A gear arm assembly for a vehicle includes gear arm housing having a first end, a second end, and an intermediate portion, the gear arm housing from the intermediate portion to the first end defining a first arm segment, and the gear arm housing from the intermediate portion to the second end defining a second arm segment. The assembly further includes a plurality of gears meshed together in series and housed within the gear arm housing, the plurality of gears including an intermediate gear within the intermediate portion of the gear arm housing. The assembly further includes a first wheel hub connected to a first gear of the plurality of gears at the first end of the gear arm housing, and a second wheel hub connected to a second gear of the plurality of gears at the second end of the gear arm housing. The assembly further includes a primary drive shaft extending into the gear arm housing at the intermediate portion and configured to connect a drive input to the intermediate gear, a spindle housing configured to connect the gear arm assembly to the frame, and a spindle rotatably coupled to and within the spindle housing and configured to allow for rotation of the gear arm housing relative to the spindle housing.

An EMU bogie and a rubber-tired train are disclosed. The EMU bogie comprises a framework, a first EMU wheelset, a second EMU wheelset and an EMU steering driving device, the framework comprises two side beams opposite to each other and cross beams connected to the two side beams; the first EMU wheelset comprises a first axletree, a first EMU wheel and a second EMU wheel which are arranged at two ends of the first axletree; the second EMU wheelset comprises a second axletree, and a third EMU wheel and a fourth EMU wheel which are arranged at two ends of the second axletree; and the EMU steering driving, device comprises a driving part and a transmission part connected to the driving part, the first EMU wheelset and the second EMU wheelset, and is used for transmitting the steering power to the first EMU wheelset and the second EMU wheelset.

An EMU bogie and a rubber-tired train are disclosed. The EMU bogie comprises a framework, a first EMU wheelset, a second EMU wheelset and an EMU steering driving device, the framework comprises two side beams opposite to each other and cross beams connected to the two side beams; the first EMU wheelset comprises a first axletree, a first EMU wheel and a second EMU wheel which are arranged at two ends of the first axletree; the second EMU wheelset comprises a second axletree, and a third EMU wheel and a fourth EMU wheel which are arranged at two ends of the second axletree; and the EMU steering driving, device comprises a driving part and a transmission part connected to the driving part, the first EMU wheelset and the second EMU wheelset, and is used for transmitting the steering power to the first EMU wheelset and the second EMU wheelset.

The present disclosure relates to a method for steering a vehicle. A corresponding vehicle includes two steerable axles VA1 and HA1 each with an angle sensor, wherein a rear axle HA1 in an all-wheel mode is synchronously steered with the front axle VA1 in the opposite direction, this being designated as a 44 steering system. The vehicle further includes a control device for setting the steering angle of the axles based on the data provided by angle sensors.

A system and method for differential traction drive and steering axis coordination for an autonomous mower or other turf device includes initiating a steering motion based on determining a target forward speed and a steering rotational speed, calculating a left wheel speed and a right wheel speed, and applying the left and right wheel speeds, wherein the steering rotational speed is driven by a steering motor and the traction wheels associated with the autonomous mower, and the left and right wheel speeds are based on the target forward speed, a distance from a steering axle to the center of the respective wheel, and the steering rotational speed.

A three-wheeled vehicle having a frame with articulated four-link straight line linkage mechanism mounted thereon, said mechanism including lateral arms arranged symmetrically about the axis of symmetry of the vehicle, and also one conditionally front wheel, and two conditionally rear wheels, each having an axis. The articulated four-link straight line linkage mechanism also includes a linear steering mechanism, a T-shaped arm, a short central arm, an O-shaped bracket, a rubber-strand torsion member of the conditionally front wheel, and one rubber-strand torsion member and L-shaped wheel arm per each conditionally rear wheel, which form a rear axle connected to the linear steering mechanism via the T-shaped linkage arm. The result is increased stability when cornering at a speed, and more accurate steering.

A transport vehicle includes a base, wheels connected to the base, and load receiving elements. At least two of the wheels have a track width therebetween in each of a transverse drive and in a longitudinal drive. The track width in the longitudinal drive and the track width in the transverse drive are each variable. The transport vehicle is transports a load having a longitudinal direction and a transverse direction between the wheels. The transport vehicle is drivable both in the transverse drive and in the longitudinal drive.

A transport vehicle includes a base, wheels connected to the base, and load receiving elements. At least two of the wheels have a track width therebetween in each of a transverse drive and in a longitudinal drive. The track width in the longitudinal drive and the track width in the transverse drive are each variable. The transport vehicle is transports a load having a longitudinal direction and a transverse direction between the wheels. The transport vehicle is drivable both in the transverse drive and in the longitudinal drive.

Aspects of the invention are directed to running gear for transport devices comprising a guide ring, a wheel carrier configured and arranged to be pivoted within the guide ring about a vertical main axis of rotation and two wheels configured and arranged to be rotated about a common axis of rotation, and an inner ring pivotably mounted in the guide ring via a rotary bearing about the main axis of rotation, and the wheel carrier is pivotably mounted via at least one pivot bearing about a pivot axis perpendicular to the main axis of rotation.

Aspects of the invention are directed to running gear for transport devices comprising a guide ring, a wheel carrier configured and arranged to be pivoted within the guide ring about a vertical main axis of rotation and two wheels configured and arranged to be rotated about a common axis of rotation, and an inner ring pivotably mounted in the guide ring via a rotary bearing about the main axis of rotation, and the wheel carrier is pivotably mounted via at least one pivot bearing about a pivot axis perpendicular to the main axis of rotation.