A passenger vehicle provided with a steering handle (15) and configured such that an attitude angle of the driver seat surface (14a) relative to a horizontal reference plane is changeable, so that a first attitude changing operation switch (25) and a second attitude changing operation switch (26) for changing the attitude angle are disposed in such positions as to be operable with a thumb of the driver of the vehicle from a steering handle grip (18) of the steering handle (15).

A prism for reflecting a laser includes: a single mounting cap at a first end of the prism, and first to seventh trihedral corner (TC) reflectors, each including a reflective surface including: three side edges, and three corners at respective intercept points between the side edges, wherein the seventh TC reflector, among the first to seventh TC reflectors, is on a second end of the prism opposite to the first end of the prism.

A boom lift includes a base having a first end and an opposing second end, a turntable coupled to the base, a boom coupled to the turntable, an assembly pivotably coupled to the first end of the base, and a first actuator coupled to the first end of the base and the assembly. The assembly includes a tractive element. The assembly extends from the base such that the tractive element is longitudinally offset from and spaced forward of the first end and the opposing second end of the base.

Motor vehicle comprising a drive system arranged in a compartment at the front of a vehicle, a cradle (2) comprising a platform (4) fastened in this compartment in the region of a floor of the vehicle, an anti-roll bar (10) fastened in the vertical direction above the platform (4), and an impact device (30) fastened to a front edge (20) of the platform (4), behind an impact block fastened to a powertrain of this vehicle, in order, in the event of a recoil of this powertrain, to allow the impact block to bear on the impact device (30), which deforms, the impact device (30) comprising an upper part projecting above the platform (4), which, in the event of a large deformation, bears on the anti-roll bar (10).

An automatic tilting vehicle is provided that includes left and right front wheels supported by knuckles, a steerable rear wheel, a vehicle tilting device, and a control unit. The vehicle tilting device includes a swing member, a tilt actuator for swing the swing member, and a pair of tie rods pivotally attached to the swing member and the knuckles. The control unit calculates a target lateral acceleration of the vehicle, estimates a lateral acceleration of the vehicle caused by the gyro moments of the wheels and calculates a target tilt angle of the vehicle based on a sum of the target lateral acceleration and the lateral acceleration caused by the gyro moments.

A leaning vehicle has a frame; a shock tower pivotally connected to the frame; front left and right ground engaging members; front left and right suspension assemblies; portions of the front left suspension assembly, the front left ground engaging member and other components of the vehicle suspended by the front left suspension assembly have a first unsprung mass; portions of the front right suspension assembly, the front right ground engaging member and other components of the vehicle suspended by the front right suspension assembly have a second unsprung mass; a moment of inertia of the shock tower being at least twenty-five percent of a combined moment of inertia of the first and second unsprung masses; a steering assembly; a rear suspension assembly; at least one rear ground engaging; and a motor.

Automatic tilting vehicle is provided that includes left and right front wheels supported by knuckles, a rear wheel steered by a steering actuator, a vehicle tilting device, and a control unit. The control unit calculates a target tilt angle of the vehicle and a target steered angle of the rear wheel based on a steering angle and a vehicle speed, controls the vehicle tilting device so that a tilt angle of the vehicle becomes the target tilt angle, and controls the steering actuator so that a steered angle of the rear wheel becomes the target steered angle. When the vehicle is turning and decelerating, a steered angle of the rear wheel is controlled not to be the target steered angle but to zero, and a tilt angle of the vehicle is reduced by a gyro moment of the rear wheel.

An annular reference surface is formed around a through-hole of an eye portion. A distal-end-side curved portion is formed at a first corner portion, on an outer side of the annular reference surface. The thickness of the distal-end-side curved portion is reduced in a range of a length from the first flat surface toward the distal end surface. A hole-side curved portion whose thickness is reduced toward an inner surface of the through-hole is formed at a second corner portion, on an inner side of the annular reference surface. The length of the hole-side curved portion is less than the length of the distal-end-side curved portion. The hole-side curved portion is curved with a greater curvature than that of the distal-end-side curved portion.

An automatic tilting vehicle is provided that includes left and right wheels supported by knuckles, a vehicle tilting device, and a control unit. The vehicle tilting device includes a swing member, an actuator for swing the swing member, and a pair of tie rods pivotally attached to the swing member and the knuckles. When a tilt angle of the vehicle is equal to or less than an allowable maximum tilt angle, a pivot point of the pivotal attachment portion at the lower end of the turning outer tie rod is located inside the vehicle with respect to a line segment connecting a grounding point of the corresponding wheel and a pivot point of the pivotal attachment portion at the upper end of the same tie rod.

Systems, devices, and methods are described for providing, among other things, a stand-up wheel chair having automatic stability control.