DE202022103763U1 - Skateboard suspension and skateboard axle - Google Patents

Abstract

Skateboard suspension (10) for attachment to a rotating element (50) of a skateboard (1) with a board (40), wherein
the rotation element (50) is designed to enable rotation of the skateboard suspension (10) on the board (40) about an axis of rotation, having the skateboard suspension (10),
a connecting element (11) designed to fasten the skateboard suspension (10) on the rotation element (50) at a fastening position,
at least one rotatably mounted roller (30), the roller (30) being located downstream of the axis of rotation of the rotary element (50) on the board (40),
a rocker arm (14) to which the roller (30) is fixed and which is fixed to the connecting element (11) by means of a first bearing (12), wherein
the first bearing (12) of the rocker arm (14) is provided in such a way that it enables a vertical movement of the at least one roller (30), the vertical movement being cushioned by a first elastic element (15).

Description

The invention relates to a skateboard suspension, a skateboard axle, in particular a skateboard front axle, and a skateboard, in particular a surf skateboard, which has the skateboard axle according to the invention.

Surf skating is a young trend sport that combines elements from surfing (wave riding) and skating. Motivated by the idea of transferring the movement sequences typical of surfing to the roller board sport of skating, so-called surf skateboards were created, which enable movement on a skateboard more or less well by imitating the sweeping and rhythmic movements of surfing.

In contrast to conventional (street) skating with conventional skateboards, the acceleration in the direction of travel is not generated by stepping (called "pushing" in technical jargon), but by driving around curves with a targeted variation of the moment of inertia around the axis of rotation of the curve. By stretching and compressing the body along the axis, on which there is a stable balance of gravitation and centrifugal force, the moment of inertia can be varied and a rotary acceleration can be generated. If the body's center of gravity is kept low when entering the curve and thus on the outside of the orbit around the center of the curve, the body's center of gravity can be brought closer to the axis of rotation (through the center of the curve) by stretching the body, thereby reducing the moment of inertia. By maintaining angular momentum, cornering is accelerated. This increase in speed in the tangential direction can be translated into straight travel during the transition, so that speed can be built up with a sequential repetition of cornering in alternating directions using this technique.

Various types of skateboards are known in the prior art, which are optimized for the movement sequence described above, in order to transfer the most authentic surfing feeling possible to the skateboard. 1a and 1b FIG. 1 shows a surf skateboard 1 according to an embodiment of the prior art, which has a rear and a front skateboard axle 20. FIG. Two rollers 30 are arranged on each of the two skateboard axles 20 . The two skateboard axles 20 are mounted on the surf skateboard board 40 (hereinafter called board 40). The view shown 1a shows the surf skateboard 1 from below, while the view from 1b shows the surf skateboard 1 from the front. The surf skateboard 1 has a longitudinal axis y and a transverse axis x, which also runs horizontally perpendicular thereto. The vertical axis, which is perpendicular to the two axes mentioned above and points in the vertical direction, is simply referred to as the vertical axis z.

For driving straight ahead, i.e. in the direction of the longitudinal axis y, the athlete stands on the board 40 in such a way that his body axis runs in the direction of the vertical axis z and, if possible, so that his body’s center of gravity lies on the longitudinal axis y, in order not to drive corners. If the athlete shifts his weight by tilting the body axis, for example in the opposite direction to the transverse axis x, a rolling movement of the board 40 about the longitudinal axis y is caused, as is shown in FIG 1b through the dashed line and in 1a is indicated by the arrow around the longitudinal axis y. The rolling movement in turn causes the skateboard axles 20 of the surf skateboard 1 to rotate about the vertical axis z from their zero position, i.e. from the position when driving straight ahead, as indicated by the dashed lines in FIG 1a implied. However, all four rollers 30 remain on the ground and do not perform any vertical movement (see 1b) . This rotation of the axles forces the surf skateboard onto a curved path. The surf skateboard 1 can then be accelerated by executing the movement sequence described above.

In order to be able to implement the described rotation of the skateboard axles, skateboard axles have a corresponding bearing with elastic elements, which exert a force on the skateboard axles when cornering, which counteracts the rotational movement of the axles and acts in the direction of the zero position (neutral position) of the axles. Compared to the axles of conventional skateboards, the special axles of the surf skateboards have in particular significantly softer elastic elements, which allow tighter curve radii, but place greater demands on the athlete's sense of balance.

In many respects, surf skateboards according to the state of the art come quite close to the typical movements during surfing. One component of the complex movement sequences, which cannot be implemented with a surf skateboard according to the prior art, is the pumping movement transferred from the person to the board, which, in combination with the buoyancy of the water, allows the surfboard to teeter about the transverse axis. This movement can also be referred to as the pitching movement of the board and on the one hand helps to find a better rhythm when cornering and supports the above-described change in the height of the body's center of gravity when cornering. On the other hand can This effect can be used for better acceleration independently of cornering. The pumping motion described is a motion very typical of surfing and as such is not found in any other related board sport such as snowboarding, wakeboarding or conventional skateboarding. It is therefore elementary for the feeling of the movement sequence when surfing.

In addition, surf skateboards according to the prior art are optimized for a specific speed and, associated therewith, a specific turning radius due to the corresponding suspensions and axles. As a result, the sequence of movements, which is similar to surfing, can only be fully achieved in the speed ranges designed for this.

Concepts from the prior art are also already known, which are only equipped with a front wheel, as for example in the patent application EP 2 186 553 A1 disclosed. However, such concepts cannot compensate for the disadvantages presented above either.

In view of the prior art described, it is therefore the object of the present invention to provide an alternative skateboard suspension, an alternative skateboard axle and an alternative skateboard with which the disadvantages identified in the prior art can be eliminated.

This object is solved by the subject matter of the independent claims. Advantageous further developments of the invention are contained in the dependent claims.

The skateboard suspension according to the invention is provided for attachment to a rotation element of a skateboard with a board, the rotation element being designed to allow the skateboard suspension to rotate on the board about an axis of rotation. A rotational movement on the board is understood to mean a rotational movement essentially around the vertical axis of the skateboard, ie in the plane spanned by the longitudinal axis and transverse axis. Deviations of up to a maximum of 45° are understood as “essentially around the vertical axis”. The skateboard suspension according to the invention initially has a connecting element which is designed to fasten the skateboard suspension to the rotating element. Furthermore, the skateboard suspension according to the invention has a rotatably mounted roller. A roller axis, which rotatably supports the roller, lies in a plane which is perpendicular to the axis of rotation of the rotary element. In this case, the roller is located downstream of the axis of rotation of the rotating element, ie positioned behind the axis of rotation in a longitudinal direction of the board in the direction of travel. This type of downstream positioning is also referred to as a follow-up or follow-up principle and is known, for example, from shopping trolleys. Furthermore, the skateboard suspension according to the invention has a rocker arm to which the at least one roller is attached and which is attached to the connecting element by means of a first bearing. The first bearing is provided in such a way that it enables a vertical movement of the roller, ie a movement in the direction of the vertical axis of the skateboard. The vertical movement is cushioned by a first elastic element.

By means of the vertical mobility of the roller, which is spring-loaded according to the invention, a vertical pumping movement of the athlete is transferred to the board, which means that a riding experience of a surf skateboard can be generated that comes much closer to the movement of surfing in its complexity than with conventional surf skateboards according to the prior art. In addition, the skateboard suspension according to the invention makes it possible to carry out the accelerating movement sequence at different speeds and with different curve radii. With the skateboard suspension according to the invention, the duration in which the angular momentum-preserving effect is effective can be influenced by the athlete and thus extended compared to embodiments of the prior art. This allows rhythms to be driven with a lower frequency, in which acceleration is achieved and thus higher speeds can be achieved overall.

In an advantageous embodiment of the invention, the roller, together with the suspension that attaches it to the rocker arm, is mounted so that it can rotate about a longitudinal axis of the rocker arm. In this way, the alignment of the roller can be improved, especially in tight curve radii, which means that the material wear of the roller can be reduced due to a lower lateral acceleration. This embodiment is particularly advantageous in which a rotational movement of the suspension about a longitudinal axis of the rocker arm is possible if this rotational movement is cushioned and/or damped by a correspondingly provided elastic element and this cushioning or damping is adjustable in particular. The elastic element is therefore provided in order to oppose a force that counteracts the rotational movement.

Also advantageous is an embodiment of the invention in which the first bearing is a Allows rotation of the rocker arm about a horizontal axis in the zero position of the skateboard suspension. Any axis that lies in the plane spanned by the transverse and longitudinal axes is to be understood as a horizontal axis. In a simple form of this embodiment, a horizontally arranged axis is provided on the connecting element, around which the rocker arm can rotate. Since the roller is connected to the rocker arm, a movement of the roller can be implemented at least partially in the vertical direction (ie a vertical movement). However, the invention is not limited to such implementation of the vertical movement of the roller. It is also conceivable, for example, to resiliently mount the oscillating lever in a linear guide, with the linear guide being understood here as the first mount. It is also conceivable to design the oscillating lever directly as a linearly guided and spring-loaded (telescopic) rod.

The first elastic element is preferably in the form of a spring, in particular in the form of a torsion spring. Springs are widely used, inexpensive components that are available in various clearly definable strengths and sizes. In addition, they have a long service life with little wear and are therefore ideal as an elastic element. Springs can be easily integrated into the structure of the bearings and thus contribute to a compact design of the skateboard suspension.

Embodiments with springs are particularly preferred if they are prestressed and the prestressing of the springs can be adjusted in particular. Thus, the axle can be adjusted and adjusted to the preferences of the athlete or his constitution with regard to his weight and strength.

In an advantageous embodiment of the invention, the skateboard suspension has, in addition to the first elastic element, a damping element which is designed to dampen the vertical movement of the roller.

The skateboard suspension advantageously has only one central roller. Thus, a high inclination of the board can be ensured when cornering with small radii. However, embodiments with two or more rollers are also conceivable.

A skateboard axle according to the invention of a skateboard with a board has at least one skateboard suspension according to the invention and at least one rotation element which is designed to enable rotation of the skateboard suspension on the board. As described above, by using such a skateboard truck, the sequence of movements of surfing on a skateboard can be imitated in the best possible way with a corresponding truck.

In an advantageous embodiment of the skateboard axle according to the invention, the rotation element has a second elastic element which is designed to provide a force counteracting this rotation in the event of a rotation of the skateboard suspension on the board. This ensures that the skateboard suspension will always return to a neutral position when no external forces are applied. The neutral position (zero position) is preferably defined in such a way that the roller is located in the direction of the transverse axis of the skateboard at the level of the longitudinal axis. The second elastic member can also provide a cornering force that helps the athlete turn cornering into straight ahead and then into cornering in the opposite direction.

The second elastic element is preferably designed as a spring, in particular as a torsion spring. As already mentioned, springs are widely used, inexpensive components that are available in various clearly definable strengths and sizes. In addition, they have a long service life with little wear and are therefore ideal as an elastic element. Springs can be easily integrated into the structure of the bearings and thus contribute to a compact design of the skateboard axle. It is particularly preferred if the spring is preloaded and the preload can be adjusted.

Also preferred is an embodiment of the skateboard axle in which the rotation element has, in addition to the second elastic element, a second damping element which is designed to damp the rotational movement of the rocker arm on the board.

In an advantageous embodiment of the invention, the axis of rotation of the rotation element and thus of the skateboard suspension on the board is set at a certain angle to the vertical axis of the board. Thus, the axis of rotation does not coincide with the vertical axis. By aligning the axis of rotation to the vertical axis, the riding characteristics of the skateboard can be adjusted and adapted to personal preferences. In addition, the position of the axis of rotation relative to the vertical axis generates a restoring moment, which moves the skateboard axis back towards the zero position, i.e. the neutral position without cornering, while the skateboard is moving. The best driving characteristics have in a range of the angle of incidence to the vertical axis between 15 and 40 degrees.

In a further advantageous embodiment of the skateboard axle according to the invention, the rotating element has a fastening section and a rotating section, the fastening section being firmly, ie immovably, connected to the board and the skateboard suspension being fastened to the rotating section by means of the connecting element. Furthermore, in this embodiment, the rotational bearing for realizing the rotation between the skateboard suspension and the board is provided between the fastening section and the rotating section. Such an embodiment has the advantage of a simple geometry, the position of the roller in relation to the attachment point being able to be determined by the dimension of the rotating section. It is possible to be able to mount rotating sections of different dimensions in order to be able to adjust the position of the roller and thus the geometry of the caster. In addition, the embodiment described has advantages with regard to the exchangeability of different components in the event of damage.

The skateboard according to the invention has at least one skateboard axle according to the invention. The skateboard axle is provided in particular as the front axle of the skateboard.

• 1a Surfskateboard 1 gemäß dem Stand der Technik in einer Ansicht von unten
• 1b Surfskateboard 1 gemäß 1a in einer Ansicht von vorne
• 2a schematische Darstellung einer ersten erfindungsgemäßen Ausführungsform eines Surfskateboards 1 in einer perspektivischen Ansicht von unten
• 2b schematische Darstellung des erfindungsgemäßes Surfskateboards 1 gemäß 2a in einer Seitenansicht
• 3 Darstellung eines erfindungsgemäßen Surfskateboards 1 in einer zweiten Ausführungsform in einer perspektivischen Detailansicht

Aspects and advantageous embodiments of the invention are explained in more detail below with reference to the accompanying drawings. These show:

• 1a Surf skateboard 1 according to the prior art in a view from below
• 1b Surf skateboard 1 according to 1a in a front view
• 2a schematic representation of a first embodiment of a surf skateboard 1 according to the invention in a perspective view from below
• 2 B Schematic representation of the surfing skateboard 1 according to the invention 2a in a side view
• 3 Representation of a surf skateboard 1 according to the invention in a second embodiment in a perspective detailed view

the 1a and 1b have already been described in more detail in the explanation of the prior art. A renewed description is therefore omitted at this point.

the 2a and 2 B show schematic representations of a first embodiment of a surf skateboard 1 according to the invention. 2a shows the surf skateboard 1 in a perspective view from below, while the 2 B shows a side view of the surf skateboard 1 . Also for them 2a , 2 B and 3 already apply with regard to the 1a and 1b defined axes (longitudinal axis y, transverse axis x, vertical axis z) of a surf skateboard 1.

The surf skateboard 1 according to the invention 2a and 2 B has a conventional skateboard axle 20 according to the prior art with two attached rollers 30 as the rear axle, a board 40 and a skateboard axle 20 according to the invention as the front axle. The skateboard axle 20 according to the invention consists of a skateboard suspension 10 according to the invention and a rotary element 50. A rocker arm 14 is connected to the connecting element 11 via a first bearing 12, with a roller 30 being arranged on the rocker arm 14, which roller 30 is located on the rocker arm 14 by means of a corresponding roller suspension can rotate about a horizontal axis. The position of the roller 30 is arranged in the direction of travel (positive direction of the longitudinal axis y) along the longitudinal axis y behind the fastening position of the skateboard axle 10 on the board 40 . The roller 30 is therefore downstream of the fastening position. The skateboard suspension 10 also has a connecting element 11 which is connected to the rotating element 50 . The rotation element 50 is connected to the board 40 and has a second bearing 53 .

The first bearing 12 allows rotation of the rocker arm 14 about a horizontal axis and thus vertical movement of the roller 30 on the skateboard suspension 10, ie movement in the direction of the vertical axis z. Even if the roller 30 in the embodiment shown moves, strictly speaking, on a circular path around the first bearing 12 of the rocker arm 14, it also performs a vertical movement within the meaning of the application. A first elastic element 15 is provided between the board 40 and the rocker arm 14 , which cushions the vertical movement of the roller 30 or the rotation of the rocker arm 14 . If the roller 30 is deflected from the zero position shown in the vertical direction, the first elastic element 15 applies a force or moment opposing this deflection to the oscillating lever 14, which tries to move the oscillating lever 14 and the roller 30 back to the zero position bring to.

The second bearing 53, however, allows a horizontal rotation of the skateboard suspension 10 together with the rocker arm 14, so a rotation about the vertical axis z. This movement is also cushioned by a second elastic element 54, which applies a force or moment during a horizontal rotational movement of the skateboard suspension 10 from the zero position shown, which counteracts this movement.

The movement sequence for controlling the surf skateboard 1 corresponds to the movement sequence already explained above with regard to the prior art for using conventional surf skateboards. If the athlete shifts his or her center of gravity from the longitudinal axis y along the transverse axis x, a rolling movement of the board 40 about the longitudinal axis y is also generated here. This rolling movement is accompanied by a horizontal rotation of the rocker arm 14 about the second bearing 13 and thus with a deflection of the roller 30 of the skateboard axle 10 from the longitudinal axis y. The surf skateboard 1 is thus forced into cornering. The surf skateboard 1 experiences a restoring moment against the rolling movement through the conventionally designed rear axle and in part through the second elastic element 54. Due to the only one roller 30 on the front axle, the surf skateboard 1 can tilt slightly. The athlete has to keep his balance when cornering under the influence of centrifugal force and weight, similar to surfing.

In contrast to conventional concepts of surf skateboards 1, the athlete is able to perform a pumping movement, which is cushioned by the first elastic element 15, by shifting the body's center of gravity along the vertical axis z by means of a movement that is similar to a squat. The pumping movement is therefore a movement of the athlete on the board, with which he moves his center of gravity up and down along the vertical axis. This movement causes a relative vertical movement between the board 40 and the roller 30 on the skateboard axle 20 according to the invention. Thus, by lowering the body's center of gravity, the athlete can compress the first elastic element 15 when entering the curve and, during cornering, use the energy stored in the first elastic element 15 by lifting the body's center of gravity again. The lowering and raising of the body's center of gravity thus describes the pumping movement. This results in a supportive effect when stretching the body to vary the moment of inertia and a beneficial and easily adaptable rhythm specification.

A further advantageous aspect is that cornering for acceleration with the surf skateboard 1 according to the invention described here works effectively with different frequencies or curve radii. This ensures an authentic surfing feeling at different speeds and curve radii.

3 shows a representation of a surf skateboard 1 according to the invention in a second embodiment in a perspective detailed view. A board 40 with a skateboard axle 20 is shown, which is composed of a skateboard suspension 10 and a rotation element 50 . The skateboard suspension 10 has a connecting element 11 which is provided for fastening the skateboard suspension 10 on the rotation element 50 . Skateboard suspension 10 and rotation element 50 together form a skateboard axle 20. In the configuration shown, skateboard axle 20 is in the zero position.

Furthermore, the skateboard suspension 10 has a rocker arm 14 with a fork 141 which is connected to a slide ring 142 on the side of the fork 141 and to the connecting element 11 on the opposite side. Furthermore, a roller suspension 31 is provided on the rocker arm 14 . Provided in the roller suspension 31 is a roller axle 311 which is arranged horizontally in the zero position of the skateboard axle and supports a roller 30 in a rotatable manner. In other words, the roller axis 311 lies in a plane which is perpendicular to the axis of rotation of the rotary element 50 . A rigid connecting rod is provided between the roller suspension 31 and the connecting element 11, on the longitudinal axis of which the sliding ring 142 is movably arranged. A first elastic element 15 in the form of a spring is provided between the sliding ring 142 and the connecting element 11 and winds around the connecting rod. A lower limit 16 of the spring is adjustably positioned along the longitudinal axis of the rigid connecting rod, for example by means of threads on the rigid connecting rod. By changing the position of the lower limit 16, the preload of the spring can be adjusted.

The rocker arm 14 in the embodiment shown is designed as a one-piece connection, but can also deviate from this in other embodiments and be designed, for example, as a multi-part and composite component. In addition, other possibilities are also conceivable to provide an elastic element, for example in which a torsion spring is provided in the fastening point between rocker arm 14 and connecting element 11 . In addition, on the rigid connecting rod can be dispensed with if the fork 141 of the rocker arm 14 is connected directly to the roller suspension 31.

The rotary member 50 has in the embodiment of 3 a fastening section 51 and a rotating section 52, the fastening section 51 fixing the skateboard axle 20 as a whole to the board 40 and the rotating section 52 being fixed to the connecting element 11. In the embodiment shown, the fastening section 51 is fastened to the board 40 and the connecting element 11 to the rotating section 52 by means of screw connections, but other forms are also conceivable. A second bearing 53 is provided between the rotating section 52 and the fastening section 51 , which enables horizontal rotation of the rotating section 52 and thus of the skateboard suspension 10 . A second elastic element 54 is provided (in 3 not shown) which, when the skateboard suspension 10 rotates, exerts a force on it in the direction of the zero position shown.

If the surf skateboard 1 is loaded by the weight of the athlete, the roller 30 moves vertically, which is made possible by the rotation of the rocker arm 14 around the first bearing 12 . To do this, the oscillating lever 14 rotates around its attachment to the connecting element 11 and, in doing so, presses the spring (the elastic element 15) by means of the sliding ring 142. The rigid connecting rod between the roller suspension 31 and the connecting element 11 also rotates about its attachment to the connecting element 11, as a result of which the roller 30 undergoes a vertical movement which is sprung by the spring. The preload of the spring and thus the force required for a specific deflection of the roller can be set using the adjustable lower limit 16 .

If the athlete performs the pumping movement described above, the result is that the distance between the board 40 and the roller 30 varies permanently in accordance with the pumping movement. This movement is supported by the first elastic element 15. A shift in weight from the longitudinal axis y in the direction of the transverse axis x causes the rotation element 50 and thus the skateboard suspension 10 to rotate on the board 40 and the skateboard 1 is forced onto a curved path. As a result of this cornering, the roller axle 311 is no longer in a horizontal arrangement, as is the case in the illustrated zero position of the axle. The second elastic element 54 causes a force that counteracts the rotation of the skateboard suspension 10 and thus helps the driver to convert the cornering into straight-ahead driving and finally into a cornering in the opposite direction and thus to accelerate the skateboard 1 .

Reference List

1

surf skateboard

10

skateboard hanger

11

fastener

12

first storage

14

rocker arm

141

Fork

142

sliding ring

15

first elastic element

16

lower limit

20

skateboard axle

30

role

31

roller suspension

311

axis

40

board

50

rotation element

51

attachment section

52

rotation section

53

second storage

54

second elastic element

x

transverse axis

y

longitudinal axis

e.g

vertical axis

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 2186553 A1 [0009]

Claims (10)

Skateboard suspension (10) for attachment to a rotating element (50) of a skateboard (1) with a board (40), wherein the rotation element (50) is designed to enable rotation of the skateboard suspension (10) on the board (40) about an axis of rotation, having the skateboard suspension (10), a connecting element (11) designed to fasten the skateboard suspension (10) on the rotation element (50) at a fastening position, at least one rotatably mounted roller (30), the roller (30) being located downstream of the axis of rotation of the rotary element (50) on the board (40), a rocker arm (14) to which the roller (30) is fixed and which is fixed to the connecting element (11) by means of a first bearing (12), wherein the first bearing (12) of the rocker arm (14) is provided in such a way that it enables a vertical movement of the at least one roller (30), the vertical movement being cushioned by a first elastic element (15). Skateboard suspension (10) according to the preceding claim, wherein the roller (30) is mounted for rotation about a longitudinal axis of the rocker arm (14). Skateboard suspension (10) according to one of the preceding claims, wherein the first bearing (12) allows rotation of the rocker arm (14) about a horizontal axis. Skateboard suspension (10) according to one of the preceding claims, wherein the first elastic element (15) is designed in the form of a spring, in particular in the form of a torsion spring, the prestressing of the spring being in particular adjustable. Skateboard suspension (10) according to one of the preceding claims, wherein in addition to the first elastic element (15) a first damping element is provided which is designed to dampen the vertical movement of the roller (30). Having a skateboard axle (20) of a skateboard (1) with a board (40), at least one skateboard suspension (10) according to any one of the preceding claims, at least one rotation element (50) designed to enable rotation of the skateboard suspension (10) on the board (40) about an axis of rotation. Skateboard axle (20) according to the preceding claim, wherein the rotation element (50) has a second elastic element (54) which is designed to provide a rotation counteracting force in the event of a rotation of the skateboard suspension (10) on the board (40). , wherein the second elastic element (54) is preferably in the form of a spring, particularly preferably in the form of a torsion spring. Skateboard axle (20) according to the preceding claim, wherein a second damping element is provided, which is adapted to dampen the rotational movement of the skateboard suspension (10) on the board (40). Skateboard axle (20) according to any of the preceding Claims 6 until 8th , wherein the axis of rotation of the skateboard suspension (10) on the board (40) to a vertical axis (z) of the board (40) at a certain angle, in particular an angle between 15 and 40 degrees is employed. Skateboard (1) having at least one skateboard axle (20) according to one of the preceding Claims 6 until 9 , wherein the skateboard axle (20) is provided in particular as a front axle.

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