A disk brake includes a brake disk, a brake caliper, which fits over the brake disk, a brake support, a brake pad and an application device, which presses the brake pad against the brake disk when braking, wherein the brake pad rests in a U-shaped well and the two legs of the “U” serve to support the brake pad in the circumferential direction of the brake disk and the “base” of the “U” serves to support the brake pad radially toward the inside. The distance between the two legs of the “U” is shorter at the radially outer ends thereof than the distance at the radially inner ends thereof.

A light mount for mounting a light to a steering arm on an axle may include a bracket designed to attach to the steering arm; and a bracket orifice extending through a portion of the bracket, the bracket orifice sized to accommodate a light pod fastener extending from a light pod, wherein the bracket and, thus, the light pod rotate with rotation of the steering arm. The bracket may have various forms and may be a Z-shaped bracket, a mounting perch integrated into the structure of a steering arm, or a mounting plate designed to be attached to an existing steering arm.

A braking structure for an in-wheel motor drive device includes: an in-wheel motor drive device including a wheel hub bearing unit (11) and a motor unit, the wheel hub bearing unit (11) including an outer ring (12) connected to a road wheel (W) and a brake rotor (BR), inner rings (13) disposed coaxially with the outer ring (12), and a plurality of rolling elements (14) arranged in annular clearance between the outer ring and the inner rings, and the motor unit being configured to drive the outer ring; a carrier member (17) coupled to a vehicle body-side member and attached to and fixed to an inner fixing member (15) for the inner rings (13); and a brake caliper bracket (18) that has its inner end (18b) connected to the carrier member (17) and that supports a brake caliper (19) at its outer end (18a).

A pad support spring includes a U-shaped portion comprising an outer peripheral surface portion, an inner peripheral surface portion and a linking surface portion. The U-shaped portion is configured to include: a pad holding portion; a cutout portion provided by cutting out a part from the linking surface portion toward the inner peripheral surface portion; a tongue piece portion which in an unassembled state has a base end formed by the cutout portion on the outer peripheral surface portion side of the pad holding portion and a distal end which projects out from an opposing surface of the inner peripheral surface portion, and which in an assembled state deforms elastically to press a brake pad in conjunction with the U-shaped portion; and a first slit portion provided by cutting out part of a first linking part.

A sliding caliper disk brake is provided, in which a stationary brake carrier configured to carry a brake caliper includes two pairs of carrier horns, one pair of which supports a reaction-side brake pad and one pair of which supports an application side brake pad. The spacing between the reaction-side pair of carrier horns is larger than the spacing between the application-side pair of carrier horns. The reaction-side brake pad and reaction-side pair of carrier horns may be shorter than the corresponding application-side brake pad and carrier horns. The arrangement of the brake carrier, the brake caliper and the brake pads permits reduction in disk brake weight, cost and brake carrier stresses while providing desired brake thermal, mechanical and service life performance.

A caliper body has a first elongated vehicle-side element facing a first braking surface, a second elongated wheel-side element facing a second braking surface opposite to the first braking surface, each having at least one thrust seat receiving a thrust device biasing at least one brake pad against the braking surfaces, and at least one caliper bridge connecting the first elongated vehicle-side element to the second elongated wheel-side element. The caliper body has caliper fixing elements connecting the caliper body to a vehicle mount, the caliper fixing elements being at least three in number and distributed along the first elongated vehicle-side element. The first elongated vehicle-side element and second wheel-side element may have each at least two pad seats, each receiving at least one brake pad and at least two opposite abutment elements abuttingly receiving a brake pad for relieving the braking action on the caliper body.

A disc brake includes: an inner pad and an outer pad respectively located on opposite sides of a rotor; a pressing device that presses the inner pad and the outer pad against the rotor; and a housing holding the pressing device. The pressing device includes: at least one first pressing member movable toward the rotor and at least one second pressing member movable away from the rotor; and a driving member movable relative to the housing in an axial direction parallel with a rotation axis of the rotor and configured to be moved by movement of the at least one second pressing member to press the outer pad against the rotor. The housing is provided with a torque receiver that receives torque acting on the outer pad in operation of the disc brake.

A caliper and supporting assembly for a disc brake may have a brake caliper with a caliper body adapted to straddle an associable disc of the disc brake, a supporting element connected to a caliper body, where the caliper body may have a first portion, and the supporting element may have a second portion. During braking action, the caliper body elastically deforms according to at least one predetermined direction, thereby determining a displacement in at least the predetermined direction of the first portion of the caliper body with respect to the second portion of the supporting element. The caliper and supporting assembly may also have at least one detecting device which detects a distance at least along the predetermined direction between the first portion of the caliper body and the second portion of the supporting element.

The present application relate to a follow-up mechanism and a brake caliper unit for gauge-changeable bogie, the follow-up mechanism includes a follow-up connector, unlocking members that are located on two sides of the follow-up connector and movably connected to the follow-up connector, a transverse displacement recognition device movably connected to the unlocking members, a toothed locking and positioning device mounted on the follow-up connector, and at least two mutually parallel fixation members; the follow-up connector is in sliding fit with the fixation members, and sliders are fixedly connected at ends of the unlocking members; the toothed locking and positioning device is movably connected to the transverse displacement recognition device and fixation members, respectively; the brake caliper unit comprises a mounting bracket, the follow-up mechanism, and a brake actuator mounted on the mounting bracket, the follow-up mechanism is installed in cooperation with the brake actuator, and the fixation members are fixedly mounted on the mounting bracket. The present application can automatically recognize the orbit change of a train, the follow-up mechanism moves with a wheel by means of its stored elastic force and the unlocking members, and can self-locked at the target gauge position, thus realizing the change in position.

A brake component positioning assembly that is removably connectable to a component of a heavy-duty vehicle. The brake component positioning assembly enables a brake system component to be positioned away from a wheel end of the heavy-duty vehicle to allow removal or servicing of at least one component of a wheel end assembly or the vehicle brake system. In one embodiment, the brake component positioning assembly includes a base block disposed in a cutout of a torque plate. A positioning block slidably engages one or more guide pins received by or disposed through the base block. A positioning bolt threadably engages the positioning block, whereby upon rotation of the positioning bolt, the positioning block and brake system component are positioned away from the bottom block and wheel end. Components of the brake component positioning assembly can be removably connected to each other.