A trailer for towing by a power vehicle is provided and generally includes a frame and a tandem wheel assembly. The frame forms an undercarriage chassis which the tandem wheel assembly is positioned there under. The undercarriage chassis includes a steerable rear wheel assembly, a steerable front wheel assembly, and an extension assembly moving the front wheel assembly between trailing position and a self-propelled position where the rear wheel assembly and the front wheel assembly are positioned to equally support the undercarriage chassis.

A connecting arrangement for a stabilizer of a vehicle, with at least one lever that extends transversely to a longitudinal direction. The lever has a bearing eye provided with a non-circular inner circumferential contour. A torsion-bar spring with a rotation axis extends in the longitudinal direction. The torsion-bar spring has an outer circumferential contour, at least at one end, that matches the inner circumferential contour of the bearing eye and which fits into the bearing eye. The wall of the bearing eye is cut through by at least one slit extending in the longitudinal direction, by which two opposite wall sections of the wall are separated from one another. The two wall sections are pressed against the non-circular outer circumferential contour of the torsion-bar spring by at least one releasable clamping element.

A bearing eye for a leaf spring for sprung support of a vehicle component on a vehicle body of a vehicle may include a through opening and a torsion spring therein, and a first catch. The bearing eye may provide pivotable mounting of the leaf spring on the vehicle body. The torsion spring is twistable relative to the bearing eye and connectable non-rotatably to the vehicle body. The first catch may project radially inwardly into the through opening, and the torsion spring has a second catch that projects radially outwardly into the through opening. The first and second catches may form a locking engagement which, depending on a degree of relative twisting between the bearing eye and the torsion spring, stops the relative twisting.

A vehicle includes wheels, suspension links, a torsion bar, and electronically controlled dampers. The suspension links support the wheels. The torsion bar generates a force to resist a tilting of the vehicle in the body roll direction. The electronic control dampers connect the torsion bar to the suspension links. At least a portion of each suspension links is located in front of the corresponding electronically controlled damper.

The present invention provides a method for manufacturing a torsion beam, the method comprising: a planarization step, in which a protruding portion of an upper mold presses the opposite end portions in the width direction of the blank to be plastically deformed to be flat while the opposite end portions in the width direction of the blank are supported by a side cam to face each other; a welding and bonding step for bonding the planarized opposite end portions in the width direction of the blank via welding; and a quenching step for heating the welded and bonded blank within a range of 900 to 970° C. for a retaining time within a range of 1 to 20 minutes and for cooling down the blank in a treatment liquid including at least one of water and oil in a range of 20 to 90° C.

A trailer for towing by a power vehicle is provided and generally includes a frame and a tandem wheel assembly. The frame forms an undercarriage chassis which the tandem wheel assembly is positioned there under. The undercarriage chassis includes a rear wheel assembly, a front wheel assembly, and an extension assembly moving the front wheel assembly between trailing position and a self-propelled position. At least one of the wheel assemblies is powered by a selectively engageable drive assembly including a motor, transmission, driveshaft, selectively engageable clutch and hub, to drive the rotation of at least one of the wheels.

An assembly comprises an upper axle ball joint support torque box, torque tube, torque tube support housing, forward torque rod, and forward torque rod support. The upper axle ball joint support torque box is configured to connect to an upper axle ball joint mount of a solid front axle of a vehicle. The torque tube support housing is configured to connect to the upper ball joint support torque box. The forward torque rod is configured to connect to the forward torque rod support and the torque tube. The forward torque rod support is configured to connect to frame structure of the vehicle. The torque tube support housing is configured to slide forward and backward along the torque tube. The assembly may comprise an anti-twist bracket configured to connect to the ball joint support torque box. The assembly, when installed, reduces side-to-side shaking of the solid front axle vehicle.

An assembly comprises an upper axle ball joint support torque box, torque tube, torque tube support housing, forward torque rod, and forward torque rod support. The upper axle ball joint support torque box is configured to connect to an upper axle ball joint mount of a solid front axle of a vehicle. The torque tube support housing is configured to connect to the upper ball joint support torque box. The forward torque rod is configured to connect to the forward torque rod support and the torque tube. The forward torque rod support is configured to connect to frame structure of the vehicle. The torque tube support housing is configured to slide forward and backward along the torque tube. The assembly may comprise an anti-twist bracket configured to connect to the ball joint support torque box. The assembly, when installed, reduces side-to-side shaking of the solid front axle vehicle.

A high speed actuation system for protracting and retracting a retractable wheel and/or track drive assembly of an amphibian includes an actuator, at least one retractable wheel and/or track drive assembly comprising at least one wheel and/or track drive supported directly or indirectly by a suspension assembly and movable between a protracted and retracted positions, an energy source for providing power to the actuator, and a controller that controls in amount the power provided by the energy source to the actuator such that the time of actuation to retract the at least one retractable wheel and/or track drive assembly from a protracted position to a retracted position, or to protract the at least one retractable wheel and/or track drive assembly from a retracted position to a protracted position, is less than 5 seconds.

Disclosed herein is a rear subframe and suspension system. The subframe may be configured to accommodate one or two electric motors for propelling an automobile. The subframe may be configured such that the motor(s) is inserted through the front end of the subframe. The subframe may substantially surround the motor. Braces may be the coupled to the subframe to secure the motor within the subframe. The subframe may further include built-in motor mounts. An independent rear suspension system and rear steering system may also be coupled to the subframe.