A brake wear monitoring system for measuring extended wear lengths includes a processing unit, a plurality of linear Hall sensors in electronic communication with the processing unit, a wear pin coupled to a brake stack, the wear pin comprising a magnetic portion, wherein the plurality of linear Hall sensors are configured to detect a position of the wear pin via the magnetic portion, and the processing unit is configured to generate an output signal, based upon the position of the wear pin relative to the plurality of linear Hall sensors, to indicate a wear status of the brake stack.

An object of the present invention is to appropriately control a clearance amount by correcting an estimation error of a contact position caused by a delay time difference between output signals of sensors, and to establish both improvement of fuel efficiency due to prevention of drag of a brake pad during non-braking and reduction in response time during braking.

A brake system includes a brake disc, a brake pad, a piston, a drive mechanism, a position sensor that detects a position of the piston, a thrust sensor that detects a thrust by which the brake pad presses the brake disc, and a brake control unit that adjusts a braking force by controlling the drive mechanism. The brake control unit includes a contact position computation unit that computes a contact position at which the brake pad and the brake disc come in contact with each other based on output signals of the position sensor and the thrust sensor, a position error computation unit that computes a position error of the contact position based on a delay time difference between the output signals of the position sensor and the thrust sensor, and a contact position correction unit that corrects the contact position obtained by the contact position computation unit by using the position error.

A first object and a second object are movable in relation to one another. The first object includes a transponder using an integrated circuit having two terminals which may or may not be shorted. The presence or absence of a short circuit between the two terminals is detected. This is accomplished at least partly by the second object depending on the relative positioning of the first and second objects. The transponder transmits, to a module having a contactless reader function, positioning information corresponding to said relative positioning using a contactless communication protocol.

A system for monitoring engagement and wear in a brake include: a pin, a first marker positioned on the pin at a first location; a second marker spaced from the first marker long the pin; and a first fixed sensing arrangement. The pin extends in an axial direction parallel to the axis of rotation, and is in contact with and moves with the moveable brake pad in use. The first fixed sensing arrangement is adapted to provide a first signal when adjacent the first or second marker, and a second signal otherwise. The first and second markers and the first fixed sensing arrangement are positioned such that the second signal indicates that the brake is in the engaged position, and a change from the second signal to the first signal indicates that the moveable brake pad and the second brake pad have been worn down by a predetermined amount.

In some examples, a device configured to determine an estimated remaining use of a brake assembly includes a magnet configured to move in response to movement of a wear pin indicator of the brake assembly, a sensor configured to generate an output signal based on a position of the magnet relative to the sensor, and processing circuitry configured to determine the estimated remaining use of the brake assembly based on the output signal generated by the sensor.

Disclosed herein is an electronic parking brake system and a control method thereof. The electronic parking brake system includes a pair of brake pads arranged on opposite sides of a brake disc, a piston configured to press at least one of the brake pads, a nut member configured to press the piston, a spindle member configured to move the nut member, an electric motor configured to rotate the spindle member, and a controller configured to estimate a wear amount of the brake pads based on change in a movement distance of the nut member.

Systems and methods for measuring the wear of carbon brakes of an aircraft are disclosed herein. The systems and methods include a 3-axis acceleration sensor module mounted on a brake assembly, the 3-axis acceleration sensor module configured to detect acceleration events of the brake assembly in three different component directions. The systems and methods further include a memory module operably connected to the 3-axis acceleration sensor module, the memory module configured to store acceleration events detected by the 3-axis acceleration sensor module and to store a pre-determined threshold for determining carbon brake wear based upon a number of acceleration events detected in a single component direction of the three different component directions. The systems and methods also include a processor module operably connected the processor module configured to compare the stored acceleration events detected in a single direction of the three different directions to the stored pre-determined threshold.

A brake device (102), in particular a utility vehicle disc brake, has a brake disc (106), at least one brake pad (104, 104), a transmission member (114) coupled to the brake pad (104, 104) for pressing the brake pad (104, 104) against the brake disc (106), a drive for generating a drive variable, a non-linear mechanism (110) operatively connected to the drive and the transmission member (114) for transmission of the drive variable to the transmission member (114), and an adjusting unit (120) for adjusting a clearance (108) between the transmission member (114) and the brake disc (106). The device includes a brake pad wear sensor for detecting the degree of wear of the brake pad (104, 104) and a control unit, with a signal-carrying connection to the sensor to vary the clearance (108) as a function of the wear of the brake pad (104, 104) determined by the sensor.

A brake pad wear measuring system for measuring brake pad wear for a vehicle disc brake system includes a first coil having a first coil face and is excitable to create a first magnetic field. A first target is spaced a fixed distance from the first coil face. The first coil and the first target are configured for movement relative to each other in response to application of the disc brake system so that the first target covers a portion of the first coil that varies with the amount of brake pad wear and varies the inductance of the first coil. The inductance of the first coil is indicative of the amount of brake pad wear. The brake pad wear measuring system also includes a second coil having a second coil face and is excitable to create a second magnetic field. A second target is configured to move toward the second coil face in response to application of the disc brake system so that the distance between the second target and the second coil face varies with the amount of brake pad wear and varies the inductance of the second coil. The inductance of the second coil is indicative of the amount of brake pad wear.

Disclosed herein is an electronic parking brake system and a control method thereof. The electronic parking brake system includes a pair of brake pads arranged on opposite sides of a brake disc, a piston configured to press at least one of the brake pads, a nut member configured to press the piston, a spindle member configured to move the nut member, an electric motor configured to rotate the spindle member, and a controller configured to estimate a wear amount of the brake pads based on change in a movement distance of the nut member.