Abstract: Methods and apparatus for controlling landing gear retract braking are described. A controller is to determine an on-ground status of a wheel of a landing gear. The controller is to generate a control signal based on the on-ground status of the wheel. The control signal is to initiate a retract braking process for the wheel. The retract braking process is to decelerate the wheel from a first rate of rotation to a second rate of rotation less than the first rate of rotation.

Abstract: Methods and apparatus for controlling landing gear retract braking are described. A controller determines wheel speed data corresponding to a speed of a wheel of a landing gear. The controller determines wheel deceleration data corresponding to a rate of change of the wheel speed data. The controller generates a first control signal in response to the wheel deceleration data being greater than a wheel deceleration threshold. The first control signal initiates a wheel deceleration regulation process, the wheel deceleration regulation process to cycle an antiskid valve between a first valve position to release brake pressure from the wheel and a second valve position to cease releasing the brake pressure from the wheel. The controller generates a second control signal in response to the wheel speed data being less than a wheel speed threshold. The second control signal terminates the wheel deceleration regulation process.

Abstract: Hydraulic systems for shrinking landing gear shrink are described. An example apparatus includes a landing gear strut, a transfer cylinder, and aircraft hydraulics. The landing gear strut has an outer cylinder and an inner cylinder. The inner cylinder moves relative to the outer cylinder from a first position to a second position as the landing gear strut moves from a deployed position to a retracted position. The landing gear strut has a first length when the inner cylinder is in the first position and a second length less than the first length when the inner cylinder is in the second position. The transfer cylinder exchanges hydraulic fluid and gas with the landing gear strut as the landing gear strut moves from the deployed position to the retracted position. The aircraft hydraulics hydraulically actuate the landing gear strut to move from the deployed position to the retracted position.

Abstract: Hydraulic systems for shrinking landing gear shrink are described. An example apparatus includes a landing gear strut, a transfer cylinder, aircraft hydraulics, a pressure vessel, and a pressure-operated check valve. The landing gear strut has an outer cylinder and an inner cylinder movable relative to the outer cylinder between a first position and a second position. The landing gear strut has a first length when the inner cylinder is in the first position and a second length less than the first length when the inner cylinder is in the second position. The transfer cylinder exchanges hydraulic fluid with the landing gear strut. The aircraft hydraulics exchange hydraulic fluid with the transfer cylinder. The pressure vessel exchanges gas with the landing gear strut. The pressure-operated check valve controls an exchange of gas between the pressure vessel and the landing gear strut based on hydraulic fluid received from the aircraft hydraulics.

Abstract: Methods and apparatus for controlling landing gear retract braking are described. A controller is to determine an on-ground status of a wheel of a landing gear. The controller is to generate a control signal based on the on-ground status of the wheel. The control signal is to initiate a retract braking process for the wheel. The retract braking process is to decelerate the wheel from a first rate of rotation to a second rate of rotation less than the first rate of rotation.

Abstract: Methods and apparatus for controlling landing gear retract braking are described. A controller determines wheel speed data corresponding to a speed of a wheel of a landing gear. The controller determines wheel deceleration data corresponding to a rate of change of the wheel speed data. The controller generates a first control signal in response to the wheel deceleration data being greater than a wheel deceleration threshold. The first control signal initiates a wheel deceleration regulation process, the wheel deceleration regulation process to cycle an antiskid valve between a first valve position to release brake pressure from the wheel and a second valve position to cease releasing the brake pressure from the wheel. The controller generates a second control signal in response to the wheel speed data being less than a wheel speed threshold. The second control signal terminates the wheel deceleration regulation process.

Abstract: Hydraulic systems for shrinking landing gear shrink are described. An example apparatus includes a landing gear strut, a transfer cylinder, and aircraft hydraulics. The landing gear strut has an outer cylinder and an inner cylinder. The inner cylinder moves relative to the outer cylinder from a first position to a second position as the landing gear strut moves from a deployed position to a retracted position. The landing gear strut has a first length when the inner cylinder is in the first position and a second length less than the first length when the inner cylinder is in the second position. The transfer cylinder exchanges hydraulic fluid and gas with the landing gear strut as the landing gear strut moves from the deployed position to the retracted position. The aircraft hydraulics hydraulically actuate the landing gear strut to move from the deployed position to the retracted position.

Abstract: Hydraulic systems for shrinking landing gear shrink are described. An example apparatus includes a landing gear strut, a transfer cylinder, aircraft hydraulics, a pressure vessel, and a pressure-operated check valve. The landing gear strut has an outer cylinder and an inner cylinder movable relative to the outer cylinder between a first position and a second position. The landing gear strut has a first length when the inner cylinder is in the first position and a second length less than the first length when the inner cylinder is in the second position. The transfer cylinder exchanges hydraulic fluid with the landing gear strut. The aircraft hydraulics exchange hydraulic fluid with the transfer cylinder. The pressure vessel exchanges gas with the landing gear strut. The pressure-operated check valve controls an exchange of gas between the pressure vessel and the landing gear strut based on hydraulic fluid received from the aircraft hydraulics.

Abstract: Methods and apparatus for controlling landing gear shrink are described. A controller is to determine an on-ground status of a left main landing gear. The controller is also to determine an on-ground status of a right main landing gear. The controller is also to generate a control signal to shrink the left main landing gear and the right main landing gear based on the on-ground status of the left main landing gear and the on-ground status of the right main landing gear.

Abstract: Methods and apparatus for controlling landing gear shrink are described. A controller is to determine an on-ground status of a left main landing gear. The controller is also to determine an on-ground status of a right main landing gear. The controller is also to generate a control signal to shrink the left main landing gear and the right main landing gear based on the on-ground status of the left main landing gear and the on-ground status of the right main landing gear.

Abstract: An electrical interlock and indication system for use with an aircraft having a hinged tail section is provided. The interlock and indication system prevents operation of a latch/lock actuation system of the hinged tail section unless a tail support is engaged to the tail section, inhibits over rotation of the hinged tail section, and detects retraction failures of latch pins located in the hinged tail section.

Abstract: The invention is directed to an actuation system in an aircraft comprising a fuselage and a hinged tail section with at least one interlock component that engages a tail support, wherein the engagement of the tail support to the tail section enables the actuation system to operate. The actuation system pulls in, latches, and locks the tail section during closing of the tail section, and the actuation system unlocks, unlatches, and releases the tail section during opening of the tail section.

Abstract: An electrical interlock and indication system for use with an aircraft having a hinged tail section is provided. The interlock and indication system prevents operation of a latch/lock actuation system of the hinged tail section unless a tail support is engaged to the tail section, inhibits over rotation of the hinged tail section, and detects retraction failures of latch pins located in the hinged tail section.

Abstract: The invention is directed to an actuation system in an aircraft comprising a fuselage and a hinged tail section with at least one interlock component that engages a tail support, wherein the engagement of the tail support to the tail section enables the actuation system to operate. The actuation system pulls in, latches, and locks the tail section during closing of the tail section, and the actuation system unlocks, unlatches, and releases the tail section during opening of the tail section.

Abstract: A brake system for use on a mobile platform such as a commercial aircraft. The brake system includes an electromechanical actuator (EMA) subsystem and a piezoelectric actuator subsystem. The EMA subsystem is used to urge a brake piston into contact with a pressure plate, and the pressure plate into contact with a brake rotor. The piezoelectric actuator subsystem is then used as a high frequency means to more effectively modulate the pressure plate into contact with the brake rotor to effect a braking action on the brake rotor. The invention allows smaller, less complex DC motors to be employed, that in turn results in significantly smaller wire bundles being needed on each wheel assembly of an aircraft where the invention is employed. The invention even more effectively modulates the pressure plate to better apply anti-skid braking signals to the brake rotor.

Abstract: A warning indication system and method of using the same in conjunction with a cargo door of an aircraft. The cargo door is positionable in an opened position; a closed position; a closed and latched position; and a closed, latched, and locked position. The method includes outputting first and second closed signals when the cargo door is in the closed position; outputting first and second latched signals when the cargo door is in the closed and latched position; and outputting first and second locked signals when the cargo door is in the closed, latched, and locked position. All of the signals are then analyzed to positively determine the position of the cargo door, while minimizing the probability of false indications. Various warnings are generated in response to the combination of signals received. The apparatus employs a dual logic system and redundant sensors to provide differing warnings dependent on the phase of flight.

Abstract: A warning indication system and method of using the same in conjunction with a cargo door of an aircraft. The cargo door is positionable in an opened position; a closed position; a closed and latched position; and a closed, latched, and locked position. The method includes outputting first and second closed signals when the cargo door is in the closed position; outputting first and second latched signals when the cargo door is in the closed and latched position; and outputting first and second locked signals when the cargo door is in the closed, latched, and locked position. All of the signals are then analyzed to positively determine the position of the cargo door, while minimizing the probability of false indications. Various warnings are generated in response to the combination of signals received. The apparatus employs a dual logic system and redundant sensors to provide differing warnings dependent on the phase of flight.

Abstract: A door actuation system for an outwardly opening aircraft door for use in an aircraft having a door opening, a cam post, and a plurality of latch pins. The door actuation system includes a locking mechanism operably coupled to the door, wherein the locking mechanism is positionable in a locked position preventing the door from being opened and an unlocked position. The system further includes a pull-in mechanism that is hydraulically actuated and includes a cam slot member capable of operably engaging the cam post of the aircraft. The pull-in mechanism is positionable in an uncammed position and a cammed position. A latching mechanism is also provided that is hydraulically actuated and includes a plurality of cam latches each capable of operably receiving one of the plurality of latch pins. The latching mechanism is positionable in a latched position and an unlatched position.

Abstract: A latch lock mechanism (20) for opening and closing a translating motion-type aircraft door (22). The latch lock mechanism (20) of this invention includes a latch shaft (38) that is mounted to the door (22) by a set of follower bearings (98) that are axially offset from the shaft. The shaft (38) is rotated by a lift lock mechanism (44) that includes a lift lock cam (106) and a cam follower (108) that tracks the cam, and a door drive linkage (1 10) that is attached to the cam follower for rotating the latch shaft. The lift lock cam (106) is rotated by a handle shaft (42) that is actuated by a handle (40). When the handle (40) is rotated, the lift lock cam (106) is similarly rotated so as to cause the upward movement of the door drive linkage (110) in the rotation of the latch shaft (38).

Abstract: A brake wear limit indicator which is matched to the brake energy capacity of the overhauled brake. A wear limit bushing is attached to the brake piston housing. The bushing length is chosen based on the brake energy capacity of the brake and is marked with a related part number. A wear pin is attached to the brake pressure plate and extends through a hole in the bushing. Brake overhaul is required when the brake wears such that the pin no longer protrudes from the bushing.