WO2024156374A1 - Bogie pin between bogie and wagon underframe of a rail vehicle - Google Patents

Abstract

A bogie pin (1) for a flexible coupling of a bogie (16) to a wagon underframe (15) of a rail vehicle is described. The bogie pin (1) comprises two mutually oppositely arranged, flat rib structures (5) which each have a foot portion (5a) and a shaft portion (5b), a prism-shaped solid structure (22), which is arranged between the two shaft portions (5b) of the two flat rib structures (5) and is connected fixedly thereto, and a connecting rib (21), which is arranged between the two foot portions (5a) of the two rib structures (5) and is fixedly connected to the two flat rib structures (5) and the prism-shaped solid structure (22). A chassis (14) for a rail vehicle is also described. A rail vehicle is additionally described. In addition, the invention describes a method for producing a bogie pin (1).

Description

Description

Pivot between bogie and wagon substructure of a rail vehicle

The invention relates to a pivot pin for a flexible coupling of a bogie to a carriage substructure of a rail vehicle. The invention also relates to a chassis for a rail vehicle. In addition, the invention relates to a rail vehicle. In addition, the invention relates to a method for producing a pivot pin for a flexible coupling of a bogie to a carriage substructure of a rail vehicle.

Rail vehicles have a chassis with bogies for traction and directional control. Wheels are mounted on the bogies and are in contact with the rails. The bogies are also connected to the undercarriage of the rail vehicle in question by a pivot pin via a longitudinally positive connection.

This design for the form fit between the bogie and the car substructure has previously been achieved either by using complex cast parts with subsequent mechanical finishing or by using welded constructions. The limiting factor in the design of the pivot pins has so far been the internal material defects in the cast part or the stresses in the weld seam of such a pivot pin.

A typical arrangement of a conventional cast pivot pin is shown in FIG 1 . Cast pivot pins are usually homogeneous one-piece components which contain both the geometry for the required form fit to the bogie and the connection geometry to the car body. The pivot pins are usually machined afterwards. The design shown in FIG 1 is very complex due to the manufacturing process and must be closely coordinated with the supplier in order to reduce the risk of internal defects or cavities in the component. The supplier must be closely involved in the design of the pivot pin at an early stage. Their feedback regarding manufacturability and manufacturing aspects have a decisive influence on the design of the pivot pin. A later change of supplier with the existing design is probably not possible without further ado. This results in a high level of dependency on the supplier. Furthermore, for this type of production, long lead times for the creation of models for the casting molds must be taken into account. The use of high-strength materials is also only possible to a limited extent due to the casting process.

FIG 2 shows a conventional arrangement of a welded pivot pin. Welded pivot pins consist of a cylindrical or rectangular body through which the force is introduced into the ribs of the pivot pin and into the structure of the underframe or car body. The material connection to the ribs is made by dimensioned weld seams. Since the force flows through the weld seams, the stress state of the weld seams is high and requires increased testing of the weld seams. A crack test must therefore be carried out on the weld seams as part of maintenance. Due to the variety of materials and sheets and their good availability, the welded construction offers a higher degree of flexibility in the design, particularly with regard to high-strength materials.

The aim is therefore to provide a pivot pin for a rail vehicle which is easier to manufacture and maintain and which provides improved traction between the bogie and the undercarriage of a rail vehicle.

This object is achieved by a pivot pin for a flexible coupling of a bogie with a carriage substructure of a rail vehicle according to patent claim 1, a chassis for a rail vehicle according to patent claim 12, a rail vehicle according to patent claim 13 and a method for Manufacturing a pivot pin for a flexible coupling of a bogie with a wagon substructure of a rail vehicle according to patent claim 14.

The pivot pin according to the invention for a flexible coupling of a bogie to a wagon substructure of a rail vehicle has two flat rib structures arranged opposite one another. The two flat rib structures each have a foot section and a shaft section. The wagon substructure forms the supporting structure of a rail vehicle or of a housing of a rail vehicle and, in the case of a self-supporting construction of a rail vehicle, can comprise the lower section of a wagon body of a rail vehicle facing the ground. Alternatively, in the case of a frame construction of a rail vehicle, the wagon substructure can also comprise the frame or the undercarriage. A bogie is understood to be a running gear of a rail vehicle in which wheel sets are mounted in a frame or chassis that can rotate relative to the wagon substructure of the rail vehicle. A positive connection between a wagon substructure and a bogie is to be understood as a connection that is positive at least in the longitudinal and transverse directions, by which a detachment of the bogie from the wagon substructure by a force in the longitudinal and transverse directions, preferably also in the vertical direction, is prevented and by which a force can be transmitted between the bogie and the wagon substructure. The positive connection is quite flexible, so that the bogie can easily rotate relative to the wagon substructure.

A rib structure is understood to be a plate-shaped structure that makes another component more stable against deformation. It is arranged perpendicularly or at an angle significantly different from 0° to the component to be stabilized. A rib structure is referred to as "flat" if its extension in space can be assigned to a two-dimensional or three-dimensional surface. which is encompassed by the rib structure and which essentially defines its course and extent. The extent of the rib structure perpendicular to this surface is small compared to its surface extent. In colloquial terms, the rib structure is therefore "thin" in the normal direction to the surface if one compares the extent of the rib structure in the normal direction with the extent of the rib structure in the surface direction, i.e. in a direction that is oriented tangentially to the surface.

In this context, a foot section is understood to mean a section of the rib structures that forms the base of a rib structure. In this context, a base is understood to mean a section of a rib structure that is designed to be firmly connected to the wagon substructure. A shaft section is understood to mean a section of a rib structure that forms a type of vertical axis that has the function of forming a positive connection with a bogie and around which the bogie can be flexibly pivoted at an angle of a few degrees.

The stiffness of the rib structures in the longitudinal direction of the rail vehicle can be influenced by the course of the contours of the rib structures. Preferably, the base-shaft structure of the rib structure results in a shape of the pivot pin that widens towards the base section. The widening shape of the pivot pin serves to transmit forces that are introduced in the base section into the pivot pin and via the pivot pin into the carriage substructure of a rail vehicle. The pivot pin has sufficient stability to transmit these forces.

The pivot pin also has a prism-shaped solid structure which is arranged between the shaft sections of the two opposing rib structures and is firmly connected to the two opposing rib structures. Furthermore, the pivot pin comprises one or more connecting ribs which are arranged between the foot sections of the two opposing rib structures and are firmly connected to the two opposing rib structures and the prism-shaped solid structure. The pivot pin thus obtains its stability through the stabilization structures arranged between the flat rib structures, in particular through the prism-shaped solid structure and the one or more connecting ribs.

Advantageously, the flow of force between a bogie and the rib structures no longer occurs via a weld seam, so that a potential fracture point is eliminated. Advantageously, the quality of the existing connecting structures, for example weld seams, can be graded, thus reducing the effort required for testing and quality assurance. Furthermore, no additional welded part, such as a bracket or a bolt, is required to introduce the force. The effort required for mechanical processing is thus reduced.

The running gear according to the invention for a rail vehicle has a wagon substructure, a bogie and a pivot pin according to the invention for connecting the wagon substructure to the bogie. The running gear according to the invention has the advantages of the pivot pin according to the invention, in particular with regard to stability, manufacturing effort and ease of maintenance.

The rail vehicle according to the invention has a chassis according to the invention. The rail vehicle according to the invention shares the advantages of the chassis according to the invention.

In the method according to the invention for producing a pivot pin for a flexible coupling of a bogie with a carriage substructure of a rail vehicle, formed rib structures with a foot section and a shaft section are produced. The two rib structures are then arranged opposite each other. Furthermore, a prism-shaped solid structure is formed. The prism-shaped solid structure is arranged between the two shaft sections of the two opposing rib structures and firmly connected to the two opposing rib structures. To stabilize the two rib structures in the transverse direction, a connecting rib is arranged between the two foot sections of the two opposing rib structures. Several connecting ribs can also be used for stabilization in order to further increase the stability of the overall structure. The connecting rib is firmly connected to the two opposing rib structures and the prism-shaped solid structure.

The method according to the invention has the particular advantage of simplified production with lower requirements for mechanical processing and lower quality requirements as regards the production of the connection points between individual components. The production time is advantageously shortened and the expenditure on specialized personnel for production is reduced.

The dependent claims and the following description each contain particularly advantageous embodiments and developments of the invention. In particular, the claims of one claim category can also be developed analogously to the dependent claims of another claim category and their description parts. In addition, within the scope of the invention, the various features of different embodiments and claims can also be combined to form new embodiments.

In one embodiment of the pivot pin according to the invention, the rib structures are designed such that they extend in their surface from their foot section to their shaft section The base is advantageously made wider so that the connection to the car substructure can be particularly stable and extensive. This stable connection also has the advantage of being able to absorb leverage forces that act from the bogie via the shaft section onto the foot section particularly well.

The foot section of a respective rib structure is preferably dimensioned to be broad in its surface area. The rib structure is aligned such that its narrow side is visible from a frontal view, a top view or a view from below, but not from a side view. The surface side of the rib structure, on the other hand, is essentially visible from a side view. The foot section should now be broad in the longitudinal direction so that it can withstand a force in the longitudinal direction particularly well. The shaft section of a respective rib structure is also preferably dimensioned to be narrow in its surface area. The shaft section should now be less wide or even relatively narrow in the longitudinal direction compared to the extent of the foot section in this direction. The shaft section forms the head region of the pivot pin, which engages in a receptacle in the bogie.

The flat rib structures are preferably T-shaped or Y-shaped, with the "stem" being formed by the shaft section and the "beam" or "fork" being formed by the foot section. This special shape advantageously creates a stable base for attachment to the car substructure and an axial shaft section is formed around which the bogie can rotate.

The foot section is preferably designed to be firmly connected to the carriage substructure and the shaft section is preferably designed to form a positive connection with the bogie in the longitudinal direction and/or transverse direction. This particularly robust The type of fastening of the pivot pin to the wagon substructure creates the conditions for a force acting on the bogie in the longitudinal or transverse direction to be transmitted via the foot section to the wagon substructure and thus the rail vehicle can be moved in different directions.

The foot section of the pivot pin according to the invention is preferably designed so that the connection between the pivot pin and the car substructure is materially bonded. The strength of the connection between the pivot pin and the car substructure is advantageously improved by the materially bonded connection. To create a material bond, a connecting material is introduced between a contact surface of the foot section and a contact surface of the car substructure. Furthermore, the contact surfaces are preferably pretreated accordingly in order to achieve particularly good contact between the connecting material and the contact surfaces.

The pivot pin is also preferably designed so that the connection between the pivot pin and the car substructure is positively locked. In the case of a positive lock, the contact surfaces of the substructure and the base section of the pivot pin are structured in such a way that they interlock and offer mechanical resistance to a relative movement of the pivot pin with respect to the car substructure in at least one direction. The strength of the connection between the base section of the pivot pin and the underside of the car substructure is advantageously increased by the positive lock.

Preferably, the material-locking connection between the pivot pin according to the invention and the car substructure is a welded connection. Such a welded connection allows a particularly strong connection between the underside of the car substructure and the pivot pin.

Alternatively, the pivot pin according to the invention is designed so that the material connection is an adhesive connection. The bonding advantageously creates a firm, material-locking connection between the pivot pin and the underside of the substructure.

In a preferred variant of the pivot pin according to the invention, the connecting rib is trapezoidal in shape. The two flat rib structures thus form a type of blunt wedge structure, whereby the contact surface of the pivot pin on the underside of the carriage substructure is slightly larger than the surface of the tip or the outer end of the shaft section and the stability in the foot section is further increased. This facilitates the introduction of force at the outer end of the shaft section and its transmission in the direction of the carriage substructure and promotes the stability of the pivot pin in the transverse direction.

Preferably, the trapezoidal connecting rib is designed by its trapezoidal shape to define the distance between the flat rib structures, such that the distance between the rib structures increases from the shaft sections to the foot sections of the rib structures. The aforementioned advantageous blunt wedge shape of the pivot pin is advantageously achieved.

The pivot pin according to the invention preferably has a contact plate which is arranged in the front direction perpendicular to the rib structures on the edges of their shaft sections in front of the prism-shaped solid structure. The contact plate advantageously absorbs wear forces due to tensile forces or acceleration forces and movements of the bogie and prevents wear of the surface, in particular the paintwork of the pivot pin.

The pivot pin according to the invention preferably has a contact plate on the rear side of the pivot pin or the prism-shaped solid structure of the pivot pin, which is opposite the front side. Wear forces due to braking forces or... Deceleration forces and movements of the bogie are absorbed and wear of the surface, in particular the paintwork of the pivot, is prevented.

The pivot pin according to the invention preferably comprises two contact plates, a contact plate on the front of the pivot pin and a contact plate on the back of the pivot pin. Wear effects caused by forces acting on the pivot pin in both longitudinal directions are advantageously reduced. The contact plate transmits the longitudinal forces of the chassis to the pivot pin. The contact plate forms the contact surface with the bogie. The pivot pin is preferably painted except in the area of the contact plates. The movements of the bogie advantageously result in stress on the hard wear plate and not on the susceptible paint layer of the pivot pin, so that the surface of the pivot pin itself is protected.

The pivot pin according to the invention preferably comprises one or more weldable metallic materials. Alternatively, non-metallic materials, in particular CFRP or GFRP materials, can also be used, wherein the components are preferably bonded to one another by means of adhesive processes.

If the components are made of metal, conventional methods for mechanical sheet metal processing, preferably cutting, milling or drilling, can be used to produce the individual components of the pivot pin according to the invention.

On the bogie side, rubber-metal elements or rubber-spring elements are preferably designed at the respective contact points to the pivot pin (longitudinal and/or transverse) to cushion longitudinal and transverse forces.

The main function of the pivot pin is to absorb the longitudinal forces. Therefore, preferably in front of and behind the pivot pin Rubber-metal spring elements with plastic wear or contact plate. The absorption of transverse forces at the pivot pin is optional; these forces can also be introduced at other points in the undercarriage or the vehicle substructure using brackets.

Preferably, the connection between the connecting rib and the rib structures of the pivot pin according to the invention is materially bonded, in particular a welded connection. Alternatively or additionally, it can be realized by an adhesive connection or also in a form-fitting manner, for example by riveting folds or by screwing.

The connection of the prism-shaped solid structure with the rib structures and/or with the connecting rib(s) can also be materially bonded and/or form-fitting.

The contact plate is preferably connected to the ribs and/or the solid structure via a welded joint. A welded joint requires less maintenance and is more stable than screw or riveted joints.

The invention is explained in more detail below with reference to the accompanying figures using exemplary embodiments. They show:

FIG 1 is a schematic representation of a chassis and its connection to the undercarriage of a rail vehicle,

FIG 2 shows a detailed representation of a conventional pivot pin in a receiving area of a bogie of a chassis of a rail vehicle,

FIG 3 is a schematic representation of a conventional cast pivot pin, FIG 4 is a schematic representation of a conventional welded pivot pin,

FIG 5 is a schematic representation of a pivot pin according to an embodiment of the invention,

FIG 6 is a view of the pivot pin shown in FIG 5 in a state mounted on the underside of a car body,

FIG 7 is a flow chart illustrating a method for producing a pivot pin according to an embodiment of the invention.

FIG. 1 shows a schematic representation 14 of a chassis with a chassis 16 or bogie, which is mounted on a car body 15 by means of a pivot 1 or forms a positive connection with the pivot 1 of the car body 15. The chassis 16 has a receiving area 18 in the middle, which has a plurality of rubber spring elements 19 at its lower end. The car body 15, which is shown in FIG. 1 in the upper section of the pictorial representation 14, has the pivot 1 already mentioned in the middle. This pivot 1 engages in the receiving area 18 of the chassis 16. The pivot 1 has a tapered pivot end 4, which is arranged between the rubber spring elements 19. A lifting protection 20 is passed through the head area of the pivot end 4.

FIG 2 shows a detailed representation 17 of a pivot pin 1 in a receiving area 18 of a bogie 16. The lower pivot end 4 is secured against displacement in the vertical direction by a lifting protection device 20. Furthermore, bushings with rubber spring elements 19 are arranged between the pivot end 4 and the bogie 16. The rubber spring elements 19 dampen shocks in the longitudinal and transverse directions and allow rotation of the bogie 16 relative to the pivot pin 1. FIG 3 shows a perspective view of a conventional one-piece cast pivot pin 1. The cast pivot pin 1 consists of a base body 2 on which four ribs 5 are arranged in pairs facing each other. The ribs 5 are flat and planar and are bordered by side edges 7, 8 and are integrally connected to the base body 2. The ribs 5 form the connection elements to the car body (not shown). In this special case, the lower pin end 4 is cuboid-shaped and is also integrally connected to the base body 2. After the casting process, the pivot pin 1 is mechanically machined. The manufacture of the pivot pin 1 is very complex due to the manufacturing process and must be closely coordinated with the supplier in order to reduce the risk of internal defects or cavities in the component. This results in a high level of dependency on the supplier. For the manufacture of such a one-piece pivot pin 1, long lead times for the creation of models for the casting molds must be taken into account. As already mentioned, the use of high-strength materials is only possible to a limited extent.

FIG 4 shows a perspective view of a conventional welded pivot pin 1. The pivot pin 1 consists of a base body 2 on which four ribs 5 are arranged in pairs facing each other. The ribs 5 are flat and planar and are delimited by side edges 6, 7, 8, 9. Each rib 5 is welded to the base body 2 with a connecting side edge 6 extending in the direction of the base body's longitudinal axis 10. For example, the connecting side edge 6 adjacent to the base body 2 can be welded on both sides along its longitudinal edges 6a by means of a Y-weld seam. The base body 2 has a base body end 3 on which a pin 4 is formed. The pin 4 arranged at the base body end 3 has a front side 11 adjacent to the base body end 3 and extends along its longitudinal axis 12 to a pin head area 13. The ribs welded to the base body 2 pins 5 rest with their rib ends on the front side 11 of the pin 4. To attach the pin 4 to the base body 2, the pin 4 can be welded to the base body end 3 and/or to the rib ends in the area of the side edges 9, for example by means of a Y-weld seam in the area of the longitudinal edges 9a, 9b of the side edge 9 and in sections along the bevelled edge 3a around the base body end 3. The pin 4 has a round cross-section, whereby this means the cross-section running normal to the longitudinal axis 12 of the pin 4. A pin 4 with a round cross-section can be produced by producing the pin 4 from a rod using a turning process. The cross-section of the pin 4 increases in the direction of the base body 2. Together with the arched contour of the ribs 5, which is caused by the arched contour side edge 8 of the ribs 5, this results in an overall shape of the pivot pin 1 that widens out from the head region 13 of the pin 4. The stiffness of the ribs 5 can be adjusted via the course of the contour side edges 8. The widening shape of the pivot pin 1 serves to transmit forces which are introduced in the head region 13 into the pivot pin 1 and via the pivot pin 1 into an element resting on the support side edges 7 (not shown), for example a car body of a rail vehicle. To transmit these forces, the pivot pin 1 welded together at the side edges 6 has sufficient stability. The ribs 5 and the base body 2 are manufactured separately from one another, but welded together.

FIG. 5 shows a pivot pin 1 according to an embodiment of the invention. The pivot pin 1 has two ribs 5 arranged in pairs, which perform both fastening functions on the car body 15 (see FIG. 6) and enable positive locking in the direction of travel with the bogie. For this purpose, the ribs are T-shaped or Y-shaped, with the beam of the T or the filled fork of the Y performing the fastening function on the car body 15. and thus forms the foot section 5a of a rib 5 and the stem of the T or Y enables the form-fitting connection with the bogie in the direction of travel and the transverse direction and thus forms the shaft section 5b of a rib 5. The two ribs 5 are aligned with their surface sides 5d in the longitudinal direction. The edge surfaces 5c of the ribs 5 are aligned perpendicular to the longitudinal direction. A connecting rib 21 is formed between the ribs 5 arranged in pairs, which distances the two ribs 5 from one another. The connecting rib 21 has a trapezoidal surface when viewed in the front direction, with the shorter roof side of the trapezoidal surface being aligned towards the shaft section 5b or the stem of the T or Y and the base side of the trapezoidal surface being aligned towards the foot section 5a or beam of the T or the upper end of the fork of the Y. The ribs 5 are therefore inclined towards each other in the direction of the shaft section 5b. A block-like or approximately prism-shaped solid structure 22 is arranged between the ribs 5 at the end of the shaft section 5b. A contact plate 23 is arranged in front of the front and rear of the solid structure 22, with which force effects of the bogie (not shown) on the pivot pin 1 are absorbed in the longitudinal direction and wear effects due to relative movements of the bogie to the pivot pin 1 are absorbed.

In FIG 6, the pivot pin 1 shown in FIG 5 is shown mounted on the underside of a car body 15. The ribs 5 of the pivot pin 1 serve both to introduce the load at the pivot point of the bogie (not shown) and to attach the pivot pin 1 to the car body 15. A possible lifting protection can be integrated via a bolt or similar if required at the narrow end, i.e. at the lower end of the pivot pin 1.

FIG 7 shows a flow chart 700 which illustrates a method for producing a pivot pin for a flexible coupling of a bogie to a carriage substructure of a rail vehicle. according to an embodiment of the invention.

In step 7.1, two rib structures 5 which are T-shaped in the longitudinal direction and each have a foot section 5a which is wide in the longitudinal direction and a shaft section 5b which is narrow in the longitudinal direction are produced.

In step 7 . I I , a prism-shaped solid structure 22 is arranged between the two shaft sections 5b of the ribs 5 in such a way that the prism-shaped solid structure 22 is firmly connected to the two shaft sections 5b of the ribs 5 .

In step 7 . I I I a slightly trapezoidal connecting rib 21 is formed.

This trapezoidal connecting rib 21 is arranged in step 7.IV between the rib structures 5 in such a way that it runs in the vertical direction from the shaft section 5b to the foot section 5a of the ribs 5 and is firmly connected to the ribs 5 and the prism-shaped solid structure 22. The connecting rib 21 defines the distance between the ribs 5, which are T-shaped in the longitudinal direction, in such a way that the distance between the ribs 5 increases from the shaft section 5b to the foot section 5a.

Finally, it is pointed out once again that the methods and devices described above are merely preferred embodiments of the invention and that the invention can be varied by the person skilled in the art without departing from the scope of the invention as defined by the claims. For the sake of completeness, it is also pointed out that the use of the indefinite articles "a" or "an" does not exclude the possibility that the relevant features may be present multiple times. Likewise, the term "unit" does not exclude the possibility that this consists of several components, which may also be spatially distributed. Regardless of the grammatical gender of a particular term, persons with male, female or other gender identity are included.

Claims

Patent claims

1. Pivot pin (1) for a flexible coupling of a bogie (16) to a carriage substructure (15) of a rail vehicle, comprising:

- two flat rib structures (5) arranged opposite one another, each having a foot section (5a) and a shaft section (5b),

- a prism-shaped solid structure (22) which is arranged between the shaft sections (5b) of the two opposing rib structures (5) and is firmly connected to the two opposing rib structures (5),

- a connecting rib (21) which is arranged between the foot sections (5a) of the two opposing rib structures (5) and is firmly connected to the two opposing rib structures (5) and the prism-shaped solid structure (22).

2. Pivot pin according to claim 1, wherein the rib structures (5) taper in surface from their foot portion (5a) to their shaft portion (5b).

3. Pivot pin according to claim 1 or 2, wherein

- the foot section (5a) of a respective rib structure (5) is dimensioned to be broad and

- the shaft section (5b) of a respective rib structure (5) is narrow in area.

4. Pivot pin according to one of the preceding claims, wherein the flat rib structures (5) are T-shaped or Y-shaped.

5. Pivot pin according to one of the preceding claims, wherein the foot portion (5a) of a respective flat rib structure (5) is designed to be firmly connected to the carriage substructure (15).

6. Pivot pin according to one of the preceding claims, wherein the shaft portion (5b) of a respective flat rib structure (5) is designed to form a positive connection with the bogie (16) in the longitudinal direction.

7. Pivot pin according to one of the preceding claims, wherein the foot sections (5a) are designed so that the connection between the pivot pin (1) and the carriage substructure (15) is materially and/or positively connected.

8. Pivot pin according to claim 7, wherein the material-locking connection comprises a welded connection and/or an adhesive connection.

9. Pivot pin according to one of the preceding claims, wherein the connecting rib (21) is trapezoidal.

10. Pivot pin according to claim 9, wherein the trapezoidal connecting rib (21) is designed by its trapezoidal shape to define the distance between the flat rib structures (5) such that the distance between the flat rib structures (5) increases from the shaft sections (5b) to the foot sections (5a) of the rib structures (5).

11. Pivot pin according to one of the preceding claims, comprising a contact plate (23) which is arranged in the front direction perpendicular to the flat rib structures (5) on the edge surfaces (5c) of the shaft sections (5b) of the flat rib structures (5) in front of the prism-shaped solid structure (22).

12. Chassis (14) for a rail vehicle, comprising:

- a carriage substructure (15) ,

- a bogie (16) ,

- a pivot pin (1) according to one of the preceding claims

1 to 11 for the flexible connection of the bogie (16) with the wagon substructure (15).

13. Rail vehicle comprising a chassis (14) according to claim 12.

14. A method for producing a pivot pin (16) according to one of claims 1 to 11 for a flexible coupling of a bogie (16) to a carriage substructure (15) of a rail vehicle, comprising the steps:

- Production of two flat rib structures

(5) with a foot section (5a) and a shaft section (5b),

- arranging the flat rib structures (5) opposite one another,

- Formation of a prism-shaped solid structure (22) ,

- arranging the prism-shaped solid structure (22) between the two shaft sections (5b) of the two opposing, flat rib structures (5),

- firmly connecting the prism-shaped solid structure (22) with the two opposing, flat rib structures (5),

- Arranging a connecting rib (21) between the foot sections (5a) of the two opposing, flat rib structures (5)

- firmly connecting the connecting rib (21) to the two opposing, flat rib structures (5) and the prism-shaped solid structure (22).