DE102011004897A1 - Axle system of commercial vehicle, has brake drum structure comprising front portion with recess that extends transverse to axis of rotation and larger than extension of outdoor unit - Google Patents

Abstract

The axle system has outdoor unit (10) with maximum dimension transverse to an axis of rotation. A brake drum structure (2) has a front portion with a recess which extends transverse to the axis of rotation and larger than extension of outdoor unit. A drum shell extends parallel to the axis of rotation. The outdoor unit is arranged in the direction of the hub unit (6). The brake drum structure is displaced from the outdoor unit and fixed to the hub unit. An independent claim is included for method for manufacturing vehicle axle system.

Description

The present invention relates to an axle system, in particular for use. in commercial vehicles, according to the preamble of claim 1.

Such, known from the prior art axle systems, have a brake drum unit, which should preferably be assembled and disassembled from the outside. If, in addition, further add-on units are attached to the axle system from the outside, then the problem arises that they first have to be dismantled in order then to be able to assemble or disassemble the brake drum unit. Especially when using sensitive add-on units whose disassembly causes a considerably increased effort, many of the advantages of a easily accessible from the outside of the brake drum unit are reduced or even reversed. Previously common material combinations did not allow an improved design of the drum brake unit.

It is therefore an object of the present invention to provide an axle system which is designed to be easily assembled and disassembled, without affecting the reliability of sensitive add-on units or the entire axle system.

This object is achieved with an axle system having the features of claim 1. Preferred embodiments emerge from the dependent claims.

According to the invention, the axle system comprises an outer unit, a hub unit and a brake drum element, the outer unit having a maximum extent D ₁ transverse to an axis of rotation, the brake drum element comprising a front part extending transversely to the axis of rotation and having a recess and a drum shell extends substantially parallel to the axis of rotation, wherein the recess of the end portion has an extension transverse to the axis of rotation of at least D ₁ , wherein the extension of the drum shell transverse to the axis of rotation is smaller than the inner dimension D _{2 of} a definable on the brake drum element and this at least partially surrounding attachment unit wherein the outer unit is arranged in the direction of the axis of rotation on the hub unit and wherein the brake drum element is displaceable over the outer unit and fixable on the hub unit. Said rotation axis is preferably the vehicle axle on which the axle system, or a suspension for wheels on commercial vehicles, is arranged. At the outer end of this axis, an outdoor unit is arranged, wherein the outdoor unit has a maximum extent D ₁ transversely, or preferably perpendicular to the axis of rotation. Preferably, the outdoor unit has a circular cross section, where D ₁ in this embodiment is the outer diameter of the outdoor unit. In further preferred embodiments, the outer unit has an elliptical, rectangular or polygonal cross section, wherein D ₁ in these cases is in each case the maximum extent transversely, or preferably perpendicular to the axis of rotation of these cross sections. According to the invention, the brake drum element comprises an end part and a drum shell, the end part extending substantially transversely and the drum shell extending substantially parallel to the axis of rotation. Preferably, the front part extends perpendicular to the axis of rotation. The front part has a recess and thus has the form of a circular ring plate in a preferred embodiment. In further preferred embodiments, the front part may also have a conical shape or have steps or steps along the axis of rotation. According to the invention a recess is provided on the front part of the brake drum element, wherein the recess has an extension transverse to the axis of rotation, which is at least as large or larger than the maximum extent D _{1 of} the outdoor unit transverse to the axis of rotation. The cross-section of the recess is preferably adapted to the cross-section of the outer unit, or congruent thereto, ie, in the case of an outer unit with a circular cross-section, the recess is preferably also circular. Preferably, the recess has a slightly larger extension than the outer unit, so that between the recess and the outer unit, a gap is formed, which in turn simplifies the assembly and disassembly of the brake drum element. The gap between the recess and the outer unit is preferably at least 1 mm, in a preferred embodiment 2 mm to 10 mm wide. It can be avoided in this way, a tapping or tilting of the brake drum element in the region of the recess on the outdoor unit during assembly or disassembly of the brake drum element. The brake drum element has, in addition to the front part, a drum shell which extends substantially parallel to the axis of rotation. Substantially parallel means that the drum casing may well have a conical or a convex-concave cross-sectional geometry, but the change in distance to the axis of rotation in the course of the cross-section is preferably small compared to the extent of the drum shell along the axis of rotation. Preferably, the drum shell has the shape of a hollow cylinder. Drum shell and front part are preferably integrally connected to each other and it results for the entire shape of the brake drum element, a hollow body with a lid, wherein the lid or the front part, in turn, has a recess. The maximum extent of the drum shell and the front part transversely to the axis of rotation is characterized by a the axle system attachable add-on unit limited. This add-on unit preferably has a region with an inwardly facing surface, this surface having an extension of D ₂ transverse to the axis of rotation. The brake drum element should be designed so that it can be at least partially inserted into the attachment unit, in particular in the region of the inwardly facing surface of the attachment unit, so that the maximum extent of the brake drum element is limited transversely to the axis of rotation to the outside by the inner dimension D ₂ of the brake drum element surrounding attachment unit. There are thus given two limiting dimensions for the brake drum element: D ₁ the outer dimension of the outer unit, which must not be exceeded by the recess in the front part of the brake drum element and the minimum extent transverse to the axis of rotation D _{2 of} the inwardly facing surface of the extension unit, which from the outer dimension the brake drum element may not be exceeded. It is achieved in this way that the brake drum element can be displaced beyond the outer unit, which means that the brake drum element can be displaced over the outer unit, which is preferably firmly connected to the hub, and can subsequently be secured to the hub. According to the invention, the brake drum element can thus be mounted and dismounted without dismantling the composite of hub unit and outdoor unit. In practice, this means that the brake drums and, for example, brake shoe elements can be replaced, maintained and reassembled within this brake drum without dismantling the remaining parts mounted on the axle system.

In a preferred embodiment, the brake drum member is mountable and dismountable while the outdoor unit remains fixedly secured to the hub unit. This preferred feature of the axle system ensures that the connection between the hub unit and the outdoor unit does not have to be loosened and is thus avoided so that, for example, dirt or other foreign objects get into the possibly sensitive outdoor unit.

In a particularly preferred embodiment, the drum shell is designed in several parts and has a friction element and a carrier area. The carrier region is preferably provided on the outside of the drum shell and the friction element attached to its inner surface. In a further preferred embodiment, the carrier region is designed in one piece with the front part of the brake drum element. Like the drum shell, the support region also has a preferably hollow-cylindrical shape, wherein the friction element is firmly connected to the support region on its inner surface with a preferably integral connection. On its outer surface, the support region preferably has reinforcements in which recesses are inserted, which are suitable for receiving fastening elements in order to be able to attach additional attachments to the axle system. By attaching local reinforcements to the carrier region, both the strength of the brake drum element can be increased, while at the same time the weight only has to be increased only slightly, compared to a complete reinforcement of the entire carrier region.

In a preferred embodiment, the support region is formed of a material of higher strength than the friction element. Preferably, the material in the carrier region has a high tensile strength, so that higher forces can be absorbed with constant cross-sectional thickness, which in turn have higher voltage (bending stress, tensile stress) in the material result. The production material of the friction element is preferably a good friction partner to common brake pads for brake shoes, which are used in drum brakes. The friction element is preferably connected by means of a positive and / or cohesive connection with the carrier region, wherein it is ensured that the high braking forces can be transmitted via this connection from the friction element to the carrier area. The preferred production material for the carrier area is nodular iron, also referred to as ductile iron, which has a particularly high tensile strength and is therefore suitable for transferring the high forces occurring at a comparatively small material thickness. The friction element is preferably made of gray cast iron, since gray cast iron is a particularly suitable friction partner for common brake lining materials. It is possible in this way to combine the good frictional properties of gray cast iron with the high tensile strength of nodular cast iron and in this way to further reduce the required material thickness. In this way, the space required by the brake drum element can be advantageously reduced advantageous. In a particularly advantageous manner, the region in which the brake drum element is fixed to the hub unit can thus be kept particularly small, since the more stable material withstands the occurring moments and forces even with a low material thickness. It can be used in this way a particularly shallow hub, which in turn is beneficial to the basic idea of the axle system according to the invention, as reduced in this way the required outer diameter of the brake drum element and the possible outer diameter, or the maximum extent D ₁ transverse to the axis of rotation of the outdoor unit can be increased. Preferably, the friction element can be inserted into the carrier region or the brake drum element by means of a centrifugal casting process.

In a preferred embodiment, the ratio of the extent of the recess to the maximum extent of the brake drum element transverse to the axis of rotation is greater than 0.4, preferably greater than 0.6 and more preferably about 0.7 to 0.85. It has been shown that by means of these ratios, the space between the two limits D ₂ outside and D ₁ inside, in material combinations of different cast iron, can be particularly well exploited. The lower limit of this ratio 0.4 is particularly preferred when a small outdoor unit is to be combined with a relatively large mounting area between the brake drum and the hub. The preferred ratio of the extent of the recess to the maximum extent of the brake drum element transverse to the axis of rotation of 0.85 is particularly advantageous when a large outdoor unit is to be combined with a relatively small brake drum element on the axle system. This ratio of 0.85 is associated with a small area which serves to secure the brake drum element to the hub unit and, consequently, with a great demand on the strength of the material of the brake drum element.

In an advantageous embodiment, the axle system comprises a wheel unit, wherein the wheel unit has a rim casing, which extends substantially parallel to the axis of rotation, wherein the inner surface of the rim shell facing the axis of rotation has a minimum extension D ₂ transversely, or preferably perpendicular to the axis of rotation and the rim casing can be pushed over the drum element and the wheel unit can be fixed to the brake drum element. A preferred object of the axle system is therefore to support a wheel unit rotatably about an axis. Preferably, this wheel unit has a rim shell, which extends substantially parallel to the axis of rotation. In other words, the rim shell is a kind of sleeve and substantially parallel in this case means that its extent along the axis of rotation is greater than the change in distance transverse to the axis of rotation. Preferably, the wheel unit may also have a convex-concave shape. Inward toward the rotation axis of the rim jacket has a minimum dimension D _2, which is in the interpretation of the axis system, the outer limit of the brake drum D element. ₂ If the outer diameter of the brake drum element is smaller than the minimum extent of the rim casing, then this can be pushed at least partially over the brake drum element. This is desirable because in this way the track width and the overall space required by the axle construction can be reduced, since the wheel unit is not arranged in front of the brake drum element, but is partially pushed over this. In further preferred embodiments, a plurality of wheel units may also be provided on the axle system.

In a preferred embodiment, the wheel unit is secured by means of a first fastening element on the brake drum element against displacement and rotation relative to the brake drum element. By means of this fuse, torques, for example torsional moments, can be transmitted from the brake drum element to the wheel unit or from the wheel unit to the brake drum element. In a preferred embodiment, a plurality of fasteners between. Brake drum element and wheel unit provided. It has proved to be advantageous that at least 8, preferably 10 to 15 and particularly preferably 16 first fastening elements, fix the wheel unit to the brake drum element. If the axle system expects a higher strength, or demands safety-related requirements, then further fastening elements can also be used. The number of fasteners is limited only by the available space on the brake drum element. In a particularly preferred embodiment, the fastening element is a screw. This engages positively or non-positively in the mounting region of the brake drum element and fixed by means of a screw head which is thickened in comparison to the rest of the screw body, the wheel unit on the brake drum element. In a further preferred embodiment, the first fastening means is a wheel bolt cast into the brake drum element, which has suitable projections in its area enclosed by the material of the brake drum element, which form a positive connection with the material of the brake drum element and the wheel bolt in this way against displacement and rotation secure relative to the brake drum element. The wheel unit is fixed in this embodiment by means screwed onto the wheel bolt wheel nuts on the brake drum element.

In a further preferred embodiment, the brake drum element is secured by means of a second fastening element on the hub unit against displacement and rotation relative to the hub unit. By means of the connection between the hub unit and the brake drum element produced by the second fastening elements, torques which are transmitted from the outdoor unit to the hub unit can be transmitted to the brake drum element and to the wheel unit fixed thereto. Preferably, the second fastening elements are arranged closer to the axis of rotation than the first fastening elements, which allows the use of a hub unit with a relatively small extent transverse to the axis of rotation. In a preferred Embodiment at least 6, preferably 10 and more preferably 12 to 16 second fastening elements between the hub unit and brake drum element are arranged. The second fastening elements engage in recesses provided for this purpose on the hub unit and exert a tensile force on the brake drum element, by means of which it is pressed against the hub unit. Particularly preferred are the second fastening elements hexagon socket screws. These have the advantage that they can be used in recesses provided for this purpose on the brake drum element and can be tightened or disengaged in the retracted state. The screw heads thus do not represent any surface unevenness on the end face of the brake drum element.

In a preferred embodiment, the hub unit and / or the drum element and / or the wheel unit are formed substantially rotationally symmetrical. In this case, essentially rotationally symmetrical means that the cross sections of the hub unit and / or the drum unit and / or the wheel unit do not change on rotation of the cutting plane about the axis of rotation or only in their non-load-bearing parts. In this case, elements may be attached or attached to the rotationally symmetrical supporting parts of the hub unit and / or the drum unit and / or the wheel unit, which are not formed rotationally symmetrical to the axis of rotation.

In a particularly preferred embodiment, the outdoor unit is a hydrostatic auxiliary drive which is designed to transmit a drive torque to the hub unit. The hydrostatic auxiliary drive is connected to both the axle and the hub and establishes a torque between these two units. The hydrostatic auxiliary drive is preferably fixed by means of suitable fastening elements on the hub unit, this with the brake drum element and this in turn with the wheel unit and there is a force and torque transmission from the hydrostatic auxiliary drive up to the wheel unit instead. The problem to be solved by the axle system results in that a stronger hydrostatic auxiliary drive usually has a larger outer diameter D ₁ , whereby the ratio of the extension of the recess to the maximum extent of the brake drum element has to increase transversely to the axis of rotation and the larger forces to be transmitted by the stronger hydrostatic drive Moments have to be dealt with in a smaller attachment area between the hub unit and brake drum element. The material requirements for the attachment area between the hub unit and the brake drum element and that between the wheel unit and the brake drum element are preferably overcome by production materials with correspondingly high strength.

In a preferred embodiment, the axle system comprises an engagement member adapted to engage the hub unit and the brake drum member in recesses provided therefor and thereby secure the hub unit and the brake drum member against rotation relative to each other. The engagement element in this way supports the torque transmission from the hub unit to the brake drum element and thus from the hydrostatic auxiliary drive to the wheel unit through the various fasteners. It may be preferred in this way, for example, the threads of the fasteners against excessive surface pressure and concomitant wear are preserved and the life of the axle system can be increased in this way. Preferably, the engagement element is a sliding block, which engages in, provided on the hub unit and brake drum element, groove. In a particularly preferred embodiment, 2, 3 or 4 sliding blocks are arranged between the hub unit and the brake drum element.

Preferably, the axle system is manufactured by the steps of providing a hub unit, a brake drum member, and a second fastener, wherein on the hub unit an outer unit having a maximum extent D _{1 is arranged} transversely to a rotation axis, the brake drum member having a front part, and wherein the end part has a recess with an extension transverse to the axis of rotation of at least D ₁ , wherein the brake drum element has an end part. Then, displacing the brake drum member via the hub unit until the end portion abuts on the hub unit, and fixing the brake drum member to the hub unit with one or a plurality of second fasteners.

It is understood that the further advantages and features of the axle system according to the invention can also be used in the method according to the invention for producing an axle system.

Further advantages and features will become apparent from the following exemplary description of a preferred embodiment of the axle system according to the invention with reference to the accompanying figures. Different features of various embodiments may be combined with each other within the scope of the invention. Show it:

1 A sectional view of a preferred embodiment of the axle system according to the invention,

2 a sectional view of a preferred embodiment of the brake drum element and

3 a view of a preferred embodiment of the brake drum element according to the invention following the direction of the axis of rotation.

In 1 a first preferred embodiment of the axle system according to the invention is shown. A brake drum element 2 is on a hub element 6 preferably by means of a second fastener 14 established. The second fastening element 14 is preferably a screw, wherein the illustrated in the figure preferred embodiment of the screw has a screw head, which consists of the left in the figure surface of the brake drum element 2 protrudes. Particularly preferred is a screw having a screw head with hexagon socket, used as this screw head can be sunk into the brake drum element and tightened in the retracted state and released again. At the, left in the figure, side of the hub unit 6 is an outdoor unit 10 at the hub unit 6 arranged. hub unit 6 and outdoor unit 10 are not shown in section, and the fasteners by means of which the outdoor unit 10 at the hub unit 6 is not explicitly shown. The outdoor unit 10 has a maximum extent D ₁ transverse to the axis of rotation A. The outdoor unit is preferred 10 a cylinder-shaped hydraulic auxiliary drive, which torque between an axis 1 and the hub unit 6 applies. The axis 1 is usually rigid or non-rotatable and the hub unit preferably via a bearing assembly on the axis 1 rotatably mounted. Furthermore, on the brake drum element 2 two wheel units 8th arranged and by means of a first fastener 12 attached. In addition to this preferred embodiment, only one of the two wheel units 8th be provided. The wheel unit 8th preferably has a rim shell 81 which extends substantially parallel to the axis of rotation A, wherein the change in distance between rim casing 81 and axis of rotation A in the course of the extension parallel to the axis of rotation compared to the amount of extension of the rim shell parallel to the axis of rotation small, preferably in the range 0.01 to 0.9, should be. The axis of rotation A facing out, inner surface of the rim shell 81 has an extent transverse to the axis of rotation A of at least D ₂ . Since the brake drum element 2 According to the invention, an extension which is smaller than D ₂ , the wheel unit can 8th preferably over the brake drum element 2 pushed away. until the transverse to the axis of rotation A aligned area of the wheel unit 8th to the brake drum element 2 borders. The rim coat 81 is preferably a kind of sleeve, which is the brake drum element 2 at least partially encloses. At the inwardly facing surface of the brake drum element 2 is preferably a friction element 4 provided, wherein the friction element is particularly preferably made of a material that forms a good friction pair with common brake lining materials. In an advantageous embodiment, the hub unit 6 , the brake drum element 2 , a rotatable part of the outdoor unit 10 , the wheel unit 8th and the first and second fastening elements ( 12 . 14 ) rotatably supported about the rotation axis A.

2 shows a sectional view of a preferred embodiment of the brake drum element according to the invention 2 , The brake drum element 2 is in this preferred embodiment in the two areas front part 21 and drum jacket 22 divided. The front part 21 preferably extends transversely to the axis of rotation A, wherein in other embodiments, not shown, a conical, hemispherical or pyramidal geometry of the front part 21 may be preferred. In addition, the front part may preferably also have shoulders parallel to the axis of rotation A. In the front part 21 According to the invention a recess is introduced, wherein the recess is preferably concentric with the outer surface of the front part 21 and preferably also the drum shell 22 is aligned. The minimum extent of the recess transverse to the axis of rotation A is preferred in the design of the axle system by the external dimensions of the outdoor unit 10 D ₁ specified. In a particularly advantageous embodiment, the front part 21 and the recess circular, or have a cylindrical geometry. The drum shell 22 preferably extends substantially parallel to the axis of rotation A, wherein its geometry is also preferably conical or has steps transverse to the axis of rotation A. The drum shell 22 preferably comprises a carrier area 25 and a friction element disposed on the inside thereof 4 , The friction element is preferably made of a material which has high coefficients of friction in combination with common brake lining materials. Particularly preferred is the production material of the friction element 4 Gray cast iron. Furthermore, it is also possible to use ceramic materials, sintered metals and / or composite combinations for producing the friction element 4 be used. The carrier area 25 is preferably made of a material of higher strength than the friction element 4 produced. Particularly preferred is the production material for the carrier area 25 Ductile iron, also referred to as ductile iron, because it has excellent strength properties. Also preferred is the front part 21 made of nodular iron. In a preferred manner, the material thickness on the front part 21 and carrier area 25 of the drum mantle 22 can be reduced, whereby the consistently high forces can now be transmitted through greater stresses in the material. This reduction in material thickness, preferably causes a reduction of the entire brake drum element 2 required installation space, so that the two geometric boundary conditions D ₁ and D ₂ can be maintained. Preferably, the carrier region 25 and the friction element 4 a flat, hollow cylindrical geometry.

3 shows a view along the direction of the axis of rotation A of a preferred embodiment of the brake drum element 2 , Preferably, the brake drum element 2 on its outside reinforcement areas 23 on. These amplification areas are preferred 23 characterized by material accumulation, wherein in each gain region 23 each a first fastener receiving 24 is provided. In the first fastener element receptacle 24 preferably engages a first fastener 12 and fixes the wheel unit 8th on the brake drum element 2 , The material accumulation of the reinforcement areas 23 allows preferably a favorable stress distribution in the power transmission of wheel unit 8th to the brake drum element 2 over the first fastener 12 and the first fastener receiving 24 , Preferably, the reinforcement areas 23 Rounded geometry gradients to avoid notch effect during power transmission. Preferably offset from the first fastener receptacles are in this preferred embodiment second fastener element receptacles 26 arranged, in each of which a second fastening element 14 is placed in the hub unit 6 engages and in this way the brake drum element 2 at the hub unit 6 fixed. The first fastener holder 24 is preferred as a threaded bore, the second fastener receiving 26 designed as a through hole. In this case, the second fastener element receptacle 26 preferably a recess of larger diameter than the through hole, in which preferably a screw head can be sunk. Shown in the figure is the preferred embodiment with eight first and second fastener element receptacles 24 . 26 , In further preferred embodiments 10 to 12 and especially preferred 13 to 18 first and / or second fastener element receptacles 24 . 26 be provided. Advantageously so many fastener recordings 24 . 26 provided as respective fasteners 12 . 14 ,

LIST OF REFERENCE NUMBERS

LIST OF REFERENCE NUMBERS

1

axis

2

Brake drum element

4

friction

6

hub unit

8th

wheel unit

10

outdoor unit

12

first fastening element

14

second fastening element

21

front part

22

drum shell

23

gain range

24

first fastener receiving

25

support region

26

second fastener receiving

81

rims coat

A

axis of rotation

D ₁

maximum extension outdoor unit

D ₂

minimal extension rim coat

Claims (12)

Axle system, in particular axle system for commercial vehicles, comprising an outdoor unit ( 10 ), a hub unit ( 6 ) and a brake drum element ( 2 ), whereby the outdoor unit ( 10 ) has a maximum extent D ₁ transverse to a rotation axis (A), wherein the brake drum element ( 2 ) a front part ( 21 ) which extends transversely to the axis of rotation (A) and has a recess, and a drum shell ( 22 ), which extends substantially parallel to the axis of rotation (A), wherein the recess of the front part ( 21 ) has an extension transverse to the axis of rotation (A) of at least D ₁ , wherein the extension of the drum shell ( 22 ) transverse to the axis of rotation (A) is smaller than the internal dimension D _{2 of} a, on the brake drum element ( 2 ) attachable and this at least partially surrounding, add-on unit, wherein the outdoor unit ( 10 ) in the direction of the axis of rotation (A) on the hub unit ( 6 ), and wherein the brake drum element ( 2 ) via the outdoor unit ( 10 ) and on the hub unit ( 6 ) is determinable. Axle system according to claim 1, wherein the brake drum element ( 2 ) can be mounted and dismounted while the outdoor unit ( 10 ) fixed to the hub unit ( 6 ) remains. Axle system according to one of the preceding claims, wherein the drum shell ( 22 ) is made of several parts and a friction element ( 4 ) and a carrier area ( 25 ) having. Axis system according to claim 3, wherein the support area ( 25 ) is formed of a material of higher strength than the friction element ( 4 ). Axle system according to one of the preceding claims, wherein the ratio of the extent of the recess to the maximum extent of the brake drum element transversely to Rotation axis greater than 0.4, preferably greater than 0.6 and more preferably about 0.7 to 0.85. An axle system according to one of the preceding claims, wherein the attachment unit is a wheel unit ( 8th ), wherein the wheel unit ( 8th ) a rim casing ( 81 ), which extends substantially parallel to the axis of rotation (A), wherein the rotation axis (A) facing, inner surface of the rim shell ( 81 ) has a minimal extent D ₂ transverse to the axis of rotation (A), and wherein the rim casing ( 81 ) over the brake drum element ( 2 ) and the wheel unit ( 8th ) on the brake drum element ( 2 ) is determinable. Axle system according to claim 6, wherein the wheel unit ( 8th ) by means of a first fastening element ( 12 ) on the brake drum element ( 2 ) against displacement and rotation relative to the brake drum element ( 2 ) is secured. Axle system according to one of the preceding claims, wherein the brake drum element ( 2 ) by means of a second fastening element ( 14 ) on the hub unit ( 6 ) against displacement and rotation relative to the hub unit ( 6 ) is secured. Axle system according to one of the preceding claims, wherein the hub unit ( 6 ) and / or the brake drum element ( 2 ) and / or the wheel unit ( 8th ) are formed substantially rotationally symmetrical. Axle system according to one of the preceding claims, wherein the outdoor unit ( 10 ) is a hydrostatic auxiliary drive, which is designed, a drive torque to the hub unit ( 6 ) transferred to. Axle system according to one of the preceding claims, comprising an engagement element, wherein the engagement element is designed, in on the hub unit ( 6 ) and on the brake drum element ( 2 ) provided recesses and in this way the hub unit ( 6 ) and the brake drum element ( 2 ) to secure against rotation relative to each other. Method for producing an axle system comprising the steps of: a) providing a hub unit ( 6 ), a brake drum element ( 2 ) and at least one second fastening element ( 14 ), wherein at the hub unit ( 6 ) an outdoor unit ( 10 ) is arranged with a maximum extent D ₁ transverse to a rotation axis (A), wherein the brake drum element ( 2 ) a front part ( 21 ), and wherein the front part ( 21 ) has a recess with an extension transverse to the axis of rotation (A) of at least D ₁ , b) displacing the brake drum element ( 2 ) along the axis of rotation (A) via the hub unit ( 6 ) until the front part ( 21 ) on the hub unit ( 6 ) and c) fixing the brake drum element ( 2 ) on the hub unit ( 6 ) by means of one or a plurality of second fastening elements ( 14 ).

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