The present invention relates to all terrain vehicles having at least a pair of laterally spaced apart seating surfaces. More particularly, the present invention relates to trail compliant side-by-side all terrain vehicles.

The present invention relates to all terrain vehicles having at least a pair of laterally spaced apart seating surfaces. More particularly, the present invention relates to trail compliant side-by-side all terrain vehicles.

A vehicle configuration wherein the center of mass of the vehicle is approximately superimposed upon the passenger and driver centers of mass when seated within the vehicle. An occupant's center of mass can be approximated using a standard center of mass position approximation, or a combination of any number of standard center of mass position approximations. The vehicle's center of mass can be approximately superimposed upon the occupant's center of mass in at least the longitudinal and vertical directions.

A vehicle is provided including an electronic power steering system, an electronic throttle control system, and a stability control system.

The present invention provides a smart mobile vehicle comprising a vehicle body, a chassis, driving wheels, a battery module, a plurality of motors and a vehicle control unit. The chassis has a suspension system, a brake system and a steering system. The two driving wheels are composed of a plurality of circular units, and the driving wheels are embedded in two-wheel frames on two sides of the vehicle body. The battery module provides the smart mobile vehicle with driving power. The plurality of motors disposed between the two circular units or on a surface of any one of the circular units; wherein the motors are electrically connected to the battery module, and the torque and directional outputs of the motors is used to drive the rotation of the two driving wheels. The vehicle control unit is electrically connected to the motors and the battery module to transmit a monitoring signal.

A vehicle is provided. The vehicle includes a frame and a front shock absorber. The front shock absorber is arranged to the frame and extends obliquely backward from bottom to top. An included angle between a projection of a central axis of the front shock absorber on a longitudinal central plane of the vehicle and a projection of a vertical line of the ground passing through a lower end of the front shock absorber on the longitudinal central plane is denoted as a, and a meets a relation of 9°≤α≤20°.

A recreational off-highway vehicle includes a vehicle frame, at least one front wheel, a pair of rear wheels, a solid rear axle, a pair of trailing arms, a rear differential and a motor. The solid rear axle rotatably supports the rear wheels at its opposite ends. Each of the trailing arms is pivotally connected to the vehicle frame and the solid rear axle. A shock absorber is coupled between the vehicle frame and each of the trailing arms. The rear differential is supported on the solid rear axle and connected to the rear wheels. The transmission has a propeller shaft connected to the rear differential to drive the rear wheels. The motor is connected operatively to the transmission. The propeller shaft includes first and second drive sections that articulates relative to each other. The second drive section is connected to the rear differential.

A family of vehicles is presented which exploit dynamic controls to stabilize in-line two wheeled vehicles. The stabilization results in improved safety at high speeds and on uncooperative surfaces. Stabilization affords balance at zero speed without auxiliary support means. Transformational wheel base length affords high visibility at low speeds and low drag at high speeds. In wheel chair configurations transforming wheel base length allows navigation up and down stairs.

A front suspension structure of a vehicle where an appropriate locus of a front wheel when going over undulating ground, an arm span, and an arm length can be secured. Left and right first arms are rotatable about a rotation axis extending forward and obliquely toward a center in a left-right direction in a plan view and passing through two proximal parts. A frame front section has left and right front coupling parts to which proximal parts of front rods of left and right upper arms are coupled respectively. A distance between the left and right front coupling parts is smaller than a width in a left-right direction of a housing of a differential gear.

A utility vehicle includes a plurality of ground-engaging members, a frame assembly, a cab frame assembly, a front suspension assembly, a rear suspension assembly, a power steering assembly, and a powertrain assembly, all of which may be configured to lower the center of gravity of the vehicle.