Precision guided extended range artillery projectile tactical base

Information

  • Patent Grant
  • 6588700
  • Patent Number
    6,588,700
  • Date Filed
    Tuesday, October 16, 2001
    23 years ago
  • Date Issued
    Tuesday, July 8, 2003
    21 years ago
Abstract
A tactical base for a guided projectile includes a base structure, and an adaptor structure for securing the base structure to a forward section of the projectile. The base further includes a plurality of fin slots, with a plurality of insert structures fitted into corresponding ones of the fin slots. A plurality of deployable fins are pivotally mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position.
Description




TECHNICAL FIELD OF THE DISCLOSURE




This disclosure is directed to projectiles such as used in artillery, and more particularly to interfaces between the explosive payload and the propelling charge.




BACKGROUND OF THE DISCLOSURE




Projectiles for artillery systems must survive an extremely severe environment during launch. This includes high pressure, shock waves and extreme accelerations from the initial explosion of the propellant charge. The severe environment also includes a muzzle exit event on the projectile structure, which results in rapid depressurization and dynamic depressurization loads. The gun used to launch the projectile typically has a muzzle brake, requiring any fins to clear the brake before deploying. This is a significant design requirement, which is difficult to achieve for most systems.




SUMMARY OF THE DISCLOSURE




A tactical base for a guided projectile is described, and includes a base structure, and an adaptor structure for securing the base structure to a forward section of the projectile. The base further includes a plurality of fin slots, with a plurality of insert structures fitted into corresponding ones of the fin slots. A plurality of deployable fins are pivotally mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position.











BRIEF DESCRIPTION OF THE DRAWING




These and other features and advantages of the present invention will become more apparent from the following detailed description of an exemplary embodiment thereof, as illustrated in the accompanying drawings, in which:





FIG. 1

is a simplified isometric view of a guided projectile embodying aspects of the invention.





FIG. 2

is an isometric view of the base structure of the projectile of

FIG. 1

, showing one fin in a stowed position.





FIG. 3

is an isometric view similar to

FIG. 2

, but showing the fin in a deployed position.





FIGS. 4A and 4B

are isometric partial views of a sector of the base structure, taken along lines


4


A—


4


A and


4


B—


4


B.





FIG. 5

is an isometric partial view of the base structure showing a portion of a fin in a deployed position.





FIG. 6

is a diagrammatic isometric view of a fin and insert structure separated from the base structure.





FIG. 7A

is a cut-away diagrammatic view of the base structure;





FIG. 7B

is a partial cut-away view of a portion of the base structure, illustrating fin retention during launch of the projectile.





FIG. 8

is a simplified diagrammatic cross-section of the base structure, further illustrating the hemispherical dome bulkhead structure.











DETAILED DESCRIPTION OF THE DISCLOSURE




The aft most component of a guided projectile, referred to as the base, performs an important role in the success of a weapon system. The base provides the interface between the extreme pressures and shock loads resulting from the explosion of the propellant charge in the gun and the rest of the projectile. In addition, the base supports aerodynamic fins, which slow the rotation of the projectile as well as providing stabilization and lift. The fins remain stowed during the firing and deploy after the projectile exits the gun barrel and muzzle brake. The base also supports a projectile obturator, which is a device which seals the gap between the gun barrel bore and the projectile body. It maximizes the efficiency of the propellant charge impulse forces, and also rotates relative to the projectile to reduce the spin rate imposed on the projectile by the gun rifling.




The invention is applicable to guided projectile systems of various size and performance requirements. The exact configuration and materials of the described embodiment can be adjusted based on the particular system requirements for other applications.





FIGS. 1-8

illustrate an exemplary embodiment of a guided projectile


10


in accordance with aspects of this invention. It is to be understood that the drawings are not to scale, and are simplified diagrammatic illustrations of aspects of the invention. The projectile can be fired from a gun or artillery piece, e.g. a large caliber piece, say 155 mm. Of course, it is to be understood that the invention is not limited to a particular caliber, and can generally be employed in gun or rocket systems. In this exemplary embodiment, the projectile includes a guidance and control section


20


, a payload section


30


, typically including an explosive charge, and a tactical base


40


.




The base


40


provides a protective interface between the explosive payload


30


on the projectile and the propelling charge from the gun. The base also provides aerodynamic flight stability. In order to provide aerodynamic flight stability, the base has mounted therein a set of fins


42


, which deploy after the projectile


10


exits the gun barrel, as illustrated in

FIGS. 1 and 3

. In this exemplary embodiment, the base is designed to survive an extremely severe environment during launch. This includes high pressure, shock waves and extreme accelerations from the initial explosion of the propellant charge, as well as a muzzle exit event in which the projectile exits the gun barrel, which results in rapid depressurization. The gun used to launch the projectile may include a muzzle brake, which is cleared before the fins


42


deploy. The fins deploy within a set time post launch, and remain positionally true to the projectile airframe within tight tolerances.




This exemplary embodiment of the base


40


integrates multiple features into a one piece construction, to which fins, inserts and pins are assembled. The base utilizes a hemispherical dome bulkhead


80


(

FIGS. 4A

,


4


B,


5


and


8


) to support high pressure launch loads transmitted to a lower conic section


40


A (

FIG. 2

) and to support the linear loads of the payload. The lower conic or aft section


40


A features numerous cavities


70


separated by walls or ribs


76


that work together with separate inserts


44


and fins


42


to provide a structure that can support itself with minimal material as well as providing a necessary fin retention device to ensure that the base will clear the muzzle brake prior to fin deployment. The cavities may or may not be filled with material such as wax or silicon rubber filler


110


(FIG.


7


A). This “radially ribbed” structure significantly strengthens the dome bulkhead which allows it to be lighter in weight. The fins


42


(

FIG. 3A

) are completely protected in slots


46


during the launch and muzzle exit events, ensuring that they will not be damaged and will perform properly. Thus, in this embodiment, the fin slots are arranged such that the air flow as the projectile is launched or fired from the artillery piece will not have a tendency to travel into the fin slot and thus “bleed” out the back, increasing aerodynamic drag. An aft wall


48


(

FIG. 5

) closes the fin slots at the aft end of the base, protecting the fins from exit gases, and also preventing air flow from entering the fin slots


46


during flight. As shown in

FIG. 2

, the aft wall has openings which communicate with cavities


70


formed therein. This is a positive aerodynamic feature.




The base


40


in an exemplary embodiment is fabricated using an investment casting method, with very little post-casting machining required, from annealed Titanium 6AL4V. For this application, the material is required to have extremely high strain rate properties (high ductility), good fracture toughness to withstand the high impulse loading from the propellant explosion, and the ability to withstand high temperatures without appreciable loss of structural properties. Another property of titanium is that it is self-healing during a hot isostatic pressing process which removes voids in the casting. Other materials can also be employed, e.g. alternate titanium alloys. The fins can be fabricated from the same or similar material as used to fabricate the base


40


.




The external shape of the base structure


40


provides a boattail shape (i.e. conic section


40


A), and terminating at the aft section


40


B for minimizing aerodynamic drag while providing dimensional interfacing requirements to the launch platform. While there are eight fins for this particular application, this can of course be adapted to accommodate any number of fins. When the fins


42


are stowed in the base


40


, their trailing edges are generally parallel with the external conic section


40


A. One fin


42


is shown in the stowed position in its insert structure


44


in

FIG. 2

, and in the deployed position in FIG.


3


. There are eight equally spaced rectangular shaped radially positioned slots


46


formed in the base structure


40


to accommodate the stowed fins. An insert


44


completely fills the gap between the fin and slot, for reasons explained below. The fin is completely protected during the severe conditions of launch and muzzle exit. This will ensure that the fin will remain aligned so that it can perform its function as designed.




The base


40


has an externally positioned circumferential groove


60


which supports an obturator


90


(FIG.


4


B), which for an exemplary application is a Nylon (TM) rotating band structure. The obturator


90


rotates about a fixed slip band


92


secured in the groove


60


. The distance from the aft end


40


B of the base to the forward end of the obturator is a design constraint for the launch platform. Just forward of this groove


60


is located a circumferential thread


62


which supports an adapter ring


94


(

FIG. 8

) which allows interfacing to different payloads. The adapter ring is designed with a thread to mate with the forward payload section, in a direction which is counter-rotational to the gun barrel rifling or the direction in which the projectile tends to rotate at launch. The adapter ring


94


can be modified to adapt to different payloads.




Located inward from the forward end


40


C of the base is a cavity


64


(

FIG. 8

) which provides weight reduction of the base. The shape of this cavity produces a hemispheric dome bulkhead


80


to resist the pressure of the propellant charge explosion. The bulkhead also provides a conic shape for the base in region


40


A to efficiently support the payload during launch. This shape is a unique aspect of this design. As shown in

FIG. 5

, the conic shape is defined by angle A.




Referring now to

FIGS. 4A-4B

, located on the aft surface


40


B of the tactical base are eight triangularly shaped cavities


70


which may or may not be filled with a soft material


110


(FIG.


7


A), e.g. wax or RTV silicon rubber, corresponding in number to the number of fins, which project forward into the base


40


up to the hemispherical domed bulkhead


80


. Located circumferentially about the aft end of the base are eight holes


72


which are perpendicular to each corresponding fin slot


44


to provide pin attachment locations for attaching the fin to the base via a pin mechanism. The holes


72


are precision bored through one side of the fin slot, breaking out the other side of the slot. Due to tight tolerances for this exemplary embodiment, the holes


72


are not cast in place with the fin slot. The pins are pressed into the opening


42


B


1


formed in the fin hub structure


42


A (FIG.


6


), with a slightly loose clearance fit in the holes


72


. Providing clearance in holes


72


and press fit in the fin hub (part of


42


) allows for better alignment control of the fin aerodynamic surfaces relative to the projectile's axis. Also, the technique of pressing the pins into the fin hub opening and the clearance hole


72


in the base


40


allows for a better length to diameter control of the pin for fin alignment.




The fins rotate about aft pivot points from a forward stowed position to an aft deployed position. This is so aerodynamic forces ensure rapid deployment to maintain projectile stability. If fins are hinged to pivot about forward pivot points, or opposite the aft pivots illustrated here, the aerodynamic forces would prevent rapid fin deployment, requiring special mechanisms adding cost and risk. In addition, fins which pivot about forward pivot points must be longer in span to provide similar stability as shorter fins pivoting from aft positions, as a function of distance from the projectile's center of gravity to the center of pressure of the fin panel area. Longer fins tend to break off due to Coriolis forces, while shorter fins not only package in smaller spaces but are typically more robust against the Coriolis forces.




The majority of loading on the base structure will be carried by the hemispherical dome bulkhead


80


. By positioning the pivot points of the fins in aft positions, the loading on the fins will be reduced, thereby preventing distortion on the fin pivot axis.




The base structure aft of the dome shape contains numerous radial ribs


76


, which reinforce the dome bulkhead allowing it to be thinner in cross section than if it was otherwise unsupported. This allows the weight of the base to be reduced. Located in the center of the base, projecting inward from the aft surface is a cylindrical hole


78


used for lightening of the structure, which may optionally be filled with the soft material


110


. This feature could be modified to adapt to a rocket motor nozzle for certain applications.





FIG. 5

shows a one sixteenth sector of the base with half of an insert and half of a fin in the deployed position is shown in FIG.


5


. The fins


42


can be made of any of various metal alloys or composite materials (for this exemplary embodiment, the fin material is titanium). The trailing edge


42


A of the fin at the tip has a notch


42


A


1


which allows the fin to be restrained by the obturator


90


when stowed (FIG.


3


). The obturator disengages after exiting the gun barrel due to rapid dynamic depressurization. This is due to high pressure trapped gas under the obturator expanding and separating it for discarding. The fin is rotated forward and stowed with the tip inboard from the obturator in the non-operational condition. The fin is designed with its center of gravity (CG) inboard from the pivot point when stowed. The launch accelerations causes each fin to be forced into their respective slots due to this CG location, which prevents premature fin deployment inside the barrel.




Referring now to

FIG. 6

, the fin slot insert


44


is a separate piece which is installed into each fin slot in the base and houses the fin. Its function is to prevent high pressure gasses from getting trapped in the fin slots beneath the fin, and to support pressure loads on the wall between the triangular cavities and the fin slots. Trapped gases beneath the fins can prematurely deploy the fins at excessive rates at muzzle exit. The fin insert also transfers loads from these walls to the fins to provide a fin retention mechanism, which will be explained below. The insert


44


can be made of any of various materials including metal alloys, composites and plastics. For this embodiment, a nylon plastic material with a specific elastic modulus has been used to conform to each fin's external shape and fit into the corresponding rectangular slot in the base. In this example, for the titanium allow 6AL4V used to fabricate the base, 6/12 moldable NYLON (TM) can be employed to fabricate the insert. Alternatively, the insert may be made from other suitable materials such as resins, structural foam or hard rubber.




The insert can be modified internally to conform to different fin panel geometries as required. The insert transfers the external profile of the fin into the corresponding rectangular shaped slot in the base, eliminating intricate expensive machining or casting processes to be required on the base. The insert


44


can be bonded in place in the base slot, using a void filler such as an adhesive. Alternatively, a snap-in device can be employed to retain the insert within the slot. The insert has a straight slot to allow the fin to exit, but the insert contours to the fin on its leading edge when stowed.




During gun firing, high pressure gases pass through the triangular cavities


70


up to the hemispherical domed bulkhead


80


, and simultaneously surround the aft region


40


A up to the obturator


90


, providing a hydrostatic condition on the structure except for the area forward of the obturator and the weight reduction cavity


64


in the front of the base


40


. The base begins to accelerate down the gun tube, forcing the forward end of the projectile ahead of it. The fins tend to rotate into a more stowed position due to inboard fin CG relative to the pivot. When the obturator


90


clears the end of the gun barrel, the barrel pressure begins to vent to atmosphere, while the pressure in the eight aft cavities


70


is still active. This captured pressure within the cavities begins to push the structural walls


76


toward the fin insert


44


, which in turn transfers the load against the side of the fin. The structure of these walls is shown in

FIG. 7A

, a diagrammatic view showing the base


40


cut in half. This load transfer event on each side of the fin


42


creates a wedging action on the fin which provides a positive restraint against fin deployment until the aft cavity gas can decay allowing the walls to return to their previous position. This event allows the walls of the structure to be supported by the insert and fin so they do not experience permanent structural failure, allowing the walls to be reduced in thickness, and also retains the fins to prevent their deployment until they clear the muzzle brake. The base wall


76


between the fin slot and the triangular cavity also provides support for the outside wall of the aft area


40


A.




The load transfer event is illustrated in

FIG. 7B

, a partial cutaway of the base


40


. During the exit of the base


40


from the gun tube, it is assumed that atmospheric pressure (Pa) exists on the outside of the base, whereas gun barrel pressure (Pb) reacts on the end and on the triangular cavities


70


. The Pb pressure is very high and forces the base walls


70


to deflect into the insert


44


, in turn compressing the insert and pressing on the fin. If the elastic modulus of the insert is too low, this would allow too much deflection of the base wall


76


, causing yielding or failure. If the elastic modulus is too high, then the pressure Pb may not press against the fin with adequate force to retain the fin until the barrel pressure Pb bleeds off to atmospheric pressure.




It is understood that the above-described embodiments are merely illustrative of the possible specific embodiments which may represent principles of the present invention. Other arrangements may readily be devised in accordance with these principles by those skilled in the art without departing from the scope and spirit of the invention.



Claims
  • 1. A tactical base for a projectile, comprising:a base structure having a forward bulkhead in a hemispherical dome shape; a plurality of fin lots defined in the base structure; a plurality of insert structures fitting into corresponding ones of the fin slots; a plurality of deployable fins mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position.
  • 2. The base of claim 1, wherein the base structure is a unitary, one-piece structure.
  • 3. The base of claim 1, wherein the base structure is fabricated of titanium or a titanium alloy.
  • 4. The base of claim 1, wherein the base structure includes an aft end having a plurality of cavities formed therein, the cavities separated by a set of corresponding radial ribs extending outwardly to a base outer surface.
  • 5. The base of claim 1, wherein the base structure includes an aft end having a plurality of cavities formed therein, the cavities separated by a set of corresponding radial ribs, the radial ribs being joined together at said forward end to form said forward bulkhead.
  • 6. The base of claim 5, wherein adjacent ribs are joined together at said forward end to form a conical structure.
  • 7. The base of claim 5 wherein said forward bulkhead is adapted to carry a majority of loading experienced by the base structure during acceleration events.
  • 8. The base of claim 5, wherein a soft material is disposed in said plurality of cavities.
  • 9. The base of claim 1, further including a circumferential groove formed in a forward portion of the base structure for receiving therein an obturator structure.
  • 10. A tactical base for a projectile, comprising:a base structure; a plurality of fin slots defined in the base structure; a plurality of insert structures fitting into corresponding ones of the fin slots a plurality of deployable fins mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position, an adapter structure for securing the base structure to a forward section of the projectile, and wherein the base structure has a threaded portion at a forward end, and wherein said adapter structure threading engages with said threaded portion.
  • 11. A tactical base for a projectile, comprising:a base structure; a plurality of fin slot defined in the base structure; a plurality of insert structures fitting into corresponding ones of the fin slots; a plurality of deployable fins mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position, wherein the base structure has defined therein a plurality of cavities each of which are open at an aft base wall, and a plurality of radially extending walls defining said cavities and said fin slots, and wherein during firing of the projectile from a gun barrel, gasses at high pressure generated from a propellant enter said cavities and tend to deflect said walls into compression with said inserts and said fins, to prevent premature fin deployment before the projectile has left the gun barrel.
  • 12. A base for a projectile, comprising:a base structure having a forward bulkhead in a hemispherical dome shape; a plurality of fin slots defined in the base structure; a plurality of deployable fins mounted to the base structure and supported within the fin slots for movement between a stowed position and a deployed position.
  • 13. The base of claim 12, further comprising an adapter structure for securing the base structure to a forward section of the projectile.
  • 14. The base of claim 12, wherein each of the fins are pivotally mounted in said slots for pivoting movement about a pivot point from said stowed position to said deployed position.
  • 15. The base of claim 14, wherein the pivot point for each of the fins is disposed adjacent said aft end, and wherein each of the fins in said stowed position are pivoted forwardly about the pivot point.
  • 16. The base of claim 14, wherein the fins have a center of gravity disposed inwardly of said pivot point so that the fins tend to remain in said stowed position when the base is in an upright position due to force of gravity.
  • 17. The base of claim 12, wherein the base structure is a unitary, one-piece structure.
  • 18. The base of claim 12, wherein the base structure is fabricated of titanium or a titanium alloy.
  • 19. The base of claim 12, wherein the base structure includes an aft end having a plurality of cavities formed therein, the cavities separated by a set of corresponding radial ribs extending outwardly to a base outer surface.
  • 20. The base of claim 12, further including a plurality of insert structures fitted into corresponding ones of the fin slots, and wherein the plurality of deployable fins are mounted in respective ones of the insert structures.
  • 21. The base of claim 12, wherein the base structure includes an aft end having a plurality of cavities formed therein, the cavities separated by a set of corresponding radial ribs, the radial ribs being joined together at said forward end to form said forward bulkhead.
  • 22. The base of claim 21, wherein adjacent ribs are joined together at said forward end to form a conical structure.
  • 23. The base of claim 12 wherein said forward bulkhead is adapted to carry a majority of loading experienced by the base structure during acceleration events.
  • 24. The base of claim 21, wherein a soft material is disposed in said plurality of cavities.
  • 25. The base of claim 12, further including a circumferential groove formed in a forward portion of the base structure for receiving therein an obturator structure.
  • 26. The base of claim 12, further comprising an adapter structure for securing the base structure to a forward section of the projectile.
  • 27. The base of claim 26, wherein the base structure has a threaded portion at a forward end, and wherein said adapter structure threading engages with said threaded position.
  • 28. The base of claim 12, wherein each of the fins are pivotally mounted in said slots for pivoting movement about a pivot point from said stowed position to said deployed position.
  • 29. The base of claim 28, wherein the pivot point for each of the fins is disposed adjacent said aft end, and wherein each of the fins in said stowed position are pivoted forwardly about the pivot point.
  • 30. The base of claim 28, wherein the fins have a center of gravity disposed inwardly of said pivot point so that the fins tend to remain in said stowed position when the base is in an upright position due to force of gravity.
  • 31. The base of claim 12, wherein the base structure has defined therein a plurality of cavities each of which are open at an aft base wall, and a plurality of radially extending walls defining said cavities and said fin slots, and wherein during firing of the projectile from a gun barrel, gasses at high pressure generated from a propellant enter said cavities and tend to deflect said walls into compression with said inserts and said fins, to prevent premature fin deployment before the projectile has left the gun barrel.
  • 32. A projectile, comprising:a nose portion; a payload portion assembled to the nose portion; a base structure connected to the payload portion and having a plurality of fin slots defined in the base structure; a plurality of insert structures fitting into corresponding ones of the fin slots; a plurality of deployable fins pivotally mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position; wherein the base structure is a unitary, one-piece structure which includes an aft end having a plurality of cavities formed therein, the cavities separated by a set of corresponding radial ribs extending outwardly to a base outer surface, and wherein the base structure has a forward bulkhead in a shape of a hemisphere.
  • 33. A projectile, comprising:a nose portion; a payload portion assembled to the nose portion; a base structure connected to the payload portion and having a plurality of fin slots defined in the base structure, and further including a circumferential groove formed in a forward portion of the base structure for receiving therein an obturator structure; a plurality of insert structures fitting into corresponding ones of the fin slots; a plurality of deployable fins pivotally mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position.
  • 34. A projectile, comprising:a nose portion; a payload portion assembled to the nose portion; a base structure connected to the payload portion and having a plurality of fin slots defined in the base structure; a plurality of insert structures fitting into corresponding ones of the fin slots; a plurality of deployable fins pivotally mounted to the base structure and supported within the insert structures for movement between a stowed position and a deployed position; and wherein the base structure has defined therein a plurality of cavities each of which are open at an aft base wall, and a plurality of radially extending walls defining said cavities and said fin slots, and wherein during firing of the projectile from a gun barrel, gasses at high pressure generated from a propellant reacts on said cavities and tend to deflect said walls into compression with said inserts and said fins, to prevent premature fin deployment before the projectile has left the gun barrel.
  • 35. A projectile, comprising:a nose portion; a payload portion assembled to the nose portion; a base structure connected to the payload portion and having a plurality of fin slots defined in the base structure, the base structure having a forward bulkhead in a shape of a hemisphere; a plurality of deployable fins pivotally mounted to the base structure and supported within the fin slots for movement between a stowed position and a deployed position.
  • 36. The projectile of claim 35, wherein the base structure is a unitary, one-piece structure.
  • 37. The projectile of claim 35, wherein the base structure is fabricated of titanium or a titanium alloy.
  • 38. The projectile of claim 35, wherein the base structure includes an aft end having a plurality of cavities formed therein, the cavities separated by a set of corresponding radial ribs extending outwardly to a base outer surface.
US Referenced Citations (4)
Number Name Date Kind
4332360 Topliffe Jun 1982 A
4334657 Mattson Jun 1982 A
6126109 Barson et al. Oct 2000 A
20010030260 Niemeyer et al. Mar 2001 A1