A sub-frame arranged to be mounted on a chassis of a car and to have the rear wheels of the car mounted thereon is arranged to receive an electric drivetrain arranged to drive the car. The sub-frame includes a cage including bars arranged to form an upper perimeter and a lower perimeter and a plurality of struts extending between the upper and lower perimeters; a pair of rear wheel suspension mounts, each rear wheel suspension mount being arranged to have one of the rear wheels of the car mounted thereon; and a plurality of brackets located on the cage and arranged to facilitate connection of the sub-frame to the chassis of the car and/or to the electric drivetrain. A frame and vehicle including such a sub-frame and a method of installing such a sub-frame are also disclosed.

A steering device includes a steering power unit, a transmission unit, an upper control arm, a steering element, an eccentric bolt and a steering knuckle. The steering power unit has at least one torque-output end. The transmission unit is connected with the torque-output end. The steering element is connected with the transmission unit. The eccentric bolt, installed at the upper control arm, is connected with the steering power unit. The steering knuckle, mounted to a wheel disc, is connected with the steering element and the upper control arm, and used for controlling the wheel disc. The steering power unit drives the steering element to push or pull the steering knuckle for controlling a turning angle, and simultaneously drives the eccentric bolt to have the upper control arm to push or pull the steering knuckle for varying a camber angle of the wheel disc. In addition, a steering method is provided.

A steering device includes a steering power unit, a transmission unit, an upper control arm, a steering element, an eccentric bolt and a steering knuckle. The steering power unit has at least one torque-output end. The transmission unit is connected with the torque-output end. The steering element is connected with the transmission unit. The eccentric bolt, installed at the upper control arm, is connected with the steering power unit. The steering knuckle, mounted to a wheel disc, is connected with the steering element and the upper control arm, and used for controlling the wheel disc. The steering power unit drives the steering element to push or pull the steering knuckle for controlling a turning angle, and simultaneously drives the eccentric bolt to have the upper control arm to push or pull the steering knuckle for varying a camber angle of the wheel disc. In addition, a steering method is provided.

A vehicle suspension system for a vehicle having a body supported on a frame includes a first suspension component having a surface and a bracket cantilevered from the surface, a second suspension component including a surface portion, and a spring element mounted to one of the bracket and the surface portion of the second suspension component. Interaction between the spring element and the another of the bracket and the surface portion of the second suspension component limits upward travel of the body of the vehicle.

A vehicle suspension system for a vehicle having a body supported on a frame includes a first suspension component having a surface and a bracket cantilevered from the surface, a second suspension component including a surface portion, and a spring element mounted to one of the bracket and the surface portion of the second suspension component. Interaction between the spring element and the another of the bracket and the surface portion of the second suspension component limits upward travel of the body of the vehicle.

A mobile power station for the purpose of recharging electric vehicles is provided. The charging station includes separate, but different, types of electrical generation capabilities. For example, the charging station may include two or more of: wind power, solar power and power generated from suspension mounted oscillators, which charge its battery pack over land. If desired, the mobile power station can be amphibious, as well, with the ability to navigate small and large bodies of water.

A five-link automobile suspension device is configured to support a lower end of a damper with a lower arm, and is capable of reducing sliding friction while ensuring a road clearance. Embodiments include a lower arm connecting a wheel support and a vehicle body, and a damper that has a lower end connected to the lower arm and is disposed to incline upward toward a vehicle-width-direction inner side in a rear view. A wall surface of the lower arm has a damper mounting portion, which supports a pivot of the damper, at a position lower than a straight line connecting a pivot on a wheel side and a pivot on a vehicle-body side of the lower arm. A bottom surface of the lower arm has a bulge formed at a position under the damper mounting portion.

The saddle-riding motor vehicle (1; 107; 207) comprises a rear driving wheel (5; 105; 205) and a front steered wheel (7; 107; 207). The front steered wheel (7; 107; 207X, 207Y) is connected to a rotatable arm (9; 109; 209X, 209Y) provided with a rotary motion about a steering axis (A-A). A wheel support (37; 137) is connected to the rotatable arm (9; 109; 209) with the interposition of a suspension (17; 117; 217X, 217Y) comprising a shock absorber (22; 122). The suspension (17; 117) comprises a Roberts four-bar linkage.

A work vehicle includes a plurality of traveling devices for driving traveling, a plurality of articulated link mechanisms having at least two or more joints and supporting the plurality of traveling devices to a vehicle body, with allowing the plurality of traveling devices to be elevated/lowered independently of each other, a driving mechanism capable of changing respective postures of the plurality of articulated link mechanisms independently of each other, and a plurality of turning mechanisms configured to support the respective plurality of the articulated link mechanisms, with allowing the link mechanisms to be orientation-changeable about a vertical axis.

A suspension device for an in-wheel motor may include: a buffer part coupled to a vehicle body, and configured to absorb shock; an arm part coupled to the vehicle body, disposed at each of a top and bottom of the vehicle body, and coupled to the buffer part; a support part coupled to the arm part, and configured to be movable upward and downward; one or more connection parts rotatably mounted on the support part, provided as a pair of connection parts, and configured to serve as a steering axis; and a fixing part mounted on the connection part, rotated in connection with the connection part, and coupled to an in-wheel motor.