The present disclosure relates to vehicle drum brakes. In one aspect, there is provided a brake shoe comprising a guide at or near its free end, which prevents brake shoe misalignment. According to a further aspect, there is provided a guide for attachment to a brake shoe at or near its free end, which prevents brake shoe misalignment. According to a further aspect, there is provided a drum brake assembly comprising a brake shoe comprising the guide.

An integrated brake spider and mounting bracket arrangement for a drum brake includes a brake spider with a spider mounting section, having openings through which fasteners may pass to secure the brake spider to an axle flange of a vehicle. The spider is also provided with a base section having an attachment surface for a bracket, and the bracket is secured by way of a metal fabrication process to the attachment surface of the base section and to actuator support structure adapted to support an actuator for the drum brake.

A system includes a carriage configured to move along a rail. The system also includes a clamping brake configured to selectively allow and prevent movement of the carriage along the rail. The clamping brake includes multiple brake pads configured to be moved inward to lock onto the rail and to be moved outward to release the rail. The clamping brake also includes multiple springs configured to apply spring forces that cause the brake pads to move inward and lock onto the rail. The clamping brake further includes a camshaft coupled to or including multiple eccentrics. The eccentrics are configured to overcome the spring forces and cause the brake pads to move outward and release the rail.

An integrated brake spider and mounting bracket arrangement for a drum brake includes a brake spider with a spider mounting section, having openings through which fasteners may pass to secure the brake spider to an axle flange of a vehicle. The spider is also provided with a base section having an attachment surface for a bracket, and the bracket is secured by way of a metal fabrication process to the attachment surface of the base section and to actuator support structure adapted to support an actuator for the drum brake.

A bracket for a brake assembly and a brake actuator includes a unitary body including a tube configured to receive a camshaft of the brake assembly and an actuator mounting arm disposed proximate a first end of the tube and configured to receive the brake actuator. In some embodiments, the tube includes one or more helical ribs formed on a radially inner surface. The bracket further includes either a brake spider or a brake spider mounting flange disposed proximate a second end of the tube. In either embodiment, material may be omitted in various locations to reduce the weight of the bracket. The bracket may be formed through an additive manufacturing process and in a manner that achieve at least one of a predetermined torsional stiffness and attenuation of a predetermined natural frequency.

The invention relates to a brake lever (20) for a drum brake arrangement (12), said brake lever being designed for transmitting the movement of a cylinder rod (14) to a brake shaft (22), wherein the brake lever (20) comprises a first portion (20a) delimiting a hole (24) for fitting the brake shaft (22) and a second portion (20b), which is configured to be pivotally connected to the cylinder rod (14) and wherein the first portion and the second portion are offset from each other with respect to a central axis (X24) of the hole (24). The brake lever further includes a stiffening member (28) that extends along a direction (L1) contained inside a plane (P1) perpendicular to the central axis (X24) of the hole and that includes an orifice (32) for fitting the brake shaft (22).

The invention is for automatic slack adjuster for an automobile with a housing having an aperture for receiving a brake cam shaft comprising of a worm gear coaxially mounted within the said housing aperture and configured to coaxially engage the brake cam shaft, such that the said worm gear and said cam shaft rotating together about a first axis. The arrangement has a bore with a single open end for receiving a worm clutch shaft. The said worm clutch shaft is mounted in the said housing to rotate about a second axis, which is perpendicular to first axis. The invention has only one side opening. The thrust load from the worm shaft is transferred through the thrust bush through the main housing of the assembly.

A slack adjuster assembly for use with a heavy-duty vehicle drum brake system, the slack adjuster assembly comprising a slack adjuster, a cam tube assembly, and an interlock assembly. The interlock assembly is disposed on an outboard side of the slack adjuster and interconnects the cam tube assembly with the slack adjuster. A component of the interlock assembly and a component of the cam tube assembly cooperate to form a rotation reference mechanism for indexing of an automatic adjustment mechanism of the slack adjuster. The slack adjuster assembly further comprising an inboard sealing assembly and an outboard sealing assembly engaging respective inboard and outboard sides of the slack adjuster to form respective 360-degree interfaces. The cam tube assembly, interlock assembly, and inboard and outboard sealing assemblies forming a continuous grease pathway between the cam tube assembly and the slack adjuster.

The invention relates to a brake device and a machine which comprises said brake device, wherein: the brake device comprises an actuator (04), a transmission an expander device, a brake lining (063) and a frictional surface; the actuator (04) moves in a limited actuator actuation region; in at least part of its actuator actuation region, the actuator (04) turns the expander device about at least one fulcrum via the transmission, in at least part of its actuator actuation region, for the purpose of braking, the actuator (04) presses the brake lining (063), via the expander device, in the direction of and onto the frictional surface to generate a pressing force and a braking torque resulting therefrom; the transmission has a non-linearity (03), i.e. a non-consistent transmission ratio, over at least part of the actuator actuation region; and the transmission turns the expander device in accordance with the non-linearity (03).

A coupling system having an inner tube, a collar, a circular gasket concentrically disposed between the inner tube and the collar; a pair of CAM levers structurally engageable with the collar, and a handle connecting the pair of CAM levers such that a user can single-handedly move the handle between the locked position and the unlocked position.