In a braking force control system for a vehicle, braking is performed by distributing a braking force required for braking the vehicle to the regenerative braking force and the friction braking force. The regenerative braking force and the friction braking force are re-distributed by predicting a nose dive phenomenon of the vehicle, whereby the occurrence of the nose dive phenomenon is prevented by minimizing damping control of an electronic control suspension (ECS). Thus, an excessive operation of the ECS may be prevented.

A method and apparatus are disclosed for cooling damping fluid in a vehicle suspension damper unit. A damping unit includes a piston mounted in a fluid cylinder. A bypass fluid circuit having an integrated cooling assembly disposed therein is fluidly coupled to the fluid cylinder at axial locations that, at least at one point in the piston stroke, are located on opposite sides of the piston. The cooling assembly may include a cylinder having cooling fins thermally coupled to an exterior surface of the cylinder and made of a thermally conductive material. The bypass channel may include a check valve that permits fluid flow in only one direction through the bypass channel. The check valve may be remotely operated, either manually or automatically by an electronic controller. A vehicle suspension system may implement one or more damper units throughout the vehicle, controlled separately or collectively, automatically or manually.

Disclosed are a system, a method, and an apparatus for controlling a suspension using image data captured by an image sensor. The suspension control apparatus includes at least one image sensor mounted to an own vehicle to capture image data of the surrounding environment of the own vehicle, and a controller configured to control the own vehicle based on the image data captured by the at least one image sensor, wherein the controller receives the image data from the at least one image sensor, extracts suspension control reference information including at least one of road environment information, own vehicle surrounding object information, and own vehicle state information based on the image data and/or an in-vehicle sensor of the own vehicle, and generates a control signal for controlling the height of a suspension according to the suspension control reference information.

An air suspension system is provided with air spring devices, a pressure accumulation tank, a compressor device that supplies compressed air at least to the pressure accumulation tank, and that includes an electric motor, a pump device, and a dryer, and a control device that performs a vehicle height increase control, a vehicle height decrease control, an air suction control, and a regeneration air discharge control. The control device performs a heat accumulation control, by actuating the pump device with the communication between the compressor device and the air spring devices being blocked, supplying the compressed air discharged through the dryer to the pump device to be circulated, and accumulating heat of compression of the compressed air in the dryer, to regenerate the dryer.

In a braking force control system for a vehicle, braking is performed by distributing a braking force required for braking the vehicle to the regenerative braking force and the friction braking force. The regenerative braking force and the friction braking force are re-distributed by predicting a nose dive phenomenon of the vehicle, whereby the occurrence of the nose dive phenomenon is prevented by minimizing damping control of an electronic control suspension (ECS). Thus, an excessive operation of the ECS may be prevented.

A vehicle fluid supply system includes a fluid supply valve configured to control fluid flow from a vehicle fluid supply to a trunk conduit in fluid communication with a vehicle tire inflation system; and a lift axle valve configured to control fluid flow from the trunk conduit to a lift axle deployment system.

A system and method for accounting for a mismatch that exists between a vehicle's bumper and potential impact point using an active suspension is disclosed. The system and method determine that a mismatch exists between a vehicle's bumper and a potential impact point and actuate the suspension to account for the determined mismatch. The system and method account for the mismatch existing between a vehicle's bumper and a potential impact point using a sensor for detecting that a mismatch exists between the bumper and the potential impact point, and a suspension configured to be actuated to account for the sensed mismatch to enable improved alignment of the bumper and the potential impact point.

In a suspension control system (20) including a variable damper (6fl, 6fr) provided between a vehicle body and each of left and rear front wheels (2fl, 2fr), a ground contact load computation unit (31) computes a front wheel target ground contact load according to a fore and aft acceleration of the vehicle body. A ground contact load distribution unit (32) computes target ground contact loads of the left and right front wheels by varying a distribution of the front wheel target ground contact load between the left front wheel and the right front wheel according to a direction and a magnitude of the fore and aft acceleration and/or a direction and a magnitude of a lateral acceleration of the vehicle body, and a damping force computation unit (33) sets a target damping force of each variable damper according to the target ground contact loads of the front wheels.

A regenerative shock absorber that includes a housing and a piston that moves at least partially through the housing when the shock is compressed or extended from a rest position. When the piston moves, hydraulic fluid is pressurized and drives a hydraulic motor. The hydraulic motor, in turn, drives an electric generator that produced electric energy. The electric energy may be provided to a vehicle, among other things. The regenerative shock absorber may also provide ride performance that comparable to or exceeds that of conventional shock absorbers.

An acceleration of a head of an occupant of a vehicle relative to the vehicle is determined based on data describing motion of the vehicle and respective poses of the head from a plurality of consecutive frames of image data. A vehicle suspension is adjusted based on the determined acceleration.