| Patent application number | Description | Published |
|---|
| 20150021431 | METHOD FOR ACCELERATED POWERED SELF PUSH BACK OF AN AIRCRAFT - A method for accelerated power push back of an aircraft equipped with a pilot-controlled engines-off taxi system that drives the aircraft without reliance on the aircraft's main engines or tugs is provided. An aircraft is quickly and efficiently moved out of a gate where it is positioned in a nose-in orientation. The pilot controls the taxi system to drive the aircraft in reverse along a perpendicular path away from the terminal to a location where there is sufficient space for the aircraft to stop and turn, and the aircraft is turned and driven in a forward direction to a takeoff runway. Pilot reliance on ground personnel guidance during push back maneuvers is minimized by providing a monitoring system designed to monitor gate and ramp areas around the aircraft in any visibility or environmental conditions and provide feedback to the pilot. | 01-22-2015 |
| 20150051757 | Method for Monitoring Autonomous Accelerated Aircraft Pushback - A method for monitoring an autonomous accelerated pushback process in an aircraft equipped with an engines-off taxi system is provided to maximize safety and facilitate the accelerated pushback process. The aircraft is equipped with a monitoring system including a number of different kinds of sensors and monitoring devices positioned to maximally monitor the aircraft's exterior ground environment and communicate the presence or absence of obstructions in the aircraft's path while the pilot is controlling the engines-off taxi system to drive the aircraft in reverse away from a terminal gate and then turn in place at a selected location before driving forward to a taxiway. The sensors and monitoring devices may be a combination of cameras, ultrasound, global positioning, radar, and LiDAR or LADAR devices, and proximity sensors located at varying heights adapted to continuously or intermittently scan or sweep the aircraft exterior and ground environment during aircraft ground movement. | 02-19-2015 |
| 20150076280 | SYSTEM AND METHOD FOR IMPROVING EFFICIENCY OF AIRCRAFT GATE SERVICES AND TURNAROUND - A system and method is provided for improving efficiency of aircraft gate services and reducing time spent by an aircraft parked parallel to an airport terminal wherein aircraft utilities and gate services provided during turnaround are supported by an arrangement of flexibly movable, service and utility-carrying extendable passenger boarding bridges that enable passenger and baggage exchange concurrently with connection of utilities and provision of gate services to the aircraft. Baggage transfer is facilitated by conveyors mounted on one or more loading bridges and designed to provide a direct connection between an aircraft and a terminal. Aircraft are maneuvered by a pilot into and out of a parallel parking location in a forward direction by an engines-off electric taxi system, enabling loading bridge, utility, and service connections to be made to multiple aircraft doors as soon as the aircraft reaches a parking location and then quickly disconnected upon departure. | 03-19-2015 |
| 20150129713 | STEERING CONTROL IN AN AIRCRAFT EQUIPPED WITH A WHEEL DRIVE SYSTEM - Control of aircraft steering during ground travel is provided in an aircraft equipped with an engines-off wheel drive system controllable to move the aircraft autonomously on the ground without reliance on the aircraft's main engines or external tow vehicles. The wheel drive system is designed to interact with the aircraft's nose wheel hydraulic steering system to augment or replace the hydraulic steering system with the operation of the wheel drive system at taxi speeds, particularly at very low taxi speeds and even when the aircraft is stopped, to steer the aircraft as it maneuvers through turns during ground travel between landing and takeoff and at other times. | 05-14-2015 |
| 20150151834 | AIRPORT TERMINAL AIRCRAFT GATE TRAFFIC MANAGEMENT SYSTEM AND METHOD - An airport terminal gate traffic management system is provided that maximizes efficiency and safety of passenger transfer and aircraft servicing and minimizes aircraft time parked at a terminal. Aircraft are driven forward into and out of gates by controllable landing gear wheel non-engine drive means and parked in a parallel or perpendicular orientation relative to the terminal that facilitates passenger transfer through a maximum number of aircraft doors. Passenger transfer and aircraft servicing may begin upon aircraft arrival using all available accessible aircraft doors. Departing aircraft may be turned by an unassisted pilot and driven forward with the controllable non-engine drive means to a takeoff runway. Airport terminal aircraft gate traffic is most effectively and efficiently managed when a significant number of aircraft using an airport are equipped with non-engine drive means controllable to move them into and out of a parking orientation optimal for passenger transfer. | 06-04-2015 |
| 20150151835 | Load Transfer in a Powered Aircraft Drive Wheel - An efficient system and method are provided wherein aircraft may be retrofitted with non-engine drive means controllable to power landing gear wheels to move the aircraft autonomously during ground movement without engines or tow vehicles so that existing landing gear structures are employed to achieve force distribution and load transfer. Non-engine drive means capable of powering a landing gear wheel to move the aircraft during taxi are integrated into existing landing gear designs so that excess drive forces are transferred and distributed through previously evaluated and certificated landing gear structures, including tow fittings, determined to be capable of handling such forces, which eliminates changes to the landing gear and facilitates retrofit and certification. Engines-off taxi technology can be rapidly designed and developed to be retrofitted on existing aircraft nose and/or main landing gear and then efficiently certificated. | 06-04-2015 |
| 20150158579 | METHOD FOR MAXIMIZING POWERED AIRCRAFT DRIVE WHEEL TRACTION - A method for maximizing traction in an aircraft drive wheel powered by non-engine drive means controllable to move the aircraft on the ground without reliance on the aircraft's brakes and dependence on friction defined by a mu-slip curve. The non-engine drive means is operated to control wheel speed and maintain the powered drive wheel in a maximized optimal traction condition when driving torques are applied to the drive wheel. Traction can be automatically maximized and maintained within an optimal range defined by a relationship between slippage and braking for maximum efficiency of aircraft ground travel under a wide variety of surface, weather, temperature, tire, and other conditions. | 06-11-2015 |
| 20150175256 | METHOD FOR ACCELERATED POWERED SELF PUSH BACK OF AN AIRCRAFT - A method for accelerated power push back of an aircraft equipped with a pilot-controlled engines-off taxi system that drives the aircraft without reliance on the aircraft's main engines or tugs is provided. An aircraft is quickly and efficiently moved out of a gate where it is positioned in a nose-in orientation. The pilot controls the taxi system to drive the aircraft in reverse along a perpendicular path away from the terminal to a location where there is sufficient space for the aircraft to stop and turn, and the aircraft is turned and driven in a forward direction to a takeoff runway. Pilot reliance on ground personnel guidance during push back maneuvers is minimized by providing a monitoring system designed to monitor gate and ramp areas around the aircraft in any visibility or environmental conditions and provide feedback to the pilot. | 06-25-2015 |
| 20150175271 | Method for Monitoring Autonomous Accelerated Aircraft Pushback - A method for monitoring an autonomous accelerated pushback process in an aircraft equipped with an engines-off taxi system is provided to maximize safety and facilitate the accelerated pushback process. The aircraft is equipped with a monitoring system including a number of different kinds of sensors and monitoring devices positioned to maximally monitor the aircraft's exterior ground environment and communicate the presence or absence of obstructions in the aircraft's path while the pilot is controlling the engines-off taxi system to drive the aircraft in reverse away from a terminal gate and then turn in place at a selected location before driving forward to a taxiway. The sensors and monitoring devices may be a combination of cameras, ultrasound, global positioning, radar, and LiDAR or LADAR devices, and proximity sensors located at varying heights adapted to continuously or intermittently scan or sweep the aircraft exterior and ground environment during aircraft ground movement. | 06-25-2015 |
| 20150175275 | SYSTEM AND METHOD FOR IMPROVING EFFICIENCY OF AIRCRAFT GATE SERVICES AND TURNAROUND - A system and method is provided for improving efficiency of aircraft gate services and reducing time spent by an aircraft parked parallel to an airport terminal wherein aircraft utilities and gate services provided during turnaround are supported by an arrangement of flexibly movable, service and utility-carrying extendable passenger boarding bridges that enable passenger and baggage exchange concurrently with connection of utilities and provision of gate services to the aircraft. Aircraft are maneuvered by a pilot into and out of a parallel parking location in a forward direction by an engines-off electric taxi system that does not rely on the use of aircraft main engines to drive the aircraft, enabling loading bridge, utility, and service connections to be made to multiple aircraft doors as soon as the aircraft arrives at a parking space and then quickly disconnected upon departure. | 06-25-2015 |
| 20150217861 | AIRCRAFT DRIVE WHEEL DRIVE SYSTEM WITH TORQUE COUPLING CLUTCH ASSEMBLY - An aircraft drive wheel drive system is provided with a torque coupling clutch assembly that transfers torque to a roller traction drive system actuating a non-engine drive means to drive an aircraft landing gear wheel and move the aircraft autonomously in a desired ground direction and at a desired ground speed. The wheel drive system and clutch assembly are mounted completely within the wheel where the clutch assembly is selectively engaged to control torque transmission to the drive system, which selectively transfers actuating torque to the non-engine drive means. A preferred selectable one way clutch is adapted to controllably transfer torque to the wheel drive system and has both failsafe overrunning and selective engagement capability in one or both rotational directions so that torque required to drive the aircraft wheel and move the aircraft at a desired ground speed and direction is transferred only when required by aircraft operating conditions. | 08-06-2015 |
| 20150217872 | METHOD FOR SLOT CREATION AT AN AIRPORT - A method is provided for creating additional takeoff and landing slots at airports that are constrained from operation by curfews that limit the hours when aircraft can operate. Aircraft may be moved on the ground to and from takeoff and landing runways without operation of the aircraft's engines entirely by tow vehicles, aircraft transfer apparatus, or non-engine drive means so that aircraft are ready to take off at the expiration of an airport's morning curfew. Aircraft may also land just prior to start of an airport's evening curfew and be moved to parking destinations entirely by tow vehicles, aircraft transfer apparatus, or non-engine drive means without operating engines. Airport capacity may be increased without requiring infrastructure expansion. | 08-06-2015 |
| 20150217873 | AIRPORT TERMINAL TRAFFIC AND PARKING MANAGEMENT SYSTEM - An airport terminal traffic and parking management system, which can be automated, is provided wherein one or more and preferably a plurality of the aircraft at an airport are moved on the ground between landing and takeoff without operation of aircraft engines or risks from jet blast and engine ingestion. Aircraft can be moved in a forward direction by tow vehicles, aircraft-moving transfer apparatus, or the like after landing to park in an efficient orientation relative to an airport terminal. Passengers deplaning and boarding and aircraft servicing can use all accessible aircraft doors to minimize time at a gate. Aircraft cleared for departure can be turned and moved in a forward direction to a takeoff runway, where the aircraft-moving apparatus is detached. Airport terminal aircraft traffic and parking are most effectively managed when a significant number of aircraft at an airport are moved by external vehicles as described. | 08-06-2015 |
| 20150221224 | PERMANENT WIRELESS COMMUNICATIONS SYSTEM FOR AN AIRCRAFT EQUIPPED WITH A WHEEL DRIVE SYSTEM - A permanent wireless onboard to ground operations communications system is provided for an aircraft equipped with a pilot-controllable drive wheel drive system for autonomous ground movement without reliance on the aircraft's engines or external tow vehicles, including an onboard wireless communications link installed to remain permanently with the aircraft designed to interface wirelessly with ground personnel at any airport, aerodrome, or airfield where the aircraft lands immediately upon landing. The permanent wireless onboard to ground operations communications system provides a substantially instantaneous connection between a pilot and ground personnel to facilitate guidance of pilot-controlled autonomous ground movement during taxi, parking in nose-in and parallel orientations, and pushback without reliance on visual signals. The present communications system establishes and maintains cockpit to ground communications during pilot-controlled autonomous aircraft ground movement to enhance the safety of ramp operations and improve the speed at which ramp operations can be safely conducted. | 08-06-2015 |
| 20150232202 | METHOD FOR MAINTAINING A SUPPLY OF AVAILABLE AIRCRAFT EQUIPPED WITH NON-ENGINE DRIVE MEANS FOR USE BY AIRLINES - A method for maintaining a supply of available aircraft equipped with non-engine drive means for autonomous ground movement is provided that enables an air carrier, particularly a low cost carrier, to operate reliably, efficiently, and economically to provide substantially uninterrupted air transport service. The present method is designed to enable airlines with fleets of older aircraft retrofitted with non-engine drive means for autonomous ground movement to operate economically and efficiently through a cooperative arrangement with a maintenance, repair, and overhaul provider that maintains and ensures an available supply network of spare and backup aircraft. The supply network may be global in geographic scope and may provide spare or backup aircraft equipped with non-engine drive means to one or more airlines. | 08-20-2015 |
| 20150251751 | SURFACE TRAVEL SYSTEM FOR MILITARY AIRCRAFT - A surface travel system for military aircraft is provided that enables efficient, quiet, and safe ground operations of one or more aircraft in a wide range of military missions and operations. The surface travel system includes controllable onboard drive means that effectively drives one or more of the aircraft's wheels to move the aircraft autonomously, efficiently, quietly, and safely on any travel surface required for a military mission. The present invention allows the rapid safe deployment of multiple aircraft from tight spaces and enhances the readiness and availability of aircraft for a wide range of military operations. | 09-10-2015 |
| 20150266565 | OPTIMIZING GROUND MOVEMENT IN A WIDE-BODY AIRCRAFT EQUIPPED WITH NON-ENGINE DRIVE MEANS - A system is provided for maximizing efficient ground travel in wide-body and other aircraft equipped with onboard non-engine drive means for autonomous ground travel. Selective operation of the non-engine drive means and selective operation of the aircraft's engines are integrated to power aircraft movement when different ground travel speeds are required between landing and takeoff, optimizing savings and maximizing the cost/benefit ratio for equipping the aircraft with a non-engine drive means. The non-engine drive means may be designed to move a wide-body aircraft at low speeds required for ground maneuvers in a ramp area to move the aircraft at speeds typically used for pushback, initial forward roll, all start-stop situations, and other low speed ground travel. One or more of the aircraft's engines may be operated to move the aircraft at higher taxi speeds. | 09-24-2015 |
| 20150274284 | SYSTEM AND METHOD FOR IMPROVING EFFICIENCY OF AIRCRAFT GATE SERVICES AND TURNAROUND - A system and method is provided for improving efficiency of aircraft gate services and reducing time spent by an aircraft parked parallel to an airport terminal wherein aircraft utilities and gate services provided during turnaround are supported by an arrangement of flexibly movable, service and utility-carrying extendable passenger boarding bridges that enable passenger and baggage exchange concurrently with connection of utilities and provision of gate services to the aircraft. Baggage transfer is facilitated by conveyors mounted on one or more loading bridges and designed to provide a direct connection between an aircraft and a terminal. Aircraft are maneuvered by a pilot into and out of a parallel parking location in a forward direction by an engines-off electric taxi system, enabling loading bridge, utility, and service connections to be made to multiple aircraft doors as soon as the aircraft reaches a parking location and then quickly disconnected upon departure. | 10-01-2015 |
| 20150298823 | AIRCRAFT PASSENGER BOARDING SYSTEM - An aircraft passenger boarding system is provided for aircraft equipped for pilot-controllable engines-off taxi that enables a pilot to drive the aircraft without engines in a forward direction into and out of an optimum parallel or angled gate parking orientation that permits terminal connections to both forward and aft doors on a terminal-facing side of the aircraft. Selected defined classes of passengers board the aircraft separately, through a designated loading bridge connected to a forward door or through a designated loading bridge connected to an aft door, to be seated in a designated front or rear aircraft section. An airline may flexibly allocate variably sized sections of the aircraft interior for each defined class, depending on the relative numbers of passengers in each class. Airport terminal interior gate space may be used to separate passenger classes as required for separate boarding through a forward door or an aft door. | 10-22-2015 |
| 20150329202 | CONTROL OF GROUND TRAVEL AND STEERING IN AN AIRCRAFT WITH POWERED MAIN GEAR DRIVE WHEELS - A controllable aircraft taxi system is provided that enables the simultaneous control of aircraft autonomous ground movement and direction of aircraft autonomous ground movement. Independently controlled non-engine drive means capable of driving an aircraft landing gear wheel to move an aircraft autonomously on the ground without reliance on the aircraft's main engines are mounted to provide driving torque to aircraft a selected number of main landing gear wheels. The aircraft nose landing gear steering system is provided with steering angle detection and measurement means adapted to communicate with main landing gear wheel non-engine drive means, enabling simultaneous control over both autonomous aircraft ground travel and direction of autonomous aircraft ground travel. The present invention overcomes steering challenges presented by using non-engine drive means on main landing gear wheels to drive aircraft autonomously during taxi. | 11-19-2015 |
| 20150353207 | Aircraft Gate Parking and Servicing Method - An improved aircraft gate parking and servicing method is provided, wherein an aircraft is maneuvered into an airport terminal gate and parked in an optimum orientation at an angle that facilitates maximum access to aircraft front and rear doors. Boarding bridges are designed to facilitate connection to doors located rear of an aircraft wing without extending over the aircraft wing to maximize efficiency of passenger transfer. Passenger transfer and servicing of the aircraft may occur concurrently before the aircraft is maneuvered out of its optimum orientation in the parking space and driven to a takeoff runway for departure. Required safety margins are maintained at all times during aircraft maneuvers into and out of the optimum parking orientation. Stairs may be provided to simultaneously access aircraft doors not connected to boarding bridges. In a preferred embodiment, aircraft are moved to an optimum parking location by engines-off electric taxi systems. | 12-10-2015 |
| 20160107539 | ELECTRIC VEHICLE TRACTION CONTROL SYSTEM AND METHOD - A traction control system and method are provided for electric vehicles with at least one drive wheel powered by an electric drive motor to maintain optimum maximum traction while the vehicle is driven on the ground. The traction control system includes drive means capable of transmitting torque through a vehicle drive wheel and controllable to move the vehicle over a ground surface. A preferred drive means is an electric motor designed to move the vehicle at desired ground speeds in response to operator input. Operator input requests a desired speed, and the system determines drive wheel torque required to produce the desired speed and provides maximum current to produce maximum torque to drive the vehicle with optimum traction at the desired speed. The system uses constant feedback to find maximum current corresponding to torque required for an inputted speed request to automatically control traction in any electric powered vehicle. | 04-21-2016 |
