Abstract: An independent rear suspension of a motor vehicle with an electrical drivetrain. The independent rear suspension including a left semi-trailing arm and a right semi-trailing arm, each of which can be articulated with an end on the body side to a chassis of the motor vehicle and are fixedly connectable to a wheel carrier on an end on the wheel carrier side, and also a transverse leaf spring for the suspension of the rear wheels. The transverse leaf spring is attached on the end side to the ends of the semi-trailing arms on the wheel carrier side, so that between the semi-trailing arms and the transverse leaf spring is formed an open installation space for receiving at least part of the electrical drivetrain.

Abstract: A control arm including a frame, a mounting structure on the frame, and a ball-and-socket joint on the frame. The ball-and-socket joint includes an insert formed of a resilient plastic material bonded in a complementary receptacle or socket of the frame. A ball portion of a ball-and-socket joint pin is rotatably arranged in the insert. A plastic material coating is provided on the ball portion and a metal coating is provided on the plastic material coating. When placed in the insert the metal coating of the ball portion contacts an inner surface of the insert.

Abstract: A longitudinal leaf spring device for the suspension of a body of a motor vehicle has a leaf spring unit in an elongated form, a coupling device for the mechanical coupling of the leaf spring unit to a motor vehicle axle and at least one bump stop unit having two separate elastic stop elements which can be connected, in a manner arranged vertically above one another, to a chassis or to the axle. According to the invention, perpendicular directions to a downwardly directed mean contact area of the upper stop element and to an upwardly directed mean contact area of the lower stop element each form an angle other than zero with the vertical.

Abstract: A fiber-reinforced plastic leaf spring and a method for producing the fiber-reinforced plastic leaf spring are provided, which is suitable in particular for use in a motor vehicle. It has an elongate leaf spring main body which comprises a first eye bushing at a first end and a second eye bushing at a second end. The leaf spring main body and the first and second eye bushings are formed using at least a first layer and a second layer of a composite material. Each of the layers is guided along a centerline of the leaf spring main body to form the leaf spring main body and, to form the first and second eye bushings, is respectively wrapped around a bushing element having a first center axis and around a bushing element having a second center axis.

Abstract: The disclosure relates to a longitudinal leaf spring device for suspension of a body of a motor vehicle. and the longitudinal leaf spring device comprises a longitudinally formed leaf spring element and a coupling device that mechanically couples the leaf spring element to a motor vehicle axle. According to the disclosure, a holder device is provided that has a base holder element for fixed connection to a vehicle chassis and a suspension adjustment element that faces the leaf spring element and is fixedly connected to the base holder element. In this case, the leaf spring element is connected in a front region, fixedly to the base holder element, and the front region is provided to come into mechanical bearing with the suspension adjustment element in at least one operating state.

Abstract: The disclosure relates to a method for operating a brake pedal unit of a vehicle, comprising feedback to a driver. The brake pedal unit has a multiplicity of pressure-sensitive or force-sensitive sensors. According to the disclosure, in the method, output signals of the multiplicity of pressure-sensitive or force-sensitive sensors are detected. At least one position and/or an orientation of the operator's foot relative to the foot support element is determined from the detected output signals. A feedback signal that characterizes the determined position and/or orientation is output at an output unit of the vehicle.

Abstract: The disclosure concerns a spring assembly with a leaf spring. The leaf spring extends in a vehicle longitudinal axis, supports a vehicle axle and is connected at least indirectly to a vehicle superstructure at a front end and at a rear end. In order to provide a wheel suspension with advantageous springing and damping behavior that is optimized with regard to weight and complexity, according to the disclosure it is provided that at least one damping region, which is at least partially fluid-filled, is integrated in the leaf spring.

Abstract: The present disclosure relates to a motor vehicle, and more specifically relates to a motor vehicle including a device for the delimitation of an extended loading area. This disclosure also relates to a corresponding method of using the subject device. In particular, the disclosed device comprises a plurality of braces (or, posts). Each of the braces comprises a longitudinal axis. The braces are connected to one another such that the spacing is variable. In one example, adjacent braces are connected by a connection element that can be deformed perpendicularly relative to the longitudinal axes. In particular, the connection elements can be elastically deformed such that they are capable of returning to their original shape after deformation.

Abstract: The invention relates to a multi-link rear suspension for a motor vehicle, having at least one transverse leaf spring arranged on the motor vehicle to extend in the transverse vehicle direction and having ends which operatively act on left and right wheel carriers to cushion a vehicle structure of the motor vehicle with respect to the wheel-carriers. The transverse leaf spring also serves as a stabilizer, thereby replacing dedicated stabilizer. In order to provide a multi-link rear suspension which is optimized in terms of structural space and which is lightweight, the multi-link rear has exclusively transverse links for guiding the wheel-carriers.

Abstract: A selective adhesion liquid silicone rubber composition is disclosed. The liquid silicone rubber composition comprises an organopolysiloxane (A) containing at least two silicon-bonded alkenyl groups per molecule, an organopolysiloxane (B) containing at least two silicon-bonded hydrogen atoms per molecule, a platinum based catalyst (C), an inhibitor (D), a silica filler (E), and an adhesion promoter (F). The organopolysiloxane (B) comprises organopolysiloxane (B1) and organopolysiloxane (B2), wherein organopolysiloxane (B1) contains siloxy units of the type (R2HSiO1/2)x where x?2. Organopolysiloxane (B2) contains siloxy units of the type (RHSiO2/2)z where z?2. Each R is independently selected from a hydrogen atom, or an aliphatic hydrocarbyl, aromatic hydrocarbyl, or organyl group. The inhibitor (D) is selected from the group consisting of acetylenic alcohols and their derivatives.

Abstract: A liquid curable silicone elastomer composition is disclosed. The liquid curable silicone elastomer composition comprises an organopolysiloxane (A) containing at least two silicon-bonded alkenyl groups per molecule, an organopolysiloxane (B) containing at least two silicon-bonded hydrogen atoms per molecule, a platinum based catalyst (C), an inhibitor (D), and a silica filler (E). The organopolysiloxane (B) is a branched polymer, contains M siloxy units, and the at least two silicon-bonded hydrogen atoms are present on the M siloxy units. The inhibitor (D) is selected from the group consisting of acetylenic alcohols and their derivatives. The inhibitor (D) is present in the liquid curable silicone elastomer composition in an amount to provide a molar ratio—of the inhibitor (D) to platinum in the catalyst (C)—of from 150 to 900 (150:1 to 900:1).

Abstract: The disclosure relates to a motor vehicle, in particular an electric vehicle or a hybrid electric vehicle. The motor vehicle has a longitudinal link rear axle with independent suspensions. Each independent suspension has a wheel carrier, a longitudinal link rigidly connected to the wheel carrier, articulated to a vehicle body of the motor vehicle, and three lateral links connected firstly to the wheel carrier and secondly to the vehicle body, or to an auxiliary frame connected to the vehicle body. A wheel axle oriented in a lateral direction of the vehicle runs through the wheel carrier. To create additional installation space for an arrangement of a traction battery of the motor vehicle, the lateral links are arranged completely offset from the wheel axle at the rear end in relation to a longitudinal axis of the vehicle of the motor vehicle.

Abstract: An air-conditioning system includes a motor vehicle, in particular a passenger vehicle, and a drone. The drone is configured to be secured, in a secured state, to the motor vehicle and released from the motor vehicle. The drone is a flying drone that is driven using propellers. The drone, in the secured state, serves to air-condition the motor vehicle using the propellers by pushing air into the passenger vehicle through a roof of the vehicle. The roof defines openings that correspond to a propeller circumference that allow air, generated by the propellers, to flow into the passenger vehicle.

Abstract: A suspension member for connecting a vehicle wheel to a vehicle. In one example, the suspension member is a control arm having a control arm body and at least one bearing receiver having a bushing. The control arm body has a recess or opening extending one direction. The control arm body has a reinforcing structure in the recess or opening. The reinforcing structure formed of a material different from that of the control arm body. For example, the reinforcing structure is formed from a fiber-reinforced plastic, while the control arm body at least in regions comprises a lightweight metal or metal alloy.

Abstract: A wheel suspension for a motor vehicle including a wheel carrier supporting a wheel. The wheel carrier connected via at least one upper camber link, a lower control arm, and a lateral toe link to the vehicle body or subframe. A stabilizer rod connects to the wheel carrier. The wheel suspension including a damper unit and a spring unit wherein the stabilizer rod and the damper unit connect to the wheel carrier at a common connecting point.

Abstract: A vehicle axle suspension having a leaf spring unit suspending a rigid axle on a structural component or portion of the vehicle. The leaf spring unit arranged on the vehicle to extend parallel with a longitudinal axis of the vehicle. A first bearing unit, secured to the structure, and pivotably connects, at a first pivot axis, to a first end portion of the leaf spring unit. A second bearing unit is secured to the structure. A connection arm pivotably connects at one end, at a second pivot axis, to the second bearing unit. The other end of the connection arm pivotably connects, at a third pivot axis, to a second end portion of the leaf spring unit. The second bearing unit including at least one resilient spring element engaging the connection arm wherein the connection arm is supported on the resilient spring element from a pivoting about the second pivot axis a predetermined extent.

Abstract: A control arm for a wheel suspension of a motor vehicle. The control arm including a base body having a spring seat for receiving a helical spring of the wheel suspension. The control arm having a first end region connected to a spring-loaded component of the motor vehicle and a second end region connected to an unsprung component of the motor vehicle. The base body includes a first partial shell composed of steel and a second partial shell composed of a composite material, the shells undetachably fixedly connected to one another at least in one region of the spring seat.

Abstract: A method of forming a three-dimensional (3D) article comprises the steps of I) printing a first heat-curable silicone composition with a 3D printer to form a layer, II) heating the layer to form an at least partially cured layer, III) printing a second heat-curable silicone composition on the at least partially cured layer with the 3D printer to form a subsequent layer, and IV) heating the subsequent layer to form an at least partially cured subsequent layer. Optionally, steps III) and IV) can be repeated with independently selected heat-curable silicone composition(s) for any additional layer(s) to form the 3D article. The first and second heat-curable silicone compositions may be the same as or different from one another.

Abstract: A motor vehicle wheel suspension having a wheel carrier connected to the vehicle body or frame. The suspension having a lower transverse link. The wheel carrier connected to the lower transverse carrier at two connection locations. A first connection location on a first side wall of the wheel carrier and second connection location on a second side wall of the wheel carrier. The first connection location including a connector connected to both the lower transverse and the wheel carrier. The second connection location including a connection between the wheel carrier and the lower transverse link.

Abstract: A process for modifying a silicone elastomeric-based surface of an article where the coefficient of friction (COF) of the silicone elastomeric-based surface is generally reduced by at least 5% is disclosed. The process comprises subjecting the silicone elastomeric-based surface of the article to vacuum ultraviolet (UV) radiation.