A hydraulic suspension system controller is disclosed, comprising a controller in operable communication with a hydraulic system of a vehicle. The controller includes at least one display, at least one indicator, and a plurality of buttons, wherein each button corresponds to a function of the controller, and wherein each function effects the hydraulic system to raise and lower at least one of a plurality of solenoids each in operable communication with a hydraulic actuator to extend or contract the hydraulic actuator. A fail-safe module is in operable communication with the controller, the fail-safe module receiving a plurality of signals from a sensor array to monitor the hydraulic system.

A method for controlling the safe operation of a rear axle of a set of combined axles powered by a motor vehicle, particularly for a vehicle designed to carry loads and which have 6×4, 8×4 or 10×4 type traction configurations, or tridem models formed by three drive axles. The method includes a set of steps and activities that ensure proper and safe operation of systems and mechanisms for uncoupling and raising a rear axle of a vehicle, and more specifically checking a status of certain operating parameters of the rear axle and of the vehicle itself in order to permit or prevent uncoupling and coupling, as well as raising and lowering of the rear axle of the vehicle.

A method for pivoting a travel unit on a machine frame of a road milling machine between an outer end position and an inner end position offset toward a center of the machine relative to the outer end position, the road milling machine having a travel mechanism with multiple travel units, of which at least one travel unit is height-adjustable via a lifting column, comprising the steps of positioning a support foot mounted on the machine frame in a ground contact position to support the machine frame, lifting the travel unit, pivoting the travel unit between the outer end position and the inner end position, lowering the travel unit, and positioning the support foot in a stowed position.

A damping control apparatus has a control unit that controls an active actuator that generates a control force for damping a sprung, and the control unit determines a predicted wheel passage position where a wheel is predicted to pass, performs a high-pass filtering on a first road surface displacement-related value, performs a low-pass filtering on a second road surface displacement-related value, calculates a target control force for damping the sprung when the wheel passes through the predicted wheel passage position based on a sum of the first road surface displacement-related value after high-pass filtering and the second road surface displacement-related value after low-pass filtering, and the second road surface displacement-related value has a higher possibility that a position where a control force corresponding to the target control force is generated misaligns with the predicted wheel passage position as compared with the first road surface displacement-related value.

The present disclosure relates to an apparatus and method for controlling a lift axle of a vehicle. To assist with braking according to an operation of a forward collision avoidance (FCA) system by using the lift axle in an emergency braking situation, the vehicle lift axle control apparatus includes a lift axle actuator that drives the lift axle of the vehicle, an interworking device that interworks with the FCA system, and a controller that controls the lift axle actuator based on information obtained from the FCA system.

A control unit for a vehicle that has a chassis and a driver's cab on the chassis, comprising a first data interface for receiving image data generated by an imaging sensor, a second data interface for receiving vehicle state data generated by a vehicle state sensor, an evaluation unit for evaluating the image data and/or the vehicle state data in order to generate a first control signal on the basis of the evaluation of the image data, which is configured to counteract a relative movement between the chassis and the driver's cab and/or generate a second control signal on the basis of the evaluation of the vehicle state data, which is configured to correct a setting of the imaging sensor, and a signal output unit for outputting the first and/or second control signals.

A calibration device includes: a first coefficient calculation unit, a first output unit, an ideal value calculation unit, a second coefficient calculation unit configured to calculate a second coefficient by dividing a second output value by the ideal value, the second output value being an actual output value of the detector when the extension/contraction amount of the suspension device is the first extension/contraction amount, and a calibration unit configured to calculate a calibration value which is an output value after calibration of the detector when the suspension device has the minimum extension/contraction amount, by using the second output value, the first extension/contraction amount, the operation amount, the first output value, and the second coefficient.

This motor shaft state detection method has: a rotation determination step for determining, using a detected current waveform of a motor, whether or not to be a non-rotational state in which the rotational speed of the motor is smaller than a predetermined speed; a current determination step for determining whether or not to be a supply state in which the absolute value of current supplied to the motor is larger than a predetermined reference value; and a determination step for, when it is determined to be the non-rotational state in the rotation determination step and it is determined to be the supply state in the current determination step, determining that the motor is in a shaft locked state.

A suspension damping device installed at a chassis of a mobile robot comprises a vehicle frame, a controlling arm set and a damping device. The vehicle frame is fixed to the chassis and arranged on the ground. One end of the controlling arm set is hinged to the vehicle frame, and the other end of the controlling arm set is hinged to a steering device, so the controlling arm set controls the motion stability of the steering device. One end of the damping device opposite to the ground is hinged to the vehicle frame, and the other end of the damping device faced to the ground is hinged to the steering device. A six-wheeled bionic chassis which comprises a chassis frame, a controller, a sensor, front wheel suspension assemblies, middle wheel suspension assemblies and rear wheel suspension assemblies is also disclosed in the present invention.

A central joint device for chassis components (2), particularly three-point link, is suggested. The central joint device comprises at least one housing unit (3), at least one joint pin unit (4) which is movably supported at least partially inside of the housing unit (3), and at least one sensor unit (5), particularly a magnetic sensor unit, which is provided for contactless detection of roll motions and pitch motions of the housing unit (3) and of the joint pin unit (4) relative to one another. The sensor unit (5) comprises at least one encoder element (6) and at least one sensor element (7). The encoder element (6) and the sensor element (7) are arranged to be spaced apart from one another and movable relative to one another.