A braking system for aircraft landing gear including a plurality of clamping zones for clamping a brake disk. The braking system comprises an actuator, a caliper, a rim rotatable about an axis of rotation, and the brake disk, which is floatingly mounted relative to the rim. The caliper comprises a stationary inner support, a movable intermediate support, and an outer support that is hinged relative to the inner support. Under action of the actuator, the movable intermediate support moves and causes the brake disk to move so that the brake disk is clamped between the intermediate support and the outer support, and then causes the outer support to tilt so that the brake disk is clamped between the inner support and the outer support.

According to the present disclosure, there is provided a self-energizing brake caliper which comprises a caliper bracket fixed to a vehicle frame and comprising a rotation axis extending in the height direction of the vehicle; a first caliper arm rotatably connected to the rotation axis; a second caliper arm rotatably connected to the rotation axis and crossing the first caliper arm; an inboard brake pad; and an outboard brake pad. The first caliper arm is slidably connected at a first end of the inboard brake pad in the inboard side of the brake disc and the outer end of the first caliper arm is connected to a second end of the outboard brake pad. The second caliper arm is connected to the second end of the inboard brake pad in the inboard side of the brake disc and the outer end of the second caliper arm is slidably connected to the first end of the outboard brake pad. The driving force of an actuator is transferred to the inner ends of the first caliper arm and the second caliper arm.

Disclosed is a friction set for a railway disk brake system for railway rolling stock including: a shoe holder including a receiving slideway; a friction shoe including a brake pad and a profiled shape configured for being slid into the receiving slideway, where the friction shoe includes a pneumatic conduit connecting a first space delimited by a first surface of the friction shoe to a second space delimited by a second opposite surface the friction shoe; at least one through hole arranged in the shoe holder and laid out so as to be facing the pneumatic conduit; and a pneumatic junction ring laid out in the pneumatic conduit forming a pneumatic guide between the through hole of the shoe holder and the pneumatic conduit of the friction shoe.

To provide a brake device and an electric brake system that appropriately brakes a rotary body of a human powered vehicle in various situations, a brake device is applicable to a human powered vehicle and includes an electric actuator operated by electric power from a power supply, a braking portion driven by the electric actuator to brake a rotary body of the human powered vehicle, and a power storage provided separately from the power supply to supply electric power to the electric actuator.

An electric brake system that appropriately brakes a rotary body of a human powered vehicle in various situations is applicable to a human powered vehicle and includes a brake device including an electric actuator operated by electric power from a power supply, and a braking portion driven by the electric actuator to brake a rotary body of the human powered vehicle, a state detector detecting a state of the human powered vehicle other than an operation of the brake device performed by a user, and a control unit controlling the brake device so that the braking portion brakes the rotary body based on a detection result of the state detector.

A self-energizing brake caliper comprises a caliper bracket fixed to a vehicle frame, a first caliper arm rotatably connected to the caliper bracket, a second caliper arm rotatably connected to the caliper bracket, an inboard brake pad, and an outboard brake pad. The first caliper arm is rotatably connected to the outboard brake pad at a first position and is configured to press against the outboard brake pad at the first position by receiving the power of an actuator at the second position which is inboard side. The second caliper arm is rotatably connected to the inboard brake pad at a third position and is configured to press against the inboard brake pad at the third position by receiving the power of an actuator at the fourth position which is inboard side.

A pull rod device arrangement of a brake calliper includes a pull rod top, a pull rod bottom, and two vertical rods, wherein the pull rod top and the pull rod bottom of the pull rod device are connected to each other. The pull rod top and the pull rod bottom of the pull rod device are designed as separate parts. A brake caliper includes the pull rod device.

A brake unit comprises said rotor disc rotatable about a central axis of rotation and a first brake pad mounting element having a first end and a second end and a longitudinal outer, side, surface extending there between, wherein a first brake pad is provided at said first end of said first brake pad mounting element and positioned facing a first face of said rotor disc. The first brake pad mounting element comprises a first locking feature provided on its outer, side, surface. The brake unit further comprises first locking element that pivots about pivot and that is movable about said pivot axis so that a locking feature of said locking element can come into contact with, or be moved away from said outer, side, surface of said first brake pad mounting element.

A disc brake (11) includes: a floating caliper (13) including a base portion (25) slidably supported by an upper guide pin (31) supported by a support (23), a piston side pressing arm (39) and an opposite piston side pressing arm (41); a pair of brake pads (17); a drive piston (15) provided on the piston side pressing arm (39); a caliper return mechanism (22) for elastically biasing the base portion disposed on an end portion of the guide pin (31) to the side opposite to the drive piston side; and an inner circumferential side washer (44) disposed on both sides in an axial direction of the rubber ring (21) elastically supporting the upper guide pin (31) in a radial direction to restrict an inner circumferential portion of the rubber ring (21) from bending deformation along an axial direction of the upper guide pin (31).

The bogie for a railway vehicle comprises a chassis; an axle mounted rotatably relative to the chassis around a transverse rotation axis, at least one wheel being mounted on each of the transverse end parts of said axle, a braking system comprising three brake discs mounted around the axle, arranged in the space defined between the wheels, and three brake forks acting on a brake disc, comprising a pair of arms extending between first and second ends, the second ends each bearing a brake pad forming a pair of brake pads, each of the pairs of brake pads being positioned around part of a brake disc, and two successive pairs of brake pads extending on either side of the rotation axis. The first ends of the arms all extend on a same side of the rotation axis.