A multi-disc brake assembly comprising a disc pack may desirably be liquid cooled (i.e. is wet) to dissipate the substantial heat generated from braking. In conventional assemblies, coolant fluid is generally delivered in a uniform manner to the discs in the disc pack. However, the heat distribution in the disc pack from braking is not uniform. But wear can be significantly increased where an inadequate amount of coolant is delivered, while drag can be increased unnecessarily where an excessive amount of coolant is delivered. In such an assembly, an improved coolant distribution can be obtained by appropriately varying the size of the numerous orifices which may be used to distribute coolant to the disc interfaces from an axial fluid rail provided in a rotating central shaft. Specifically, the orifices decrease in size from the middle to the ends of the disc pack.

Brake rotor apparatus for use with vehicles are disclosed. An example apparatus includes a brake rotor having braking surfaces. The apparatus includes first fins coupled to the brake rotor and disposed between the braking surfaces. The first fins are distributed along a first radius of the brake rotor and extend radially outward. The apparatus includes second fins coupled to the brake rotor and disposed between the braking surfaces. The second fins are distributed along a second radius of the brake rotor smaller than the first radius and adjacent the first fins.

A heat dissipation structure for a brake pad is provided for being assembled to a caliper device. The caliper device includes a caliper body, and the caliper body has a receiving space. The heat dissipation structure includes: a main body, integrally extruded from aluminum and cut to have an ultimate appearance, including a plate body and a heat dissipation portion integrally extending from the plate body, the plate body for being disposed on the caliper body and at least partially extending into the receiving space, when the main body is assembled to the caliper body, the heat dissipation portion is exposed outside the caliper body. A brake pad assembly is further provided, including a heat dissipation structure as described above, further including a brake pad, the brake pad disposed on a lateral face of the plate body.

A multi-disc brake assembly comprising a disc pack may desirably be liquid cooled (i.e. is wet) to dissipate the substantial heat generated from braking. In conventional assemblies, coolant fluid is generally delivered in a uniform manner to the discs in the disc pack. However, the heat distribution in the disc pack from braking is not uniform. But wear can be significantly increased where an inadequate amount of coolant is delivered, while drag can be increased unnecessarily where an excessive amount of coolant is delivered. In such an assembly, an improved coolant distribution can be obtained by appropriately varying the size of the numerous orifices which may be used to distribute coolant to the disc interfaces from an axial fluid rail provided in a rotating central shaft. Specifically, the orifices decrease in size from the middle to the ends of the disc pack.

Method of assembling a drum brake device includes positioning a portion of a brake shoe (22) support structure (40, 42) near an opening of a brake actuating cylinder (80); manipulating the support structure (40, 42) so that a window (44) of the support structure (40, 42) is received over a portion of a shoe mount (50); moving the support structure (40, 42) relative to the shoe mount (50) so that the portion of the support structure (40, 42) is received into the brake actuating cylinder (80) and the support structure (40, 42) is engaged by the shoe mount (50) in a manner that the shoe mount (50) restricts movement of the brake shoe (22) in two dimensions and allows selective movement in a third dimension; and securing the brake shoe (22) in an installed position by placing the drum (26) over the brake shoe (22) with the braking surface facing the friction lining.

A caliper body for a disc brake is described. The caliper body is adapted to straddle an associable brake disc. The caliper body may have a first elongated portion, or a vehicle-side elongated portion, at least partially adapted to face the first braking surface. The caliper bdy may also have a second elongated portion, or wheel-side elongated portion, opposite to the first elongated portion and at least partially adapted to face the second braking surface. At least one part of the first elongated portion has at least a first module and at least one part of the second elongated portion has at least a second module. The first module and the second module are obtained by at least one non-additive manufacturing technique.

Disclosed is a disc brake rotor; the rotor including a central hub coaxial with and supporting annular rings which form an inboard brake band and an outboard brake band for engagement with brake pads of a disc brake; the inboard brake band and the outboard brake band maintained in a parallel spaced apart configuration by an array of pillars; the array of pillars arranged in repeating families of individually shaped pillars. Also disclosed is a method of optimising shape of pillars in groups of pillars of a disc brake rotor; the disc brake rotor comprising inner and outer annular brake bands maintained in spaced apart parallel configuration by the groups of pillars; the method including the steps of:arranging the pillars into repeating families of pillars; each family lying in a 22.5 degree sector of the rotor;further arranging each family into two groups of pillars; an outer group of pillars and an inner group of pillars;forming each outer group of pillars and inner group of pillars to comprise of two larger pillars and two smaller pillars, and wherein each larger pillar and each smaller pillar in a family of pillars has a distinctive shape.

A drive wheel for a motor vehicle may include at least one sleeve-type wheel rim and an external-rotor motor that includes a rotor. The sleeve-type wheel rim may be connected directly and in a torque-coupled manner to the rotor using a releasable connection.

Aspects of the present disclosure relate to a skewed roller impeller cage including a metallic ring with radially arranged slots in which rollers are positioned. Impeller shaped channels are defined around a top side of the cage to force fluid to circulate from an outer diameter of the cage to an inner diameter of the cage and vice versa. Cutouts defined at the inner diameter of the cage allow fluid to circulate from the top side of the cage to the bottom side due to centrifugal forces moving the fluid from the inner diameter back to the outer diameter of the cage to allow for continuous circulation of the fluid about the cage.

A disc brake runs wet by use of cooling fluid, in particular for a road vehicle, and includes stationary stator discs arranged in parallel to and at a distance from one other, and between which in each case a rotatable rotor disc is arranged. During braking, the radially extending stator discs and rotor discs can be pressed against one another, closing an air gap and, after the brake has been released, can be separated from one another, forming the air gap. The brake is designed such that the rotor discs have cooling channels which can be filled with cooling fluid immediately before or at the start of braking.