DE102022131074A1 - Wheel suspension for a motor vehicle and corresponding motor vehicle - Google Patents

Abstract

The invention relates to a wheel suspension (1) for a motor vehicle, with a wheel carrier (7) on which a wheel hub (5) is or can be mounted so as to be rotatable about a wheel hub axis of rotation (8) by means of a wheel bearing (6), and with two chassis links (11, 12) of a first link arrangement (9), two chassis links (13, 14) of a second link arrangement (10) and a tie rod (23) articulated to a tie rod kinematics point (24) on the wheel carrier (7), wherein the chassis links (11, 12, 13, 14) are articulated to the wheel carrier (7) in such a way that the wheel carrier (7) describes a rotational movement about a virtual wheel carrier axis of rotation (36) when the tie rod (23) is displaced, and wherein a horizontal plane (38) receiving a wheel center (37) and oriented horizontally and a horizontal plane (38) receiving the wheel center (37) and oriented perpendicular to the horizontal plane (38) vertical plane (39) delimits several orthants (40, 41, 42, 43) from one another, wherein in the installed position of the wheel suspension (1) the tie rod kinematics point (24) is arranged in a first of the orthants (40, 41, 42, 43). It is provided that the wheel carrier rotation axis (36) runs through a second of the orthants (40, 41, 42, 43) opposite the first orthant (40) with respect to the wheel hub rotation axis. The invention further relates to a motor vehicle with a wheel suspension (1).

Description

The invention relates to a wheel suspension for a motor vehicle, with a wheel carrier on which a wheel hub is or can be mounted so as to be rotatable about a wheel hub axis of rotation by means of a wheel bearing, and with two chassis links of an upper link arrangement, two chassis links of a lower link arrangement and a tie rod articulated to a tie rod kinematics point on the wheel carrier, wherein the chassis links are articulated to the wheel carrier in such a way that the wheel carrier describes a rotary movement about a virtual wheel carrier axis of rotation when the tie rod is displaced, and wherein a horizontal plane receiving a wheel center and oriented horizontally and a vertical plane receiving the wheel center and perpendicular to the horizontal plane delimit several orthants from one another, wherein in the installed position of the wheel suspension the tie rod kinematics point is arranged in a first of the orthants. The invention further relates to a motor vehicle.

The state of the art includes, for example, the publication EN 10 2018 206 402 A1 This shows a wheel suspension for a motor vehicle, with a wheel carrier which is mounted so as to be rotatable about a steering axis for steering the motor vehicle, on which a wheel hub carrying a rim of a wheel of the motor vehicle is mounted or can be mounted so as to be rotatable about a wheel hub axis of rotation by means of a wheel bearing and which has a bearing point for connecting a tie rod and with a first control arm arrangement and a second control arm arrangement which engage the wheel carrier at a distance from one another in the axial direction with respect to the steering axis for coupling the wheel carrier to a body of the motor vehicle. In this case, it is provided that in the installed position of the wheel suspension, a kinematic point of a tie rod bearing used to connect the tie rod to the bearing point is arranged in front of the steering axis in the direction of travel of the motor vehicle and above a horizontal plane which receives or intersects the wheel hub axis of rotation and is arranged horizontally.

The publication further reveals EN 10 2019 002 655 A1 an axle arrangement for a vehicle, which is characterized by a subframe with a wheel carrier on each side of the subframe, wherein a lower trapezoidal control arm, an upper camber control arm and a tie rod behind the wheel carrier center are arranged between the subframe and the respective wheel carrier, wherein a longitudinal force coupling is arranged between the respective wheel carrier and the respective trapezoidal control arm and wherein a spring and a damper act on the respective trapezoidal control arm.

The object of the invention is to propose a wheel suspension for a motor vehicle which has advantages over known wheel suspensions and is preferably of compact construction, in particular in a longitudinal direction of the motor vehicle. Furthermore, the wheel suspension should preferably be particularly well suited for a motor vehicle designed as an electric vehicle.

This is achieved according to the invention with a wheel suspension for a motor vehicle with the features of claim 1. It is provided that the wheel carrier axis of rotation runs through a second of the orthants opposite the first orthant with respect to the wheel hub axis of rotation.

Advantageous embodiments with expedient further developments of the invention are specified in the dependent claims. It is pointed out that the embodiments explained in the description are not restrictive; rather, any variations of the features disclosed in the description, the claims and the figures can be implemented.

The wheel suspension is preferably part of the motor vehicle, but can of course be separate from it. It serves to connect the wheel carrier and thus a wheel of the motor vehicle to a body of the motor vehicle. The wheel suspension is preferably provided and designed for suspension, in particular for spring suspension, of the wheel carrier with respect to the body. The wheel is rotatably mounted or at least rotatably mountable on the wheel carrier of the wheel suspension. For this purpose, the wheel is attached or at least can be attached to the wheel hub, which is ultimately rotatably mounted on the wheel carrier, for example by means of a wheel bearing. The wheel or at least a rim of the wheel is therefore rotatably mounted on the wheel carrier via the wheel hub. The rim serves as a carrier for a tire of the wheel, namely preferably for an air-filled tire.

The wheel hub can be part of the wheel bearing or integrated with it. For example, the wheel hub is designed as one piece with an inner ring or an outer ring of the wheel bearing and/or made of the same material, whereas the other ring, i.e. either the outer ring or the inner ring, is attached to the wheel carrier. The wheel carrier, the wheel bearing and the wheel are not necessarily part of the described wheel suspension, but can be optional.

The wheel carrier has, for example, a wheel bearing receptacle, which is designed as an opening, in particular as an edge-closed opening, in the wheel carrier. In the wheel bearing receptacle the wheel bearing is arranged at least in some areas. In addition, the wheel hub and/or a shaft coupled to it in a rotationally fixed manner engages at least in some areas in the wheel bearing receptacle. Particularly preferably, the wheel hub and/or the shaft, in particular together, penetrate the wheel bearing receptacle in the axial direction with respect to the wheel hub rotation axis at least partially, in particular completely.

The wheel hub is preferably coupled to a drive device at least temporarily via the shaft. The drive device can be designed as a single-wheel drive. It preferably has an electric traction machine, by means of which a drive torque aimed at driving the motor vehicle can be generated or is generated at least temporarily.

The wheel bearing is preferably designed as a rolling bearing and in this respect has the inner ring and the outer ring, between which rolling elements are present to reduce friction. The inner ring is assigned to the wheel hub, in particular it is connected to the wheel hub, for example it is designed as one piece with it or is attached to it, whereas the outer ring is assigned to the wheel carrier, in particular it is connected to the wheel carrier, for example it is attached to it. The outer ring is preferably located in the wheel bearing receptacle. In other words, the outer ring rests with its outer peripheral surface on an inner peripheral surface of the wheel carrier that delimits the wheel bearing receptacle.

The wheel carrier is connected or can be connected to the body via the chassis links. After the wheel suspension has been mounted on the motor vehicle, each of the chassis links engages the body on the one hand and the wheel carrier on the other, in particular in a pivotable manner. The engagement with the body can be implemented directly or only indirectly, for example via a subframe or subframe. The chassis links are, for example, in the form of wishbones and/or longitudinal links. The chassis links are preferably in the form of two-point links, so each of the chassis links is designed as a two-point link in this case.

In the wheel suspension described here, the chassis links are part of the first link arrangement and the second link arrangement, with each of the link arrangements having two chassis links. In addition to the chassis links of the two link arrangements, the wheel suspension has the tie rod, which ultimately also serves to connect the wheel carrier to the body.

Each of the chassis links has a first kinematic point and a second kinematic point. Each of the chassis links is connected to the wheel carrier via its first kinematic point and to the body via its second kinematic point. The tie rod has the tie rod kinematic point and is connected to the wheel carrier via this. The kinematic points are the pivot points of the connections of the chassis links and the tie rod to the wheel carrier or the body. Preferably, each of the chassis links and the tie rod are connected to the wheel carrier or the body by means of a bearing. In the case of the tie rod, this bearing can be referred to as a tie rod bearing, and the bearings of the chassis links can be referred to as chassis link bearings.

The bearings usually allow both a rotary movement of the chassis control arm or the tie rod around a rotation axis and a tilting movement of the chassis control arm or the tie rod in relation to the wheel carrier or the body. The rotary movement and the tilting movement take place around the respective kinematic point, which therefore represents the pivot point or a pivot point of the respective bearing. The kinematic point is preferably on the rotation axis of the respective bearing. For example, the bearing is in the form of a ball joint or ball and socket joint.

The tie rod is connected to the wheel carrier at a bearing point on the wheel carrier. The bearing point is, for example, on a track lever on the wheel carrier, which is designed as a projection that extends from a base body of the wheel carrier or protrudes beyond it. The wheel bearing mount is preferably designed in the base body. It can be provided that the tie rod bearing on the wheel carrier side is integrated into the tie rod. However, it can also be separate from it. The same applies to the chassis control arm bearings on the wheel carrier side.

Each of the first kinematic points defines, together with the second kinematic point of the respective chassis control arm, an imaginary straight line, which is regarded as the longitudinal center axis of the chassis control arm. The imaginary straight lines of the chassis control arms intersect at an intersection point for each of the control arm arrangements. The virtual wheel carrier rotation axis is defined by the two control arm arrangements or their chassis control arms. For example, each of the two control arm arrangements defines a point on the wheel carrier rotation axis, so that for the two control arm arrangements the wheel carrier rotation axis corresponds to an imaginary straight line through the points defined by the control arm arrangements. In particular, These points correspond to the above-mentioned intersection points, which lie on the wheel carrier axis of rotation.

The wheel hub rotation axis, also known as the spread axis, is usually skewed in the vehicle, but it is essentially aligned in the direction of or parallel to the vehicle's vertical axis in order to allow a compensating movement of the wheel carrier and thus of the wheel attached to it. In order to align the wheel carrier rotation axis accordingly, the wheel carrier-side kinematic points of the chassis control arms that define it must be at different heights in relation to the vehicle's vertical axis. These heights are also referred to as control arm levels.

The chassis links are part of the link arrangements. In other words, both the first link arrangement and the second link arrangement each have at least two of the chassis links. The two link arrangements serve to couple or connect the wheel carrier to the body. To do this, they each engage the wheel carrier on the one hand and can be coupled or are coupled to the body on the other. In the present case, the chassis links of the two link arrangements are arranged at different heights. The first link arrangement or the chassis links assigned to it are in a first height and the second link arrangement or the chassis links assigned to it are in a second height that is different from the first height.

For the present wheel suspension, it is assumed that in the installation position the first height position of the first control arm arrangement is above the second height position of the second control arm arrangement, so that the first control arm arrangement can also be referred to as the upper control arm arrangement and the second control arm arrangement can also be referred to as the lower control arm arrangement. The respective associated chassis links can also be referred to as the upper chassis links and the lower chassis links. The installation position is to be understood as an arrangement of the wheel suspension on or in the motor vehicle for the intended use of the motor vehicle. In other words, the wheel suspension in the installation position is on or in the motor vehicle in such a way that normal and intended driving of the motor vehicle is possible.

The installation position can be present after the wheel suspension has actually been installed on or in the motor vehicle. However, the installation position can also describe an arrangement of the wheel suspension in such a way that it is analogous to an actually installed state. In order to arrange the wheel suspension in the installation position, it is therefore not necessary to actually install the wheel suspension on or in the motor vehicle, although this can of course be provided.

The chassis links are articulated to at least the wheel carrier in such a way that the wheel carrier describes the rotational movement around the wheel carrier rotation axis if the tie rod is displaced. The wheel carrier can be steerable or non-steerable. In the steerable design, the tie rod is coupled to a steering device of the motor vehicle on its side facing away from the wheel carrier. If, however, the wheel carrier is not steerable, the tie rod is articulated to the body on its side facing away from the wheel carrier and can therefore not be displaced or can only be displaced to a limited extent. The displacement of the tie rod is therefore initially understood to be an imaginary or virtual displacement which - if it actually existed - would cause the rotational movement of the wheel carrier.

An imaginary horizontal plane contains the wheel center and is aligned horizontally. The wheel center lies on the wheel hub axis of rotation and is centrally located in the axial direction with respect to the wheel or at least the rim. The horizontal plane is understood to be a horizontal plane which, for example - assuming a zero wheel camber - completely contains the wheel hub axis of rotation or - assuming a non-zero wheel camber - is intersected by it at least at an intersection point corresponding to the wheel center.

After the wheel suspension has been installed on or in the motor vehicle, the horizontal plane is preferably parallel to a surface on which the motor vehicle is arranged. The surface can be in the form of a roadway or a street, for example. After the wheel suspension has been installed, the horizontal plane is spanned by the longitudinal direction and the transverse direction of the motor vehicle and is perpendicular to a vertical axis of the motor vehicle.

For example, there is an imaginary plane perpendicular to the inner circumferential surface of the wheel carrier that delimits the wheel bearing mount, which intersects the wheel hub axis of rotation at an intersection point. Preferably, the imaginary plane is located in the middle of the wheel bearing mount in the axial direction with respect to a longitudinal center axis of the wheel bearing mount, thus representing a center plane of the wheel bearing mount. The horizontal plane The horizontal plane is now parallel to the ground and includes the intersection point of the wheel hub rotation axis and the imaginary plane. Perpendicular to the horizontal plane is the imaginary vertical plane, which also completely includes the wheel hub rotation axis or at least intersects it. The vehicle vertical axis mentioned above lies completely in the vertical plane, which is correspondingly perpendicular to the ground of the vehicle.

The horizontal plane and the vertical plane together delimit several orthants from each other, which are in the form of quadrants. Two of the orthants are above the wheel center, two other orthants are below the wheel center. At the same time, two of the orthants are at the front in the direction of travel, i.e. they face the front of the vehicle, whereas two other orthants are at the back in the direction of travel, i.e. they face the rear of the vehicle. The direction of travel is understood to mean a forward direction in which the vehicle moves forward.

The orthants can be classified as follows: top front, top rear, bottom front and bottom rear. For the purposes of this description, the following nomenclature is used: a first of the orthants is at the top front, a second of the orthants at the bottom rear. A third of the orthants is located at the top rear, a fourth of the orthants at the bottom front. In a clockwise direction when viewed from above in the direction of the wheel hub's axis of rotation, the order of the orthants is as follows: first orthant, third orthant, second orthant and fourth orthant.

The wheel suspension described here is designed in such a way that, in the installed position of the wheel suspension, the tie rod kinematic point at which the tie rod is hinged to the wheel carrier is located in the first orthant, i.e., in the installed position, above the wheel center and in front of the wheel center in the direction of travel. The entire tie rod is particularly preferably arranged in the first orthant, so that the entire tie rod is above the wheel center in the vertical direction of the vehicle and in front of the wheel center in the longitudinal direction of the vehicle.

In addition, the wheel carrier rotation axis should run through the second orthant, which is opposite the first orthant with respect to the wheel hub rotation axis, i.e. be arranged behind the wheel center in the direction of travel. In other words, the wheel carrier rotation axis runs below the vertical plane behind the horizontal plane, namely exclusively behind the horizontal plane. Preferably, an intersection point of the wheel carrier rotation axis with the horizontal plane is arranged behind the vertical plane in the direction of travel.

The wheel suspension described is extremely compact, particularly in the longitudinal direction of the vehicle. It also enables the use of an electric traction machine in combination with a steerable wheel axle or a steerable wheel. In particular, the traction machine is arranged in the direction of travel behind an axle differential gear. Furthermore, special and misuse loads acting on the chassis control arms are reduced, particularly in comparison with vehicle control arms that are mainly aligned in the transverse direction of the vehicle. A linear course of the track curve over the compression is also achieved by appropriate alignment of the vehicle control arms.

A further development of the invention provides that the wheel carrier rotation axis intersects the horizontal plane at an angle that is at least 75° and at most 105°, at least 80° and at most 100°, at least 85° and at most 95° or approximately or exactly 90°. This means that the vehicle controls are arranged and aligned in such a way that the wheel carrier rotation axis is perpendicular or at least almost perpendicular to the ground or a road surface. This realizes the aforementioned advantages.

A further development of the invention provides that a wheel center plane receiving the wheel center is arranged in the axial direction with respect to the wheel hub axis of rotation in the middle of a wheel attached or attachable to the wheel hub, wherein each of the chassis links has a longitudinal center axis intersecting the wheel center plane in the second orthant or in a third of the orthants on the same side of the vertical plane. The wheel center point lies in the wheel center plane. The wheel center plane is preferably perpendicular to the wheel carrier axis of rotation. In the axial direction, the wheel center plane is arranged centrally with respect to the wheel, i.e. it intersects the wheel in its center. The second orthant has already been explained; it lies below the horizontal plane and behind the vertical plane in the direction of travel. The third orthant lies on the same side of the vertical plane as the second orthant. Accordingly, it also lies behind the vertical plane in the direction of travel, but above the horizontal plane.

The longitudinal center axis of each chassis link intersects the wheel center plane in the second orthant or in the third orthant. This means that intersection points of the longitudinal center axes of the chassis links with the wheel center plane are arranged either in the second orthant, the third orthant or both the second orthant and the third orthant. For example, at least one of the intersection points lies in the second orthant and at least one other of the intersection points in the third Orthant. Preferably, several of the intersection points are located in the second Orthant and the third Orthant. In particular, the intersection points for the chassis links of the first link arrangement are located in the third Orthant and the intersection points for the chassis links of the second link arrangement are located in the second Orthant. In other words, the longitudinal center axes intersect the wheel center plane on the one hand of the vertical plane, namely on the side of the vertical plane that is at the rear in the direction of travel. This also serves to achieve the advantages already mentioned.

A further development of the invention provides that the chassis links are each articulated to the wheel carrier via a first kinematic point, wherein the first kinematic points of the chassis links of the first link arrangement are in the first orthant and/or the third orthant, and/or that the first kinematic points of the chassis links of the second link arrangement are in the second orthant and/or a fourth of the orthants arranged on the same side of the horizontal plane. The first kinematic points of the chassis links have already been discussed. The chassis links are articulated to the body directly or indirectly via these. The orthants and their arrangement have already been explained. The fourth orthant is arranged on the same side of the horizontal plane as the second orthant. It lies accordingly below the horizontal plane and is arranged in front of the vertical plane in the direction of travel.

The first kinematic points of the chassis links of the first link arrangement are either in the first orthant, the third orthant, or in both the first orthant and the third orthant. For example, one of the first kinematic points is in the first orthant and another of the first kinematic points is in the third orthant. In other words, the first kinematic points of the chassis links of the first link arrangement are above the horizontal plane, i.e. on the side of the horizontal plane facing away from the ground. In the vertical direction of the vehicle, they are therefore above the center of the wheel.

Additionally or alternatively, the first kinematic points of the chassis links of the second link arrangement are located in the second orthant, the fourth orthant, or both in the second orthant and in the fourth orthant. For example, one of the first kinematic points is located in the second orthant and another of the first kinematic points is located in the fourth orthant. In other words, the first kinematic points of the chassis links of the second link arrangement are below the horizontal plane and consequently on the side of the horizontal plane facing the ground. This means that the first kinematic points are located below the wheel center in the vertical direction of the vehicle.

Additionally or alternatively, the first kinematic points of the chassis links of the first link arrangement are located in the vertical direction of the vehicle above the tie rod kinematic point or above the entire tie rod. Additionally or alternatively, the first kinematic points of the chassis links of the second link arrangement are located in the vertical direction of the vehicle below the tie rod kinematic point, preferably below the entire tie rod. It can be provided that the first kinematic points of the chassis links of the first link arrangement and the first kinematic points of the chassis links of the second link arrangement are arranged in the vertical direction of the vehicle on opposite sides of an imaginary plane that runs through the tie rod kinematic point and is aligned parallel to the horizontal plane. The described embodiment also serves to achieve the advantages mentioned.

A further development of the invention provides that the chassis links are each articulated or articulated via a second kinematic point to a body or a subframe connected or connectable to the body, wherein the second kinematic points of the chassis links of the first link arrangement are in the first orthant and/or the third orthant and/or the second kinematic points of the chassis links of the second link arrangement are in the second orthant and/or the fourth orthant. The chassis links are thus articulated to the body or the subframe via the second kinematic points. The subframe is an element of the motor vehicle that is separate from the body and which in turn is articulated or attached to the body. The subframe serves to stiffen the body. By means of the subframe, forces acting between the second kinematic points, which act on the subframe via the chassis links, are at least partially balanced before they are introduced into the body.

The second kinematic points of the chassis links of the first link arrangement are located in the first orthant, the third orthant or both the first orthant and the third orthant. In the latter case, for example, at least one of the second kinematic points is located in the first orthant and at least one other of the second kinematic points is located in the third orthant. In other words, the second kinematic points of the chassis links of the first link arrangement are located in the vertical direction of the vehicle above the wheel center or on the side of the horizontal plane facing away from the ground.

Additionally or alternatively, the second kinematic points of the chassis links of the second link arrangement are located in the first orthant, the fourth orthant or both the second orthant and the fourth orthant. In the latter case, for example, at least one of the second kinematic points is located in the second orthant and at least one other of the second kinematic points is located in the fourth orthant. In other words, the second kinematic points of the chassis links of the second link arrangement are located in the vertical direction of the vehicle below the wheel center or on the side of the horizontal plane facing the ground. This also achieves the goal of creating a particularly compact wheel suspension.

A further development of the invention provides that a first of the chassis links of the first link arrangement and a first of the chassis links of the second link arrangement are arranged such that their second kinematic points are arranged in the first orthant and/or the fourth orthant, and/or that a second of the chassis links of the first link arrangement and a second of the chassis links of the second link arrangement are arranged such that their second kinematic points are arranged in the second orthant and/or the third orthant.

This means that the second kinematic points of the two first suspension links are in the first orthant, in the fourth orthant or in both the first orthant and the fourth orthant. In the latter case, for example, the second kinematic point of at least one of the first suspension links is in the first orthant and the second kinematic point of at least one other of the first suspension links is in the fourth orthant. In other words, the second kinematic points of the two first suspension links are in front of the vertical plane in the direction of travel of the motor vehicle, i.e. on the side of the vertical plane facing the front of the motor vehicle.

Additionally or alternatively, the second kinematic points of the two second chassis links are arranged in the second orthant, the third orthant or both in the second orthant and in the third orthant. In the latter case, the second kinematic point of at least one of the second chassis links is in the second orthant and the second kinematic point of at least one other of the second chassis links is in the third orthant. In other words, the second kinematic points of the second chassis links are behind the vertical plane in the direction of travel, on a side of the vertical plane facing the rear of the motor vehicle. The objectives described at the beginning are also achieved with such a design of the wheel suspension.

A further development of the invention provides that the chassis links each intersect the vertical plane at a sweep angle, with a mean sweep angle of the chassis links of the first link arrangement and a mean sweep angle of the chassis links of the second link arrangement having different signs. The sweep angle describes the orientation of the chassis links in the longitudinal direction of the vehicle. The sweep angle is therefore to be understood as the angle at which the chassis links or their respective longitudinal center axis intersect the vertical plane, namely when viewed from above onto the horizontal plane. The respective sweep angle is thus determined in an imaginary plane which is parallel to the horizontal plane and lies at the intersection point of the longitudinal center axis of the former chassis link and the vertical plane.

The sweep angle of the chassis links of the first link arrangement is calculated by averaging the sweep angles of the chassis links of the first link arrangement, and the sweep angle of the second link arrangement is calculated by averaging the sweep angles of the chassis links of the second link arrangement. The sweep angle corresponds to an angle at which an imaginary straight line intersects the vertical plane when viewed from above, with the imaginary straight line describing an angle bisector of the respective chassis links or their longitudinal center axes.

The mean sweep angles have different signs. This means that the chassis links of the first link arrangement on the one hand and the chassis links of the second link arrangement on the other hand are inclined in different directions with respect to the vertical plane in the longitudinal direction of the vehicle on average. An imaginary first straight line lying between the longitudinal center axes of the chassis links of the first link arrangement in plan view and a second imaginary straight line lying centrally between the longitudinal center axes of the chassis links of the second link arrangement in plan view are inclined in different directions with respect to the vertical plane, namely again viewed from above. For example, the first straight line in a direction extending from the wheel carrier device of the second kinematic points is further forward in the direction of travel than the second imaginary straight line. This again achieves the aforementioned advantages.

A further development of the invention provides that at least one of the sweep angles is at least 10° and at most 40°. At least one of the sweep angles, but preferably several of the sweep angles, particularly preferably All sweep angles are - in terms of magnitude - between 10° and 40°, including these values. Again, this serves to achieve the advantages mentioned.

A further development of the invention provides that the tie rod has, on its side facing away from the tie rod kinematics point, a further tie rod kinematics point which is at a distance from the vertical plane that is at least 80% and at most 120% of a distance between the vertical plane and the second kinematics point of the first chassis link of the second link arrangement. The further tie rod kinematics point is on the side of the tie rod facing away from the wheel carrier. The tie rod kinematics point can also be referred to as the first tie rod kinematics point and the further tie rod kinematics point as the second tie rod kinematics point.

Viewed in the longitudinal direction of the vehicle, the further tie rod kinematics point and the second kinematics point of the first chassis link of the second link arrangement are at exactly or at least approximately at the same height. The distance of the further tie rod kinematics point from the vertical plane is therefore between 80% and 120% (these values included) of the distance between the vertical plane and the second kinematics point of the corresponding chassis link. This also makes it possible to achieve the aforementioned advantages in a simple manner.

A further development of the invention provides that a distance between the kinematic points of the first chassis link of the first link arrangement and/or a distance between the tie rod kinematic points of the tie rod is at least 50% and/or at most 75% of the distance between the kinematic points of the second chassis link of the first link arrangement and/or the distance between the kinematic points of the second chassis link of the second link arrangement. The distance between the kinematic points of the chassis links corresponds to their respective length, the distance between the tie rod kinematic points corresponds to the length of the tie rod.

The length of the first chassis control arm of the first control arm arrangement and/or the length of the tie rod are at least 50% of the length of the second chassis control arm of the first control arm arrangement or the length of the second chassis control arm of the second control arm arrangement. Additionally or alternatively, the length of the first chassis control arm of the first control arm arrangement and/or the length of the tie rod are at most 75% of the length of the second chassis control arm of the first control arm arrangement or the length of the second chassis control arm of the second control arm arrangement. This also serves to achieve the advantages mentioned at the beginning.

A development of the invention provides that the first kinematic point of the first chassis link of the first link arrangement and/or the first kinematic point of the first chassis link of the second link arrangement have a distance from the vertical plane that is smaller than a distance of the first kinematic point of the second chassis link of the first link arrangement from the vertical plane and/or than a distance of the first kinematic point of the second chassis link of the second link arrangement from the vertical plane. In other words, the first kinematic point of the first chassis link of the first link arrangement or the first kinematic point of the first chassis link of the second link arrangement is closer to the vertical plane than the first kinematic point of the second chassis link of the first link arrangement or the second chassis link of the second link arrangement.

For example, the vertical plane intersects the first kinematic point of the first chassis link of the first link arrangement and/or the first kinematic point of the first link of the second link arrangement or is at least very close to them. The first kinematic point of the second chassis link of the first link arrangement and/or the first kinematic point of the second chassis link of the second link arrangement are, however, further away from the vertical plane. For example, the distance of the first kinematic point of the first chassis link of the first link arrangement and/or the distance of the first kinematic point of the first chassis link of the second link arrangement is at most 30%, at most 20% or at most 10% of the distance of the first kinematic point of the second chassis link of the first link arrangement and/or the distance of the first kinematic point of the second chassis link of the second link arrangement. Again, the aforementioned advantages are achieved in this way.

A further development of the invention provides that the first kinematic point of the second chassis link of the first link arrangement and/or the first kinematic point of the second chassis link of the second link arrangement are located in the second orthant and/or the third orthant. The two first kinematic points are therefore located, for example, in the second orthant, the third orthant or both in the second orthant and in the third orthant. In particular, one of the first kinematic points is located in the second orthant and another of the first kinematic points is located in the third orthant. Ultimately, this means that little At least one of the first kinematic points, preferably both first kinematic points, are arranged above the horizontal plane, i.e. on the side facing away from the ground. This again achieves the advantages mentioned.

A further development of the invention provides that a coupling rod is connected to the wheel carrier at a first coupling rod kinematic point and to a stabilizer or one of the chassis links at a second coupling rod kinematic point. In addition to the chassis links and the tie rod, the wheel suspension therefore has the coupling rod. The coupling rod connects the wheel carrier to the stabilizer or the chassis link. For this purpose, the coupling rod is connected to the wheel carrier at its first coupling rod kinematic point and to either a stabilizer or the chassis link at its second coupling rod kinematic point. The coupling rod eliminates one degree of freedom of the wheel carrier, ensuring reliable guidance of the wheel carrier in the vertical direction of the vehicle.

A further development of the invention provides that a wheel spring and/or a wheel damper are articulated to the second chassis link of the second link arrangement. The wheel spring and the wheel damper can be separate from one another or they can be designed as a spring-damper unit. In any case, the wheel spring, the wheel damper or both engage the second chassis link of the second link arrangement or are articulated to it. They are particularly preferably arranged between the chassis links of the first link arrangement or extend between them in the direction of the second chassis link of the second link arrangement. This also serves to achieve the advantages mentioned.

The invention further relates to a motor vehicle with a wheel suspension, in particular a wheel suspension according to the statements in the context of this description, wherein the wheel suspension has a wheel carrier on which a wheel hub is or can be mounted so as to be rotatable about a wheel hub axis of rotation by means of a wheel bearing, and two chassis links of a first link arrangement, two chassis links of a second link arrangement and a tie rod articulated to a tie rod kinematics point on the wheel carrier, wherein the chassis links are articulated to the wheel carrier in such a way that the wheel carrier describes a rotational movement about a virtual wheel carrier axis of rotation when the tie rod is displaced, and wherein a horizontal plane receiving a wheel center and aligned horizontally and a vertical plane receiving the wheel center and perpendicular to the horizontal plane delimit several orthants from one another, wherein in the installed position of the wheel suspension the tie rod kinematics point is arranged in a first of the orthants. It is provided that the wheel carrier rotation axis runs through a second of the orthants opposite the first orthant with respect to the wheel hub rotation axis.

The advantages of such a design of the motor vehicle or the wheel suspension have already been pointed out. Both the motor vehicle and the wheel suspension can be further developed in accordance with the statements in this description, so reference is made to these in this respect.

The features and combinations of features described in the description, in particular the features and combinations of features described in the following description of the figures and/or shown in the figures, can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the invention. Thus, embodiments are also to be regarded as being encompassed by the invention that are not explicitly shown or explained in the description and/or the figures, but which emerge from the embodiments explained or can be derived from them.

• 1 eine schematische isometrische Darstellung einer Radaufhängung für ein Kraftfahrzeug,
• 2 eine schematische Seitendarstellung der Radaufhängung,
• 3 eine weitere schematische Darstellung der Radaufhängung,
• 4 eine schematische Draufsicht auf die Radaufhängung in einer ersten Ansicht,
• 5 eine schematische Draufsicht auf die Radaufhängung in einer zweiten Ansicht, sowie
• 6 eine schematische Seitendarstellung der Radaufhängung.

The invention is explained in more detail below using the initial examples shown in the drawing, without limiting the invention. In the drawing:

• 1 a schematic isometric representation of a wheel suspension for a motor vehicle,
• 2 a schematic side view of the wheel suspension,
• 3 another schematic representation of the wheel suspension,
• 4 a schematic plan view of the wheel suspension in a first view,
• 5 a schematic plan view of the wheel suspension in a second view, as well as
• 6 a schematic side view of the wheel suspension.

The 1 shows a schematic isometric representation of a wheel suspension 1 for a motor vehicle not shown in detail. The wheel suspension 1 serves to suspend a wheel 2 on a body of the motor vehicle not shown. In the embodiment shown here, the wheel 2 has a rim 3 and a tire 4, whereby the latter is an air-filled tire. The wheel 2, in particular the rim 3, is attached to a wheel hub 5, in particular detachably attached. The wheel hub 5, which is not visible here, is mounted on a wheel carrier 7 so as to be rotatable about a wheel hub rotation axis 8 by means of a wheel bearing 6 (also not shown).

The wheel carrier 7 is in turn mounted on the body of the motor vehicle by means of a first link arrangement 9 and a second link arrangement 10. The first link arrangement 9 has a first chassis link 11 and a second chassis link 12. The second link arrangement 10 has a first chassis link 13 and a second chassis link 14. The first chassis link 11 has a first kinematic point 15 and a second kinematic point 16, the second chassis link 12 has a first kinematic point 17 and a second kinematic point 18. The first chassis link 13 of the second link arrangement 10 has a first kinematic point 19 and a second kinematic point 20, the second chassis link 14 has a first kinematic point 21 and a second kinematic point 22. The chassis links 11, 12, 13 and 14 are articulated to the wheel carrier 7 via the first kinematic points 15, 17, 19 and 21 and to the body via their second kinematic points 16, 18, 20 and 22.

In addition to the chassis links 11, 12, 13 and 14, the wheel suspension 1 has a tie rod 23 which is articulated at a first tie rod kinematic point 24 on the wheel carrier 7 and at a second tie rod kinematic point 25 on the body or a steering device of the motor vehicle. There is also a coupling rod 26 which is articulated at a first coupling rod kinematic point 27 on the wheel carrier 7 and at a second coupling rod kinematic point 28 on a stabilizer 29. In the embodiment shown, the wheel 2 is a drivable wheel, and the wheel hub 5 is accordingly coupled to a drive shaft 30. However, this can also be omitted, in which case the wheel 2 cannot be driven.

The kinematic points 15 and 16, 17 and 18, 19 and 20, 21 and 22 and 24 and 25 each define a longitudinal center axis 31, 33, 33, 34 and 35 of the respective chassis control arm 11, 12, 13 and 14 or the tie rod 23. The wheel carrier 7 is articulated to the body by means of the two control arm arrangements 9 and 10 and the tie rod 23 in such a way that it rotates about a virtual wheel carrier axis of rotation 36 (only indicated very schematically here) when the tie rod 23 is (imagined) displaced. For example, an infinitesimally small displacement of the tie rod 23, in particular in the direction of its longitudinal center axis 35, leads to an infinitesimally small rotational movement of the wheel carrier 7 about the wheel carrier axis of rotation 36.

The 2 shows a schematic side view of the wheel suspension 1, wherein the wheel 2 is not shown. However, a wheel center 37 can be seen, which lies on the wheel hub axis of rotation 8 and is centrally located in the axial direction with respect to the wheel hub axis of rotation 8 with respect to the wheel 2. A horizontal plane 38 and a vertical plane 39 run through the wheel center 37. The horizontal plane 38 is arranged horizontally with respect to a surface or a roadway on which the motor vehicle is intended to be located, and the vertical plane 39 is perpendicular to the horizontal plane 38. Both include the wheel center 37, so that the wheel center 37 lies on an imaginary straight line of intersection of the horizontal plane 38 and the vertical plane 39.

When the wheel suspension 1 is arranged as intended, the vertical plane 39 is arranged perpendicular to the ground and is thus aligned parallel to a gravity vector describing the gravity acting on the wheel suspension 1. The horizontal plane 38 and the vertical plane 39 separate a first orthant 40, a second orthant 41, a third orthant 42 and a fourth orthant 43 from each other. The first orthant 40 and the second orthant 41 are mirror images of each other with respect to the wheel hub rotation axis 8 or the wheel center 37. This also applies to the third orthant 42 and the fourth orthant 43.

It follows from this that the first Orthant 40 and the third Orthant 42 are arranged above the horizontal plane 38 and the second Orthant 41 and the fourth Orthant 43 are arranged below the horizontal plane 38. In addition, the first Orthant 40 and the fourth Orthant 43 are arranged in front of the vertical plane 39 in the direction of travel of the motor vehicle and the second Orthant 41 and the third Orthant 42 are arranged behind the vertical plane 39 in the direction of travel. In other words, viewed in the direction of a vehicle's longitudinal axis and a vehicle's vertical axis, the first Orthant 40 is at the top front, the second Orthant 41 is at the bottom rear, the third Orthant 42 is at the top rear and the fourth Orthant 43 is at the bottom front.

The wheel suspension is designed such that the first tie rod kinematic point 24 is arranged in the first orthant 40. Furthermore, the first kinematic points 15 and 17 of the chassis links 11 and 12 of the first link arrangement 9 are arranged above the horizontal plane 8 and thus in the first orthant 40 and the third orthant 42. Furthermore, the first kinematic points 19 and 21 of the chassis links 13 and 14 of the second link arrangement 10 are arranged below the horizontal plane 38, thus lying in the second orthant 41 and the fourth orthant 43. The second kinematic points 16 and 18 of the chassis links 11 and 12 of the first link arrangement 9 are also arranged above the horizontal plane 38, thus lying in the first orthant 40 and the third orthant 42. The second kinematic points 20 and 22 of the chassis links 13 and 14 of the second link arrangement 10 are arranged below the horizontal plane 38, thus lying in the second orthant 41 and the fourth orthant 43.

The second kinematic points 16 and 20 of the chassis links 11 and 13 are arranged in front of the vertical plane 39 in the direction of travel, i.e. in the first orthant 40 and the fourth orthant 43. The second kinematic points 18 and 22 of the chassis links 12 and 14 are arranged behind the vertical plane 39 in the direction of travel, i.e. in the second orthant 41 and the third orthant 42. It can also be seen that the second kinematic point 20 of the first chassis link 13 of the second link arrangement 10 is just as far away from the vertical plane as the second tie rod kinematic point 25. However, at least the distance is similar, for example the distance of the tie rod kinematic point 25 is at least 80% and at most 120% of the distance of the kinematic point 20 from the vertical plane 39.

The 3 shows a further schematic representation of the wheel suspension 1. It can be seen here that the longitudinal center axes 31 and 32 and the longitudinal center axes 33 and 34 of the chassis links 11 and 12 and the chassis links 13 and 14 each meet at an intersection point 44 and 45 respectively. The two intersection points 44 and 45 lie on the wheel carrier axis of rotation 36 or define it. It can be seen that the wheel carrier axis of rotation 36 lies below the horizontal plane 38 running through the wheel center 37 in the direction of travel behind the horizontal plane 38 and thus in the second orthant 41. The direction of travel of the motor vehicle is indicated by the arrow 46.

The 4 shows a schematic top view of the wheel suspension 1 in a first view. In addition to the vertical plane 39, a wheel center plane 47 is now shown, which is perpendicular to the vertical plane 39 and includes the wheel center 37. It is clear that intersection points of the longitudinal center axes 31, 32, 33 and 34 of the chassis links 11, 12, 13 and 14 intersect the wheel center plane 47 in the direction of travel behind the vertical plane 39, i.e. in the second orthant 41 and/or the third orthant 42. This results in a wheel carrier rotation axis 36 which is almost perpendicular to the ground or the roadway, provided the motor vehicle is arranged as intended. Furthermore, it is clearly visible that the first kinematic points 15 and 19 of the chassis links 11 and 13, i.e. the front chassis links, are close to the vertical plane 39, at least closer than the kinematic points 17 and 21 of the chassis links 12 and 14, i.e. the rear chassis links.

The 5 shows a schematic top view of the wheel suspension 1 in a second view. The longitudinal center axes 31, 32, 33 and 34 of the chassis links 11, 12, 13 and 14 each intersect the vertical plane 39 at a sweep angle when viewed from above. The average sweep angles of the link arrangements 9 and 10 result from the average of the sweep angles of the respective chassis links 11 and 12 or 13 and 14. For the first link arrangement 9, the average sweep angle is indicated by the bisector 48 and for the second link arrangement 10 by the second bisector 49. It can be seen that the average sweep angles have different signs with respect to the vertical plane 39. In addition, the second kinematic points 16, 20 and 25 are located in front of the vertical plane 39 in the direction of travel, and the second kinematic points 18 and 22 are located behind the vertical plane 39 in the direction of travel.

The 6 shows a schematic side view of the wheel suspension 1. It can be seen that all kinematic points 19, 20, 21 and 22 of the chassis links 13 and 14 of the second link arrangement 10 are located below the wheel center point 37 or below the horizontal plane 38. In addition, they are arranged below the kinematic points 24 and 25 of the tie rod 23 or below the entire tie rod 23.

The described wheel suspension 1 is particularly compact and, in addition, a wheel 2 suspended with it can advantageously be driven with an electric traction machine. It should be expressly pointed out that in the exemplary embodiment, some or even all of the features explained in the description are shown in combination with one another. The wheel suspension 1 can, of course, also be implemented in other embodiments with which the described advantages are achieved, which only have some of the features and not others.

LIST OF REFERENCE SYMBOLS:

1

Wheel suspension

2

wheel

3

rim

4

Tires

5

wheel hub

6

Wheel bearing

7

Wheel carrier

8th

Wheel hub rotation axis

9

1. Handlebar arrangement

10

2. Handlebar arrangement

11

1. Chassis link

12

2. Chassis link

13

1. Chassis link

14

2. Chassis link

15

1. Kinematic point of the 1st chassis link of the 1st link arrangement

16

2. Kinematic point of the 1st chassis link of the 1st link arrangement

17

1. Kinematic point of the 2nd chassis link of the 1st link arrangement

18

2. Kinematic point of the 2nd chassis link of the 1st link arrangement

19

1. Kinematic point of the 1st chassis link of the 2nd link arrangement

20

2. Kinematic point of the 1st chassis link of the 2nd link arrangement

21

1. Kinematic point of the 2nd chassis link of the 2nd link arrangement

22

2. Kinematic point of the 2nd chassis link of the 2nd link arrangement

23

Tie rod

24

1. Tie rod kinematics point

25

2. Tie rod kinematics point

26

Coupling rod

27

1. Coupling rod kinematic point

28

2. Coupling rod kinematic point

29

stabilizer

30

drive shaft

31

Longitudinal center axis

32

Longitudinal center axis

33

Longitudinal center axis

34

Longitudinal center axis

35

Longitudinal center axis

36

Wheel carrier rotation axis

37

Wheel center

38

Horizontal plane

39

Vertical plane

40

1. Orthant

41

2. Orthant

42

3. Orthant

43

4. Orthant

44

Intersection

45

Intersection

46

Arrow

47

Wheel center plane

48

Angle bisector

49

Angle bisector

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed 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 accepts no liability for any errors or omissions.

Cited patent literature

• DE 102018206402 A1 [0002]
• DE 102019002655 A1 [0003]

Claims (10)

Wheel suspension (1) for a motor vehicle, with a wheel carrier (7) on which a wheel hub (5) is or can be mounted so as to be rotatable about a wheel hub axis of rotation (8) by means of a wheel bearing (6), and with two chassis links (11, 12) of a first link arrangement (9), two chassis links (13, 14) of a second link arrangement (10) and a tie rod (23) articulated to a tie rod kinematics point (24) on the wheel carrier (7), wherein the chassis links (11, 12, 13, 14) are articulated to the wheel carrier (7) in such a way that the wheel carrier (7) describes a rotational movement about a virtual wheel carrier axis of rotation (36) when the tie rod (23) is displaced, and wherein a horizontal plane (38) receiving a wheel center (37) and is horizontally aligned and a horizontal plane (38) receiving the wheel center (37) and standing perpendicular to the horizontal plane (38) Vertical plane (39) delimits several orthants (40, 41, 42, 43) from one another, wherein in the installed position of the wheel suspension (1) the tie rod kinematics point (24) is arranged in a first of the orthants (40, 41, 42, 43), characterized in that the wheel carrier axis of rotation (36) runs through a second of the orthants (40, 41, 42, 43) opposite the first orthant (40) with respect to the wheel hub axis of rotation. Wheel suspension after Claim 1 , characterized in that a wheel center plane (47) receiving the wheel center (37) is arranged in the axial direction with respect to the wheel hub axis of rotation (8) in the middle of a wheel (2) fastened or fastenable to the wheel hub (5), wherein each of the chassis links (11, 12, 13, 14) has a longitudinal center axis (31, 2 30, 33, 34) intersecting the wheel center plane (47) in the second orthant (41) or in a third of the orthants (40, 41, 2 40, 43) present on the same side of the vertical plane (39). Wheel suspension according to one of the preceding claims, characterized in that the chassis links (11, 12, 13, 14) are each articulated to the wheel carrier (7) via a first kinematic point (15, 17, 19, 21), the first kinematic points (15, 17, 19, 21) of the chassis links (11, 12) of the first link arrangement (9) being present in the first orthant (40) and/or in the third orthant (42), and/or that the first kinematic points (19, 21) of the chassis links (13, 14) of the second link arrangement (10) being present in the second orthant (41) and/or a fourth of the orthants (40, 41, 42, 43) arranged on the same side of the horizontal plane (38). Wheel suspension according to one of the preceding claims, characterized in that the chassis links (11, 12, 13, 14) are each articulated or articulateable via a second kinematic point (16, 18, 20, 22) to a body or to a subframe connected or connectable to the body, wherein the second kinematic points (16, 18) of the chassis links (11, 12) of the first link arrangement (9) are present in the first orthant (40) and/or the third orthant (42) and/or the second kinematic points (20, 22) of the chassis links (13, 14) of the second link arrangement (10) are present in the second orthant (41) and/or the fourth orthant (43). Wheel suspension according to one of the preceding claims, characterized in that a first of the chassis links (11, 12) of the first link arrangement (9) and a first of the chassis links (13, 14) of the second link arrangement (10) are arranged such that their second kinematic points (16, 20) are arranged in the first orthant (40) and/or the fourth orthant (43), and/or that a second of the chassis links (11, 12) of the first link arrangement (9) and a second of the chassis links (13, 14) of the second link arrangement (10) are arranged such that their second kinematic points (18, 22) are arranged in the second orthant (41) and/or the third orthant (42). Wheel suspension according to one of the preceding claims, characterized in that the chassis links (11, 12, 13, 14) each intersect the vertical plane (39) at a sweep angle, wherein a mean sweep angle of the chassis links (11, 12) of the first link arrangement (9) and a mean sweep angle of the chassis links (13, 14) of the second link arrangement (10) have different signs. Wheel suspension according to one of the preceding claims, characterized in that the tie rod (23) has, on its side facing away from the tie rod kinematics point (24), a further tie rod kinematics point (25) which has a distance from the vertical plane (39) which is at least 80% and at most 120% of a distance between the vertical plane (39) and the second kinematics point (20) of the first chassis link (13) of the second link arrangement (10). Wheel suspension according to one of the preceding claims, characterized in that a distance between the kinematic points (15, 16) of the first chassis link (11) of the first link arrangement (9) and/or a distance between the tie rod kinematic points (24, 25) of the tie rod (23) is at least 50% and/or at most 75% of the distance between the kinematic points (17, 18) of the second chassis link (12) of the first link arrangement (9) and/or the distance between the kinematic points (21, 42) of the second chassis link (14) of the second link arrangement (10). Wheel suspension according to one of the preceding claims, characterized in that the first kinematic point (15) of the first chassis link (11) of the first link arrangement (9) and/or the first kinematic point (19) of the first chassis link (13) of the second link arrangement (10) have a distance from the vertical plane (39) which is smaller than a distance of the first kinematic point (17) of the second chassis link (12) of the first link arrangement (9) from the vertical plane (39) and/or than a distance of the first kinematic point (21) of the second chassis link (14) of the second link arrangement (10) from the vertical plane (39). Motor vehicle with a wheel suspension (1), in particular a wheel suspension (1) according to one or more of the preceding claims, wherein the wheel suspension (1) has a wheel carrier (7) on which a wheel hub (5) is or can be mounted so as to be rotatable about a wheel hub axis of rotation (8) by means of a wheel bearing (6), and two chassis links (11, 12) of a first link arrangement (9), two chassis links (13, 14) of a second link arrangement (10) and a tie rod (23) articulated to a tie rod kinematics point (24) on the wheel carrier (7), wherein the chassis links (11, 12, 13, 14) are articulated to the wheel carrier (7) in such a way that the wheel carrier (7) describes a rotational movement about a virtual wheel carrier axis of rotation (36) when the tie rod (23) is displaced, and wherein a wheel center (37) receiving and horizontally oriented A horizontal plane (38) and a vertical plane (39) receiving the wheel center (37) and perpendicular to the horizontal plane (38) delimit several orthants (40, 41, 42, 43) from one another, wherein in the installed position of the wheel suspension (1) the tie rod kinematics point (24) is arranged in a first of the orthants (40, 41, 42, 43), characterized in that the wheel carrier axis of rotation (36) runs through a second of the orthants (40, 41, 42, 43) opposite the first orthant (40) with respect to the wheel hub axis of rotation.

Images