A parking lock mechanism comprises: a parking gear disposed on a power transmission member mechanically coupled to a drive wheel; and a parking pawl provided with a lock claw configured to mesh with the parking gear and switching between a lock state in which the lock claw is meshed with the parking gear and an unlock state in which meshing between the lock claw and the parking gear is released. In the mechanism, the lock claw includes a first end surface and a second end surface opposite to each other in a face width direction, the lock claw includes a tooth tip surface provided with a retreated portion at a corner on the second end surface side, and a position of a center of gravity of the parking pawl is on the second end surface side relative to a center plane in the face width direction of the lock claw.

A parking lock mechanism comprises: a parking gear disposed on a power transmission member mechanically coupled to a drive wheel; and a parking pawl provided with a lock claw configured to mesh with the parking gear and switching between a lock state in which the lock claw is meshed with the parking gear and an unlock state in which meshing between the lock claw and the parking gear is released. In the mechanism, the lock claw includes a first end surface and a second end surface opposite to each other in a face width direction, the lock claw includes a tooth tip surface provided with a retreated portion at a corner on the second end surface side, and a position of a center of gravity of the parking pawl is on the second end surface side relative to a center plane in the face width direction of the lock claw.

An electric motor-driven parking brake of a motor vehicle can be released in an emergency by applying emergency current from a parallel emergency current source to the motors controlling the parking brake. The direction of the emergency current is selected to reverse the motors, i.e., release the parking brake.

A system, apparatus and method provide emergency differential braking for effecting braked steering of an aircraft. A brake input device is provided that not only allows for emergency and parking brake functions, but also enables differential braking. The brake input device (e.g., a parking and/or emergency brake lever, pedal, handle, etc.) can be used in a brake system including a brake system control unit (BSCU), one or more electro-mechanical actuator controllers (EMACs) and a brake assembly including one or more electrical actuators. Each EMAC is electrically coupled to one or more of the actuators so as to provide electrical power for driving the actuators. Each EMAC is also communicatively coupled to the BSCU so as to receive braking data therefrom. In an emergency, the input device sends braking signals directly to the brake actuators.

A system, apparatus and method provide emergency differential braking for effecting braked steering of an aircraft. A brake input device is provided that not only allows for emergency and parking brake functions, but also enables differential braking. The brake input device (e.g., a parking and/or emergency brake lever, pedal, handle, etc.) can be used in a brake system including a brake system control unit (BSCU), one or more electro-mechanical actuator controllers (EMACs) and a brake assembly including one or more electrical actuators. Each EMAC is electrically coupled to one or more of the actuators so as to provide electrical power for driving the actuators. Each EMAC is also communicatively coupled to the BSCU so as to receive braking data therefrom. In an emergency, the input device sends braking signals directly to the brake actuators.

A parking brake device is provided which includes a rigid base with a high manufacturing yield. A base for a braking unit of this parking brake device includes: a structural material having: a structural main body that supports a parking lever; and a plurality of leg portions that extend from the structural main body, an end of each leg portion being fixed to a vehicle body, wherein at least one (rear-side leg portion) of the leg portions is folded over and faces the structural main body so as to produce a shape to be installed onto the vehicle body.

A system for controlling the positions of a caliper and a cable of an electric parking brake (EPB) includes: an actuator driving motor used for engaging and disengaging a parking brake of an EPB system; an electronic control module for controlling the motor; and a vehicle battery for supplying power to the motor and the electronic control module, wherein the electronic control module includes a ripple measuring unit for measuring the ripple of the motor by receiving an output signal of the motor and a current measuring unit for measuring a change in the driving current of the motor.

A work vehicle is provided with a body and ground engaging means configured to allow motion of the body on ground, and braking means for locking ground engaging means, and an operative element carried by said body and configured to execute a specific working operation. The work vehicle further includes a first and a second joystick configured to respectively control the operation of ground engaging means and operative element based on movement of joystick and first and second input means configured respectively to control the activation/deactivation of parking brake functionality of the work vehicle and the activation/deactivation of hydraulic systems of work vehicle. Furthermore, the work vehicle includes a control system configured to receive second and first control signals derived from first and second input means respectively and each configured to assume a respective activation value and a respective deactivation value and inhibit the operation of the joystick linked to the operation of ground engaging means if both control signals are in activation state.

The invention relates to an activation device (1) for a parking brake with a parking brake lever (2) swivel-mounted on a bearing block (3) and with a blocking device comprised of a pawl (13) on the parking brake lever (2) and a locking segment (12) on the bearing block (3). The parking brake lever (2) is fixed in place in a swivel position via the engagement of the pawl (13) with the locking segment (12). The swivel position of the parking brake lever (2) is transmitted via a transmission element to the parking brake and with a transfer device in or on the parking brake lever (2). The engagement of the pawl (13) with the locking segment (12) is released by actuating the transfer device. To form a swivel bearing, a shaft is provided to which a holder (7) for the transmission element and the parking brake lever (2) can be affixed in different rotational positions. As an alternative, or in addition, a linear movement of the pawl (13) is brought about by means of the transfer device.

To provide a driving assistance device with which a brake held state can be automatically or easily set. A driving assistance device includes a controller configured to collect detection results of an operation state of an operation lever and a state of a vehicle, the controller determines whether to set a holder to be held or released based on the operation state of the operation lever and the state of the vehicle, and a switching instruction unit provides an instruction for switching the holder between a held state and a released state in accordance with a result of the determination by the controller.