64 is connected to the foot 42, 44 via a web 66, 68.
The sectional view C-C also shows by a dot-dash line the profile 70, 72 of a standard rail, such as e.g. a 60E1 profile (previously UEC 60), from which normally the wing rails of a frog region are produced by folding and bending.
As is evident in the graphic representation, the distance between the inner faces 74, 76 of the webs 66, 68 of the sections 20, 22 facing each other is greater than that of standard rails, so that as a result more space is available for the frog tip 12, which in turn allows the width B of the base body 54 to be embodied larger than in frogs for which the wing rails are entirely produced from standard rails.
The width B of the base body 54 may be 50% greater than the width of the base body of frog tips that extend between wing rails produced from standard rails. In particular, the width B of the base body 54 in the front tip region, i.e. in the region where the frog tip 12 first comes into contact with the flank 58 or 60, is greater than 60 mm, preferably greater than 70 mm, and particularly preferably is in the range between 75 mm and 85 mm.
Since the wing rail sections 20, 22 are machined out of a steel block, cross-sectional areas are greater than those of standard rails, as is illustrated in
Irrespective of the increased distance between the inner faces 74, 76 of the wing rail sections 20, 22, these possess sufficient mass to bear the dynamic loads that are exerted by the trains traversing the railway switch, because according to the invention one uses as starting material for the sections 20, 22 a block that possesses correspondingly large dimensions, in order to produce the sections 20, 22 by metal cutting processes.
The corresponding blocks may each possess a cross-sectional area of 16000 mm2 to 40000 mm2, whereby in particular a cuboid shape with a height H between 160 mm and 200 mm and a width B between 100 mm and 200 mm should be mentioned. The length is dependent on that of the section 20, 22 to be embodied, i.e. in particular between 1.2 m and 15 m.
As material for the section are used steels with a tensile strength Rm with 1175 MPa≤Rm≤1500 MPa, an elongation at break A with 9%≤A≤12% and a Brinell hardness HBW with 350 HB≤HBW≤480 HB. Chromium bainitic steel is mentioned as an example. The Brinell hardness HBW is measured with a ball diameter of d=2.5 mm, a test load of F=1.839 kN, and an exposure time of 10 s-15 s.
In this, the machining can be performed in such a manner that the area moments of inertia vertical to the longitudinal axis of the sections 20, 22 along the entire length are equal or substantially equal, but at least in the region where the frog tip 12 is in contact with the sections 20, 22, i.e. at the flanks 58, 60, or differ from each other by a maximum of 20%, preferably by a maximum of 10%.
As examples shall be mentioned area moments of inertia ly between 200 cm4 and 1130 cm4 and lx between 1700 cm4 and 5300 cm4 for a cross-sectional area in the range between 6500 mm2 and 15000 mm2. In the computation of the area moment of inertia ly the force onto the section 20, 22 is exerted laterally, i.e. from the direction of the flank and in the computation of the area moment of inertia lx the force acts upon the section 20, 22 in the direction of the head surface 57. Computations are done by software.
According to the invention it is intended in this regard, that in those areas in which during their construction (cant, recessed region or passage openings for rods) material has accumulated or been removed, equivalent material masses will be removed or remain in excess in other areas, as will be explained in the following.
Because the sections 20, 22 have been machined from a block, it is possible to achieve, in particular by milling, an optimal geometry with high precision and very small tolerances in the wheel transfer zone, such as in particular a cant of the running surface or milled cutouts to accommodate the frog tip, in order to in particular allow a small deviation of the basic track trajectory between the running edge of the wing rail section 20, 22 and the running edge of the frog tip 12 that follows the basic track trajectory, as is illustrated with the help of
In this region, in which the frog tip 12 at its upper surface, i.e. the area where extends the crest, the frog tip 12 is embodied plateau-like and possesses a width H that at the beginning of the tip, i.e. the functional frog tip, is in a range between 8 mm and 12 mm. The width is facilitated because of a milled cutout 80 extending in the flank 60, so that the running edge 82 in its foremost region 84 is offset inwards relative to the running edge 85 of the section 22, which defines the basic track trajectory. In this recessed region, which has been produced by the milled cutout 80, is positioned and consequently protected the point 112 of the frog tip 12. After a length E, the running edge 82 extends in extension of the running edge 85 of the section 22, as in the basic track trajectory. The length E may be between 80 mm and 150 mm, in particular around 100 mm. Where the running edge transitions into the basic track trajectory course, it possesses a quasi fold.
It is evident that in front of the point 112 of the frog tip 12 a space 86 is present in the milled cutout 80. This space 86 is necessary, so that during a thermal expansion the frog tip 112 remains in the milled slot.
The fact that the frog tip 12 at its head end, in its front rideable area, extends in a plateau-like manner is also shown in
In
The angle α of the flank 58 or 61 relative to the vertical (line 63) is between 10° and 20°.
The width H of the frog tip 12 is the width of the head surface and is defined by extending the right and the left flank 58, 61 up to the level of the running edge 157. The running edge is that particular line along the longitudinal direction of the frog tip 12, which, for example in accordance with the standards of Deutsche Bahn AG, extends 14 mm below the crest of the head surface.
It is evident from the graphic representation that the width of the tip body 56 increases starting from the beginning of the tip, as is evident when comparing the contours 65, 67, 69. Contour 69 corresponds to the cross section of the frog tip 12 in the area, in which the running edge of the frog tip 12 or 56 corresponds to the basic track trajectory of the running edge, i.e. the one of section 22. The equivalent applies for section 20.
The mass of the material removed by milling is subsequently left in excess on the opposite side of section 22, which results in a slight change of geometry of the section 22 compared to its basic track trajectory, so that after the fact, irrespectively of the milled cutout 80, the area moment of inertia remains the same.
The same approach is followed with respect to the usually present elevation, which in accordance with the state of the art is embodied by relining and bending of the wing rail.
In contrast, the invention intends that the cant of the section 22, and consequently also of section 24, is produced from the block by milling, in order to avoid a lowering of a wheel during the crossing of the transition. A related elevation is shown in
Corresponding to the excess material present in the area of the cant, i.e. its mass, material is removed in an adjacent area in the section 22, so that in cross-sectional areas the masses present are equal to those in adjacent areas, consequently resulting in equal area moments of inertia.
The sectional view S-S (
Since the webs 66, 68 of sections 20, 22 are relatively thick in comparison to the ones of standard rails, there is no need for a reworking of the bores 96, 98 e.g. in their edge regions, in order to achieve the necessary strength. Furthermore, the mass that is removed from the bores 96, 98, in general is also compensated for by material in excess protrusions in the sections 20, 22, so that in principle equal area moments of inertia are created, even though in the immediate cut area of the bores 96, 98 these may be smaller than in the adjacent areas, without this violating the invention's teaching.
A corresponding excess protrusion is shown in
The sectional view B-B in
A corresponding distance block originates from section 22, which also possesses a cutout corresponding to the cutout 106, which merges flushly with the cutout 106. In the thusly creates space, the nose 104 is movable during a move of the frog tip 12, which ensures that the frog tip 12 can not be unduly lifted, since the vertical movement of the nose 106 is limited by the section 110 that borders the cutout 106 at the head side.
In this, the dimensions of the nose 104 and of the cutout 106 are matched to each other in a way that substantially facilitates a frictionless adjustment of the frog tip 12.
The sections 20, 22 are connected by high-strength bolts via the distance blocks 108. Illustrated in
The wheel transfer zone, in which the wheel load substantially is dissipated equally by both the frog tip 12 and the section 22 or 20, is at a distance LU from the functional frog tip 112, preferably with 200 mm≤LU≤3,000 mm. Because of the deflection of section 22 or the frog tip 12, the wheel transfer zone 123 is not a single point but rather a region. In this region the head surface of the frog tip 12 possesses a width of approximately 30 mm to 55 mm.
Also illustrated is the length LT of the section 20, 22, in which the prevailing area moment of inertia is equal or substantially equal. The length LT ranges between 250 mm and 9,000 mm and extends between the functional frog tip 112 to the region, in which the frog tip 12 detaches from the section 20 or 22, i.e. is spaced apart from the latter. In
The section 20, 22 extends beyond this point (distance LS), preferably for two more sleeper spacings. The distance LS preferably is between 600 mm and 1,200 mm.
Furthermore,
The invention is characterized by a frog 10, comprising rail wings 16, 18 that possess at least a rail head 62, 64 and a rail web 66, 68, as well as comprising a frog tip 12 arranged adjustably between the wing rails, whereby in the area of the frog tip extends a wheel transfer zone between the frog tip and the wing rail, whereby the wing rails are connected to each other detachably and each wing rail comprises a separate wing rail section that extends from the frog tip along at least the length of the wheel transfer zone, and is produced from a forged block or consists of such.
The frog is characterized in that the area moments of inertia lx, ly in cross-sections extending vertical to the longitudinal axis of the wing rail sections, at least in the region of the contact surface of the frog tip to the wing rail section, are equal or substantially equal and differ by a maximum of ±20%, in particular by a maximum of ±10%.
The invention is further characterized in that corresponding to the mass of material in a wing rail section's 20, 22 area that is the result of change of the geometry deviating from the basic geometry of the wing rail section, an equivalent material mass is removed or remains in excess in the area of the change of geometry, in order to achieve an equal or substantially equal area moment of inertia.
The invention also is characterized in that the contact surface between the tip area of the frog tip 12 to the wing rail section 20, 22 is a section of a region 80 extending recessed relative to the wing rail section's running edge, such as a milled cutout, in the flank 60 of the wing rail section, whereby preferably, corresponding to the mass of the material removed to form the recessed area 80, excess material is to remain on the wing rail section, in particular on the side of the wing rail section 20, 22 facing away from the frog tip.
The frog according to this invention is characterized in that the running edge trajectory of the frog tip 12, which originates at a distance E from the functional frog tip 112, transitions into the basic track trajectory defined by the running edge of the section 20, 22 with 80 mm≤E≤150 mm.
A frog with an anti derail-device originating from the wing rail 16, 18, in which a frog tip 12 is adjustably arranged in the foremost region 10, is characterized in that the anti-derail device is integrally machined out of the block.
The frog is further characterized in that the anti-derail device is embodied in one piece in the first distance blocks 108, via which the wing rail sections 20, 22 are connected and supported against each other.
The invention is also characterized by distance blocks 108 that are machined from the blocks as one piece together with the wing rail sections 20, 22, each of which possesses a cutout 106, whereby in the assembled wing rail sections the cutouts merge to form an open chamber, in which the foremost area 104 of the frog tip 12 is adjustably arranged.
The frog according to the invention is also characterized in that the frog tip 12 comprises an in particular cuboid base body (54) with, originating from the latter, a tip body 56 with a triangular cross-section, and in that the width B of the base body B is B>60 mm, in particular B>70 mm, preferably 75 mm≤B≤85 mm.
The frog tip with at least one passage opening for a rod element 100, 102, such as a locking rod or detector rods, that is embodied in the web 66, 68 of the wing rail 16, 18, is characterized in that the web 66, 68 of the wing rail section 20, 22 in at least the area of the passage opening 96, 98 possesses a thickness D with D>30 mm, in particular D>40 mm, particularly preferred 40 mm≤D≤60 mm, very particularly preferred 45 mm≤D≤50 mm.
The frog is further characterized in that between the frog tip 12 and the wing rail section 20, 22 is located a transition region, in which a cant is produced from the block by metal cutting processes.
The frog is also characterized in that outside of the frog tip 12, the wing rail sections 20, 22 are supported against each other via second distance blocks 32, 34 that are machined from the block in one piece with the wing rails.
The invention is further characterized in that the wing rail section 20, 22 is machined from the block in a manner so that in regions in which the geometry of the wing rail section deviates from its basic geometry, such as a cant or the region 80 recessed relative to running edge 85, corresponding to the mass of material that results from the change of the geometry course, an equivalent amount of material mass in an adjacent area in the wing rail section is removed or remains in excess relative to the basic geometry.
Furthermore, the invention is also characterized by a method for producing wing rails 16,18 for a frog 10 with a movable frog tip 12, in which at least one section 20, 22 of each wing rail 16, 18 is produced from a forged steel block by metal cutting processing, whereby a cant of the running surface is integrated by machining in a region where the frog tip 12 is in contact with the wing rail section 20, 22.
The invention's method is characterized in that together with the wing rail section 20, 22 an anti-derail device for the frog tip 12 is machined from the block in one piece.
Also, the method according to this invention is characterized in that in the flank 58, 60 of the wing rail section 20, 22 extending on the frog-tip side is machined from the block a region 80 that is recessed relative to the basic track trajectory of the running edge 85 and possesses a contact surface for the frog tip 12, 112.
The invention's method is further characterized in that the wing rail section 20, 22 is machined from the block in such a fashion that regions where the geometry of the wing rail section deviates from its basic geometry, such as the cant or the region 80 recessed relative to the running edge 85, corresponding to the mass of material that results from the change of geometry course, material mass in an adjacent area in the wing rail section is removed or remains in excess relative to the basic geometry, so that the moment of inertia of the wing rail section remains unchanged or substantially unchanged.
The invention's method is also characterized in that the wing rail section 20, 22 is machined from the block in such a manner that the area moments of inertia in cross sections extending vertical to the longitudinal axis of the wing rail section at least in the area of the contact surface of the frog tip
12 to the wing rail section are equal or substantially equal, and differ from each other by a maximum of ±20%, in particular a maximum of ±10%.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2021 106 050.8 | Mar 2021 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2022/053769 | 2/16/2022 | WO |
