The present invention generally relates to vehicles having stowable fins, and, more particularly, to a system for stowing and deploying the fins.
Many types of vehicles utilize two or more protruding surfaces to affect the fluid flow around the vehicle, thereby facilitating control of its flight path. Exemplary types of such vehicles include aircraft, airships, unmanned aerial vehicles, and various types of ordnance, e.g., missiles, rockets, guided projectiles, bombs, torpedoes and the like.
For example, missiles generally have a cylindrical body, with at least two aerodynamic surfaces or fins that extend outwardly from the sides of the missile body (vehicle housing) to affect the aerodynamic characteristics of the missile in flight. The fins typically have an airfoil shape that is oriented edge-on or slightly inclined relative to the airflow when the missile is flying in a straight line. These fins may be, for example, static (fixed) or dynamic (selectively movable, i.e., controllable). Fixed fins generally are used to stabilize the missile during flight and do not move once fully deployed. Controllable fins (control fins) are used to control or steer the missile by selectively varying the attitude of the fins relative to the airflow under the direction of the missile's control system.
In many cases, the fins are stowed in a position adjacent to the outside surface or within the missile body during storage and mounting on a vehicle prior to use. In some cases, the missile is stored in a tube, a canister or other protective casing, and the protective casing also may serve as a launch tube. The fins are stowed in such a manner as to permit more missiles to be stored and/or transported in a limited space. Stowing fins in such a manner also reduces the likelihood of damage to the fins during storage and handling. Additionally, such stowing maximizes subsystem packaging volume inside the vehicle housing for various components, e.g., electronic components, propulsion systems, warheads and the like.
The fins are deployed from the stowed position shortly after deployment of the missile, or during the launch phase of the missile. Various relatively complex deployment systems have been developed to permit the fins to be stowed, deployed and locked into place. Control fins may further be moved (usually only rotated) by an actuator system once the control fins are deployed.
In some cases, the fins are stowed by folding the fins like jack knifes or sling foils into the body of the vehicle through longitudinal slots in the vehicle's housing. Complicated retention features and housings are provided to retain the fins in the vehicle housing until the vehicle clears the weapon system, e.g., a bomb bay, a launch rail, a bore of a weapon system, e.g., a cannon, a gun, a howitzer, a mortar tube, a canister or the like. For example, covers are employed to seal the longitudinal slots and retain the fins until needed in flight. In some cases, multiple mechanisms are used, for example, a cover deployment system is provided to effectively discard the covers and a fin deployment system is provided to deploy the fins in flight.
Many fin deployment systems require the fins to deploy about more than one axis. That is, fin deployment systems require a fin to pivot or rotate about a first axis and then to pivot or rotate about a second axis in order to transition from a stowed configuration to a deployed configuration. In some cases, the fins transition to an intermediate configuration before transitioning to a final deployed configuration.
The systems presently used to retain, deploy, lock into place and control (if applicable) the fins tend to be relatively heavy, complex and expensive to design, build and maintain. Moreover, some systems occupy a relatively large volume within the missile, a significant disadvantage because of the limited space within the missile.
There is a need for a simple and reliable system to stow stowable vehicle fins in a stowed configuration, deploy the fins about a single axis, and retain or lock the stowable vehicle fins into a deployed configuration and, in some cases, control the fins in the deployed configuration. The present invention provides a deployment system for stowing and deploying stowable fins that meets this need and provides further advantages in cost, weight and space savings. Additionally, the present invention allows for smaller vehicles with increased capability and performance.
More particularly, the present invention provides a vehicle with a deployment system that automatically deploys a fin from a stowed orientation to a deployed orientation as soon as the fin is released. The deployment system includes a spring that provides a biasing force that urges the fin to move quickly, simply and reliably from the stowed orientation to the deployed orientation about a single axis. The deployment system also includes one or more slots or other means for locking the fin in the deployed orientation.
An exemplary deployment system for the vehicle includes a bushing that can be mounted in a cylindrical cavity in the vehicle housing. The fin includes a foil that is connected to a shaft (and may be integral with the shaft) that extends through a through hole in the bushing. The shaft is connected to the bushing through a drive spring that biases the shaft to the deployed orientation. The shaft, the bushing and the spring thus cooperate to move the fin from the stowed orientation to the deployed orientation. The shaft controls or guides the fin as it is deployed.
Additionally, the drive spring will rotate and translate-the fin as it is deployed and/or secure (lock) the fin from further rotation relative to the bushing in the deployed orientation. A blind slot or detent may be formed in the shaft to receive a locking mechanism that inhibits axial movement of the fin relative to the shaft in the deployed orientation. A shear pin or other retaining means may be provided to fixedly retain the bushing in the vehicle housing.
According to an aspect of the invention, a missile includes: a missile body; a deployable fin having a shaft inserted into a cavity in the missile body; and a torsion spring coupled to the shaft, wherein the spring is configured such that torsion from the spring rotates the fin about an axis of the shaft, thereby deploying the fin.
According to another aspect of the invention, a method of launching a missile, includes the steps of: placing the missile in a launch tube, wherein fins of the missile are in a stowed configuration, pressing against guide rails of the launch tube; accelerating the missile, wherein the fins continue to press against the guide rails of the launch tube while the missile is in launch tube; and after the missile exits the launch tube, deploying the fins by use of torsion and compression spring forces to effect single-axis rotation of each of the fins.
To the accomplishment of the foregoing and related ends, the invention provides the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative embodiments of the invention. These embodiments are indicative, however, of but a few of the various ways in which the principles of the invention may be employed. Other objects, advantages and novel features of the invention will become apparent from the following detailed description of the invention when considered in conjunction with the drawings.
In the annexed drawings, which are not necessarily to scale:
A missile has fins that rotate about a single axis to deploy from a stowed position, in which a foil of the missile may be substantially parallel to a missile body, to a deployed position, in which the foil may be substantially perpendicular to the missile body. A foil longitudinal axis of each fin is angled relative to a shaft of the fin, such that a single-axis rotation of the shaft moves the wing or foil from the stowed position to a deployed position. A coil spring may provide both torsion and compression forces to rotate the fin into the deployed position and lock it into place. Torsion rotates the shaft until it reaches a seat on a bushing that is around the shaft. Then compression forces from the spring engage a keyed protrusion on the shaft with a corresponding keyway in the bushing, locking the shaft in place. There may be an additional lock once the fin is deployed, such as a spring-loaded pin in the missile body that engages a depression in the shaft.
Referring now to the drawings, and initially to
Each fin 12 has a foil 19 with a leading edge 20 and a trailing edge 22 that bound the chord of the foil 19, and a longitudinal axis 24 that extends approximately along the length of the foil 19. The leading edge 20 of the foil 19 faces in a forward direction generally toward the leading or forward end of the vehicle 10 during flight. The thickness of the foil 19 is less than its width or length, and the geometry of the foil 19 is selected for its intended application.
In the stowed configuration shown in
The missile body 16 has cavities 27 for receiving respective shafts 28 of the fins 12. As will be described in greater detail below, rotation of the fin 12 about the axis of the shaft 28 moves the fin 12 from its stowed configuration (
The movement of the foil 19 from the stowed configuration shown in
The fin 12 is connected to the vehicle housing 16 through the deployment system 14, which moves the fin 12 from the stowed orientation to the deployed orientation. The deployment system 14 is mounted at least partially in the cavities 27 in the vehicle housing 16 (
Turning now to
With reference in addition to
The shaft 28 may be manufactured to fit with a close tolerance against the inner diameter of the bushing 34. The bushing 34 is fixedly mechanically coupled to the missile body 16, and functions to protect the missile body 16, which may be made of a relatively soft material, such as aluminum. The bushing 34 thus may be made of a relatively hard material, such as steel.
With additional reference to
On the opposite end from the keyway 56, the bushing 34 has an external step, ledge or shelf 58. The shelf 58 is formed by an abrupt decrease in the external diameter of the bushing 34. The shelf 58 is configured for engaging the drive spring 36, for example by having one or more holes therein.
The raised portion 52 of the bushing 34 has top surface 64 (
The shear pins 42 and 44 (
With reference now to
The missile body 16 includes a locking mechanism 92 for further locking the fin 12 in place once it has reached its deployed position. The locking mechanism includes a spring-loaded locking pin 94 that is biased by a spring 96 to press against the shaft 28. Once the fin 12 has reached its deployed position, illustrated in the right hand side of
With reference to
Once the missile 10 exits the launch tube, the fins 12 are no longer retained by the sides of the launch tube, and begin to deploy. With the fins 12 in the stowed configuration, the drive spring 36 stores energy both due to the compression of the spring 36 and torsion of the spring 36. The deployment is driven by the drive spring 36. One end of the spring 36 is fixedly coupled to the bushing 34, which in turn is fixedly connected to the missile body 16. However, the other end of the spring 36 is coupled to the retainer 38, which in turn is connected to the shaft 28 by the retainer pin 40. This end of the spring 36, along with the retainer 38 and the shaft 28, are free to turn relative to the bushing 34. Thus the shaft 28 begins to rotate on its axis, within the bushing 34, rotating the fin 12 toward its deployed position. During this rotation, illustrated in
Once the key 46 contacts the key seat 66, illustrated in
In addition, this further pulling down of the shaft 28 into the cavity 27 causes the recess or detent 51 to reach the location of the spring-loaded pin 94, which under the action of the spring 96 then engages the recess 51. This engagement of the lock mechanism 92 helps prevent rotations of the shaft 28, and in addition, prevents translation of the shaft 28 along its axis.
It will be appreciated that the deployment of the fins 12 occurs spontaneous upon the exit of the missile 10 from its launch tube, without further actuation to start the deployment process. As an alternative, it will be appreciated that the deployment system 14 may be manually or automatically activated.
The invention thus provides a simple and reliable mechanism to both hold the fins in a stowed position and to release the fins to a deployed configuration. Further, no parts of the device are shed or broken away upon deployment of the fins, thereby minimizing or eliminating the risk of injury to the launch vehicle or operator.
Although the invention has been shown and described with respect to certain preferred embodiments, it is obvious that equivalent alterations and modifications will occur to others skilled in the art upon the reading and understanding of this specification and the annexed drawings. In particular regard to the various functions performed by the above described components (assemblies, devices, sensors, circuits, etc.), the terms (including a reference to a “means”) used to describe such components are intended to correspond, unless otherwise indicated, to any component which performs the specified function of the described component (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiments of the invention. In addition, while a particular feature of the invention may have been disclosed with respect to only one of several embodiments, such feature may be combined with one or more other features of the other embodiments as may be desired and advantageous for any given or particular application.