A retainer for a segmented annular heat shield of a wheel includes a first end, a second end opposite the first end, and a body extending between the first end and the second end. Both the first end and the second end are configured to be coupled to at least one of the wheel and a torque bar. Further, the body includes opposing longitudinal sides configured to respectively engage and secure a respective heat shield segment of the segmented annular heat shield. Also, the retainer includes a cover coupled to and extending over at least the body, with an air gap being defined between the body and the cover.

A brake assembly includes a wheel hub having a radially-outer diameter and a plurality of splines that are spaced apart around the radially-outer diameter. A brake disc is mounted on the wheel hub and has a radially-inner diameter and a plurality of pockets that are spaced apart around the radially-inner diameter. The pockets receive the splines such that the brake disc rotates with the wheel hub. Each pocket has opposing axially-extending side walls. Each side wall has an outwardly-chamfered outboard end and an inboard locking recess. A plurality of spacers are radially disposed between the splines and pockets. Each spacer has opposing arms connected together by a brace. Each arm has an outwardly-chamfered end and outwardly-projecting locking foot which together mate with the outwardly chamfered outboard end and inboard locking recess, respectively, so as to lock the spacer in the pocket.

A disk brake device for a vehicle, that includes an internally-ventilated or solid brake disk. The internally-vented brake disk is configured having ventilation openings on the vehicle side, on the radial inside in the region of a brake disk chamber, which ventilation openings are fluidically connected to cooling channels in the interior of the brake disk. The solid brake disk is configured without such ventilation openings and with cooling channels. A brake caliper fitting is configured over the brake disk with a brake pad arranged on both sides of the brake disk. The brake disk device is configured with a brake dust filter housing that encompasses the brake disk on the radial outside and is arranged downstream of the brake caliper, together with the brake pads. The disk brake device has at least one means for forced guidance of brake dust.

The invention at hand refers to a wheel disc brake assembly comprising a wheel rim, a coupler ring and an annular brake disc arranged in a concentric manner, wherein an outer surface of the coupler ring is connected to an inner surface of the wheel rim and an inner surface of the coupler ring is connected to an outer surface of the annular brake disc. The wheel disc brake assembly further comprises a caliper with at least two brake pads facing each other, wherein the caliper surrounds at least a part of the inner surface of the annular brake disc and the at least two brake pads are configured to press against opposite side faces of the annular brake disc.

An electric wheel drive unit (1) for driving a wheel of a motor vehicle is provided having a brake device (2) for braking the electric wheel drive unit (1) during operation, and a housing (3) which accommodates the brake device (2) in its interior (I). The brake device (2) is designed to convert kinetic energy into heat in order to perform braking, and to suck in a fluid in the axial direction (A) and to feed it in the radial direction (R) in order to cool the brake device (2) by a flow of fluid which is for the most part oriented radially and flows through the brake device (2).

A braking device for a vehicle capable of resulting in an increased driving comfort is provided. The braking device may have a brake disc of a disc brake for rotating about a rotation axis, in which the disc may have a disc body. The disc body may have a braking band having opposite braking surfaces and at least one connection portion for connecting the disc to a connection device of a vehicle associable with the braking device. The braking band defines an axial direction parallel to the rotation axis of the brake disc, a radial direction orthogonal to the axial direction and a tangential or circumferential direction orthogonal both to the axial direction and to the radial direction. The connection portion is connected to the braking band by connecting elements, the connecting elements being a plurality of elements equally spaced apart in circumferential direction.

The present disclosure relates to a brake drum for a drum brake for a vehicle. The brake drum comprises a braking surface adapted to receive at least one brake shoe of the drum brake. The brake drum further comprises a cooling arrangement comprising a set of cooling conduits located between a braking surface and an outer surface. The material of the brake drum located radially between the set of cooling conduits and the braking surface at an inner axial cross-section has an inner axial aggregate thermal conductance and the material of the brake drum located radially between the set of cooling conduits and the braking surface at the outer axial cross-section has an outer axial aggregate thermal conductance. Accordingly, the inner axial aggregate thermal conductance is different from the outer axial aggregate thermal conductance.

A brake disc assembly includes a central drive hub and a wear disc, which includes first and second faces held together axially about the hub. Each face has a respective inner surface and is formed of at least two distinct segments. Each segment extends between two radial edges. The radial edges of the segments of one face do not extend opposite the radial edges of the segments of the other face. Each segment of the face is adapted to be secured to a segment of the other face via at least one fastening member adapted to hold said faces.

A brake assembly for use in a disc brake mechanism of a vehicle. The brake assembly includes an aluminum ceramic composite rotor connected to a central aluminum hub. The rotor includes projections extending radially inward toward the hub and engaging with through holes in the hub. The projections extend through the through holes to connect the rotor to the hub. The engagement between the projections and the through holes allows for radial movement of the projections relative to the through holes, which radial movement may be caused by thermal expansion of the rotor from heat generated during a breaking operation.

A brake rotor assembly can include a structural part having a receiving surface and at least one friction surface parts having a contact surface. The friction surface part can be fixably attached to the receiving surface of the structural part such that the contact surface faces away from the receiving surface of the structural surface to form at least part of an annular braking surface arranged concentrically around an axis of rotation of the structural part.