A simple and inexpensive power brake system for a three-wheel vehicle with two wheels in the rear. One embodiment of the present invention allows the backing plate of a drum brake to rotate about twenty degrees on the axle of the front wheel that is attached to a brake drum, or a backing plate of a caliper of a disk brake to rotate about twenty degrees on the axle of the front wheel that is attached to a brake disk. Rotation of the backing plate is coupled to actuate the rear brake(s).

A braking system includes a brake pad that is coupled to a slider assembly that moves linearly within a guide. The slider assembly and guide are coupled to a first brake. A second brake actuator is coupled to the slider assembly, the guide and a second brake. When the first brake is actuated, the slider assembly is pressed against a rotating braking surface and the friction of the brake pad against the rotating braking surface can cause the slider assembly to move within the guide which actuates the second brake actuator. The second brake actuator then actuates the second brake. When the first brake is released, the slider assembly is removed from the rotating braking surface and the second brake actuator is released which releases the second brake.

A braking system includes a brake pad that is coupled to a slider assembly that moves linearly within a guide. The slider assembly and guide are coupled to a first brake. A second brake actuator is coupled to the slider assembly, the guide and a second brake. When the first brake is actuated, the slider assembly is pressed against a rotating braking surface and the friction of the brake pad against the rotating braking surface can cause the slider assembly to move within the guide which actuates the second brake actuator. The second brake actuator then actuates the second brake. When the first brake is released, the slider assembly is removed from the rotating braking surface and the second brake actuator is released which releases the second brake.

The present disclosure provides a brake apparatus comprising: a single monolithic brake shoe having a circular shape, wherein the shoe has a spacing defined therein at a predetermined location thereof; an actuator disposed in the spacing, wherein the actuator includes a hollow cylinder an a piston slidably contained in the cylinder, wherein when the actuator is activated, the spacing increases; and a brake lining lined on an outer face of the brake shoe, wherein when the spacing increases, the lining selectively contacts a brake drum, wherein the piston is step-shaped such that a braking force of the brake apparatus having the single monolithic brake shoe is substantially equal to a braking force of a brake apparatus having two individual brake shoes.

A bicycle brake assisting apparatus may comprise a main body, a traction apparatus, two control cable members, a rear brake tube, and a front brake tube, and the traction apparatus further comprises an operating block and a rotating piece which are pivotally connected with each other. The bicycle brake assisting apparatus of the present invention is configured to achieve the effect of stopping the rear wheel of the bicycle first and concurrently stopping the rear wheel and the front wheel of the bicycle thereafter regardless of pulling a left brake lever, a right brake lever, or both of the brake levers of a bicycle, thus increasing safety of use for a cyclist.

A dissymmetric braking system has at least one right wheel braking device, at least one left wheel braking device, at least one device to apply a braking action, at least one actuating device to transform the braking action into a first pressure, at least one right wheel connection, at least one left wheel connection, and at least one pressure reducing device having at least one transfer device receiving the first pressure. The transfer device transforms the first pressure into a reduced second pressure, whereby avoiding, during the braking action, a fluidic connection between a fluid having the first pressure and a fluid having the second pressure to determine, during the braking action, a relationship between the first pressure and the second pressure with linear trend without variation of linearity throughout the operating field of the pressure reducing device, so that the braking action of one of the right wheel braking device and left wheel braking device is lower than the other.

A bicycle brake assisting apparatus may comprise a main body, a traction apparatus, two control cable members, a rear brake tube, and a front brake tube, and the traction apparatus further comprises an operating block and a rotating piece which are pivotally connected with each other. The bicycle brake assisting apparatus of the present invention is configured to achieve the effect of stopping the rear wheel of the bicycle first and concurrently stopping the rear wheel and the front wheel of the bicycle thereafter regardless of pulling a left brake lever, a right brake lever, or both of the brake levers of a bicycle, thus increasing safety of use for a cyclist.

A brake assembly has first and second brake pads, a brake caliper, a brake caliper guide configured to guide a relative movement of the brake caliper in a braking direction, and an actuating member operatively connected to the first brake pad and configured to move the first brake pad into a braking direction by being translationally or rotationally driven. The operative connection between the brake caliper and the first brake pad includes a transfer mechanism configured to move the brake caliper in an opposite direction of the moving direction of the first brake pad in the braking direction. The transfer mechanism is operatively connected to the brake caliper guide for a relative movement of the brake caliper with respect to the brake caliper guide. The actuating member is configured to drive the transfer mechanism for the opposite movement of the brake caliper along the brake caliper guide with respect to the first brake pad being moved in the braking direction.

A brake assembly has first and second brake pads, a brake caliper, a brake caliper guide configured to guide a relative movement of the brake caliper in a braking direction, and an actuating member operatively connected to the first brake pad and configured to move the first brake pad into a braking direction by being translationally or rotationally driven. The operative connection between the brake caliper and the first brake pad includes a transfer mechanism configured to move the brake caliper in an opposite direction of the moving direction of the first brake pad in the braking direction. The transfer mechanism is operatively connected to the brake caliper guide for a relative movement of the brake caliper with respect to the brake caliper guide. The actuating member is configured to drive the transfer mechanism for the opposite movement of the brake caliper along the brake caliper guide with respect to the first brake pad being moved in the braking direction.

A device for generating a force applied to a component includes a force generating element supported on a resilient support device having first and second, or only a second, spring elements in series in a force transmission chain being stressed during force transmission. The first spring element is less stiff than the second. The first spring element is stressed by a first supporting force over a first spring travel. A spring travel exceeding the first spring travel and a force absorption by the first spring element exceeding the first supporting force are prevented by a first mechanical engaging device. The second spring element is formed by a spring module having a second spring stressed by a second mechanical engaging device with a second supporting force permitting the second spring to only be further stressed when exceeding the second supporting force. A travel sensor detects displacement of the force generating element.