A bracket assembly for a brake assembly and a brake actuator includes a tube configured to receive a camshaft of the brake assembly. A brake spider mounting flange and actuator mounting arm are disposed proximate opposite ends of the tube and configured for coupling to a brake spider and the actuator. The arm has inboard and outboard memberseach with a body having one end affixed to the tube and an actuator mounting flange extending from another end of the body. The mounting flanges define aligned bores configured to receive a fastener of the actuator. A centerline of a gusset joining the body and flange of the inboard member is angled relative to at least one of a plane containing a longitudinal axis of the tube and a plane containing a load path line joining the center points of a tube bore and pushrod notch formed in the inboard member.

A drum brake assembly includes a brake spider having a central aperture configured to receive an axle extending therethrough and first and second brake shoes. Each of the first and second brakes shoes has a first end pivotally coupled to the brake spider. First and second cam followers are disposed at corresponding second ends of the first and second brake shoes. A camshaft has a shaft extending through a camshaft aperture in the brake spider and disposed along a rotational axis and a cam disposed at a first end of the shaft and in engagement with the first and second cam followers. An electric motor has an output shaft coupled to the camshaft. A controller is configured to drive the electric motor to cause rotation of the camshaft and move the first and second brake shoes between positions of engagement and disengagement with an associated braking surface.

A drum brake assembly includes a brake spider having a central aperture configured to receive an axle extending therethrough and first and second brake shoes. Each of the first and second brakes shoes has a first end pivotally coupled to the brake spider. First and second cam followers are disposed at corresponding second ends of the first and second brake shoes. A camshaft has a shaft extending through a camshaft aperture in the brake spider and disposed along a rotational axis and a cam disposed at a first end of the shaft and in engagement with the first and second cam followers. An electric motor has an output shaft coupled to the camshaft. A controller is configured to drive the electric motor to cause rotation of the camshaft and move the first and second brake shoes between positions of engagement and disengagement with an associated braking surface.

A brake assembly apparatus is provided for a vehicle braking system. The brake assembly apparatus comprises a vibration damping sleeve for damping vibration between a first braking component and a second braking component. The sleeve includes (i) a first set of spring elements projecting toward a circumferential surface of the first braking component and tuned with a first preload against the circumferential surface of the first braking component, and (ii) a second set of spring elements projecting toward a circumferential surface of the second braking component and tuned with a second preload against the circumferential surface of the second braking component. The first and second sets of spring elements cooperate to damp vibration of certain frequencies between the first and second braking components based upon the first and second preloads.

A brake assembly apparatus is provided for a vehicle braking system. The brake assembly apparatus comprises a vibration damping sleeve for damping vibration between a first braking component and a second braking component. The sleeve includes (i) a first set of spring elements projecting toward a circumferential surface of the first braking component and tuned with a first preload against the circumferential surface of the first braking component, and (ii) a second set of spring elements projecting toward a circumferential surface of the second braking component and tuned with a second preload against the circumferential surface of the second braking component. The first and second sets of spring elements cooperate to damp vibration of certain frequencies between the first and second braking components based upon the first and second preloads.

A brake assembly having a brake spider that may receive an anchor pin or a sleeve that receives an anchor pin. Features such as splines may be provided with the anchor pin to help secure the anchor pin to the brake spider or the sleeve. Engagement features may be provided with the sleeve to help secure the sleeve to the brake spider.

A brake assembly having a brake spider that may receive an anchor pin or a sleeve that receives an anchor pin. Features such as splines may be provided with the anchor pin to help secure the anchor pin to the brake spider or the sleeve. Engagement features may be provided with the sleeve to help secure the sleeve to the brake spider.

A linear actuation assembly comprising: (a) a differential assembly and (b) a pair of linear actuators in communication with the differential assembly; wherein the pair of linear actuators are movable along an axis so that during movement of each of the pair of linear actuators a pair of brake shoes are moved to create a brake force or moved to release a brake force, and wherein the differential assembly distributes power equally to each of the pair of linear actuators until resistance of one of the brake shoes increases then the differential assembly ceases to provide power to the brake shoe with increased resistance and distributes the power from the brake shoe with increased resistance to a brake shoe of lower resistance until a brake force is created.

A linear actuation assembly comprising: (a) a differential assembly and (b) a pair of linear actuators in communication with the differential assembly; wherein the pair of linear actuators are movable along an axis so that during movement of each of the pair of linear actuators a pair of brake shoes are moved to create a brake force or moved to release a brake force, and wherein the differential assembly distributes power equally to each of the pair of linear actuators until resistance of one of the brake shoes increases then the differential assembly ceases to provide power to the brake shoe with increased resistance and distributes the power from the brake shoe with increased resistance to a brake shoe of lower resistance until a brake force is created.

Disclosed is an electronic parking brake. The electronic parking brake is provided with an operating lever, which is configured to support first and second brake shoes, which are installed at both sides inside a drum, and push the first and second brake shoes toward an inner surface of the drum when a pivot lever is pulled, and is electronically activated to operate the pivot lever to brake the drum, and the electronic parking brake includes a housing mounted on a vehicle body; an actuator installed at the housing and configured to generate a driving force for braking; a power conversion unit having a nut member configured to be rotated by receiving the driving force from the actuator, and a spindle member screw-coupled to the nut member to allow a rectilinear movement; and a parking cable configured to move according to a reciprocal linear movement of the spindle member, operate the parking brake, release an operation of the parking brake, and be connected to an end of one side of the spindle member, wherein the parking cable has a predetermined length and is formed with a single integrated type steel bar body to prevent occurrence of a bending deformation.