A kit including first and second retaining brackets for hydraulic disc brake systems is provided. The first retaining bracket is adapted for circumferential fixation about a conventional caliper associated with hydraulic disc brakes. The second retaining bracket is adapted for positioning against an underside of the caliper and for fixation to a conventional mounting bracket for the caliper. The first and second retaining brackets provide additional reinforcement for the brake pads of the hydraulic disc brake system, preventing them from becoming dislodged or misaligned.

A floating-caliper disc brake of a utility vehicle includes a brake disc, a brake carrier spanning the brake disc and having lining shafts arranged on both sides of the brake disc, a brake caliper overlapping the brake disc and movable relative to the brake carrier, brake linings arranged on both sides of the brake disc in a lining shaft of the brake carrier, and having a lining carrier plate and a friction lining attached thereto. An application-side brake lining can be pressed against the brake disc by an application device and a reaction-side brake lining can be pressed against the brake disc by a brake caliper back, by moving the brake caliper. The brake caliper can be reset by a resetting device along a wear adjustment path in an axial direction to the axis of rotation of the brake disc. With the same volume of the friction linings in the new condition, the friction lining thickness of the reaction-side brake lining is not the same as the friction lining thickness of the application-side brake lining (5).

A floating-caliper disc brake of a utility vehicle includes a brake disc, a brake carrier spanning the brake disc and having lining shafts arranged on both sides of the brake disc, a brake caliper overlapping the brake disc and movable relative to the brake carrier, brake linings arranged on both sides of the brake disc in a lining shaft of the brake carrier, and having a lining carrier plate and a friction lining attached thereto. An application-side brake lining can be pressed against the brake disc by an application device and a reaction-side brake lining can be pressed against the brake disc by a brake caliper back, by moving the brake caliper. The brake caliper can be reset by a resetting device along a wear adjustment path in an axial direction to the axis of rotation of the brake disc. With the same volume of the friction linings in the new condition, the friction lining thickness of the reaction-side brake lining is not the same as the friction lining thickness of the application-side brake lining (5).

A disc brake, an axle assembly having a disc brake, and a method of assembly. The disc brake may include a first friction element and a second friction element. The first and second friction elements may have an effective contact area with a brake rotor of at least 10,000 mm.sup.2.

A disc brake, an axle assembly having a disc brake, and a method of assembly. The disc brake may include a first friction element and a second friction element. The first and second friction elements may have an effective contact area with a brake rotor of at least 10,000 mm.sup.2.

Provided is an electric brake including: a brake mechanism configured to transmit, based on a braking request, a thrust force generated through drive of an electric motor to a piston configured to move brake pads to be pressed against a disc rotor; and an ECU for rear electric brake configured to control the drive of the electric motor, and to move, in a non-braking state, the piston to a predetermined clearance position at which a clearance between each of the brake pads and the disc rotor is a predetermined amount. The ECU for rear electric brake is configured to drive the electric motor so that a period from generation of the braking request to a start of the pressing of the disc rotor by the brake pads is a predetermined period regardless of a position of the piston at a time when the braking request is generated.

The present disclosure relates to a zero-drag control device of an EMB system and a zero-drag control method using the same, which effectively control a drag phenomenon. By adjusting a gap between a disk and a pad in consideration of not only a braking intention through a brake pedal but also an accelerating intention through an accelerator pedal, the drag phenomenon can be effectively controlled and the braking response can be improved.

The present disclosure relates to a zero-drag control device of an EMB system and a zero-drag control method using the same, which effectively control a drag phenomenon. By adjusting a gap between a disk and a pad in consideration of not only a braking intention through a brake pedal but also an accelerating intention through an accelerator pedal, the drag phenomenon can be effectively controlled and the braking response can be improved.

A cable tension adjuster for a manually operated, height-adjustable wheeled vehicle. The vehicle includes a brake assembly including a brake cable assembly and a brake cable housing shaped to enclose an excess portion of the brake cable assembly. The brake assembly includes a cable adjuster coupled to the brake cable assembly, where the cable adjuster is enclosed by the brake cable housing. The brake cable housing provides an access port to access the cable tension adjuster.

A cable tension adjuster for a manually operated, height-adjustable wheeled vehicle. The vehicle includes a brake assembly including a brake cable assembly and a brake cable housing shaped to enclose an excess portion of the brake cable assembly. The brake assembly includes a cable adjuster coupled to the brake cable assembly, where the cable adjuster is enclosed by the brake cable housing. The brake cable housing provides an access port to access the cable tension adjuster.