A vehicle frame apparatus that is configured to be operably secured to a vehicle so as to provide modifications to the vehicle in order to facilitate the vehicle accepting accessories such as but not limited to a wheelchair tub. The present invention includes a hanger assembly wherein the hanger assembly includes an upper portion and a lower portion. The hanger assembly is operably to provide a lower mounting position for the axle on vehicles having independent wheel suspension. The present invention further includes an upper spring mount and a lower spring mount. The lower spring mount provides a spring retention member configured to assist in position maintenance of the lower end of a spring. An upper shock mount is included so as to position the shock in a proper position. A hub spacer is also included so as to move the hub outward from the axle.

A device for the height adjustment of a road vehicle interposed between a frame and a suspension of the road vehicle so as to allow the vehicle to shift from a road configuration to a race configuration and vice versa. The device comprises a base body provided with a first end, which can mechanically be connected to the frame of the road vehicle; a first mass, which can be connected to the base body so as to be movable along a sliding axis; a second mass, which is connected to the first mass so as to be movable along the sliding axis as well and is configured to be able to be connected to a suspension of the road vehicle and to change the stroke of the suspension depending on the position of the second movable mass.

Techniques are described for compensating for movements of sensors. A method includes receiving two sets of sensor data from two sets of sensors, where a first set of sensors are located on a roof of a cab of a semi-trailer truck and a second set of sensor data are located on a hood of the semi-trailer truck. The method also receives from a height sensor a measured value indicative of a height of the rear of a rear portion of the cab of the semi-trailer truck relative to a chassis of the semi-trailer truck, determines two correction values, one for each of the two sets of sensor data, and compensates for the movement of the two sets of sensors by generating two sets of compensated sensor data. The two sets of compensated sensor data are generated by adjusting the two sets of sensor data based on the two correction values.

Chassis arrangement for a motor vehicle for passenger transportation, having two axles which are arranged at a spacing from one another in the motor vehicle longitudinal direction and in each case have wishbones with the incorporation of a spring element for the independent wheel suspension system. A first axle, lying at the front in a driving direction, is lowered from a neutral position by from 5 to 50 mm, 10 to 20 mm, in order to drive in said driving direction, and a second axle, lying at the rear in the driving direction, is raised by from 5 to 50 mm, 10 to 20 mm, in each case by way of adjustment of the spring elements, it being possible for the driving direction to be reversed.

Deployable step systems for accessing vehicle cargo spaces on vehicles equipped with a tailgate assembly having a door subassembly may include a bumper integrated step pad that is movable between a stowed position and a deployed position. In the stowed position, the step pad establishes a portion of the bumper, and in the deployed position, the step pad is rearward and vertically lowered relative to the bumper.

A saddle-type vehicle includes a vehicle body frame including a main frame extending obliquely rearward and downward from a head pipe, and a seat frame extending rearward from the main frame and supporting a riding seat, wherein a front wheel is supported by a front portion of the vehicle body frame via a front fork, and a rear wheel is supported by a rear portion of the vehicle body frame via a swing arm, and a vehicle height adjustment device provided below the seat frame to elastically support the seat frame and configured to adjust a height of the seat frame. The vehicle height adjustment device includes an actuator unit and a cushion unit connected with each other by a pipe. The actuator unit has a stepped portion, and at least a part of the cushion unit is disposed in a space formed by the stepped portion.

Techniques are described for compensating for movements of sensors. A method includes receiving two sets of sensor data from two sets of sensors, where a first set of sensors are located on a roof of a cab of a semi-trailer truck and a second set of sensor data are located on a hood of the semi-trailer truck. The method also receives from a height sensor a measured value indicative of a height of the rear of a rear portion of the cab of the semi-trailer truck relative to a chassis of the semi-trailer truck, determines two correction values, one for each of the two sets of sensor data, and compensates for the movement of the two sets of sensors by generating two sets of compensated sensor data. The two sets of compensated sensor data are generated by adjusting the two sets of sensor data based on the two correction values.

A saddle-type vehicle includes a vehicle body frame including a main frame extending obliquely rearward and downward from a head pipe, a down frame extending downward from the head pipe and supporting an engine, and a seat frame extending rearward from the main frame and supporting a riding seat, wherein a front wheel is supported by a front portion of the vehicle body frame via a front fork, and a rear wheel is supported by a rear portion of the vehicle body frame via a swing arm, and a vehicle height adjustment device provided below the seat frame to elastically support the seat frame and configured to adjust a height of the seat frame. The vehicle height adjustment device includes an actuator unit and a cushion unit. The actuator unit is disposed between the cushion unit and the engine.

Techniques are described for compensating for movements of sensors on a vehicle. A method includes receiving two sets of sensor data from two sets of sensors, where a first set of sensors are located on a roof of a cab of the semi-trailer truck and a second set of sensor data are located on a hood of the semi-trailer truck. The method also receives from a height sensor a measured value indicative of a height of the rear of a rear portion of the cab of the semi-trailer truck relative to a chassis of the semi-trailer truck, determines two correction values, one for each of the two sets of sensor data, and compensates for the movement of the two sets of sensors by generating two sets of compensated sensor data. The two sets of compensated sensor data are generated by adjusting the two sets of sensor data based on the two correction values.

Chassis arrangement for a motor vehicle for passenger transportation, having two axles which are arranged at a spacing from one another in the motor vehicle longitudinal direction and in each case have wishbones with the incorporation of a spring element for the independent wheel suspension system. A first axle, lying at the front in a driving direction, is lowered from a neutral position by from 5 to 50 mm, 10 to 20 mm, in order to drive in said driving direction, and a second axle, lying at the rear in the driving direction, is raised by from 5 to 50 mm, 10 to 20 mm, in each case by way of adjustment of the spring elements, it being possible for the driving direction to be reversed.