WO2018141612A1 - Shaft-hub connection and method for creating a shaft-hub connection - Google Patents

Abstract

The present invention relates to a method for creating a shaft-hub connection (20) and to a shaft-hub connection, comprising a shaft (1) having a round or non-round outer diameter, wherein the method comprises at least the following steps: • a) arranging the shaft (1) in a machining system (50) to machine an exterior surface (6) of the shaft (1) at least in a seat region (4), • b) generating at least one material expansion extending at least in sections in the circumferential direction and in the axial direction in the seat region of the shaft, wherein the material expansion (5) stays the same or runs conically along the shaft longitudinal axis in the axial direction, • c) connecting the hub (10) and shaft (1) such that in the seat region (4) a press connection is created between the shaft (1) and the hub (10). The invention also relates to a machining system (50) for machining an exterior surface (6) of the shaft at least in a seat region (4) to create the shaft-hub connection (20).

Description

 Shaft-hub composite and method for generating a shaft-hub composite Description

The present invention relates to a method for producing a shaft-hub composite with a non-round outside diameter having shaft. Furthermore, the invention relates to a shaft-hub composite.

STATE OF THE ART

From DE102008064426A1 a shaft-hub connection is known, according to which a plurality of cams or a plurality of bearing rollers are mounted on a shaft. The shaft itself has on its outer periphery projecting portions which serve as abutment surfaces for the hub, which is for example a cam. The shaft is tubular. The bore of the hub, which serves to receive the shaft, has a plurality of fitting recesses, which serve to receive the projecting portions of the shaft when the hub is pushed onto the shaft. After the postpositioning of the hub, in particular of the cam, on the shaft, it is rotated about its central longitudinal axis in such a way that displacement of the hub in the longitudinal direction of the shaft is prevented due to the sections projecting from the shaft outer surface. For this purpose, a very costly and structurally complex design of the shaft, in particular the outer surface of the shaft, and also to be arranged on the shaft connecting parts or hubs, as here the cams required. Another shaft-hub connection is shown for example in WO2005 / 066522A1. Here, a shaft is processed during a rolling process such that results in a material accumulation at a desired position. After the machining process of the shaft, for example, a cam is pressed onto the shaft to the correct position. After this pressing operation of the cam on the shaft, a further processing, in particular rolling of the outer surface of the shaft, to subsequently impose the next cam. Such press connections are known with regard to the transmission of forces or moments serving in the longitudinal direction and / or in the circumferential direction of the shaft. However, such structurally designed shaft-hub connections can absorb only small torques and axial forces due to the tolerance deviations and the material properties of the material formed as accumulation. This results in the risk of loosening or twisting of the hub from the shaft when high loads occur during operation of the shaft-hub connection, for example, as a use of a camshaft. From the patent DE4218624C2 another shaft-hub connection is known, according to which a cam is provided with an opening which has an annular inner part with a shaft opening. The inner part has a 10-cornered shape with rounded corners. This inner part is arranged in the opening of the cam and serves to receive the shaft. At least one flared portion having an outer diameter greater than the outer diameter of the shaft itself is formed on the shaft. The assembled component, in particular the cam, comprising the engaging body and the annular inner member, is press-fitted to this flared portion of the shaft applied substantially under plastic deformation, thus providing, for example, a crankshaft or a gear shaft. Disadvantages also have an effect in this patent, for example, the maximum achievable coverage of the profiles of the shaft and the hub and thus the maximum achievable positive locking just like the material expansion generated during material deformation, which is also limited. This means that, for example, the head diameter of the material widening can not be increased in any desired manner. In addition, a reduction in the inner diameter of the cam is limited, since this inner diameter can not be made smaller than the outer diameter of the shaft, as otherwise the cam would dig when applied to the shaft already in the fundamental wave. Consequently, the maximum achievable coverage as well as the torques to be transmitted is limited in such configured shaft-hub connections. DISCLOSURE OF THE INVENTION

 It is therefore the object of the present invention to remedy the above-described disadvantages in a shaft-hub composite as well as in a method for producing a shaft-hub composite at least partially. In particular, it is the object of the present invention to provide a shaft-hub assembly and a method for producing a shaft-hub assembly, which enable a transmission of high axial forces and torques in a simple and cost-effective manner.

The above object is achieved by a method for producing a shaft-hub composite with the features according to claim 1 or 2 and by a shaft-hub composite with the features according to claim 9 or 10 and by a processing system with the features according to claim 18 Further features and details of the invention emerge from the subclaims, the description and the drawings. In this case, features and details that are described in connection with the method according to the invention apply independently also in connection with the shaft-hub assembly according to the invention and in each case vice versa, so that reciprocal reference is always made to the individual aspects of the invention. In addition, the shaft-hub composite according to the invention can be produced by the method according to the invention for producing a shaft-hub composite. The method for producing a shaft-hub assembly with a shaft and a hub having a through-hole for receiving the shaft comprises at least the following steps:

a) arranging the shaft in a processing system for machining an outer surface of the shaft at least in a setting region,

b) generating at least one material widening extending at least in sections in the circumferential direction and in the axial direction in the setting region of the shaft, wherein the widening of the material in the axial direction along the wavelength axis is conical,

c) connecting the hub and the shaft in such a way that a press connection, in particular a transverse press connection between the shaft and the hub, is produced in the setting region.

Alternatively, the method for producing a shaft-hub composite with a shaft having a non-round outer diameter and a hub having a through-hole for receiving the shaft has at least the following steps:

a) arranging the shaft in a processing installation for machining an outer surface of the shaft at least in a setting area,

b) generating at least one material widening (5) extending at least in sections in the circumferential direction and in the axial direction in the setting region (4) of the shaft,

c) connecting the hub and the shaft such that in the set area, a press connection between the shaft and the hub is formed.

 Here, the material expansion in the axial direction along the shaft viewed in the radial direction is consequently consistent.

Within the scope of the invention, it is conceivable that in step b) a material widening in the axial direction along the shaft longitudinal axis is produced.

The composite can be, for example, a shaft-gear composite or a composite for forming a camshaft. It is conceivable that the shaft is a solid shaft or a hollow shaft, on which the hub, in particular the cam is pressed. The shaft advantageously has an unround outer diameter, particularly advantageously a uniform non-round outer diameter. It is possible that the shaft is designed as a polygonal shaft with a plurality of edges, in particular three or more edges and consequently a plurality of corners. However, it is also conceivable that the shaft has a round outer diameter. Advantageously, the shaft is processed in a processing plant to produce a material widening. The tools used for this purpose, which are, for example, grinding tools, particularly advantageous roller burnishing tools, are advantageously evenly spaced from one another in the circumferential direction aligned or arranged the shaft. However, it is also conceivable that the processing system has only a single tool for machining the shaft, in particular when a shaft with a round outer diameter is to be processed. The tools are for machining the outer surface or surface of the shaft in at least one setting region, which is a region in which a press connection between the shaft and the hub is to be created. It is conceivable that more than one setting region, advantageously a plurality of setting regions, is produced on the shaft. Particularly advantageously, each setting region has a conical material widening extending in an axial direction of the shaft. As axial direction is understood in the context of the invention, the direction along the wavelength axis. As a material widening in the region of the setting region of the shaft, a rolling or toothing, in particular a posing of material is advantageously produced, which serves to produce a press connection, in particular a transverse press connection between the shaft and the hub, in particular in the setting region of the shaft. When using a non-round outer diameter shaft having, however, it is also conceivable that the material expansion is not conical, but consistent, that means neither rising nor descending, extending in an axial direction of the shaft. In particular, the torque transmission is advantageously already made possible when using a shaft with a non-circular outer diameter due to this non-round and increased particularly advantageous compared to a shaft with a round outer diameter. After the generation of the setting region, in particular the material expansion in the setting region of the shaft, the hub is advantageously pushed onto the shaft as far as the setting region or up to the setting region, so that a press connection is produced between the shaft and the hub. It is possible that after setting the hub on the shaft, a further setting area on the shaft is processed such that on this another material expansion is generated before another hub is pushed onto the shaft and placed on this wider setting range of the shaft. However, it is also conceivable that, in particular, a plurality of setting areas on the shaft are processed successively by generating material widenings before the hubs, such as cams or gears, are pushed onto the shaft. Here, the application of a thermal joining method method, as explained in more detail below, advantageous.

In the context of the invention, it is furthermore conceivable that, prior to step c), a passage opening running conically in the axial direction is produced for receiving the shaft in the hub. Advantageously, the hub is pushed onto the shaft such that the conically extending through opening extends substantially congruent with the conically extending material widening in the setting region of the shaft. A material widening running conically in the axial direction along the longitudinal axis of the shaft is a material widening which has an outer diameter in an end region of the setting region, in particular in a setting region end, which is greater than at the beginning of the setting region, in particular in the setting region beginning or beginning (in the axial direction considered). As a result, the conical through hole in the hub of the is formed such that in a region of a first end face of the hub, the inner diameter of the through hole is formed smaller than at a portion of the opposite (second) end face of the hub. This means that the passage opening of the hub is substantially funnel-shaped, corresponding to the conical course of material expansion in the setting region of the shaft.

Advantageously, the hub is pushed onto the shaft in such a way that when arranging the hub in the setting region of the shaft, the portion of the material widening which has a larger outer circumference interacts with the region of the passage opening of the hub, which has a larger inner diameter. Viewed in a longitudinal direction of the shaft, the material widening advantageously increases conically or funnel-shaped, wherein the hub is pushed so that increases in the same viewing direction, the inner diameter of the through hole of the hub conical or funnel-shaped or increases.

It is furthermore conceivable that structuring into a surface of a passage opening of the hub is produced temporally before step c). Accordingly, it is possible that, for example, a widening of the material, in particular a curling or also a toothing, is produced in the surface of the passage opening of the hub as structuring. This advantageously increases the connection between the hub and the shaft in the setting region of the shaft so that high axial forces and / or torques can be transmitted, for example due to an additional positive connection between the shaft and the hub. It is also possible that additionally or alternatively to the configuration of the conically extending passage opening in the hub for receiving the shaft, the structuring is formed in the surface of the passage opening.

In the context of the invention, it is conceivable that the through-opening of the hub is non-circular, in particular comparable to the geometric configuration of the outer diameter of the shaft, as a uniform out-of-round, in particular polygonal. In this case, a high torque transmission between the hub and shaft is advantageously possible.

It is also possible that after step c) a bearing element for supporting the shaft, for example in a bearing frame of a cylinder head cover, is positioned on the shaft. It is advantageously conceivable that the bearing element has a bearing ring with a circular outer diameter. To enable the bearing element to be arranged on the shaft, the bearing element also has a passage opening for receiving the shaft, which is geometrically comparable to the outside diameter of the shaft, in particular as a uniform non-circular or polygonal shape. As already stated, it is conceivable that the shaft and the hub are connected together using a thermal joining process. In this case, it is possible, for example, for the shaft to be cooled and / or the hub to be heated before the hub and the shaft are connected to one another. For this purpose, the at least one expansion of material on the at least one setting region of the shaft is advantageous.

It is further claimed a shaft-hub composite with a shaft and a through hole for receiving the shaft have hub. The shaft has at least one material widening, which runs conically in the axial direction, and has a setting region which extends at least in sections in the axial direction and in the circumferential direction of the shaft. The hub is arranged according to the invention on the setting region of the shaft and axially and / or radially pressed with the shaft.

Alternatively, the shaft-hub composite comprised at least one shaft having a non-round outer diameter and a hub having a passage opening for receiving the shaft. The shaft comprises at least one set of material having a set area, which extends at least partially in the axial direction and circumferential direction of the shaft. The hub is arranged according to the invention on the setting area of the shaft and axially compressed.

In the context of the invention, it is therefore conceivable that the shaft has a round or non-circular outer diameter. Advantageously, the shaft is a polygonal shaft having, for example, three corners and three edges or four corners and four edges. The edges or sides or stretching thus extend between the corners of the polygon, in particular polygon. The corners themselves advantageously have a rounded geometric shape. It is advantageously possible for the material widening generated in the setting region of the shaft to be a rolling or toothing or a knurl. As a result, the torque transmission is advantageously increased and prevents unwanted in the axial direction of movement of the hub along the shaft longitudinal axis on the shaft. It is within the scope of the invention conceivable that the material posing without radial increase or decrease - viewed in an axial direction - along the longitudinal axis of the shaft, or has a conical or funnel-shaped geometric shape, and is therefore formed radially increasing or decreasing. The funnel-shaped material widening can advantageously be formed on a shaft with a round or non-circular outer diameter. It is also conceivable that the material deposition extending uniformly in the radial direction may be formed on a shaft with a round or non-round outer diameter.

It is also conceivable that the passage opening of the hub extends conically in the axial direction. As already mentioned above, it is possible that the conical shape of the through hole the hub is congruent to the conical course of material expansion in the setting region of the shaft is formed to prevent at least in an axial direction or shaft direction of the shaft displacement of the hub on the shaft after setting the hub on the setting range of the shaft. It is possible within the scope of the invention that a surface, in particular an inner surface, of the passage opening of the hub has a structuring, in particular a material widening, such as, for example, a curling or toothing. Accordingly, it is conceivable that the surface of the passage opening additionally or alternatively to the conical course of the passage opening of the hub has a structuring, wherein this structuring can be geometrically tuned to the material expansion of the shaft in the setting region. This means that for example also on the surface of the passage opening, a rolling or toothing geometrically comparable to the rolling or toothing in the setting of the shaft is used, so that a defined engagement or incision is made possible when arranging the hub on the shaft in the setting range of the shaft advantageous to significantly increase the torque transmission and axial force transmission. It is also conceivable that the passage opening of the hub is formed geometrically comparable to the geometric configuration of the outer surface of the shaft and advantageously has a comparable polygonal configuration, whereby a particularly advantageous sufficient torque transmission is ensured. In the context of the invention is further conceivable that a bearing element, in particular a bearing ring axially adjacent to the hub is positioned on the shaft such that at least one end face of the bearing element serves as a stop acting in the axial direction of the hub. It is possible that the bearing element is arranged on an end face of the hub on the shaft, in the direction - starting from the opposite end of the hub - the hub due to the outer diameter-reducing material expansion (conical tapering of material expansion) in the setting region the shaft can not absorb increased axial force. This means that the bearing ring or the bearing element is advantageously arranged on the end face of the hub on the shaft, in the region of which the passage opening has the smallest inner diameter, while the shaft has the smallest outer diameter of the material widening in the section of the setting region.

It is also possible that the shaft-hub assembly is produced by means of a method according to the preceding type.

In the shaft-hub composite according to the invention described, all the advantages which have already been described for the method according to the invention for producing a shaft-hub composite according to the first aspect of the invention result. Furthermore, a processing system for processing an outer surface of the shaft is claimed at least in a setting region for producing a shaft-hub assembly according to the aforementioned type. According to the invention, the processing plant has a number of tools which are at least a factor of one higher than the number of corners of the shaft. If the shaft used is a shaft with a round outer diameter, it is therefore conceivable for the machining system to have only a single tool which is used to machine the outer surface of the shaft to produce a structuring in a setting region of the shaft. When using a shaft with a non-circular outer diameter, in particular a polygonal shaft with, for example, three corners and three edges, the processing system has at least four tools to be aligned circumferentially around the shaft. In this case, the tools are arranged at an angle of four times 90 ° around the shaft. However, it would also be conceivable that instead of the four tools described only three tools with an angular offset of 90 ° (three times 90 °) are used, in which case the position of the fourth (missing) tool would remain unoccupied. Furthermore, it is possible that the tool or tools are designed to be displaceable in their position about the shaft, thus, advantageously, during the processing of the shaft or the outer surface of the shaft, to move around the shaft. It is also conceivable that the shaft, advantageously during its processing, is rotated about its longitudinal axis in order to be able to feed the still unprocessed areas of the outer surface to a tool. Also, an arrangement of only two tools is conceivable, which advantageously have an angular offset of 180 °.

In the context of the invention, it is conceivable that the tools are so hydraulically, pneumatically or electromechanically driven or spring-loaded mounted that exert a pendulum-balancing pressure on the shaft to be machined. As a result, a uniform machining of the outer surface of the shaft is advantageously made possible.

In the described processing plant, all the advantages that have already been described for the inventive method for producing a shaft hub composite according to the first aspect of the invention or to the inventive shaft-hub composite according to the second aspect of the invention.

Embodiments of a shaft hub assembly according to the invention and a method for its production will be explained in more detail with reference to drawings. The schematic shows:

FIG. 1 shows a side sectional view of a hub and a shaft before method step c),

FIG. 2 is a side sectional view of an embodiment of a shaft-hub assembly; 3 shows a side sectional view of an embodiment of a hub for a shaft-hub assembly according to the invention, FIG. 4 shows a lateral sectional view of a machining of the shaft for producing a shaft-hub assembly according to the invention,

Figure 5 in a sectional side view of a further embodiment of a shaft-hub composite according to the invention, and

Figure 6 shows an embodiment of a processing plant for machining a shaft for a shaft-hub composite according to the invention.

Elements with the same function and mode of operation are each provided with the same reference numerals in FIGS. 1 to 6.

FIG. 1 shows, in a lateral sectional view, a shaft 1, which forms an embodiment of a shaft-hub assembly 20 according to the invention (compare FIG. 2) with the hub 10 after arranging the hub 10 on the setting region 4 of the shaft 1. The shaft 1 is in this case designed as a hollow shaft and has a through hole 2 which extends completely along the longitudinal axis 3 through the shaft 1. The longitudinal axis 3 is advantageously also referred to as the axial axis. The shaft 1 has a setting region 4 which is designed such that a material widening 5 is formed on an outer surface 6 of the shaft 1. The material expansion 5 is generated for example by a roll.

The setting region 4 has a setting region beginning 4.1 and a setting region end 4.2, between which the material widening 5 advantageously extends conically or funnel-shaped. The material widening 5 has an outer diameter h1 in the setting region beginning 4.1 of the setting region 4, which is smaller than in the setting region end 4.2 of the setting region 4. This means that the material widening 5 formed in the setting region end 4.2 of the seating region 4 has a larger outer diameter h2. The outer diameter of the material widening 5 consequently rises continuously starting from the setting region start 4.1 to the setting region end 4.2, as a result of which a funnel-shaped or conically formed material widening 5 is or are generated along the setting region 4 of the shaft 1. Outside the at least one setting region 4, the shaft 1 has at least one, advantageously two or more free regions 7, in which the outer surface 6 of the shaft 1 does not comprise a material widening 5. In the at least one free area 7, the shaft 1 is substantially unprocessed, consequently has no material widening and is ground, for example, only round on its outer surface 6. Furthermore, a hub 10 is shown in FIG. 1 which has a passage opening 11 for receiving the shaft 1. It is conceivable that the passage opening 11 comprises a substantially untreated surface 12 and an insertion bevel 13. As an untreated surface 12 of the through-hole 11, for example, a surface without structuring is understood, in particular a structureless surface, apart from the occurrence of turning or scurfing marks. It is advantageously conceivable that the passage opening 11 is formed geometrically comparable to the outer periphery of the shaft 11. Thus, it is conceivable that the passage opening 11 of the hub 10 has a non-circular, in particular a uniform non-circular, particularly advantageous a polygonal geometric shape. It is therefore conceivable that both the shaft 1 and the through hole 11 of the hub 10 are formed out of round. The hub 10 is advantageously postponed after machining the through hole 11 and the setting region 5 of the shaft 1 in the mounting direction 30 on the shaft 1 such that a press connection, in particular a transverse press connection between the hub 10 and the shaft 1 in the setting region 4 is generated. However, it is also conceivable that the shaft 1 is pushed through the through-opening 11 of the hub 10, until in the setting region 4 of the shaft 1, a press connection between the hub 10 and the shaft 1 is formed.

An embodiment of a correspondingly produced shaft-hub composite 20 according to the invention is shown in particular in FIG. 2 in a lateral sectional view. Advantageously, the passage opening 11 of the hub 10 extends in a conical or funnel-shaped form. In particular, in mounting direction 30 while an increase in the axial forces is possible because an unintentional axial movement of the hub 10 in mounting direction 30 after application of the hub 10 on the setting portion 5 of the shaft 1 is prevented. In the case of the shaft-hub composite 20, the hub 10 is advantageously placed on the setting region 4 of the shaft 1 in such a way that the conical progressions of the material expansion 5 and the through-opening 11 advantageously extend congruently. This means that the hub 10 is arranged in the setting region 5 of the shaft 1 such that the section of the structuring 14 with the larger inner diameter H2 (see FIG. 3) interacts with the section of the material expansion 5, which likewise has a larger outer diameter h2 (see FIG 1). FIG. 3 shows an embodiment of a hub 10 of a shaft-hub assembly according to the invention. The hub 10 has a passage opening 11 which comprises a structuring 14. The structuring 14 is advantageously designed as a rolling or toothing. It is also possible that the structuring 14 shown is a rotational contour or milling contour. Particularly advantageously, the structuring 14 and consequently also the passage opening 11 of the hub 10 have a conical, in particular funnel-shaped, course in the axial direction or along the longitudinal axis 3 of the shaft. This means that, for example, in the section of the passage opening start 11.1 of the through-opening 11, the inner diameter H2 of the structuring 14 or the through-bore 11 becomes larger is formed as in a portion of the passage opening end 11.2 of the through hole 11, on which the inner diameter H l is formed smaller than at the passage opening start 11.1. Consequently, the passage opening 11, in particular the structuring 14, is advantageously tapered in a funnel-shaped or conical manner starting from the start of the passage opening 11 1 towards the passage opening end 11.2. It is conceivable that the hub 10 additionally or alternatively to a conical passage opening 11, the structuring 14 which, depending on the geometric configuration of the passage opening 11 consequently also comprises a conical or funnel-shaped course. Advantageously, the structuring 14, in particular the passage opening 11, is formed geometrically comparable to the material widening 5 in the setting region 4 of the shaft 1.

4 shows a side sectional view of a machining of a shaft 1 for producing a shaft-hub assembly 20 according to the invention (see FIG. 5). As shown in FIG. 4, in a setting region 4 of the shaft 1, a conically extending material widening 5 is produced by using tools 51. 2 and 51. 4 of a processing system, as shown in FIG. For this purpose, the tools 51.2 51.4, which are advantageously roller burnishing tools, have a tool profile 56 which serves to structure the outer surface of the shaft 1. Advantageously, the tool extends profile of both tools 51.2 51.4 in the direction of the axis of rotation D of the tools 51.2 51.4 considered conical. This means that the outer diameter of the tool 51.2 51.4, in particular of the roller burnishing tool or of the roller burnishing roller, viewed in an ascending or descending manner in the direction of the axis of rotation D, runs. Due to the conically extending tool profile 56, a structuring 5, which runs conically in the direction of the longitudinal axis L, also takes place in the setting region 4 of the shaft 1.

FIG. 5 shows a side sectional view of a further embodiment of a shaft-hub composite 20 according to the invention. The embodiment of the shaft-hub assembly 20 according to the invention shown in FIG. 5 differs from the embodiment of a shaft-hub assembly 20 shown in FIG. 2 in that, in addition, a bearing element 40, in particular a ring bearing element, on the shaft 1 is arranged. The bearing element 40 is advantageously arranged axially adjacent to the hub 10 on the shaft 1 and thereby also serves as a stop for preventing unwanted axially directed movement of the hub, in particular against the indicated mounting direction 30. Advantageously, the bearing element 40 on an end face of the hub 10th arranged on the shaft 1, at which the material widening 5 of the shaft 1 has the smallest outer diameter. FIG. 6 schematically shows an embodiment of a processing installation 50 for machining a shaft 1, which serves as a component of a shaft-hub assembly 20 according to the invention (see, for example, FIGS. 1, 2 or 5). The processing plant 50 has at least one tool, Advantageously, a plurality, in particular four tools 51.1-51.4, which are aligned in the circumferential direction about the shaft 1, which is designed here as a shaft 1 with non-circular outer diameter, for machining the outer surface 6 of the shaft 1. Advantageously, the tools 51.1-51.4 are offset from each other at an angle of 90 ° (four times 90 °). The tools 51.1-51.4 are used to produce a structuring, in particular a rolling (see, for example, Figures 1, 2 and 5) on the outer surface of the shaft 1. Advantageously, the tools 51.1-51.4 can thus rotate within a square, without the contact to a lose the side surface of the shaft. Each tool 51.1-51.4 advantageously has a hydraulic cylinder 52.1-52.4, wherein each of the hydraulic cylinders 52.1-52.4 is connected via a line system 55 to a hydraulic master cylinder 53 and a pressure accumulator 54. By applying pressure to the system, contact between the tools 51.1-51.4 and the shaft 1 is made possible. In addition, the required forming force is advantageously produced hereby. Advantageously, the tools 51.1-51.4 are rotated or rotated about their axes of rotation by the rotation of the shaft 1 about its longitudinal axis. Consequently, the tools 51.1-51.4 are advantageously designed as rotary bodies or rotary bodies. As a result, a rolling of the tools 51.1-51.4 on the shaft 1 is made possible. With the aid of the abovementioned pressure accumulator 54, deviations of the real conditions of engagement between the individual tools 51.1-51.4 and the shaft 1 are also advantageously compensated. Advantageously, the machining system shown in FIG. 5 has at least floatingly mounted tools 51.1-51.4 or a floating shaft 1. It is particularly advantageous formed a floating system of tools 51.1-51.4 and shaft 1, in which the tools 51.1-51.4 evenly distributed viewed in the circumferential direction around the shaft 1 are arranged.

The floating mounting of the tools can be realized for example by means of the described hydraulics or mechanically. An electromechanical or even pneumatic application is conceivable here as well.

As an alternative to the use of the pressure accumulator 54, it would also be conceivable to use the residual compatibility of the entire hydraulic system of the processing system 50 as a kind of pressure accumulator. For example, air bubbles in the hydraulic medium or expansion of the hydraulic lines when pressure is applied serve this purpose.

Furthermore, it is conceivable to replace a number of usable tools, for example, by bearing element or bearing points in order to ensure the required contact force between the remaining tools 51.1-51.4 or the remaining tool (at least one tool must remain) and the shaft 1. LIST OF REFERENCE NUMBERS

1 wave

 Through Hole

 (Shaft) axis

 setting area

 .1 Setting range beginning

 4.2 Setting area end

 5 material expansion

 6 outer surface

 7 outdoor area

10. hub

 11 passage opening

 11.1 Start of opening

 11.2 passage opening end

 12 surface of the passage opening

 13 insertion bevel

 14 structuring

20 shaft-hub composite

30 mounting direction

40 bearing element h l smallest outer diameter of material expansion h2 largest outer diameter of material expansion

H l smallest internal diameter of structuring

H2 largest internal diameter of structuring

50 processing plant

 51.1-51.4 Tool

 52.1-52.4 hydraulic cylinder

 53 hydraulic master cylinder

 54 pressure accumulator

 55 pipe system

56 Tool profile Rotary axis Wavelength axis

Claims

claims 1. Method for Producing a Shaft-Hub Joint (20)  with a shaft (1) and a hub (10) having a passage opening (11) for receiving the shaft (1),  the method comprising at least the following steps:  a) arranging the shaft (1) in a processing installation (50 for machining an outer surface (6) of the shaft (1) at least in a setting area (4),  b) generating at least one at least partially in the circumferential direction and in the axial direction extending material expansion (5) in the setting region (4) of the shaft (1), wherein the material expansion (5) in the axial direction along the shaft longitudinal axis (3) is conical, c) connecting the hub (10) and the shaft (1) such that in the setting region (4) a press connection between the shaft (1) and the hub (10) is formed. 2. Method for Producing a Shaft - Hub - Composite (20)  with a shaft (1) having a non-round outer diameter and a hub (10) having a passage opening (11) for receiving the shaft (1),  the method comprising at least the following steps:  a) arranging the shaft (1) in a processing installation (50 for machining an outer surface (6) of the shaft (1) at least in a setting area (4),  b) generating at least one at least partially circumferentially and in the axial direction extending material expansion (5) in the setting region (4) of the shaft (1), c) connecting the hub (10) and the shaft (1) such that in the setting region ( 4) a press connection between the shaft (1) and the hub (10) is formed. 3. Method according to one of the preceding claims,  characterized in that  in step b), a material widening (5) running conically in the axial direction along the longitudinal axis of the shaft (3) is produced. 4. Method according to one of the preceding claims,  characterized in that  before the step c) an axially extending through opening (11) for receiving the shaft (1) in the hub (10) is generated. 5. Method according to one of the preceding claims, characterized in that a structuring (14) is produced in a surface (12) of a passage opening (11) of the hub (10) before step c). 6. Method according to Ansp  characterized in that  as a structuring (14) a material expansion (5), in particular a rolling or a toothing or a rotational contour or a milling contour is generated. 7. Method according to one of the preceding claims,  characterized in that  after step c) a bearing element (40) for supporting the shaft (1) is positioned on the shaft (1). Method according to one of the preceding claims,  characterized in that  the shaft (1) and the hub (10) are interconnected by means of a thermal joining process. Shaft-hub - composite (20) having a shaft (1) and a hub (10) having a through-hole (11) for receiving the shaft (1), wherein at least the shaft (1) has at least one material widening in the axial direction ( 5), which extends at least in sections in the axial direction and circumferential direction of the shaft (1),  and the hub (10) on the setting region (4) of the shaft (1) is arranged and pressed axially. Shaft - hub - composite (20) having a non - round outer diameter shaft (1) and a through hole (11) for receiving the shaft (1) having hub (10), wherein at least the shaft (1) comprises at least one material widening (5) having setting region (4) which at least partially in the axial direction and circumferential direction of the shaft ( 1) extends,  and wherein the hub (10) is arranged on the setting region (4) of the shaft (1) and axially compressed. Shaft - hub - composite (20) according to Ansp characterized in that the shaft (1) has a round or non-circular outer diameter. 12. shaft - hub - composite (20) according to one of the preceding claims 9 to 11,  characterized in that  the material expansion (5) is a curling or toothing or a knurl. 13. shaft - hub - composite (20) according to any one of the preceding claims 9 to 12,  characterized in that  the passage opening (11) of the hub (10) extends conically in the axial direction. 14. shaft - hub - composite (20) according to claim 13,  characterized in that  the conical shape of the passage opening (11) of the hub (10) is congruent to the conical course of the material expansion (5) in the setting region (4) of the shaft (1). 15. shaft - hub - composite (20) according to one of the preceding claims 9 to 14,  characterized in that  a surface (12) of the passage opening (11) of the hub (10) has a structuring (14), in particular a material widening. 16 shaft - hub - composite (20) according to one of the preceding claims 9 to 15,  characterized in that  a bearing element (40) is positioned axially adjacent to the hub on the shaft (1) in such a way that at least one end face of the bearing element (40) serves as an abutment for the hub (10) which acts in the axial direction. 17. shaft - hub - composite (20) according to one of the preceding claims 9 to 16,  characterized in that  the shaft-hub composite (20) is produced by means of a method according to one of the preceding claims 1 to 6. 18. Processing system (50) for machining an outer surface (6) of the shaft (1) at least in a setting region (4) for producing a shaft-hub assembly (20) according to one of the preceding claims 7 to 14,  characterized in that the processing installation (50) has a number of tools (51.1 - 51.4) which at least one factor higher than the number of corners of the shaft (1). 19. Processing plant (50) according to claim 18,  characterized in that  the processing installation has at least four tools (51.1 - 51.4) to be aligned circumferentially about the shaft (1). 20. Processing plant (50) according to claim 19,  characterized in that  the tools (51.1 - 51.4) are arranged at an angle of four times 90 ° about the shaft (1). 21. Processing plant (50) according to one of claims 18 to 20,  characterized in that  the tools (51.1 - 51.4) are hydraulically, pneumatically or electromechanically driven or spring-loaded in such a way that they exert a pendulum-compensating pressure on the shaft (1) to be machined.