WO2019185265A1 - Axle strut for a vehicle - Google Patents

Abstract

The invention relates to an axle strut (1) for a vehicle, comprising a shaft (2) and a first and a second bearing region (3a, 3b), wherein the axle strut (1) comprises a support winding (4), a profiled core (6) and a first and a second load-introducing element (7, 8), wherein the support winding (4) and the profiled core (6) are made from a fibre-plastic composite material, and wherein the first load-introducing element (7) is arranged on the first bearing region (3a) and the second load-introducing element (8) is arranged on the second bearing region (3b), wherein the profiled core (6) is arranged spatially between the two load-introducing elements (7, 8). According to the invention, the load-introducing element (7, 8) is formed of at least a first and a second load-introducing segment (7a, 7b, 8a, 8b), wherein the load-introducing segment (7a, 7b, 8a, 8b) has, at least in part, a wrapping (9a, 9b, 10a, 10b) made of a fibre-plastic composite material. The support winding (4) also at least partially contacts the wrapping (9a, 9b, 10a, 10b) of the load-introducing segment (7a, 7b, 8a, 8b), and the support winding (4) at least partially encloses the load-introducing segments (7a, 7b, 8a, 8b) of the load-introducing element (7, 8) and the profiled core (6) and connects same with each other along a longitudinal axis (5) of the axle strut (1). The invention further relates to a method for producing an axle strut (1) according to the invention.

Description

 Axle strut for a vehicle

The present invention relates to an axle strut with the above-mentioned

Features of claim 1. Furthermore, the invention also relates to a method for producing such a Achsstrebe.

Axle struts for chassis of vehicles, such as commercial vehicles, trucks or cars are mainly loaded axially by both compressive and tensile forces. With roll loads, the axle strut is subjected to torsion to a slight extent. A particular challenge to the load capacity of the axle strut results from a misuse load case, z. B. when a jack to the

Axle strut is attached.

For example, from DE 10 2013 007 284 A1 a connecting strut, with a rod portion and with both ends of the same arranged and directed transversely to the longitudinal axis of the rod portion bearing eyes, wherein the connecting strut is at least partially made of fiber-reinforced plastic. The fiber-reinforced plastic is at least partially formed by prepregs. The bearing lugs are each formed by one or more circumferential first prepreg winding layers, and connected to one another by means of one or more second prepreg winding layers guided from one to the other bearing eye over a pitch circle thereof to form the pole section.

From DE 10 2015 215 077 A1 an axle strut is known which comprises a shaft and two bearing areas. The axle strut has a support winding, a core profile and two load-transfer elements, wherein the support winding and the core profile are formed from fiber-reinforced plastic composite material.

The present invention is based on the prior art based on the object to propose an improved axle strut. For this purpose, the axle strut should have an improved load behavior, with stresses within the axle strut being received and distributed in an improved manner. In particular, the carrying capacity of the axle strut should be increased. In addition, the axle strut should be modularized.

The present invention proposes, starting from the above object, an axle strut with the features of claim 1 before. Further advantageous embodiments and developments will become apparent from the dependent claims.

An axle strut for a vehicle according to the invention comprises a shaft and a first and second storage area. The axle strut comprises a support winding, a core profile and a first and second Lasteinleit element. The support winding and the core profile are formed from a fiber-reinforced plastic composite material. The first load-introducing element is arranged on the first storage area and the second load-introducing element is arranged on the second storage area. The core profile is spatially arranged between the two Lasteinleit elements.

According to the invention, the respective load introduction element is formed from at least one first and second load introduction segment. The respective load-introducing segment has at least partially a respective wrapping made of a fiber-reinforced plastic composite material. Furthermore, the support winding comes at least partially to the respective wrapping of each load introduction segment to the plant. The support winding encloses the Lasteinleit segments of the respective Lasteinleit element and the core profile at least partially and connects them along a longitudinal axis of the Achstrebe each other.

In other words, the respective load-introducing element is designed in several parts and comprises at least the first and second load-introducing segments. Alternatively, the respective Lasteinleit element have further Lasteinleit segments that together form the respective Lasteinleit element.

The wrapping of the respective load introduction segment takes place in particular along a single axis of rotation. For example, the respective wrapping of the respective Lasteinleit segment is formed by the fact that the respective Lasteinleit- segment is rotated about an axis of rotation while a wrapping tape on a Lateral surface of the respective load introduction segment is stored. The two end faces of the respective load introduction segment have no wrapping. When enclosing the two Lasteinleit elements and the core profile with the supporting winding along the lateral surface of the axle strut, the Lasteinleit segments and the core profile are positively connected with each other. As a result, the axle strut is formed.

Characterized in that the respective wrapping is formed on the lateral surface of the respective Lasteinleit segment, the respective support winding comes about the respective wrapping on the respective load introduction segment to the plant. The connection between the support winding and the load introduction segment is significantly improved due to the wrapping. The wrapping is preferably formed identically to the supporting winding and preferably has endless fibers. Due to the identical design, a particularly stable coupling between the supporting winding and the wrapping takes place. In particular, the liability and thus the power transmission are thus improved. Two load introduction segments which come into abutment against one another have surface contact, the wrapping being formed on these surfaces. As a result of the substantially planar contact of two surfaces with wraps, a web is formed between the two load-transfer segments. The webs, which are thus arranged in the contact surfaces between two Lasteinleit segments, counteract deformation of the Lasteinleit elements and allow improved power and force in the fiber direction along the webs. In particular, a transverse support to the Lasteinleit elements by the webs.

The axle strut has a shaft and two bearing areas. The shaft is arranged between the two bearing areas and connected thereto. The axle strut thus extends from the first storage area via the shaft to the second storage area. The first storage area limits the axle strut to a first side, the second storage area limits the axle strut to a second side. The shaft here is longer than wide, wherein the shaft preferably has a smaller width than the two bearing areas at its widest point. For example, the bearing areas can be cylindrically shaped from their base. be formed. The first storage area flows smoothly into the shaft. The second storage area also flows smoothly into the shaft. In other words, the transition between the bearing areas and the shaft has no kink or edge.

In particular, the axle strut is intended to be used in a chassis of a vehicle, for example in a commercial vehicle, truck or car. On the axle strut act in a ferry operation compressive and tensile forces that burden them axially. Axial means in this case in the longitudinal direction of the axle strut, wherein the longitudinal direction is defined by the two storage areas. In other words, the longitudinal direction of the axle strut is defined from the first storage area to the second storage area along the shaft. Furthermore, the axle strut is subjected to torsion when a roll load occurs on the chassis in which the axle strut is used. If, for example, a jack is attached to the axle strut, a so-called abuse load case occurs, i. H. Bending stresses act on the axle strut, which the axle strut must withstand.

The axle strut has the radial support winding. The carrier winding is made of fiber-reinforced plastic composite material (FKV). Preferably, the support winding of a carbon fiber reinforced plastic (CFRP) is formed. Alternatively, the support winding can also be formed from a glass fiber reinforced plastic (GRP) or from an aramid fiber reinforced plastic (AFK) or from another suitable FRP. The support winding is in particular endless fiber reinforced. Further, the support winding is formed as a radial winding and thus extends substantially around the longitudinal axis of the Achstrebe around. Thus, at least partially a lateral surface of the axle strut is formed by the radial support winding.

The axle strut also has the core profile. This core profile is formed from a FKV, preferably made of GRP. Alternatively, the core profile may also be derived from another suitable FKV, e.g. As CFK or AFK, be formed. The core profile is preferably a pultrusion profile, but alternatively may be as a pultring profile or as a winding profile or as a braided profile or as another be formed suitable profile. As a result, the core profile is inexpensive to manufacture.

The core profile can be manufactured continuously, which allows modularity to be realized. In other words, in continuous production, the core profile may be cut to a length of shaft required for a specific vehicle type. The core profile has a certain axial softness in a preferred use of an FKV with a fiber angle that deviates significantly from 0 °, for example by 45 °. This is necessary in the event of an abuse load case in order to redirect the forces occurring there in the supporting winding. Axial forces are thus not or only to a very limited extent directed into the core profile.

The axle strut has a load introduction element on each of its bearing areas. Each load introduction element has a receptacle for a bearing. Each inclusion of the load introduction elements is suitable for each bearing, z. As a rubber-metal bearing to record. By means of these recordings, an operative connection between the Lasteinleit elements and the bearings is made. According to the invention is the respective

Load introduction element formed from at least a first and second load-introducing segment. Spatially between the two Lasteinleit elements the core profile is arranged, wherein the shaft of the axle strut thus has the core profile.

Preferably, the respectively first load introduction segment comes into contact essentially flatly with the respective second load introduction segment. In addition, the second load introduction segment in each case comes to lie substantially flat against the core profile.

In other words, contact surfaces are formed on the lateral surface of the respective load introduction segment, which are intended to cooperate with other contact surfaces on the adjacent load introduction segment and / or on the core profile in order to transmit forces between the components.

According to one embodiment, the respective load-introducing element is formed from at least a first, second and third load-introducing segment. Preferably, the respective first load introduction segment is substantially flat on the respective Weil's second load introduction segment for investment. In addition, the second load introduction segment in each case comes into contact with the third load introduction segment essentially flatly. In addition, each third Lasteinleit segment comes to a substantial area on the core profile to the plant. By the term substantially flat is to be understood that small recesses or a small offset between two Lasteinleit segments can be formed. The load introduction segments preferably come into contact with one another flatly, wherein no pores, recesses and / or inclusions are arranged in the contact surfaces.

Preferably, at least one filling element is arranged in an intermediate space, which is formed spatially between two load-introduction segments which come into contact with one another. In particular, the respective intermediate space is generated by a rounding of side edges of the respective load introduction segment. The rounding of the side edges allow an improved deposition of the wrap on the lateral surface of the respective load introduction segment. The adhesion and the nestling of the respective wrapping on the respective load introduction segment are thus increased.

For example, the respective filling element is formed corresponding to the intermediate space. In other words, the shape of the respective filling element essentially corresponds to the shape of the intermediate space. In this case, the intermediate space is substantially completely closed by the respective filling element. The support winding comes when wrapping the Lasteinleit elements and the core element to the respective filling element between two Lasteinleit segments to the system, so that essentially no cavities between the support coil and the Lasteinleit- segments are formed. Furthermore, the filling elements allow a targeted introduction of forces into the webs between the Lasteinleit segments.

The respective filling element preferably comprises a metal and / or a fiber-plastic composite material. For example, the respective filling element is completely formed from a fiber-reinforced plastic composite material. Furthermore, it is also conceivable to form a core of the respective filling element made of a metal, preferably of aluminum, and to wrap it around with a fiber-reinforced plastic composite material. Further preferably, the core profile is tubular. In other words, the core profile is designed as a hollow profile. Preferably, the core profile is formed as a pultrusion tube or as a pultrusion tube or as a winding tube or as a braided tube. This achieves a mass reduction. The tube cross-section can be configured, for example, rectangular, circular, oval, square or in any other suitable form. In addition, other profile shapes for the core profile are conceivable. For example, the core profile has a double H-shaped cross-section.

According to a preferred embodiment, the tubular core profile is at least partially filled with a foam material. The foam material is essentially intended to fill the cavity in the tubular core profile to z. B. to stabilize the cross section and to support a geometric conservation of the cross section of the core profile at pressure loads. In particular, the foam material is formed from a polymer, for example polyurethane. Furthermore, it is also conceivable that the foam material is designed as Styrofoam (EPS) or polypropylene (EPP).

According to a further preferred embodiment, the first bearing region of the axle strut is arranged in a first plane, which is spaced apart from a second plane, in which the second bearing region of the axle strut is arranged. The first load-introducing element is thus arranged in the first plane. The second load-introducing element is thus arranged in the second plane. The two planes are formed parallel to each other and horizontally spaced from each other. In other words, the distance between the first plane and the second plane leads to an offset of the two bearing areas, so that the shaft is formed obliquely between the two bearing areas. Preferably, however, the distance of the two planes is small, so that only a small offset is realized. Thus, the axle strut has two break points, in each case at the transition between the respective storage area and the shaft.

Furthermore, it is also conceivable that the axle strut is formed flat, wherein the first storage area is arranged in the same plane as the second storage area. In order nevertheless to generate an offset between the two bearing areas, but not to introduce a kink in the axle strut, the two holes for receiving a respective bearing element are made obliquely in the respective Lasteinleit element.

Preferably, the respective load introduction segment is formed of a metal. For example, the respective load-introducing segment is formed from a light metal alloy, preferably an aluminum alloy. The formation of the Lasteinleit- elements made of an aluminum alloy allows cost-effective production in the extrusion process. Alternatively, the respective load-introducing element is formed from a FKV. For example, the Lasteinleit elements can be molded as molded parts of preferably long fiber reinforced, thermosetting plastic composite material. Alternatively, the load-introducing elements may be formed from a long-fiber-reinforced thermoplastic FKV (LFT) or a short-fiber-reinforced thermoplastic FKV (KFT). This achieves a mass reduction of the axle strut in comparison to the use of metallic load introduction elements.

According to a preferred embodiment, both load-introducing elements are formed voltage-optimized. This means that there is a homogeneous voltage curve for loads acting on the respective load-transfer element.

According to a further embodiment, the axle strut has two bearings. A first bearing is disposed in the bore of the first load-introducing element and a second bearing is disposed in the bore of the second load-introducing element. Each bearing is connected by means of a transition fit and by means of an adhesive with its respective bore. Both bearings can be uniformly shaped. Alternatively, the first bearing may be shaped differently than the second bearing. Preferably, both bearings are designed as rubber-metal bearings. An advantage of the transition fit and on the adhesive is that the connection of the Lasteinleit- elements to the support winding and the Lasteinleit elements themselves are less stressed than when using only an interference fit. The bearings are thereby secured against lateral squeezing during a load case. moreover occur in the Lasteinleit elements no plastic deformation in contrast to the use of only an interference fit.

The process according to the invention for the production of the axial strut according to the invention comprises at least the following process steps:

First, a winding of fiber-reinforced plastic composite material, a support winding, a core profile and at least a first and second load introduction segment for a respective first and second Lasteinleit-element takes place. For example, three load initiation segments are established for each load initiation element. The Lasteinleit elements are preferably formed of aluminum, wherein the support winding and the core profile are formed from fiber-reinforced plastic composite material.

Thereafter, the respective first and second load introduction segment is at least partially wrapped with the respective winding to form a wrapping on the respective load introduction segment. Subsequently, the wrapped Lasteinleit-segments and the core profile are inserted and compacted in an assembly tool. The core element may comprise a foam core.

Preferably, filling elements are inserted into respective intermediate spaces, which are spatially formed between the load introduction segments which come into contact with one another in order to fill the intermediate spaces. The support winding is radially applied along a longitudinal axis of the preassembled axle strut about the load-launching segments and the core profile, with the assembly rotated or the support winding moved about the assembly, or both the assembly rotated and the support winding around the assembly is moved. Finally, the finished axle strut is removed from the assembly tool.

In the following preferred embodiments of the invention will be explained in more detail with reference to the drawings. This shows 1 is a schematic perspective view of an axle strut according to the invention according to a first embodiment,

2a is a schematic perspective view of three Lasteinleit segments of a load-introducing element according to the invention according to a second embodiment,

2b is a schematic perspective view of the three Lasteinleit segments of FIG 2a with a respective wrapping,

2c is a schematic perspective view of the three load-introducing segments according to FIG. 2b in a mounting position, FIG.

2d is a schematic perspective view of an axle strut according to the invention shown in half according to the second embodiment,

3 is a schematic side view of an axle strut according to the invention according to a third embodiment,

Fig. 4 is a schematic side view of a Achsstrebe invention with two bearings according to a fourth embodiment, and

5 is a schematic perspective view of a core profile of the axle strut according to FIG. 1.

According to FIG. 1, an axle strut 1 for a vehicle (not shown here) comprises a shaft 2 and a first and second bearing area 3a, 3b. The axle strut 1 is formed from a support winding 4, a core profile 6 and a first and a second load introduction element 7, 8. The first Lasteileitelement 7 has a first, second and third Lasteinleit segment 7a, 7b, 7c. The second Lasteileitelement 8 has a first, second and third Lasteinleit segment 8a, 8b, 8c. The first load-introducing element 7 is disposed on the first bearing portion 3a, and the second load-introducing element 8 is disposed on the second bearing portion 3b. The respective Lasteinleit segment 7a, 7b, 7c, 8a, 8b, 8c has a respective wrapping 9a, 9b, 9c, 10a, 10b, 10c of a fiber-plastic composite material. The respective wrapping 9a, 9b, 9c, 10a, 10b, 10c is designed to circulate along a respective lateral surface of the respective load introduction segment 7a, 7b, 7c, 8a, 8b, 8c and thus encloses the respective load introduction segment 7a, 7b, 7c , 8a, 8b, 8c form-fitting.

Two respective faces of the Lasteinleit segments 7a, 7b, 7c, 8a, 8b, 8c have no wrapping 9a, 9b, 9c, 10a, 10b, 10c. The respective first load introduction segment 7a, 8a comes with a part of the lateral surface substantially flat against a part of the lateral surface of the respective second load introduction segment 7b, 8b to the plant. The respective second load introduction segment 7b, 8b comes with a part of the lateral surface substantially flat against a part of the lateral surface of the third load input segment 7c, 8c to the plant. Furthermore, each third load-introducing segment 7c, 8c comes with a part of the lateral surface substantially flat against the core profile 6 to the plant.

In the contact planes between the respective Lasteinleit segments 7a, 7b and 7b, 7c and 8a, 8b and 8b, 8c, the wraps 9a, 9b and 9b, 9c and 10a, 10b and 10b, 10c extend parallel to each other and form webs. The fiber flow at the respective webs and the possibility of power absorption in the fiber direction along the webs increases the carrying capacity of the axle strut. 1

The respective first load introduction segment 7a, 8a has a bore 13a, 13b whose center axis 14a, 14b is perpendicular to the longitudinal axis 5 of the axle strut 1. The respective bore 13a, 13b is in the end face 16a of the respective first load introduction segment 7a , 8a and extends transversely to the longitudinal axis 5 of the axle strut 1 to a second - not shown here - end face on the back of the respective first Lasteinleit segment 7a, 8a. The end face 16a of the respective first load introduction segment 7a, 8a is substantially pear-shaped and is composed of a semicircle and an isosceles trapezoid. The corners of the trapezoid are provided with a radius and thus rounded, whereby the respective wrapping 9a, 10a can better cling to the lateral surface of the respective first load introduction segment 7a, 8a.

The respective second Lasteinleit segment 7b, 8b has a substantially trapezoidal end face 16b, wherein in the end face 16b in each case three recesses 17 are formed, which are transverse to the longitudinal axis 5 of the Achsstrebe 1 up to a second - not shown here - face the back of the respective second load introduction segment 7b, 8b extend. The recesses 17 are formed substantially triangular, wherein the corners are provided with a radius and thus rounded, whereby the respective wrapping 9b, 10b can better conform to the lateral surface of the respective second Lasteinleit segment 7b, 8b. In the present case, the recesses 17 are formed as an isosceles triangle, wherein each two of the three recesses 17 on the respective second Lasteinleit- segment 7b, 8b in a first direction and each one of the three recesses 17 on the respective second Lasteinleit segment 7b, 8b in a order 180 ° to the first direction rotated direction shows.

The respective third Lasteinleit segment 7c, 8c has a substantially rectangular end face 16c, wherein the corners are provided with a radius and thus rounded. As a result, the respective wrapping 9c, 10c can better cling to the lateral surface of the respective third load introduction segment 7c, 8c.

The support winding 4 comes to the respective wrapping 9a, 9b, 9c, 10a, 10b, 10c of the respective Lasteinleit segment 7a, 7b, 7c, 8a, 8b, 8c for conditioning and enclosing the Lasteinleit segments 7a, 7b, 7c, 8a , 8b, 8c of the respective Lasteinleit element 7, 8 and the core profile 6. As a result, the two Lasteinleit elements 7, 8 and the core profile 6 along the longitudinal axis 5 of the Achstrebe 1 positively connected to each other. The respective wrapping 9a, 9b, 9c, 10a, 10b, 10c, the support winding 4 and the core profile 6 are formed from a fiber-plastic composite material, the two Lasteinleit elements 7a, 7b are formed of a metal, in this case made of an aluminum alloy. In particular, the support winding 4 is formed of a glass fiber reinforced plastic. FIGS. 2a, 2b, 2c and 2d show four method steps for producing an axle strut 1 according to the invention in accordance with a further exemplary embodiment. FIGS. 2a to 2c show the load introduction segments 7a, 7b, 7c of the first load introduction element 7a. The second load introduction element 7b is not illustrated, but is identical to the first load introduction element 7a. The embodiment of the axle strut 1 according to FIGS. 2a to 2d differ from the embodiment of the axle strut 1 illustrated in FIG. 1 only in the construction of the second load introduction segment 7b. Therefore, reference is made to the description of FIG. 1. According to the embodiment of the axle strut 1 according to FIGS. 2a to 2d, the second load introduction segment 7b has no recesses.

In Fig. 2a, the Lasteinleit segments 7a, 7b, 7c of the first Lasteinleit element 7 are shown. The rounded corners of the respective load introduction segment 7a, 7b, 7c are intended to guide the respective wrapping 9a, 9b, 9c shown in FIG. 2b in exact position and to nestle the respective wrapping 9a, 9b,

9c at the respective load introduction segment 7a, 7b, 7c to realize.

In Fig. 2c, the Lasteinleit segments 7a, 7b, 7c are inserted into a - not shown here - assembly tool and compressed or compacted. The first load introduction segment 7a comes into contact with the respective second load introduction segment 7b in a planar manner, with the second load introduction segment 7b coming into abutment flat against the third load introduction segment 7c. In a respective intermediate space 11, which is formed spatially between two load-engaging segments 7a, 7b and 7b, 7c which come into abutment with each other, a respective filling element 12 is inserted in order to close the respective intermediate space 11. The respective gap 11 is formed by the rounding of the respective load-introducing segment 7a, 7b, 7c at the corner edges. The respective filling element 12 is formed corresponding to the respective intermediate space 11 and fills it in such a way that the carrying winding 4 (shown in FIG. 2d), which in a subsequent step on the respective wrapping 9a, 9b, 9c of the respective load introduction segment 7a, 7b, 7c comes to rest, can lie flat. In the present case, the respective filling element 12 has an end face which substantially corresponds to a three-pointed star or is substantially T-shaped. Consequently, essentially no cavities are formed between the support winding 4 and the load-transfer segments 7a, 7b, 7c. Furthermore, the filling elements 12 allow an improved introduction of force into between the

Load introduction segments 7a, 7b and 7b, 7c formed webs. In Fig. 2d, the assembled axle strut 1 is shown in half. The support winding 4 is guided radially along the longitudinal axis 5 of the Achsstrebe 1 to the Lasteinleit segments 7a, 7b, 7c and the core profile 6. The third Lasteinleit segment 7c comes flat on the core profile 6 to the plant. By the support winding 4, the Lasteinleit- elements 7, 8 are pressed axially against the core profile 6 and positively connected to each other.

In Fig. 3, the axle strut 1 according to the invention has a lateral offset. In other words, the first bearing portion 3a of the axle strut 1 is arranged in a first plane 17a, which is spaced from a second plane 17b, in which the second bearing portion 3b of the axle strut 1 is arranged. Consequently, the shaft 2 is arranged obliquely between the two bearing areas 3a, 3b. The axle strut 1 thus has two buckling points 18a, 18b.

4, an axle strut 1 according to the invention with two bearings 19a, 19b is shown. The respective bearing 19a, 19b is arranged in the respective bore 13a, 13b of the respective load-introducing element 7, 8. The respective bore 13a, 13b is formed obliquely in the respective load-introducing element 7, 8. That is, the center axes 14a, 14b of the bores 13a, 13b are arranged so as to have a zero angle to a respective axis 15 which is perpendicular to the longitudinal axis 5 of the axle strut 1. Due to the oblique bores 13a, 13b, the two bearings 19a, 19b are also introduced obliquely in the axle strut 1. As a result, the axle strut 1 has a lateral offset. This means that the axle strut 1 is inclined in itself so that the first storage area 3a is arranged in a different horizontal plane than the second storage area 3b. In FIG. 4 it can be clearly seen that the longitudinal axis 5 of the axle strut 1 forms an angle to a hoisting angle. has a horizontal axis 20. This horizontal axis 20 is perpendicular to the central axes 14a, 14b.

FIG. 5 shows a schematic representation of the core profile 6 of the axle strut 1 according to the exemplary embodiments according to FIGS. 1 and 2d. Shown is the core profile 6, which is formed from a fiberglass. In Fig. 5 it can be clearly seen that the core profile 6 has a double-H-shaped cross-section. This is advantageous because a collapse of the core profile 6 under high pressure, which prevails, for example, during curing of the axle strut in an autoclave, is prevented. The core profile 6 can therefore withstand high external pressures.

The invention is not limited to the preceding embodiments. In particular, further developments of the respective embodiments are conceivable. For example, a transverse winding or transverse windings can be provided either around the bearing areas, or both about the bearing areas and about the shaft of the axle strut to support the support winding in the load application area when tensile forces occur and to protect the axle strut from contamination. The transverse winding or the transverse windings are formed for example of fiberglass. Of course, the shaft length of the axle strands is variable, that is, depending on how long the core profile is, the axle strut is made longer or shorter. Furthermore, the angle that the central axes of the bores in the Lasteinleit elements have to a vertical axis is variable. Depending on the vehicle type, this angle can be shaped differently, so that a different lateral offset can be achieved.

REFERENCE CHARACTERS

Torque rod

 shaft

a, 3b storage area

 supporting winding

longitudinal axis

apex

 Load introduction element, 7b, 7c Load introduction segment

 Load introduction elementa, 8b, 8c Load introduction segmenta, 9b, 9c Wrapping

0a, 10b, 10c wrapping

1 space

2 filling element

3a, 13b bore

4a, 14b central axis

5a, 15b axis

6a, 16b, 16c end face

7a, 17b level

8a, 18b break point

9a, 19b bearings

0 axis

Claims

claims

Axle strut (1) for a vehicle, comprising a shaft (2) and a first and second bearing region (3a, 3b), wherein

 the axle strut comprises a support winding, a core profile, and a first and second load introduction element,

 - The support winding (4) and the core profile (6) are formed from a fiber-reinforced plastic composite material, and

 the first load introduction element (7) is arranged on the first storage area (3a) and the second load introduction element (8) is arranged on the second storage area (3b),

 the core profile (6) is arranged spatially between the two load introduction elements (7, 8),

characterized in that the respective Lasteinleit element (7, 8) of at least a first and second Lasteinleit segment (7a, 7b, 8a, 8b) is formed, wherein

 the respective load introduction segment (7a, 7b, 8a, 8b) at least partially has a respective wrapping (9a, 9b, 10a, 10b) of a fiber-plastic composite material,

- The support winding (4) at least partially on the respective wrapping (9a, 9b,

10a, 10b) of the respective load introduction segment (7a, 7b, 8a, 8b) comes to rest, and

 - The support winding (4) the Lasteinleit segments (7a, 7b, 8a, 8b) of the respective Lasteinleit element (7, 8) and the core profile (6) at least partially encloses and along a longitudinal axis (5) of the Achstrebe (1) connects with each other.

2. Achsstrebe (1) according to claim 1, characterized in that the respective first Lasteinleit segment (7a, 8a) substantially flat against the respective second load input segment (7b, 8b) comes to rest, the respective second Lasteinleit- segment (7b, 8b) substantially flat against the core profile (6) comes to rest.

3. Achsstrebe (1) according to claim 1, characterized in that the respective Lasteinleit element (7, 8) of at least a first, second and third Lastein- guide segment (7a, 7b, 7c, 8a, 8b, 8c) is trained.

4. Achsstrebe (1) according to any one of the preceding claims, characterized in that the respective first Lasteinleit segment (7a, 8a) substantially flat against the respective second Lasteinleit segment (7b, 8b) comes to rest, wherein the respective second Lasteinleit segment (7b, 8b) substantially flat on the third Lasteinleit segment (7c, 8c) comes to rest, and wherein the respective third Lasteinleit- segment (7c, 8c) substantially flat against the core profile (6) for conditioning comes.

5. Achsstrebe (1) according to any one of the preceding claims, characterized in that in an intermediate space (11) spatially between two adjacent to each other coming to load Lasteinleit segments (7a, 7b, 7b, 7c, 8a, 8b, 8b, 8c ) is formed, at least one filling element (12) is arranged.

6. axle strut (1) according to claim 5, characterized in that the respective filling element (12) corresponding to the intermediate space (11) is formed.

7. axle strut (1) according to claim 5 or 6, characterized in that the respective filling element (12) comprises a metal and / or fiber-reinforced plastic composite material.

8. Axle strut (1) according to one of the preceding claims, characterized in that respective load introduction segment (7a, 7b, 7c, 8a, 8b, 8c) is formed of a metal.

9. Achsstrebe (1) according to any one of the preceding claims, characterized in that the respective first Lasteinleit segment (7a, 8a) has a bore (13a, 13b) whose central axis (14a, 14b) has an angle to a respective axis (15a, 15b) which is perpendicular to the longitudinal axis (5) of the axle strut (1).

10. Achsstrebe (1) according to one of claims 1 to 7, characterized in that the respective first Lasteinleit segment (7a, 8a) has a bore (13a, 13b) whose central axis (M) is perpendicular to the longitudinal axis (5 ) of the axle strut (1).

1 1. Achsstrebe (1) according to one of the preceding claims, characterized in that the respective second Lasteinleit segment (7b, 8b) has a substantially trapezoidal end face (16).

12. Axle strut (1) according to one of the preceding claims, characterized in that the respective second load introduction segment (7b, 8b) has at least one recess (17).

13. Axle strut (1) according to one of the preceding claims, characterized in that the core profile (6) has a double-H-shaped cross-section.

14. A method for producing an axle strut (1) according to one of claims 1 to 13, characterized by the following method steps:

 - Producing a winding of fiber-reinforced plastic composite material, a support winding (4), a core profile (6) and at least one first and second Lasteinleit segment (7a, 7b, 8a, 8b) for a respective first and second Lasteinleit element (7, 8) .

 At least partially wrapping the respective first and second load introduction segments (7a, 7b, 8a, 8b) with the respective winding to form a wrapping (9a, 9b) on the respective load introduction segment (7a, 7b, 8a, 8b),

- Inserting the wrapped Lasteinleit segments (7a, 7b, 8a, 8b) and the

 Core profile (6) in an assembly tool,

 - applying the support winding (4) radially along a longitudinal axis (5) of the preassembled Achsstrebe (1) to the Lasteinleit segments (7a, 7b, 8a, 8b) and the core profile (6) around,

 - Remove the axle strut (1) from the assembly tool.

15. The method according to claim 14, characterized in that at least one filling element (12) in an intermediate space (1 1) is inserted, which is spatially formed between the abutting each other to load Lasteinleit segments (7a, 7b, 8a, 8b;) ,