This electric power steering device is provided with a function for: notifying a parking assistance device of a statically-steerable upper limit number obtained from an estimated motor current when static steering is performed in turnabout and a current limit value for the purpose of overheat protection of an electric power steering; and notifying the parking assistance device of whether the electric power steering can perform steering according to a target steering angle command, from a target steering angle and a target vehicle speed from the start of parking to the completion thereof, thus preventing interruption due to overheat of the electric power steering during parking assistance.

This electric power steering device is provided with a function for: notifying a parking assistance device of a statically-steerable upper limit number obtained from an estimated motor current when static steering is performed in turnabout and a current limit value for the purpose of overheat protection of an electric power steering; and notifying the parking assistance device of whether the electric power steering can perform steering according to a target steering angle command, from a target steering angle and a target vehicle speed from the start of parking to the completion thereof, thus preventing interruption due to overheat of the electric power steering during parking assistance.

An electric power steering control method. Said method comprises the following steps executed by an EPS system: acquiring an expected control signal sent by an LKA system, the expected control signal comprising an expected angle signal or an expected torque signal; on the basis of vehicle configuration codes, performing compatibility verification on the expected control signal, and acquiring a compatibility verification result; and if the compatibility verification result indicates being compatible, acquiring a target torque value according to the expected control signal, and controlling steering of a power-assisted motor on the basis of the target torque value. Said method uses vehicle configuration codes to perform compatibility verification on expected control signals corresponding to different interface types, and when a compatibility verification result indicates being compatible, controls the operation of a power-assist motor according to a target torque value determined by the expected control signal.

A corner module apparatus for a vehicle may include a driver configured to provide a driving force to a wheel of a vehicle, a suspension connected to the driver, and being configured to absorb shock transferred from a road surface, and a steering unit connected to the suspension, the steering unit rotatably installed under a frame module coupled to a vehicle body, and being configured to adjust a steering angle of the wheel.

A drive (1) for a steering axle (26) of an industrial truck includes two steering arms (11, 12), an axle arch (8), a tie rod (13) configured as a spindle (13), a spindle nut (7) fixed axially on the tie rod (13), and a gear stage (21). Adjustment of the steering arms (11, 12) can be effected by axial displacement of the tie rod (13), and by the spindle nut (7) being able to be driven by a drive output element (7) of the gear stage (21). The drive (1) has two mutually coaxial electric motors (17, 18) disposed parallel to the tie rod (13). A drive element (14) of the gear stage (21) can be driven by the two electric motors (17, 18), which are disposed so as to be axially centric between the two electric motors (17, 18). Also disclosed is a steering axle and an industrial truck.

A corner module apparatus, includes a corner module including a driving unit configured to provide driving power to a wheel of a vehicle, a suspension unit coupled with the driving unit and configured to absorb an impact to the wheel from a road surface, and a steering unit coupled with the suspension unit and configured to adjust a steering angle of the wheel; a main platform installed under a vehicle body of the vehicle and configured to have a battery mounted thereon; a first corner module platform detachably coupled with one side of the main platform and configured to have the corner module coupled therewith; and a second corner module platform detachably coupled with another side of the main platform and configured to have the corner module coupled therewith.

Disclosed is a corner module apparatus for a vehicle. The corner module apparatus includes processors configured to obtain a steering angle, obtain a lever ratio indicating whether a front wheel and a rear wheel of a bicycle model defined with respect to a vehicle are inphase or reverse-phased and indicating a steering angle ratio. The corner module apparatus also includes a controller configured to calculate a front wheel heading angle of the bicycle model from the steering angle, calculate a rear wheel heading angle of the bicycle model based on the calculated front wheel heading angle and the lever ratio, calculate first to fourth target angles of a left front wheel, a right front wheel, a left rear wheel, and a right rear wheel of the vehicle by expanding the bicycle model to a four-wheel vehicle model, and independently control steering of each of the four wheels.

A steering axle for a steerable vehicle has an axle housing and a steering drive with an electric motor and motor shaft. A first planetary stage includes a first sun gear, first planet gears, and a first planet carrier. A last planetary stage includes a last sun gear, last planet gears, a last planet carrier, and a ring gear. A force flux from the motor shaft runs via the first sun gear and the first planet gears to the first planet carrier. The force flux furthermore runs via the last sun gear to the last planet gears. The force flux furthermore runs from the last planet gears to the ring gear. In relation to the axle housing, the ring gear is pivotably mounted about a pivot axis. The last planet carrier is connected in a rotationally fixed manner to the axle housing. Also disclosed is a corresponding industrial truck.

A steering drive for a steering axle of a steerable vehicle includes an electric motor with a motor shaft. A steering lever is rotatable about a pivot axis that is parallel to the electric motor. First and second planetary stages each have a sun gear, planet gears, and a planet carrier. The steering drive is configured such that a force flow runs from the first sun gear via the first planet gears to the first planet carrier. The force flow furthermore runs via the second sun gear and via the second planet gears to the second planet carrier, and furthermore runs to the steering lever. The steering drive has a spur gear stage and is configured such that a force flow from the motor shaft to the first sun gear runs via the spur gear stage. Also disclosed is a steering axle and an industrial truck.

A steering drive includes an electric motor with a motor shaft and a steering lever rotatable about a pivot axis. A first planetary stage has a first sun gear, first planet gears, a first ring gear, and a first planet carrier. A final planetary stage has a final sun gear, final planet gears, a final ring gear, and a final planet carrier. A force flow runs from the motor shaft to the first sun gear, and from the first sun gear via the first planet gears to the first planet carrier and to the first ring gear. The force flow runs via the final sun gear and via the final planet gears to the final ring gear, runs from the first ring gear and from the final ring gear to the steering lever, and runs via a first sun gear shaft from the electric motor to the first sun gear.