Systems and methods for brake cable adjustment are disclosed herein. In this regard, a gage block tool for adjusting a brake cable may comprise a body comprising, a first member extending in a first direction, the first member having a first length and a first thickness, and a second member extending in a second direction, the second member having a second length and a second thickness. At least one of the first member or the second member may be sized and configured to be placed between a stop and a lever of a brake valve, the brake cable connected between the lever and a brake handle being properly adjusted when the gage block sandwiched between the lever and the stop contacts both the lever and the stop while the brake handle is in a park lock position.

The invention relates to an activation device (1) for a parking brake with a parking brake lever (2) swivel-mounted on a bearing block (3) and with a blocking device comprised of a pawl (13) on the parking brake lever (2) and a locking segment (12) on the bearing block (3). The parking brake lever (2) is fixed in place in a swivel position via the engagement of the pawl (13) with the locking segment (12). The swivel position of the parking brake lever (2) is transmitted via a transmission element to the parking brake and with a transfer device in or on the parking brake lever (2). The engagement of the pawl (13) with the locking segment (12) is released by actuating the transfer device. To form a swivel bearing, a shaft is provided to which a holder (7) for the transmission element and the parking brake lever (2) can be affixed in different rotational positions. As an alternative, or in addition, a linear movement of the pawl (13) is brought about by means of the transfer device.

A handbrake operating linkage for a railroad tank car, in which a hand wheel used to provide tension in the linkage is located on a lateral side of the car body, near an end of the car and at a height permitting a person standing on the ground alongside the tank car to set the handbrake. The hand wheel is located on the car at an end of the car opposite the end at which an airbrake cylinder-and-piston assembly is located, and the linkage extends from an airbrake cylinder lever to the hand wheel by way of a direction-reversing lever and a bell crank, avoiding a requirement for parts of the linkage to pass through direction-changing sheave wheels.

A handbrake operating linkage for a railroad tank car, in which a hand wheel used to provide tension in the linkage is located on a lateral side of the car body, near an end of the car and at a height permitting a person standing on the ground alongside the tank car to set the handbrake. The hand wheel is located on the car at an end of the car opposite the end at which an airbrake cylinder-and-piston assembly is located, and the linkage extends from an airbrake cylinder lever to the hand wheel by way of a direction-reversing lever and a bell crank, avoiding a requirement for parts of the linkage to pass through direction-changing sheave wheels.

A cable assembly is provided for use with Bowden cables that combines a splitter and compensator. The cable assembly includes a hollow housing having a longitudinal axis, a first end defining a first aperture for receiving the wire of an input cable, and a second end defining a second aperture for receiving the wires of the output cables. A slider is provided within the housing for joining the wires of the input and output cables. The slider is configured for movement within the housing and along the axis. A conduit cap fixes the conduits of the output cables to one another. The conduit cap is configured for movement within the housing. A compression spring is configured to bias the conduit cap away from the first end of the housing.

A vehicle braking system includes a piston rod extendable from an air brake chamber, a rotatable cam shaft, and a slack adjuster coupled to the piston rod and the cam shaft. The slack adjuster is configured to rotate the cam shaft as the piston rod extends. The slack adjuster has a control gear coupled to the cam shaft such that the control gear rotates as the cam shaft is rotated. A pinion gear meshes with the control gear such that the pinion gear rotates as the control gear rotates, and a take-off gear meshes with the pinion gear such that the take-off gear rotates as the control gear rotates. A magnet coupled to the take-off gear is configured to rotate as the take-off gear rotates. A sensor is configured to sense rotation of the magnet, and an indicator is configured to indicate brake stroke of the piston rod.

Systems and methods for brake cable adjustment are disclosed herein. In this regard, a gage block tool for adjusting a brake cable may comprise a body comprising, a first member extending in a first direction, the first member having a first length and a first thickness, and a second member extending in a second direction, the second member having a second length and a second thickness. At least one of the first member or the second member may be sized and configured to be placed between a stop and a lever of a brake valve, the brake cable connected between the lever and a brake handle being properly adjusted when the gage block sandwiched between the lever and the stop contacts both the lever and the stop while the brake handle is in a park lock position.

A braking system for a rollator with a frame includes an adjustable handle to be installed on a right subframe or a left subframe of the frame of the rollator, a bracket fixedly connected to the handle, a lever rotatably connected to the bracket, a lock movably connected to the bracket and configured to fix the lever in a locked position when the lock is moved relative to the bracket once the lever is rotated toward the frame, and a wire operably connected between the lever and a brake on the frame of the rollator, such that the wire applies the brake when the lever is rotated toward the bracket and when the lever is fixed in the locked position.

A rollator braking system for a rollator includes two handles, two brake lever assemblies, and two wires. The rollator includes a frame and a plurality of wheels attached to the frame for moving the rollator. The two handles are adjustably connected to the frame, and each handle including a gripping member. Each of the two brake lever assemblies include a bracket fixedly connected to the handle and a lever rotatably connected to the bracket to rotate towards and away from the gripping member when in an unlocked position, and fixedly connected to the bracket when in a locked position. Each of the two wires are operably connected between a lever assembly and a brake on one of the wheels such that when the lever is rotated towards the gripping member, the brake slows rotation of the wheel, and when the lever is in the locked position the brake stops the rotation of the wheel.

In order to improve a master unit for vehicles, in particular for vehicles steered by a handlebar, comprising a housing, a master cylinder unit provided in the housing, an actuation unit for manually actuating the master cylinder unit with a push lever pivotable relative to the housing about a push lever pivot axis and with a push element transmitting a movement of the push lever to the master cylinder unit, which push element is provided on the push lever and, when the actuation unit is manually actuated, acts, via a pressure surface at a contact point, on a contact surface of the master cylinder unit, such that an optimal adaptation to the particular circumstances is possible, it is proposed that, in order to adjust a transmission ratio of the actuation unit with which the actuation unit acts on the master cylinder unit, a lever arm effective in the event of the actuation is adjustable between the contact point and the push lever pivot axis by means of an adjustment device.