The parallel maneuvering system is a steering system for portable devices, portable platforms and the like, allowing individual wheels to be steered in a parallel and simultaneous manner. The parallel maneuvering system includes a first coupler and a second coupler, which are slidably mounted with respect to one another, and which each include a pair of arms for eccentric pivotal attachment to a corresponding pair of wheel assemblies. The first and second couplers are mounted within a hollow chassis, and the wheel assemblies are mounted to the hollow chassis such that respective wheels thereof are mounted external to the hollow chassis, and respective eccentric crank arms thereof are mounted within the hollow chassis. At least one linear actuator may be provided for selectively driving sliding movement of the first coupler with respect to the second coupler.

The disclosure relates to a steering control system useful for providing stable control during high-speed operation of harvesters, such as self-propelled windrowers. The steering control system utilizes sensors for detecting a ground drive wheel speed or a swash plate position of hydraulic pumps for determining an angle of curvature used as input for controlling a steering cylinder associated with a first caster.

The present invention relates to a control system for use in an agricultural harvester, the system comprising a control panel (10) configured to send at least one mode signal (11) to a control means (20) via an user's (100) command (50), the control means (20) being configured to receive the mode signal (11) and generate a set of instructions (30), the set of instructions (30) being a function of the received mode signal (11), the control means (20) being configured to control at least one piece of equipment from a set of equipment (40) of the agricultural harvester depending on the generated set of instructions (30), providing greater reliability, precision and efficiency in its operation and elimination of operational errors caused by the user.

A steerable suspension system for a vehicle, especially useful in a self-propelled vehicle that can include a worker-platform and optionally include pick-up, transport, and delivery apparatus for produce bins. The steerable suspension system includes independent pairs of parallel arms, each pair coupled to a single steerable drive-wheel, serving as both a suspension and as a shock absorber, with the parallel-acting pair of arms maintaining the steering-leg in its substantially vertical position relative to a ground surface. This steerable suspension system aids the steerable movement and suspension of the vehicle, while increasing safety and maneuverability, and helps to reduce the number of workers required to operate the vehicle.

Disclosed herein is a zero-turn radius vehicle for facilitating transporting of objects, in accordance with some embodiments. Accordingly, the zero-turn radius vehicle may include a frame. Further, the zero-turn radius vehicle may include a plurality of wheels rotatably coupled with the frame. Further, the zero-turn radius vehicle may include a propelling mechanism disposed of in the frame. Further, the propelling mechanism may be operationally coupled with the pair of opposing wheels. Further, the zero-turn radius vehicle may include an attachment member coupled to the frame. Further, the attachment member may be configured for moving between a plurality of positions. Further, the zero-turn radius vehicle may include a control member disposed of in the frame. Further, the control member may be operationally coupled with at least one of the propelling mechanism and the attachment member.

A motorized personal transport utility vehicle comprises a frame, independent front and rear suspension and a plurality of wheel hubs. Each suspension arm is pivotally coupled to a central frame portion. A pair of front wheel hubs are coupled to the front suspension arms and a pair of rear wheel hubs are coupled to the rear suspension arms. Each of the wheel hubs includes an integrated electric hub motor. The front and rear suspension arms are configured such that the front wheel hub track width is greater than the rear wheel hub track width such that the inner width between the insides of the front wheel hubs is greater than the outer width between the rear wheel hubs.

A vehicle includes a chassis, a first actuator coupled to the chassis, a second actuator coupled to the chassis, a third actuator coupled to the chassis, a fourth actuator coupled to the chassis, and a fluid circuit. The fluid circuit is configured to facilitate selectively fluidly coupling the first actuator, the second actuator, the third actuator, and the fourth actuator in a plurality of different configuration. In each of the plurality of different configurations, two of the first actuator, the second actuator, the third actuator, and the fourth actuator are fluidly coupled together while the other two of the first actuator, the second actuator, the third actuator, and the fourth actuator are fluidly decoupled.

A vehicle system includes a controller. The controller is configured to be communicably coupled to a plurality of actuators of a vehicle that facilitate repositioning a plurality of tractive elements coupled to a chassis of the vehicle. The controller is configured to (i) control the plurality of actuators to selectively reposition each of the plurality of tractive elements through a range of motion to attempt to maintain the chassis level and (ii) drive each of the plurality of actuators toward a mid-stroke position while continuing to attempt to maintain the chassis level and while the vehicle is moving.

A lift device includes a base, an arm, a tractive element, and a steering actuator. The arm has a base end coupled to the base and a tractive element end. The arm includes a steering actuator interface positioned along an exterior surface of the arm. The tractive element is coupled to the tractive element end. The steering actuator has a first end coupled to the steering actuator interface and an opposing second end coupled to the tractive element. The arm includes a plate extending from the exterior surface of the arm at an upward angle and past the steering actuator.

A steerable drive wheel assembly includes two independently motor-driven wheels. The wheels are supported in side-by-side orientation for independent rotation about a common horizontal rolling axis, and equally laterally offset from said vertical steering axis. The wheels and their respective drive motors are carried in a drive module that is mounted like a turret under an intermediate suspension module via a rotary bearing. The intermediate suspension module is mounted on linear bearing assemblies within an outer housing. Biasing members urge the intermediate suspension module together with its drive module downwardly to maintain traction with a floor. A compact configuration is achieved by overlapping the drive motors with the opposite wheels. Position control is achieved by a strategic sensor array. Electrical wire management is achieved by a serpentine energy chain located in the plane of the rotary bearing.