A control surface actuation system has the ability to move aerodynamic control surfaces using a rotational motion of a motor. In an arrangement, rotational motion of the motor enables the aerodynamic control surfaces of a rotating projectile to oscillate and thus vary the angle of the control surfac
A control surface actuation system has the ability to move aerodynamic control surfaces using a rotational motion of a motor. In an arrangement, rotational motion of the motor enables the aerodynamic control surfaces of a rotating projectile to oscillate and thus vary the angle of the control surfaces as the projectile spins. The rotation of a motor in one direction in combination with a gear and a link and a crank arm attached to a shaft of the aerodynamic control surfaces allows the control surfaces to move in fluttering motion to induce the maneuvering of a projectile in the desired direction. A controller takes information regarding the current condition of the projectile and drives the motor to move the aerodynamic devices to maneuver the projectile.
대표청구항▼
What is claimed is: 1. A projectile comprising: a body configured to spin about a projectile longitudinal axis during flight along a flight path; an aerodynamic device coupled to a shaft carried by the body; a crank coupled to the shaft, a general back and forth motion of the crank causing an oscil
What is claimed is: 1. A projectile comprising: a body configured to spin about a projectile longitudinal axis during flight along a flight path; an aerodynamic device coupled to a shaft carried by the body; a crank coupled to the shaft, a general back and forth motion of the crank causing an oscillating motion of the shaft and the aerodynamic device; a motor; a drive arrangement interposed between the crank and the motor for translating unidirectional rotational motion of the motor into generally limited oscillating, back-and-forth motion of the crank and of the aerodynamic device relative to the body of the projectile; and a controller for controlling the velocity and phase of the unidirectional rotational motion of the motor to create the oscillating, back-and-forth motion of the crank and aerodynamic device in synchronism with the spinning of the body to control the flight path of the projectile. 2. A projectile of claim 1 wherein the controller receives inputs related to control activation; spin velocity (ω) of the projectile; spin coordination angle (θ) of the projectile; a commanded phase angle (θ) of the aerodynamic device defining a commanded direction of veer of the projectile; position of the aerodynamic device; and velocity of the aerodynamic device; and wherein the controller implements feed forward of a signal corresponding to the spin velocity (ω) of the projectile; and wherein the controller outputs a drive signal to vary the position and velocity of the motor to adjust a phase position of the aerodynamic device in the oscillating, back-and-forth motion to equal the commanded phase angle. 3. A projectile of claim 1 wherein the motor carries a pinion and the drive arrangement comprises: a link having one end coupled to the crank; and a gear coupled to the pinion and carrying the other end of the link, unidirectional rotation of the gear inducing limited, back-and-forth angular motion of the crank in relation to the rotation of the motor. 4. A projectile of claim 1 wherein the motor carries a pinion and the drive arrangement comprises: a link having one end coupled to the crank; and a gear train having a plurality of gears, the gear train coupled to the pinion and having a gear train output carrying the other end of the link, unidirectional rotation of the gears of the gear train inducing limited, back-and-forth angular motion of the crank in relation to the rotation of the motor. 5. A projectile of claim 4 wherein the motor, the gear train, and the pinion are matched to move the link at a rate of over 10 strokes per minute. 6. A projectile of claim 5 wherein the motor, the gear train, and the pinion are matched to move the link at a rate of between 100 strokes to 16,000 strokes per minute. 7. A projectile of claim 1 wherein the motor carries a pinion and the drive arrangement comprises: a link having one end coupled to the crank; a gear coupled to the pinion; a pair of stop pins carried by the gear; an arm having a pair of ends, one end pivotally carried by the gear, the other end pivotally coupled to the other end of the link, wherein the rotation of the gear in one direction moves the link into engagement with one of the stop pins and establishes a first specific amplitude of the oscillating, back-and-forth motion of the aerodynamic device, and the rotation of the gear in the other direction moves the arm into engagement with the other stop pin and establishes another specific amplitude of the oscillating, back-and-forth motion of the aerodynamic device. 8. A projectile of claim 1 further wherein the motor carries a pinion and the drive arrangement comprises: a link having one end coupled to the crank; a gear coupled to the pinion; the crank coupled to the shaft having a slot for receiving the one end of the link; an adjustment device for positioning the other end of the link in a specific position within the slot to adjust the amplitude of the motion of the crank in relation to the rotation of the motor relative to the body of the projectile. 9. A projectile of claim 1 wherein the aerodynamic device comprises a pair of fins for interacting with the air through which the projectile rotates. 10. A projectile of claim 1 wherein the aerodynamic device comprises a pair of valves and a cavity interposed between the valves for directing a flow of air through the projectile from one valve to the other valve therein redistributing the pressures acting on the projectile, the valve surfaces protruding into the air stream creating lift and drag, and also changing a boundary layer of the projectile and thus altering the flight path of the projectile. 11. A projectile of claim 1, wherein the projectile is from the group of an artillery shell, bomb, and missile and the projectile has significant spin rate about the projectile's longitudinal axis. 12. A projectile of claim 1, wherein the shaft is a first one of a pair of nested shafts, the first nested shaft being an inner shaft and a second nested shaft being an outer shaft having a hollow cavity, the inner shaft laying in the hollow cavity of the outer shaft, and wherein the aerodynamic device is a first of a pair of aerodynamic devices each mounted to a respective one of the shafts about a common axis and each being actuated independently. 13. A control surface actuation system comprising: a control surface, the control surface having a pivot and rotatably carried by a body; a crank coupled to the control surface, an angular motion of the crank causing a rotational motion of the control surface about the pivot; a motor; and a drive arrangement interposed between the crank and the motor for translating rotational motion of the motor into generally angular motion of the crank, the drive arrangement including an arm having a first end coupled to the motor and an elongated link coupled between a second end of the arm and the crank, wherein the rotational motion of the motor is translated into a rotational motion of the control surface about the pivot via longitudinal motion of the link. 14. A control surface actuation system of claim 13 wherein an electronic controller operates the system as a servo actuator. 15. A control surface actuation system of claim 13 wherein the drive arrangement further includes at least one gear interposed between the motor and the link for translating high speed low torque motion into lower speed higher torque motion. 16. A control surface actuation system of claim 13 wherein the motor has a longitudinal axis that is parallel with a pivot axis of the control surface. 17. A control surface actuation system of claim 13 wherein the drive arrangement further includes: a gear box having at least one gear coupled to the motor; and wherein the arm extends from the gear box to the link. 18. A control surface actuation system of claim 17 wherein the link is coupled to at least one of the arm and the crank by a respective joint having three degrees of freedom. 19. A control surface actuation system of claim 18 wherein the joint is a ball joint. 20. A control surface actuation system of claim 13 wherein the control surface is a single aerodynamic surface. 21. A control surface actuation system of claim 13 wherein the control surface is one of a plurality of aerodynamic surfaces wherein each of the aerodynamic surfaces has an associated drive arrangement. 22. A control surface actuation system of claim 13 wherein the aerodynamic surface is an air brake or a spoiler panel. 23. A method of controlling a projectile comprising the steps of: providing the projectile with a pair of aerodynamic surfaces; rotating the projectile about a projectile longitudinal axis during flight along a flight path; moving the pair of aerodynamic surfaces in an oscillating, back-and-forth motion in synchronism with the rotation of the projectile during the flight of the projectile to control the flight path of the projectile. 24. A method of controlling a projectile of claim 23 comprising the steps of: firing the projectile from a gun; creating a rotation of the projectile along a longitudinal axis of the projectile due to the rifling of the barrel of the gun; driving a shaft of a motor in a unidirectional rotary motion at a controlled rate wherein the moving of the aerodynamic devices in the oscillating, back-and-forth motion is effected through a drive arrangement coupled between the aerodynamic surfaces and the rotating shaft of the motor.
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