An axle-to-beam connection for a suspension assembly of an axle/suspension system of a heavy-duty vehicle including an axle, a beam, and a top pad. The beam includes an alignment assembly for aligning the axle with the beam. The top pad includes an integrally-formed bump stop boss and is fixedly attached to the axle and removably attached to the alignment assembly of the beam.

An axle arrangement for a baler includes a first axle, a second axle, and a pair of elongate members. The first axle has first and second ends. First and second suspension cylinders are positioned at the first and second ends. The first axle is coupled with the chassis. The second axle has first and second ends. First and second suspension cylinders are positioned at the first and second ends to accommodate generally vertical loads. A first elongate member interconnects the first end of the second axle with the first end of the first axle. A second elongate member interconnects the second end of the second axle with the second end of the first axle.

Axle mounting unit (1), in particular for commercial vehicles, comprising a surrounding element (10), an end element (20), at least one fastening element (30) and a securing device (40), wherein the axle mounting unit (1) is configured for mounting a first chassis part (A), in particular an axle, with a second chassis part (L), in particular a control arm, wherein the surrounding element (10) is configured to be arranged on the first chassis part (A), wherein the end element (20) is configured to be arranged on the second chassis part (L), wherein the surrounding element (10) has at least two legs (12) which each extend in a leg direction (S), wherein the end element (20) extends between the two legs (12) or is configured to extend between the two legs (12), wherein the fastening element (30) braces the end element (20) with the surrounding element (10) or is configured to brace the end element (20) with the surrounding element (10), wherein the securing device (40) is a form-fit securing device and/or is a means for creating a form-fit securing device, wherein the form-fit securing device serves to limit and/or prevent a displacement of the separated part in the leg direction (S) in a positive-locking manner in the event of mechanical failure or the severing of a part of the axle assembly unit (1), in particular a part of the leg (12).

Provided herein is an electric axle assembly including a first motor-generator assembly, a second motor generator assembly, an axle housing, a first axle half shaft drivingly connected to the first motor-generator assembly and a second axle half shaft drivingly connected to the second motor-generator assembly. The first and second motor-generator assemblies each include a motor-generator and a housing and gear carrier portion. The axle housing includes a first axle tube portion, a second axle tube portion, a center portion, and an opening extending through the center portion of the axle housing, wherein the first axle tube portion and the second axle tube portion are disposed on axial opposite sides of the central portion. The first and second half shafts extended into the opening of the axle housing, and the first motor-generator assembly and the second motor-generator assembly are connected to the axle housing assembly.

A motor drive device includes: a trailing arm that extends in a vehicle front-rear direction and includes a vehicle body-side attachment portion and wheel-side support portion, the vehicle body-side attachment portion formed on a forward portion side of the trailing arm and coupled to a vehicle body via a rubber bush, the wheel-side support portion formed on a rear side of the trailing arm and supporting a rear wheel; and a motor that is supported by the trailing arm and drives the rear wheel. The motor and the rubber bush are disposed in such a way that motor and the rubber bush are seen as being substantially aligned in a vehicle up-down direction when viewed in a vehicle width direction.

The invention relates to a chassis for a utility vehicle, having a first .sup.J chassis element extending transversely with respect to the vehicle longitudinal direction and a second chassis element (5) fixed to the outer side thereof, wherein the second chassis element (5) is supported against the outer side of the first chassis element via at least one roughened supporting area (11, 12). In order to avoid relative movements between the chassis elements connected by clamping forces in a utility vehicle chassis, the roughening comprises a surface structure produced by machining the supporting area (11, 12) in a blasting process and preferably a laser beam process. The invention further relates to specific individual parts of such a chassis, specifically an axle shell, an axle guide (5), and a brake carrier.

A clamping system for mating an I-Beam frame to an undercarriage is disclosed. The clamping system utilizes clamping brackets to secure the undercarriage to the trailer frame. The undercarriage has adapter sides oriented perpendicular to the undercarriage adapter bottom. The clamping brackets have two portions oriented perpendicular to each other. Holes are located in the clamping brackets to receive bolts or screws. The trailer frame is aligned onto the undercarriage and positioned such that proper tongue weight is applied. The clamping brackets are rigidly installed on the clamping bracket sides. Clamping screws are installed into the clamping brackets and torqued to a value such that a compressive force is applied between the bottom of the I-Beam and the undercarriage adapter bottom. The compressive force applied prevents unwanted relative motion between the I-Beam frame and the undercarriage during use.

A clamping system for mating an I-Beam frame to an undercarriage is disclosed. The clamping system utilizes clamping brackets to secure the undercarriage to the trailer frame. The undercarriage has adapter sides oriented perpendicular to the undercarriage adapter bottom. The clamping brackets have two portions oriented perpendicular to each other. Holes are located in the clamping brackets to receive bolts or screws. The trailer frame is aligned onto the undercarriage and positioned such that proper tongue weight is applied. The clamping brackets are rigidly installed on the clamping bracket sides. Clamping screws are installed into the clamping brackets and torqued to a value such that a compressive force is applied between the bottom of the I-Beam and the undercarriage adapter bottom. The compressive force applied prevents unwanted relative motion between the I-Beam frame and the undercarriage during use.

A suspension interconnection assembly comprises first and second saddle brackets and a fastener. Each saddle bracket comprises a base, a pair of arms spaced apart and have the base disposed therebetween, and a pair of shoulders. Each shoulder is disposed between the base and a respective arm. Each shoulder has a first beveled surface. The pair of shoulders cooperates with the base and the pair of arms to at least partially define a U-shaped pocket. The U-shaped pockets of each saddle bracket are sized to partially receive an axle housing. The fastener interconnects the saddle brackets to couple the saddle brackets and a spring to the axle housing. The beveled surfaces of each saddle bracket are adapted to operatively engage the peripheral wall. The pairs of arms of each saddle bracket are adapted to operatively engage one another after the beveled surfaces operatively engage the peripheral wall.

A rear suspension apparatus of a vehicle includes: a transverse helper leaf spring connected to a rear axle and disposed in a transverse direction; and a first stopper mechanism and a second stopper mechanism contacting the transverse helper leaf spring when the vehicle moves. The rear suspension apparatus is capable of improving riding quality by using a new spring constant value generated by the transverse helper leaf spring when freight is loaded and a vehicle body frame moves downwardly, and restricting rolling movement of the vehicle when rolling is caused, thereby increasing roll stiffness and improving driving stability.