Venting a cylinder of a piston-cylinder unit of a power brake pressure generator of a hydraulic power brake system for a motor vehicle. A piston in the cylinder is displaced from a forward-displaced position back into a home position and subsequently forward again. When the piston is displaced back, a connection valve is closed so that the piston sucks brake fluid from a brake fluid container, the brake fluid flowing over a lip seal acting in the manner of a pressure relief valve as the first piston seal. During the forward stroke, the piston pushes brake fluid through the then open connection valve into the brake fluid container. Any air contained in the cylinder is pushed with the brake fluid from the cylinder and separates from the brake fluid in the brake fluid container.

A brake signal transmitter (10) includes a housing (11) and a liquid drainage system (20). The liquid drainage system (20) includes an opening in the housing (11) and a cover (30) that extends over or along the opening. The cover (30) includes at least one aperture that allows a liquid to be drained through the cover (30). The opening (21) of the housing (11) is arranged on a downward side of the housing (11) relative to a gravitational force the transmitter is mounted horizontally. The cover (30) may be a cap having a filter inserted therein. The filter may define a tortuous path to block ingress of water or debris into the housing. The cover may include resilient fingers that snap fit into a socket of the housing.

Transportable system for the diagnosis, evaluation and prediction of leakages in hydraulic circuits of low pressure between 0 to 7 bar and of high pressure from 0 to 170 bar, quickly and safely for the operator is provided having a first independent circuit of high pressure and low flow and a second independent circuit of low pressure and high flow wherein the first independent circuit comprises: a first pressure subsystem, which delivers pressure to a first 4/3 valve with ports A, B, P and T, which is actuated by first solenoids, to deliver pressure to a first coupling A or to a first coupling B, in fluid communication with the ports A and B of the first 4/3 valve respectively a computer arranged to control the pressure of each pressure subsystem and associated method.

A bicycle brake caliper apparatus comprises a caliper housing and a plug. The caliper housing includes a fluid chamber and an opening for receiving the plug therein, wherein the opening extends to an outside of the housing at a first location. The housing also includes a fluid passage in fluid communication with the fluid chamber, wherein the fluid passage is in fluid communication with an outside of the housing at a second location offset from the first location. The fluid passage is closed when the plug is in a first position. The fluid passage is open when the plug is in a second position so that fluid is allowed to flow from the fluid chamber, through the fluid passage and to the outside of the housing at the second location.

According to one aspect, a method includes applying a first force to a piston using an actuator that includes a displacement indication arrangement. The piston is part of a hydraulic braking system included in a vehicle. The hydraulic braking system includes fluid, wherein when the first force is applied to the piston, the piston moves. The method further includes determining when a pressure of the fluid reaches a target pressure, obtaining at least a first measurement of a displacement of the piston when the pressure of the fluid reaches the target pressure using the displacement indication arrangement, and determining when the at least first measurement of the displacement of the piston indicates an anomaly in the hydraulic braking system. When it is determined that the at least first measurement of the displacement of the piston indicates the anomaly, the anomaly in the hydraulic braking system is identified.

A self-adaptive air bag blocking device is disclosed. The device includes an air bag, a first gas conveying pipe and a second gas conveying pipe, wherein an air chamber is formed in the air bag, a ring-shaped abutting surface is formed on the peripheral side of the air bag, so that the abutting surface abuts against a mouth of a container. The first gas conveying pipe is communicated with the air chamber and the outer part of the air bag, so that air enters the air chamber to enable the air bag to expand. The abutting surface is elastically deformed and tightly abuts against the inner wall of the container to form air-tight abutment, and the second gas conveying pipe is arranged on the air bag, so that air enters the container through the second gas conveying pipe, and thus the working liquid is discharged.

A mobile device may authorize with a paired telematics control unit of a vehicle to ensure the vehicle is in a remote service mode; send a command request to the telematics control unit requesting an operation to be automatically performed by a vehicle electronic control unit in place of manual input by an assistant; and receive diagnostic data from the vehicle electronic control unit via the telematics control unit. The telematics control unit may query electronic control units of the vehicle to identify whether the vehicle is in a mode in which commands from a remote service application of a mobile device can be processed; indicate the mode to the application; and receive the command request requesting a service operation to be automatically performed by one of the electronic control units.

A hydraulic fitting (10) for a hydraulic transmitter system (100) having a housing (12) in which a fluid reservoir (16), a pressure chamber (20) which is fluidically connected to the fluid reservoir (16) and a venting bore (22, 22) which connects the pressure chamber (20) to a housing surroundings are configured, wherein the venting bore (22, 22) can be closed in a closed position (III) during operation and can be opened to produce a venting position (V), also having an additional fluid connection between the fluid reservoir (16) and the pressure chamber (20) which is interrupted during operation but which can be temporarily opened to permit rapid venting in a rapid venting position (IV) while the venting bore (22) remains closed.

A brake caliper assembly may comprise a caliper body comprising an inner body and an outer body and a hose connection; the inner body may comprise a piston set and bleed port; the outer body may comprise a piston set and bleed port; a fluid path within the caliper body may comprise an inner body segment between the bleed port and the piston set of the inner body and an outer body segment between the bleed port and the piston set of the outer body; air can be removed from the inner body segment of the fluid path within the caliper body at the bleed port by flowing fluid between the hose connection; air can be removed from the outer body segment of the fluid path within the caliper body at the bleed port by flowing fluid between the hose connection. Air can be removed from the fluid path within the caliper body by flowing fluid between the bleed port of the inner body segment and the bleed port of the outer body segment. Each piston set may comprise at least two pistons; each body may comprise a fluid path across each piston.

A hydraulic braking system includes: a master cylinder including: a pressurizing piston fluid-tightly and slidably fitted in a housing; a front pressure chamber located in front of the pressurizing piston and connected to a brake cylinder; and a rear chamber located behind the pressurizing piston; a rear-hydraulic-pressure control device connected to the rear chamber of the master cylinder and configured to supply control hydraulic pressure to the rear chamber; and an air bleeding device configured to perform air bleeding for an air bleeding target portion as at least a portion of the rear-hydraulic-pressure control device, in a state in which working fluid is prevented from being supplied to the rear chamber.