The present invention relates generally to airborne deployment systems and, more particularly, to embodiments of a low cost deployment system and method suitable for operator “hand safe” use in conjunction with an airborne object, such as a projectile or missile.
Traditionally, canards and other deployable flight control surfaces have been primary utilized onboard larger airborne munitions, such as missiles. However, more recently, deployable canards have been utilized in conjunction with relatively small munitions, such as artillery shells and other projectiles. As a specific example, precision guidance kits (PGKs) have recently been developed that include a plurality of deployable canards. Each PGK is adapted to threadably mount to the nose of an artillery shell in place of a conventional fuse. In addition to providing a fusing function, the PGK guides the flight of the artillery shell by manipulating the position of the deployable canards in accordance with signals received from an onboard global positioning system (GPS) unit.
Deployable flight control surfaces of the type described above are typically maintained in a non-deployed position during launch or firing and subsequently released into a deployed position during flight. The deployable flight control surfaces are urged toward the deployed position by a structural biasing means (e.g., a spring) or by centrifugal forces, which act on the munition as it spins rapidly during flight. A deployment system carried by the airborne munition prevents deployment flight control surfaces until the desired time of deployment, which may occur shortly after munition launch or firing. By initially maintaining the flight control surfaces in a non-deployed or stowed position, the flight control surfaces are protected from physical damage that might otherwise in the course of soldier handling. In addition, by stowing the flight control surfaces during munition launch or firing, drag is reduced and the range of the munition is increased.
Conventional deployment systems utilized onboard larger airborne munitions, such as missiles, are generally reliable and robust. However, such conventional deployment systems tend to be undesirable bulky and costly for deployment aboard smaller airborne munitions, such as artillery shells and other projectiles. There thus exists an ongoing need to provide a deployment system suitable for utilization onboard airborne munitions (e.g., projectiles) and other airborne objects (e.g., satellites and sub-munitions) that is relatively compact and inexpensive to manufacture, in addition to being rugged and reliable. It is also desirable to provide a method for equipping an airborne object with such a deployment system. Other desirable features and characteristics of the present invention will become apparent from the subsequent Detailed Description and the appended Claims, taken in conjunction with the accompanying Drawings and this Background.
A deployment system is provided for utilization onboard an airborne object including a deployable element. In one embodiment, the deployment system includes a circumferential restraint and a release mechanism mounted to the airborne object. The circumferential restraint is disposed at least partially around the airborne object in a constraining position wherein the circumferential restraint prevents deployment of the deployable element. The release mechanism normally resides in a first position in which the release mechanism maintains the circumferential restraint in the constraining position. The release mechanism is movable to a second position to release the circumferential restraint from the constraining position and permit deployment of the deployable element.
A method is also provided for equipping an airborne object, which includes at least one deployable element, with a deployment system. In one embodiment, the method includes the steps of: (i) placing the deployable element in a non-deployed position, (ii) disposing a circumferential restraint around the airborne object in a constraining position wherein the circumferential restraint physically prevents deployment of the deployable element, and (iii) mounting a pin retraction mechanism to the body of the airborne object. The pin retraction mechanism normally resides in an extended position wherein the pin retraction mechanism engages the circumferential restrain to maintain the circumferential restraint in the constraining position. The pin retraction mechanism is movable to a retracted position wherein the pin mechanism releases the circumferential restraint from the constraining position and permits deployment of the deployable element.
At least one example of the present invention will hereinafter be described in conjunction with the following figures, wherein like numerals denote like elements, and:
The following Detailed Description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding Background or the following Detailed Description.
In general, deployment system 30 includes two primary components: (i) a release mechanism, and (ii) a circumferential restraint. The release mechanism may comprise any device suitable for selectively releasing the circumferential restraint from a constraining position wherein the circumferential restraint maintains canards 12 in a non-deployed position as described more fully below. The release mechanism conveniently comprises a pin actuation mechanism and preferably comprises a “hand safe” explosively actuated pin retraction mechanism of the type described below. The circumferential restraint conveniently comprises at least one elongated flexible member, such as one or more wires, elastomeric cords, ropes, spring members, or the like. In a preferred group of embodiments, the circumferential restraint assumes the form of one or more retention cables as described more fully below in conjunction with
In certain embodiments, deployment system 30 may further include one or more guide members that guide the circumferential restraint (e.g., retention cable 34) along a desired path. In the illustrated exemplary embodiment, deployment system 30 further includes first and second guide posts 52 (shown in
At the desired time of deployment, pin 44 of EA pin retraction mechanism 32 is retracted via the detonation of explosive material 46 within casing 36 (
The foregoing has thus provided an exemplary embodiment of a deployment system suitable for use onboard an airborne object. In addition to being reliable and robust, the above-described exemplary deployment system is also relatively lightweight, compact, and inexpensive to produce. As a result, the above-described deployment system is especially well-suited for deployment aboard a smaller airborne munition, such as an artillery shell. As an additional advantage, embodiments of the deployment system are amenable to fully automated manufacturing processes. For example, in the above-described exemplary embodiment, the provision of guide posts 52 (
In the above-described exemplary embodiment, deployment system 30 included first and second guide posts 52 (
The has thus been provided multiple exemplary embodiments of a deployment system for utilization aboard an airborne object, such as a projectile, that is reliable, compact, relatively inexpensive to produce, and amenable to automated manufacture. Although, in the above-described exemplary embodiments, the deployment system was utilized to maintain one or more canards in a deployed position until such time as it is desired to release the canards to a deployed position, the deployment system may be utilized to selectively deploy various other types of deployable elements, such as other types of flight control surfaces, antennae, solar collectors, landing gears, and other deployable features. Furthermore, although the foregoing has described a first exemplary embodiment of the deployment system in the context of a precision guidance kit adapted threadably mounted to an artillery shell and a second exemplary embodiment of the deployment system in the context of a generalized missile, it will be appreciated that embodiments of the deployment system are equally suitable for utilization onboard a wide variety of airborne objects, including other types of airborne munitions (e.g., unmanned air vehicles), airborne sub-munitions, modular components adapted to be mounted to airborne munitions (e.g., fuse kits), satellite, land or water based robotic vehicles, and certain aircraft. It is noted, however, that embodiments of the deployment system are compact and relatively inexpensive to manufacture and are consequently especially well-suited for deployment aboard smaller sized airborne munitions, such as artillery shells and other projectiles.
The foregoing has also provided an exemplary method for equipping an airborne object, such as a projectile or other airborne munition, including at least one deployable element, such as a canard or other flight control surface, with a deployment system. In general, the exemplary method includes the steps of: (i) placing the deployable element in a non-deployed position; (ii) disposing a circumferential restraint (e.g., a retention cable) around the airborne object in a constraining position wherein the circumferential restraint physically prevents deployment of the deployable element; and (iii) mounting a pin retraction mechanism (e.g., an explosively actuated pin retraction mechanism) to the body of the airborne object. The pin retraction mechanism normally resides in an extended position wherein the pin retraction mechanism engages the circumferential restrain to maintain the circumferential restraint in the constraining position. The pin retraction mechanism is movable to a retracted position wherein the pin mechanism releases the circumferential restraint from the constraining position and permits deployment of the deployable element. In certain embodiments, the method further includes the step of forming a guide post projecting from the airborne object at a location substantially axially aligned with the deployable element and axially offset from the pin retraction mechanism. When provided, the guide post engages the circumferential restraint to guide a portion of the circumferential restraint along a serpentine path.
While multiple exemplary embodiments have been presented in the foregoing Detailed Description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing Detailed Description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set-forth in the appended Claims.
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Number | Date | Country | |
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20100282895 A1 | Nov 2010 | US |