A stabilizing arrangement for a tilting running gear of a non-rail-borne vehicle is disclosed. The stabilizing arrangement includes a balance beam configured to have each end coupled to a respective suspension side of a multi-track running gear axle of the tilting running gear. A pivot bearing is connected to a frame or body of the vehicle and defines a stationary axis of rotation. The pivot bearing rotatably supports the balance beam about the stationary axis of rotation. At least one stabilizing element is connected to the balance beam and is supported with respect to a frame or body of the vehicle. The at least one stabilizing element is configured to provide a reaction force to counteract a tilting moment of the vehicle. A non-rail-borne vehicle comprising the stabilizing arrangement also is disclosed.

A stabilizing arrangement for a tilting running gear of a non-rail-borne vehicle is disclosed. The stabilizing arrangement includes a balance beam configured to have each end coupled to a respective suspension side of a multi-track running gear axle of the tilting running gear. A pivot bearing is connected to a frame or body of the vehicle and defines a stationary axis of rotation. The pivot bearing rotatably supports the balance beam about the stationary axis of rotation. At least one stabilizing element is connected to the balance beam and is supported with respect to a frame or body of the vehicle. The at least one stabilizing element is configured to provide a reaction force to counteract a tilting moment of the vehicle. A non-rail-borne vehicle comprising the stabilizing arrangement also is disclosed.

A vehicle includes a left front wheel, a right front wheel, and a rear wheel that tilt together with a body frame, wherein, while a large capacity of a fuel tank is ensured, a variation in the center-of-gravity position of the vehicle while driving is small. When viewed in a side view with the body frame in an upright position, the fuel tank is disposed between a first center and a second center, the first center being located between a third center and right and left front wheel ground contacting portions, the second center being located between the third center and a rear wheel ground contacting portion, the third center being located between the right and the left front wheel ground contacting portions and the rear wheel ground contacting portion.

A vehicle includes a left front wheel, a right front wheel, and a rear wheel that tilt together with a body frame, wherein, while a large capacity of a fuel tank is ensured, a variation in the center-of-gravity position of the vehicle while driving is small. When viewed in a side view with the body frame in an upright position, the fuel tank is disposed between a first center and a second center, the first center being located between a third center and right and left front wheel ground contacting portions, the second center being located between the third center and a rear wheel ground contacting portion, the third center being located between the right and the left front wheel ground contacting portions and the rear wheel ground contacting portion.

A vehicle of the present disclosure may include at least one pair of opposing wheels coupled to a tiltable central chassis by a four-bar linkage or the like, such that the wheels are configured to tilt in unison with the central chassis. A steering actuator and/or a tilting actuator may be discretely controllable by an electronic controller of the vehicle. The controller may include processing logic configured to maintain alignment between a median plane of the chassis and a net force vector caused by gravity and any induced centrifugal forces. Various control algorithms may be utilized to steer the vehicle along a desired path, either autonomously or semi-autonomously.

A leaning suspension system for vehicles includes suspension arms that rotate about the same pivoting point. A swing frame also rotates about the same pivoting point. The center of gravity of the vehicle remains lower than the pivoting point even when the vehicle is leaning. A wheel mount assembly is rotatably mounted to a suspension arm. A shock absorber has an end that is connected to the wheel mount assembly and another end that is connected to the suspension arm. A control unit of the vehicle includes a computer that controls actuators of the leaning suspension system based on received sensor information. The vehicle can be a tricycle or a quadracycle.

A leaning suspension system for vehicles includes suspension arms that rotate about the same pivoting point. A swing frame also rotates about the same pivoting point. The center of gravity of the vehicle remains lower than the pivoting point even when the vehicle is leaning. A wheel mount assembly is rotatably mounted to a suspension arm. A shock absorber has an end that is connected to the wheel mount assembly and another end that is connected to the suspension arm. A control unit of the vehicle includes a computer that controls actuators of the leaning suspension system based on received sensor information. The vehicle can be a tricycle or a quadracycle.

A brake controlling operation transmission member includes a leaning-associated deforming portion that deforms in response to turning of a body frame. A vehicle includes at least a portion of the leaning-associated deforming portion located between a first restrictor located below a lower cross portion in relation to an up-and-down direction of the body frame and a central portion in a left-and-right direction of the body frame so as to prevent movement of the brake controlling operation transmission member and a brake device.

A brake controlling operation transmission member includes a leaning-associated deforming portion that deforms in response to turning of a body frame. A vehicle includes at least a portion of the leaning-associated deforming portion located between a first restrictor located below a lower cross portion in relation to an up-and-down direction of the body frame and a central portion in a left-and-right direction of the body frame so as to prevent movement of the brake controlling operation transmission member and a brake device.

A fan generates an air flow that cools a portion of an engine unit. A ventilation opening causes air flow directed to the fan to pass therethrough. Under a condition that a body frame is in an upright state and a condition that a left front wheel and a right front wheel are not turned by a steering device, the ventilation opening is disposed directly behind a lower cover of an inner fender, ahead of a rear end of a rear wheel, on the right of a left end of the left front wheel, and on the left of a right end of the right front wheel.