A vehicle includes a body frame, a left front wheel and a right front wheel, a link mechanism configured to be deformed as a vehicle body leans, and vehicle components disposed directly forward of the link mechanism in relation to a front-and-rear direction of the vehicle. The vehicle components are supported on the body frame via penetrating portions that extend from the body frame toward the front of the vehicle and penetrate the link mechanism.

A vehicle suspension system includes a frame, a damper and a rocker arm. The frame is connected with the rocker arm through the damper, the swing part of swing arm limits the swing arm's rotation angle by matching the limit structure on the frame; the bottom of damper is provided with the universal structure, the damper is connected with the rocker arm through the universal structure, and the universal structure controls the damper in free deflection. A deviation motion of vehicle wheels on both ends by coordinating the swing arm, vibration damper, etc. to avoid the slipping and rollover due to great sides way upon vehicle steering and the lateral wheels disengagement from ground and to enhance the safety of cornering driving of vehicles.

Multi-link suspension systems for vehicle are described having various linkage arms that connect to distinct points of a wheel mount. Each of the linkage arms are preferably coupled to the wheel mount via a spherical ball joint and mounted such that they can independently move with respect to the other linkage arms. A shock assembly is preferably mounted between two of the linkage arms on a separate links that is configured to vary its length based on movement of one or both of the two linkage arms.

A leaning vehicle including a vehicle body, two front wheels, and a support mechanism by which the two front wheels are supported by the vehicle body. The support mechanism includes a joint mechanism that is a ball joint and that includes a ball stud including a ball part connected to a shaft, and a holder having an open end part through which the ball stud is insertable, such that the ball part is freely rotatable in the holder. The open end part includes first to fourth inner edge parts. When the ball stud is in a steering neutral and leaning neutral position, in a direction along a central axis of the ball stud, the first and second inner edge parts do not overlap, and the third and fourth inner edge parts overlap, the ball part. The ball stud is tiltable between the first and second inner edge parts.

A tiltable motor vehicle having 3 or more wheels and at least one bridge having opposite first and second ends where first and second wheel hub assemblies are disposed. First and second wheels are mounted on the first and second wheel hub assemblies. First and second suspension guides are also associated with the first and second wheel hub assemblies, each being attached to a respective end of the at least one bridge such that the suspension guide is rotatable about at least a tilt axis relative to the at least one bridge. Each wheel hub assembly being movable along or across the respective suspension guide such that the wheels are movable relative to the at least one bridge during suspension action. Movement of the wheels and the wheel hub assemblies associated with suspension rebound and compression action and rotation of the bridges relative to the body associated with tilting action are both substantially independent of movement of the steering element.

A leaning vehicle leaning leftward or rightward when turning left or right. The leaning vehicle include a main body, left and right front wheels, a linkage mechanism located between and supporting the left and right front wheels, and a lean actuator connected to the linkage mechanism. The lean actuator is located at least partially further rearward than the linkage mechanism, and at least partially between the left and right front wheels in a left-right direction. The leaning vehicle further has a leg shield located further rearward than the left and right front wheels, with at least a portion thereof between each of the left and right front wheels, and a leg of a driver when the driver is driving the leaning vehicle. The leg shield includes an intermediate portion covering at least a part of a left portion and a right portion of the lean-actuator.

A leaning vehicle including a vehicle body, front and rear wheels, a leaning mechanism that causes the vehicle body and the front and rear wheels to lean left or right when the leaning vehicle turns left or right, a lean actuator, a support stand, a detection device that detects a getting on intention input and or a getting off intention input, which respectively indicate that a rider of the leaning vehicle intends to get on and off the leaning vehicle, and a control device configured to control the lean actuator to thereby control a lean angle of the vehicle body while the vehicle body is in motion, based on a manipulation that the rider performs for turning in the left or right direction, and control the lean angle of the vehicle body while the leaning vehicle is not in motion, based on a detection result of the detection device.

This invention relates to a rolling motor vehicle with three or four wheels, comprising a frame 6 that extends from a forecarriage 8, which supports at least two front wheels 10′,10″, to a rear 12 which supports one or more rear wheels 14. The frame 6 defines an accommodating area 15 for a driver P. The forecarriage 8 in turn comprises: —a forecarriage frame 16; —at least one pair of front wheels 10′,10″ kinematically connected to each other and to the forecarriage frame 16 by means of a rolling kinematic mechanism 20 which enables the front wheels to roll in a synchronous and specular manner, each wheel 10′,10″ being connected to said rolling kinematic mechanism 20 by means of a respective axle journal 60, said axle journal 60 being mechanically connected to a rotation pin 68 of the wheel in order to support it rotatably around an axis of rotation R′-R′, R″-R″; —a roll control system 100 of the motor vehicle; —suspension means 90 which guarantee each axle journal 60 at least one spring suspension movement with respect to said rolling kinematic mechanism 20. The roll control system comprises a rod 110, which connects the two front wheels directly to each other at the respective axle journals 60 at its two ends by means of hinging means 72,73,74 which enable said rod 110 to passively follow the movements of the axle journals 60, the roll movements of the two front wheels and of the respective axle journals causing changes in the lying position of said rod 110 with respect to a vertical projection plane, which is transverse to a centre line plane M-M of the motor vehicle. The rod 110 is usable directly or indirectly by the driver P as a command element of the roll control system 100 to control the rolling movements of the two front wheels without having to put his feet on the ground, adjusting the lying position of the rod 110 itself with his own body. Said command element 110, 120 is disposed so as to be accessible and maneuverable by the driver P from the accommodating area 15.

A coupling mechanism for a vehicle body having mutually pivotable first and second frames comprises an axle fixed to the first frame, a rotating member fixed to the second frame and rotatably mounted around the axle, and a torsional resistance module that is actuated when the axle and the rotating member rotate relative to each other. The torsional resistance module includes two force magnifying mechanisms connected between the first frame and the rotating member. A buffering member is disposed between the force magnifying mechanisms. When the buffering member is pressed, a relative torsional resistance is provided between the first and second frames through transmission of the force magnifying mechanisms. The torsional resistance has a non-linear relationship with a relative rotational angle between the first and second frames.

The present disclosure belongs to the technical field of two-wheel vehicles. A two-wheel automatic balance reset mechanism comprises a balance bar arranged between a frame and each front wheel support, the balance bar comprises a piston cylinder and a piston rod, the piston rod is movably arranged in a piston chamber of the piston cylinder, two ends of the piston chamber are mutually interconnected to form a first channel, a main control valve is arranged on the first channel and divides the first channel into a medium intake end and a backflow end, a medium tank is arranged at the backflow end, a pump is arranged at the medium intake end, and the pump is interconnected with the medium tank. A system comprises a main control module and an acquisition module, and the acquisition module comprises a balance sensor arranged on the frame and a speed sensor.