This invention relates to flight vehicles that include fixed or controllable flight surfaces that generate aerodynamic forces and/or moments (e.g. canards or fins), and more particularly to flight vehicles that include flight surfaces in a stowed position under a shroud that are capable of moving to a deployed position when the shroud is deployed.
Flight vehicles including but not limited to missiles, rockets, gun-launched projectiles, unmanned aerial vehicles (UAVs), miniature air launched decoys (MALDs), small diameter bombs (SDBs) and the like include fixed or controllable flight surfaces that generate aerodynamic forces and/or moments (e.g. canards or fins) for stabilizing and controlling their flight through the atmosphere. In certain applications there is limited space to stow the flight vehicles or there may be a risk of damaging the flight surfaces prior to or during launch. In particular, in container, tube or gun-launched flight vehicles the flight surfaces must be stowed within or wrapped around the body of the vehicle and deployed after the vehicle clears the container/tube/barrel. A deployment mechanism is positioned inside the body of the vehicle to drive the flight surfaces into position. The deployment mechanism may include motor driven gear assemblies, springs or pyrotechnic charges. By definition, “canards” are positioned forward of any main wing typically just behind the nose cone assembly. “Fins” are positioned at the tail of the vehicle aft of the main wing.
For certain applications a “shroud” is placed over the nose cone and then released in flight. The shroud may perform one or more functions depending on the application. The shroud may be used to simply protect the nose cone during transit, loading and firing from a weapons system. The shroud may form a “sabot” to match smaller diameter projectiles to a larger diameter tube or barrel. The shroud may be used to protect a payload such as an optical seeker for guidance and navigation positioned in the nose cone. The shroud may be used to provide aerodynamic properties for launch or a portion of flight. In some applications the shroud is released immediately as the vehicle exits the tube or barrel. In other applications the shroud may be released in flight just prior to activating the seeker.
The following is a summary of the invention in order to provide a basic understanding of some aspects of the invention. This summary is not intended to identify key or critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some concepts of the invention in a simplified form as a prelude to the more detailed description and the defining claims that are presented later.
The present invention provides a nose or tail assembly for a flight vehicle in which the deployment of the canards or fins is driven by energy imparted by the shroud. A tip section is rotatably coupled to a base, and both are stowed in an external volume between the shroud and nose/tail assembly. As the shroud is released, a drive feature on a shroud segment engages the tip section to rotate and join the base to form a complete canard or fin. This eliminates the need for storing the canards or fins in or wrapped around the body and eliminates the need for a complex deployment mechanism occupying an internal volume of the body. Although viable for all sizes of flight vehicles, the shroud-driven deployment system scales to very small diameter vehicles (e.g., diameter of 3 inches or less) in which the internal volume is not available to store either flight surfaces or deployment mechanisms.
In an embodiment, a nose or tail assembly includes a tapered section positioned fore or aft of the flight vehicle body. A shroud including a plurality of detachable segments defines an external volume between the tapered section and the shroud. A tip section is rotatably attached to a base at pivot point and positioned forward of the base within the external volume in a stowed position. A drive feature is positioned on an interior surface of one of the segments of the shroud forward of the pivot point and adjacent an edge of the tip section in the stowed-position. The drive feature is responsive to in flight release of the shroud to engage the edge and rotate the tip section to a deployed position such that the base and tip section form a complete flight surface. The drive feature suitably contacts and slides along the edge as the tip section as it rotates and disengages prior to full deployment and locking of the complete flight surface.
In an embodiment, the base includes a clevis that includes first and second side members that define a slot such that the tip section rotates on the pivot point into the slot between the first and second side members to form the completed flight surface. The first and second side members forming a portion of both a leading and a trailing edge and a portion of top and bottom surfaces of the complete flight surface. The span of the complete flight surface exceeds that of either the base or the tip section and extends outside the external volume. The slot may be formed with a taper to provide an interference fit with the tip section to slow and possibly lock the tip section. Alternately, a locking mechanism such as a cantilevered spring may be provided in the base to lock the tip section.
In an embodiment, the segments of the shroud are configured to pivot away from the flight vehicle and release to provide a controlled deployment of the tip section. The shroud may include an air intake to pressurize the shroud and pivot the segments away from the flight vehicle.
In an embodiment, a nose assembly has an internal volume that includes a guidance system adjacent the base and tip section in the external volume. The guidance system occupies the space that could be used to otherwise house conventional deployable flight surfaces and the deployment mechanism.
These and other features and advantages of the invention will be apparent to those skilled in the art from the following detailed description of preferred embodiments, taken together with the accompanying drawings, in which:
The present invention provides a nose or tail assembly for a flight vehicle in which the deployment of the fixed or controllable canards or fins is driven by energy imparted by the shroud. A tip section is rotatably coupled to a base, and both are stowed in an external volume between the shroud and nose/tail assembly. As the shroud is released, a drive feature on a shroud segment engages the tip section to rotate and join the base to form a complete canard or fin. This eliminates the need for storing the canards or fins in or wrapped around the body and eliminates the need for a complex deployment mechanism occupying an internal volume of the body. In a nose assembly that internal volume may be occupied by a guidance system for example. In a tail assembly that internal volume may be occupied by a motor for example. In either case, there is little internal volume left to store canards/fins and the deployment mechanism. Although viable for all sizes of flight vehicles, the shroud-driven deployment system scales to very small diameter vehicles (e.g., diameter of 3 inches or less) in which the internal volume is not available to store either flight surfaces or deployment mechanisms.
The present invention is applicable to all types of flight vehicles in which internal volume is limited and the need for flight surfaces with an extended span is present. Flight vehicles may include but are not limited to missiles, rockets, gun-launched projectiles, unmanned aerial vehicles (UAVs), miniature air launched decoys (MALDs), small diameter bombs (SDBs) and the like. These vehicles are typically launched from a container, tube or gun barrel although the invention is applicable to other launch modes. Typically the shroud and flight surfaces will open at launch as the vehicle exits the container, tube or barrel. However, in certain applications deployment of the shroud and flight surfaces may occur in flight, for example, just prior to activating an optical seeker. The flight surfaces may be fixed or controllable. Without loss of generality, the present invention will be described in context of a small diameter gun-launched guided projectile in which the nose cone assembly is provided with shroud-driven deployable canards.
Referring now to
The nose cone assembly 20 includes a tapered nose section 22 outfitted with shroud-driven deployable canards 24. An internal volume 26 of nose section 22 is suitably provided with sensors and a guidance system “G” 28. The guidance system 28 may comprise an optical seeker in which case the nose section is formed from an optically transparent material of a GPS. A control actuation system (CAS) 30 is positioned within the internal volume to drive a control rod 32 to rotate the canards 24.
A shroud 34 includes a plurality of segments 36 that are detachably mounted around the circumference of the tapered nose section 22 for in flight release. In this embodiment, segments 36 are held in place by bands 38 around the shroud, which are cut by the barrel rifling during launch. Air enters an intake 40 at the tip of shroud 34 producing pressure on the interior surfaces 41 of the segments causing them to expand moving backwards and outwards until the segments detach.
Shroud 34 defines an external volume 42 between the tapered nose section 22 and the shroud. In this embodiment, four bases 44 mounted on the nose section within the external volume at 90 degree spacing around the circumference of the nose section in mechanical cooperation with control rods 32. Bases 44 are nominally aligned parallel to a central axis 46 of the projectile. An outer edge 48 of each base 44 is suitably adjacent an interior surface of the shroud segment. Each base 44 is suitably provided with a lock mechanism 50 shown here as a cantilevered spring.
Four tip sections 52 are rotatably attached to the respective bases 44 at pivot point 54. Each tip section 52 is positioned forward of the base 44 within the external volume in a stowed position. The base 44 and tip section 52 are designed such that when the tip section 52 rotates to engage the base in a full-deployed position the base 44 and tip section 52 form a complete canard 24 having a span 56 that extends outside the external volume and the diameter of the projectile. Span 56 is greater than the span of either the base or tip section individually. In typical applications base and tip section will each provide about half of the total span.
A like plurality of drive features 60, here four, are formed on interior surfaces 41 of respective shroud segments 36. In this embodiment, the number of segments equals the number of canards. Alternately, the number of segments could be greater than the number of canards with some segments not including a drive feature. The drive feature 60 is positioned forward of the pivot point 54 adjacent an edge 62 of tip section 52 in the stowed-position. As the shroud releases in flight, drive feature 60 engages edge 62 and rotates the tip section to a deployed position such that the base and tip section form complete canard 24. A portion of tip section 52 is formed with a detent 64 that rotates past and engages the cantilever spring to lock the tip section in place.
The shroud-driven canard deployment system resides entirely in the external volume 42 between the nose section 22 and shroud 34. No components of either the canard or the deployment mechanism occupy any of the internal volume 26 of the nose section. That internal volume albeit small is reserved for the guidance system and the CAS. Furthermore, the system only utilizes energy in the shroud segments as they release to deploy and lock the tip sections to form the complete canard 24. No deployment mechanisms such as motors, spring or pyrotechnic device that store and then release energy, which typically occupy a portion of the internal volume, are used.
Referring now to
A drive feature 102 on an interior surface of a shroud segment is position forward of pivot point 82 adjacent an edge 104 of tip section 72. The drive feature 102 may rest against edge 104 or be slightly spaced apart therefrom in the stowed position. Drive feature 102 such as a drive pin preferably has a rounded surface so that it contacts and slides along edge 104 as the tip section rotates to full deployment. The drive feature 102 disengages edge 104 as the tip section continues to rotate prior to full deployment. The tip section carries sufficient momentum to continue rotating to a deployed and locked position. It is important that the drive feature 102 disengage prior to full deployment to avoid damage to the complete canard 70.
Referring now to
Referring now to
As the shroud begins to open up and the segments 202 pivot off a hinge point 214, the drive pin 206 moves backwards (aft) and outwards (away from the longitudinal axis) such that the drive pin 206 engages and rotates the tip section 216 about pivot point 208 in base 218. In this embodiment, at shroud angle 14° the drive pin 206 has disengages from tip section 216. The momentum of the tip section carries it to mate and lock into base 218 to form the complete canard 204 at shroud angle 16°. At release, the drive pin 206 may be fore or aft of pivot point 208 depending on the geometry of the base and tip section and the location of pivot point 208. At release, the drive pin 206 is above the pivot point and the four drive pins 206 lie on a circle 220 whose diameter is greater than the circle 212 through the pivot points 208.
As previously mentioned, the present invention for shroud-driven deployment of flight surfaces can be implemented in the tail assembly of a flight vehicle. In such an embodiment, the aft section of the flight vehicle would taper to a diameter less than the body. As with the nose cone assembly, a plurality of bases would be positioned around the tapered tail section. A like number of tip sections would be rotatably mounted to the bases and positioned forward when stowed. A segmented shroud would cover the tail section and provide drive features to rotate and deploy the tip sections to form complete tail fins. The difference in implementation would be in the shroud. The segments would have to be hinged at the smallest diameter portion at the aft end of the vehicle. Air intakes would be provided around the circumference of the vehicle to pressurize and release the shroud segments. Alternately a different mechanism such as a pyrotechnic charge could be used to release the segments.
While several illustrative embodiments of the invention have been shown and described, numerous variations and alternate embodiments will occur to those skilled in the art. Such variations and alternate embodiments are contemplated, and can be made without departing from the spirit and scope of the invention as defined in the appended claims.
This invention was made with government support under HR0011-15-C-0081 awarded by the Department of Defense. The government has certain rights in this invention.