A suspension element includes a housing, a first joint, and a second joint. The housing is configured to couple a tractive element assembly to a vehicle. The housing has a first end configured to engage a portion of the vehicle and a second end configured to interface with the tractive element assembly. The first joint includes a first actuator and a first resilient member. The first actuator is configured to facilitate linear extension and retraction of the suspension element. The second joint includes a second actuator and a second resilient member. The second actuator is configured to facilitate rotational movement of the suspension element. The first resilient member and the second resilient member are configured to support a static load of the vehicle.

A RevoKnuckle-type suspension for a wheeled vehicle has a hub mounted to a bearing carrier for rotation relative thereto about a steering axis, and a shock absorber connected non-rotatably to the bearing carrier. The shock absorber has an outer cylinder having an axially-extending guide hole defined therein, and a piston and attached piston rod retained for axial reciprocation in the guide hole. The guide hole and at least one of the piston and the piston rod retained therein have respective complementary-shaped, non-circular cross-sectional shapes which engage one another to resist axial rotation of the piston and/or the piston rod within the guide hole. The carrier is therefore restrained against rotation relative to the vehicle sprung structure without the need for any additional component(s) such as a control arm or stabilizer, as required in a traditional RevoKnuckle-type suspension.

A chassis portion, for a vehicle chassis, including a chassis rail 33b, a cross member 35a, a suspension hanger 51 integral, fastened or fastenable to the cross member, and an arrangement for clamping, a portion of the chassis rail, between a portion of the hanger and a portion of the cross member.

A locking mechanism configured to selectively secure a vehicle slider frame assembly to a vehicle frame assembly includes a locking member configured to move between a locked position and an unlocked position, an actuator shaft operably coupled with the locking member such that turning the actuator shaft along a longitudinal axis of the actuator shaft moves the locking member between the locked and unlocked positions, the actuator shaft including a first portion and a second portion that telescopingly engage one another and are releasably secured to one another, and a spring member positioned over the actuator shaft and configured to bias the at least one locking member toward the locked position.

A slider suspension system for a heavy-duty vehicle includes a slider assembly with a main member that is movable relative to a primary frame of the heavy-duty vehicle in a first direction along the extent of the main member. The main member has a first portion and a second portion extending transverse to the first portion. A friction reducing slider wear pad is fixed to the main member and interposed between the main member and the primary frame. The friction reducing slider wear pad has a first segment fixed to the first portion of the main member. The friction reducing slider wear pad also has a second segment engaging at least a part of the second portion of the main member to inhibit movement of the friction reducing pad relative to the main member in a second direction transverse to the first direction.

The present invention relates to a motor wheel for a vehicle and a vehicle comprising the motor wheel. The motor wheel comprises a wheel, an electric motor, a reduction gear transmitting rotation from the electric motor to the wheel, and a dampening structure connecting the wheel to a vehicle bearing member. The electric motor comprises an electric motor case. The reduction gear comprises a reduction gear case coupled to the electric motor case and rotatably mounted within the wheel hub. The electric motor case is connected to the bearing member of the vehicle and is displaceable relative to the bearing member. The invention improves dynamic properties to the vehicle, reduces vibrations transmitted to the vehicle body, and provides a more comfortable drive.

Example bicycle suspension components and analysis devices are described herein. An example suspension component includes a first tube and a second tube configured in a telescopic arrangement having an interior space, a spring system including a pneumatic chamber containing a mass of a gas forming a pneumatic spring configured to resist compression of the telescopic arrangement, and a suspension component analysis (SCA) device. The SCA device may include a pressure sensor to detect a pressure of the gas in the pneumatic chamber and provide a signal indicative of the detected pressure and circuitry configured to receive the signal. The circuitry and the pressure sensor are at least partially disposed in the interior space.

A suspension and steering mechanism for a vehicle including at least one suspension arm, a steering arm, and a steering actuator. The suspension arm includes a wheel mounting end and a base end rotatably coupled with a reference frame via a base axis. The steering arm is coupled with the suspension arm at a rotation point of the steering arm. An actuated end of the steering arm extends toward a first direction from the rotation point. The steering actuator includes an actuating end and a fixed end, and is rotatably coupled at the fixed end with the suspension arm and rotatably coupled at the actuating end with the actuated end of the steering arm. A horizontal location of the fixed end is within at least one of a horizontal cross-section of the suspension arm and a triangle defined by the rotation point and the largest width of the base axis.

A compact vehicle suspension system comprises a sliding ride motion guide having a fixed guide portion and a telescoping guide portion telescopically movable relative to one another. The sliding ride motion guide is fixed to a wheel hub knuckle via the fixed guide portion and is rotatably and structurally fixed via the telescoping guide portion at a top mount to a vehicle body. A coil over shock absorber is rotatably connected to a lower control arm at a first end and to the vehicle body at a second end. Arms of the fixed guide portion of the sliding ride motion guide may span the wheel hub knuckle to which a drive shaft may be connected. Vertical motion of the wheel is defined by a sliding axis of the sliding ride motion guide and an arc of the lower control arm.

A leaning vehicle includes: a body frame; a right wheel and a left wheel; a linkage mechanism including arms rotatably supported on the body frame; a left-right tilt angle control mechanism configured to control a tilt angle of the body frame in a left direction or in the right direction by adjusting a rotation of the arms with respect to the body frame; and a control section. The control section controls the left-right tilt angle control mechanism to change the tilt angle of the body frame in the left direction or in the right direction in accordance with an input to the leaning vehicle from a rider while the leaning vehicle is stopped.