Flyer assembly
First Claim
1. A flyer assembly adapted for launching with, transit in, and deployment from an artillery shell having a central void region extending along a ballistic shell axis, comprising:
- A) a jettisonable shroud extending along a shroud axis and positionable within said central void region with said shroud axis substantially parallel to said shell axis;
B) a flyer adapted when in a first state to withstand a launch acceleration force along a flyer axis and adapted when in a second state to effect aerodynamic flight, the flyer in said first state being positionable within said shroud with said flyer axis parallel to said shroud axis and said shell axis, the flyer including;
a) a body member disposed about said flyer axis; and
b) a foldable wing assembly mounted to the body member, the wing assembly being configurable in a folded state characterized by a plurality of nested wing segments when the flyer is in said first state;
the wing assembly being configurable in an unfolded state characterized by a substantially uninterrupted aerodynamic surface when the flyer is in said second state;
wherein the flyer is adapted for coupling to the shroud so as to maintain a portion of the flyer in tension during an acceleration of the flyer along the flyer axis resulting from the launch.
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Accused Products
Abstract
A flyer assembly is adapted for launching with, transit in, and deployment from an artillery shell having a central void region extending along a ballistic shell axis. The flyer assembly includes a jettisonable shroud and a flyer. The shroud extends along a shroud axis, and is positionable within the central void region with the shroud axis substantially parallel to the shell axis. The flyer is adapted to withstand a launch acceleration force along a flyer axis when in a first state, and to effect aerodynamic flight when in a second state. When in the first state, the flyer is positionable within the shroud with the flyer axis parallel to the shroud axis and the shell axis. The flyer includes a body member disposed about the flyer axis, and a foldable wing assembly mounted to the body member. The wing assembly is configurable in a folded state characterized by a plurality of nested wing segments when the flyer is in the first state. The wing assembly is configurable in an unfolded state characterized by a substantially uninterrupted aerodynamic surface when the flyer is in the second state. The flyer assembly is adapted to be launched from a ballistic delivery system such as an artillery cannon, and can thus reach a target quickly, without expending system energy stored within the flyer. During launch, the flyer is coupled to the shroud so as to maintain a portion of the flyer in tension during an acceleration of the flyer along the flyer axis resulting from the launch. The flyer assembly is adapted to withstand the high g-load and high temperature environments of a cannon launch, and can tolerate a set-back g load of about 16,000 g.
122 Citations
29 Claims
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1. A flyer assembly adapted for launching with, transit in, and deployment from an artillery shell having a central void region extending along a ballistic shell axis, comprising:
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A) a jettisonable shroud extending along a shroud axis and positionable within said central void region with said shroud axis substantially parallel to said shell axis;
B) a flyer adapted when in a first state to withstand a launch acceleration force along a flyer axis and adapted when in a second state to effect aerodynamic flight, the flyer in said first state being positionable within said shroud with said flyer axis parallel to said shroud axis and said shell axis, the flyer including;
a) a body member disposed about said flyer axis; and
b) a foldable wing assembly mounted to the body member, the wing assembly being configurable in a folded state characterized by a plurality of nested wing segments when the flyer is in said first state;
the wing assembly being configurable in an unfolded state characterized by a substantially uninterrupted aerodynamic surface when the flyer is in said second state;
wherein the flyer is adapted for coupling to the shroud so as to maintain a portion of the flyer in tension during an acceleration of the flyer along the flyer axis resulting from the launch. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25)
wherein each wing segment comprises a span-wise axis; - and
wherein when the wing assembly is in the folded state said span-wise axis of each wing segment is substantially parallel to the flyer axis, and wherein when the wing assembly is in the unfolded state said span-wise axis of each wing segment is substantially transverse to said flyer axis.
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3. A flyer assembly according to claim 1,
wherein the shroud comprises a support mechanism disposed at an interior surface of the shroud, wherein the flyer comprises a bulkhead for coupling to the support mechanism of the shroud, and wherein the flyer is adapted to be hung by the bulkhead on the support mechanism of the shroud. -
4. A flyer assembly according to claim 1, wherein the body member comprises a central void region, and further wherein the wing assembly is mounted on an outer surface of the body member exterior to the central void region.
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5. A flyer assembly according to claim 4, wherein the central void region is adapted to store system energy to be dispensed during an aerodynamic flight of the flyer.
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6. A flyer assembly according to claim 5, wherein the flyer is operable to reach a predetermined ballistic range at a predetermined velocity without expending the system energy stored within the flyer.
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7. A flyer assembly according to claim 6, wherein the predetermined ballistic range is about 22 km, and the predetermined average ground speed is about 22 km/min.
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8. A flyer assembly according to claim 1,
wherein the body member comprises a nose section, a mid-body section, and a tail section, and wherein the bulkhead is disposed at a junction between the nose section and the mid-body section, and wherein the mid-body section and the tail section of the flyer are maintained in tension during an acceleration of the flyer along the axis resulting from the launch. -
9. A flyer assembly according to claim 1, wherein the flyer assembly is adapted for expulsion from the artillery shell after reaching a predetermined ballistic range.
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10. A flyer assembly according to claim 9, further comprising a mechanism for decelerating and de-spinning the flyer assembly subsequent to an expulsion of the flyer assembly from the shell.
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11. A flyer assembly according to claim 10, wherein the deceleration mechanism comprises a parachute.
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12. A flyer assembly according to claim 9, wherein the shroud comprises a separation mechanism for jettisoning the shroud subsequent to the expulsion of the flyer assembly from the shell and upon a reaching of the expelled flyer assembly of a predetermined altitude.
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13. A flyer assembly according to claim 12, wherein the separation mechanism comprises charges embedded within the shroud.
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14. A flyer assembly according to claim 1, wherein the flyer is an unmanned air vehicle.
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15. A flyer assembly according to claim 1, wherein the flyer assembly is adapted to be launched from a ballistic delivery system.
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16. A flyer assembly according to claim 1, wherein the ballistic delivery system is selected from the group consisting of a cannon, an aircraft, a rocket, and a submarine.
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17. A flyer assembly according to claim 1, wherein the shroud is substantially cylindrical.
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18. A flyer assembly according to claim 1, wherein a weight of the shroud adds to a weight of the flyer so as to provide an optimal ballistic range for the flyer assembly.
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19. A flyer assembly according to claim 18, wherein the optimal ballistic range is about 22 km.
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20. A flyer assembly according to claim 1, wherein an outermost one of the plurality of wing segments is placed under compression, and all but the outermost one of the plurality of wing segments is placed under tension, during an acceleration of the flyer along the flyer axis resulting from the launch.
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21. A flyer assembly according to claim 1, wherein an inner surface of the shroud abuts an outermost one of the plurality of wing segments of the foldable wing assembly, and provides a radial restraining force that counters a centrifugal force arising from a spinning of the flyer assembly, thereby preventing a buckling of one or more wing segments.
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22. A flyer assembly according to claim 1, wherein the flyer is constructed from a composite material.
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23. A flyer assembly according to claim 1, wherein the flyer is adapted to withstand a set-back acceleration of about 16,000 g along the flyer axis.
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24. A flyer assembly according to claim 1, further comprising a foldable tail assembly mounted to the body member, the tail assembly being configurable in a folded state and in an unfolded state.
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25. A flyer assembly according to claim 3, wherein the support mechanism comprises a hanger.
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26. A method for deploying a flyer, the method comprising:
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positioning the flyer within a jettisonable shroud so that an axis of the flyer is parallel to an axis of the shroud;
positioning the jettisonable shroud within a central void region in an artillery shell so that a shroud axis is parallel to a ballistic shell axis;
launching the shell from a ballistic delivery assembly;
expelling the shroud and the flyer from the shell;
jettisoning the shroud; and
deploying the flyer so as to configure in an unfolded state a foldable wing assembly mounted to a body member of the flyer. - View Dependent Claims (27, 28, 29)
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Specification