The present invention discloses an electric parking brake control device capable of accurately determining operation of an electric actuator. The electric parking brake control device is capable of performing an application process for controlling the electric actuator to move in the direction in which a friction member is pressed against a rotation body that rotates integrally with a wheel and a release process for controlling the electric actuator to move in the direction in which the friction member is moved away from the rotation body. Even upon receiving (time t12) a new operation request for operating the electric actuator during a period (time t1 to t5) from the start of the application process or the release process to the completion of the process, the electric parking brake control device does not change the operation of the electric actuator on the basis of the operation request.

A control system for a vehicle has a powertrain system that includes electric power propulsion system and a second propulsion system, a geographical position sensing system, a geographic map database, and a controller. The controller monitors a geographic location of the vehicle determine the geographic location of the vehicle in relation to a first predefined region and a first user-identified region. The powertrain system is controlled to generate propulsion power employing only the electric power propulsion system when the geographic location of the vehicle is within the first predefined region and when the geographic location of the vehicle is within the first user-identified region. The powertrain system is controlled to generate propulsion power employing the second propulsion system when the geographic location of the vehicle is outside the first predefined region and outside the first user-identified region.

A brake system has at least two electromechanical wheel brakes and a central control unit. Each wheel brake has a wheel-specific control unit for controlling the deceleration moment exerted on a vehicle wheel by the respective wheel brake. The brake system has at least one rotational speed sensor per vehicle wheel. The central control unit is connected to the wheel-specific control units of the wheel brakes via a data bus for the exchange of control signals. The rotational speed sensors are each directly connected to the wheel-specific control unit of the wheel brake of the respective vehicle wheel for transmission of the ascertained rotational speed information. The wheel-specific control units are each configured to control a deceleration moment exerted by the respective wheel brake on the respective vehicle wheel on the basis of the received rotational speed information and the control signals received from the central control unit.

A method for controlling wheel slip in a braking system of a vehicle includes receiving, by an input interface module of a slip control module, information representative of the vehicle and information representative of an estimate of the status of the vehicle, outputting, by the input interface module, input wheel slip control information, determining, by a parameter self-loading module, based on information representative of the vehicle and information representative of an estimate of the status of the vehicle, wheel slip control parameters, determining, by a plurality of wheel slip control enabling modules of the slip control module, a plurality of enabling signals of the wheel slip control, and determining, by each closed-loop wheel slip control module of a plurality of closed-loop wheel slip control modules of the slip control module a setpoint value of a control variable to be applied to a respective corner of the vehicle to minimize error between the defined slip setpoint and the estimated wheel slip value.

A cuboidal hydraulic block of a hydraulic power unit of a hydraulic power vehicle braking system for use in a left-hand drive vehicle or a right-hand drive vehicle to be attachable, rotatably by 180° about a horizontal axis, at a splashboard of a motor vehicle. An electric motor of a power brake pressure generator is thus selectively situated on a right or a left side of the hydraulic block.

A brake system for motor vehicles may include an actuation device (e.g., brake pedal), a travel simulator to generate a feedback force on the actuation device, a first piston-cylinder unit having at least one piston that separates two working chambers that are connected via at least one hydraulic line to at least one wheel brake of a brake circuit, a control device and a pressure supply unit driven by an electric motor. At least one wheel brake may be assigned to each brake circuit, and each wheel brake may be connected to its associated hydraulic connecting line via a controllable switching valve. An outlet valve may be assigned to a single wheel brake or to a single wheel brake of each brake circuit in a hydraulic connection between the wheel brake and a pressure medium storage container, without any further valve disposed as such.

A braking device comprising a body; inner supporting means for supporting the body for rotation about a first axis; outer supporting means for supporting the inner supporting means for rotation about a second axis; means for rotating the body about the first axis; means for connecting a rotation that is desired to be braked about a fourth axis to the body so as to transmit rotation and torque to the body (2) about the second axis (102); suspension means for supporting the outer supporting means.

Provided is an electronic brake system including, a master cylinder including a first piston connected to a pedal and a second piston configured to partition a first master chamber and a second master chamber provided in front of the first piston, a reservoir in which a braking fluid is stored, the reservoir connected to the first master chamber by a first reservoir passage, and connected the second master chamber by a second reservoir passage, a hydraulic pressure supply device configured to generate a hydraulic pressure by an electrical signal output in response to a displacement of the pedal, a first connection line configured to connect the first master chamber to a first hydraulic circuit, a second connection line configured to connect the second master chamber to a second hydraulic circuit, and a third connection line configured to connect the hydraulic pressure supply device to the reservoir, wherein a mechanical part including the reservoir and the master cylinder is installed in a first block, and an electronic part including the hydraulic pressure supply device and the first hydraulic circuit, the second hydraulic circuit is installed in a second block, and each of the first connection line, the second connection line, and the third connection line is provided to connect the first block to the second block.

A control apparatus for an electromechanical-brake-booster of a vehicle, having: an electronic-device to control an electric-motor of the electromechanical-brake-booster so that an output piston, connected indirectly to the electric-motor, of the electromechanical-brake-booster is displaceable out of its initial-position by the controlled electric-motor, such that only after a displacement of the output-piston out of its initial-position by at least a predefined limit displacement travel does a frictional engagement exist between the output-piston and an input-piston that is indirectly connected to the brake-pedal and is displaced by the actuation of the brake-pedal, and such that a speed of the output-piston displaced out of its initial-position by less than the limit displacement travel is at first increased from a reference-speed to a maximum-speed and is then reduced from the maximum-speed to the reference-speed. The invention furthermore relates to a method for operating an electromechanical-brake-booster of a vehicle.

For a compact design of a hydraulic block of a hydraulic modulator of a vehicle slip-controlled hydraulic-power brake system, an electric motor of a power brake-pressure generator is disposed on the same side of the hydraulic block as solenoid valves for a brake-pressure control and an electronic control unit for controlling the electric motor and the solenoid valves.