A brake module is provided. The brake module includes a first brake lever, a second brake lever, a moveable member, a first cable, a second cable, a first brake unit, a second brake unit, a third cable and a fourth cable. The first cable connects the first brake lever and the moveable member. The second cable connects the second brake lever and the moveable member. The third cable connects the first brake unit and the moveable member. The fourth cable connects the second brake unit and the moveable member. When a lever force is applied to the first cable or the second cable, the third cable applies a first brake force to the first brake unit, the fourth cable applies a second brake force to the second brake unit, and the lever force is smaller than the sum of the first brake force and the second brake force.

A tiltable vehicle is configured to transform between an autonomous mode and a rideable mode by pivoting the handlebars and steering column of the vehicle about a pitch axis. In the autonomous mode, the steering column is folded back toward the chassis and a tiltable chassis of the vehicle is prevented from tilting. In the rideable mode, the steering column is unfolded and the chassis is free to tilt. In some examples, a tiltable vehicle includes features beneficial for vehicle-sharing, such as parking devices or a basket. These features may be included on any suitable vehicle and are not limited to use on transforming vehicles.

A hydraulic brake distributor for a two-wheeled vehicle has an outer body that forms an internal cavity accommodating two floating piston valve elements. The two floating piston valve elements are axially movable and mutually coupled in a telescopic manner. One of the two floating piston valve elements has an internal through-channel.

A hydraulic brake distributor for a two-wheeled vehicle has an outer body that forms an internal cavity accommodating two floating piston valve elements. The two floating piston valve elements are axially movable and mutually coupled in a telescopic manner. One of the two floating piston valve elements has an internal through-channel.

A hydraulic-type time-difference brake apparatus includes at least a driving device, a housing, a first pump mechanism and a second pump mechanism as main components combined together. The driving device is provided with a first driving rod, a second driving rod, a brake starting member and a housing, one end of the first driving rod is connected to the brake starting member, and the other end is connected to the first pump mechanism, the first driving rod can push the first pump mechanism and output the first braking force to the rear wheel brake; one end of the second driving rod is connected to the brake starting member by a sliding device, and the other end is connected to the second pump mechanism, the second driving rod can push the second pump mechanism and output the second braking force to the front wheel brake. The sliding process of the sliding device can delay the time the brake starting member activates the second driving rod, so that the start time between the first driving rod and the second driving rod will have a time difference. In this way, the driver can cause the rear wheel brake and the front wheel brake to generate a time-difference brake by only one braking operation, the rear wheel brake can first generate a braking force on the rear wheel to reduce the speed of the rear wheel, then the front wheel brake will generate a larger braking force on the front wheel more than the rear wheel after a time difference to improve the safety of the vehicle.

A hydraulic-type time-difference brake apparatus includes at least a driving device, a housing, a first pump mechanism and a second pump mechanism as main components combined together. The driving device is provided with a first driving rod, a second driving rod, a brake starting member and a housing, one end of the first driving rod is connected to the brake starting member, and the other end is connected to the first pump mechanism, the first driving rod can push the first pump mechanism and output the first braking force to the rear wheel brake; one end of the second driving rod is connected to the brake starting member by a sliding device, and the other end is connected to the second pump mechanism, the second driving rod can push the second pump mechanism and output the second braking force to the front wheel brake. The sliding process of the sliding device can delay the time the brake starting member activates the second driving rod, so that the start time between the first driving rod and the second driving rod will have a time difference. In this way, the driver can cause the rear wheel brake and the front wheel brake to generate a time-difference brake by only one braking operation, the rear wheel brake can first generate a braking force on the rear wheel to reduce the speed of the rear wheel, then the front wheel brake will generate a larger braking force on the front wheel more than the rear wheel after a time difference to improve the safety of the vehicle.

Example brake systems and apparatus for providing pitch control on bicycles are described herein. An example rear brake caliper described herein includes a caliper housing to be coupled to the bicycle. The caliper housing includes a first port to be fluidly coupled to a first fluid line fluidly coupled to a front brake actuator and a second port to be fluidly coupled to a second fluid line fluidly coupled to a front brake caliper. The rear brake caliper also includes a valve between the first port and the second port. The valve is operable to affect fluid flow between the first port and the second port.

Example brake systems and apparatus for providing pitch control on bicycles are described herein. An example rear brake caliper described herein includes a caliper housing to be coupled to the bicycle. The caliper housing includes a first port to be fluidly coupled to a first fluid line fluidly coupled to a front brake actuator and a second port to be fluidly coupled to a second fluid line fluidly coupled to a front brake caliper. The rear brake caliper also includes a valve between the first port and the second port. The valve is operable to affect fluid flow between the first port and the second port.

A brake hydraulic pressure control unit capable of improving mountability of a brake system on a motorcycle is obtained. In addition, a brake system for a motorcycle including such a brake hydraulic pressure control unit and a motorcycle are obtained. In the brake hydraulic pressure control unit of the brake system for a motorcycle, an inlet valve, an outlet valve, and a pump in one of hydraulic circuits as a boost-type hydraulic circuit and a first valve and a second valve in the hydraulic circuit are separately provided in a primary base body and a secondary base body. The primary base body and the secondary base body are separated from each other.

A brake hydraulic pressure control unit capable of improving mountability of a brake system on a motorcycle is obtained. In addition, a brake system for a motorcycle including such a brake hydraulic pressure control unit and a motorcycle are obtained. In the brake hydraulic pressure control unit of the brake system for a motorcycle, an inlet valve, an outlet valve, and a pump in one of hydraulic circuits as a boost-type hydraulic circuit and a first valve and a second valve in the hydraulic circuit are separately provided in a primary base body and a secondary base body. The primary base body and the secondary base body are separated from each other.