Patent application number | Description | Published |
20120289371 | Hybrid Tape for Robotic Transmission - The hybrid tape includes an outer member that is formed with a material having desirable tensile qualities, such that the outer member is tailored to exhibit superior fatigue performance in tension induced from bending. The hybrid tape further includes an inner member that is formed with a material having desirable compression qualities, such that the inner member is tailored to exhibit superior fatigue performance in compression induced from bending. The hybrid tape is configured such that the bend neutral axis is located between the inner material and the outer material, thereby insuring the outer material only experiences tension in bending while the inner material only experiences compression in bending. | 11-15-2012 |
20120305698 | Method and Apparatus for Actively Manipulating Aerodynamic Surfaces - A method and apparatus is provided, including an actuator system that may be connected to a wing frame for controlling an active element. The actuator system may include sliding elements movable along an axis parallel to the span-wise axis of the wing. The sliding elements may be connected to fixed elements and a crank element, the crank element generally comprising a beam element and a cross-axis flexure pivot element. The beam element may be offset from the pivot element so that the crank element is rotatable about the pivot element with a negative stiffness under an external force that tends to pull the sliding elements away from the fixed elements. | 12-06-2012 |
20130058793 | System for Heat Dissipation from an Internal Actuator in a Rotor Blade - A rotor blade for an aircraft includes an airfoil skin, an active element, and an actuator configured to operate the active element. A heat pipe is configured to promote heat transfer from the actuator to the airfoil skin. The heat pipe has a slope gradient such that a centrifugal force generated during rotation of the rotor blade promotes travel of a condensed working fluid within the heat pipe to move from a condenser end of the heat pipe toward an evaporator end of the heat pipe. | 03-07-2013 |
20130082136 | METHOD AND APPARATUS FOR ACTIVELY MANIPULATING AERODYNAMIC SURFACES - A method and apparatus is provided, including an actuator system that may be connected to a wing frame for controlling an active element. The actuator system may include sliding elements movable along an axis parallel to the span-wise axis of the wing. The sliding elements may be connected to fixed elements and a crank element, the crank element generally comprising a beam element and a pivot element. The beam element may be offset from the pivot element so that the crank element is rotatable about the pivot element with a negative stiffness under an external force that tends to pull the sliding elements away from the fixed elements. | 04-04-2013 |
20130216399 | ELASTOMERIC SIGNAL TRANSMISSION AND MOTION AMPLIFICATION - A system and method to amplify displacement includes a housing forming a cylindrical chamber having an elastomeric material disposed therein. The chamber being sealed with a first membrane and a second membrane. The first membrane being attached to a first end having and the second membrane being attached to a second end, the first end having a greater diameter than the second end. The method including producing an input displacement with a driver attached to the first membrane, which in turn results in an amplified output displacement at the second end. | 08-22-2013 |
20140060249 | ACTUATION SYSTEM FOR AN ACTIVE ELEMENT IN A ROTOR BLADE - In accordance with one embodiment of the present application, an actuation system is configured for actuation of an airfoil member with a flap mechanism. The actuation system can include an upper drive tape and a lower drive tape, each partially wrapped around a first bearing and second bearing. An inboard frame can be actuated by at least one linear actuator. Similarly, an outboard frame can be actuated by at least one linear actuator. The inboard frame is coupled to the upper drive tape, while the outboard frame is coupled to the lower drive tape. An actuation of the inboard frame and outboard frame in a reciprocal manner acts move a flap input lever reciprocally upward and downward. A flap mechanism is configured to convert the movement of the flap input lever into rotational movements of the airfoil member. | 03-06-2014 |
20140064960 | ACTUATION SYSTEM FOR AN ACTIVE ELEMENT IN A ROTOR BLADE - In accordance with one embodiment of the present application, an actuation system is configured for actuation of an airfoil member with a flap mechanism. The actuation system can include an upper drive tape and a lower drive tape, each partially wrapped around a first bearing and second bearing. An inboard frame can be actuated by at least one linear actuator. Similarly, an outboard frame can be actuated by at least one linear actuator. The inboard frame is coupled to the upper drive tape, while the outboard frame is coupled to the lower drive tape. An actuation of the inboard frame and outboard frame in a reciprocal manner acts move a flap input lever reciprocally upward and downward. A flap mechanism is configured to convert the movement of the flap input lever into rotational movements of the airfoil member. | 03-06-2014 |
20140064965 | ACTUATION SYSTEM FOR AN ACTIVE ELEMENT IN A ROTOR BLADE - In accordance with one embodiment of the present application, an actuation system is configured for actuation of an airfoil member with a flap mechanism. The actuation system can include an upper drive tape and a lower drive tape, each partially wrapped around a first bearing and second bearing. An inboard frame can be actuated by at least one linear actuator. Similarly, an outboard frame can be actuated by at least one linear actuator. The inboard frame is coupled to the upper drive tape, while the outboard frame is coupled to the lower drive tape. An actuation of the inboard frame and outboard frame in a reciprocal manner acts move a flap input lever reciprocally upward and downward. A flap mechanism is configured to convert the movement of the flap input lever into rotational movements of the airfoil member. | 03-06-2014 |
20150069175 | Rotor Position Determination System with Magneto-Resistive Sensors - According to one embodiment, a method for determining a position of a rotor blade includes receiving a plurality of measurements from a plurality of magneto-resistive sensors and determining a position of the at least one magnet based on the received plurality of measurements. In this example, one of the plurality of magneto-resistive sensors and the at least one magnet moves with a rotor blade. | 03-12-2015 |