Patent Application
20110094372
There are different techniques for steering or guiding a projectile during flight. For example, guided projectiles can be fin-stabilized or spin-stabilized and can use internal and/or external air-actuated control methods. As used herein guided projectiles include, but are not limited to, bullets, artillery projectiles (e.g. shells and shots), and tube-launched missiles. The Defense Advanced Research Projects Agency (DARPA) EXtreme ACcuracy Tasked Ordinance (EXACTO) project and the United States Army's Excalibur artillery projectile are examples of systems which use guided projectiles.
Typical guided projectiles which use internal air-actuated control methods include a chemical gas generator which is responsible for generating pressurized gas. The pressurized gas is then released through one or more orifices in the projectile to adjust the trajectory of the projectile. However, the chemicals used to generate the gas have a limited shelf-life which means that the guided projectile must either be used or replaced periodically. In addition, the components necessary for generating the pressurized gas and controlling the amount of pressure of the generated gas can be costly.
In one embodiment, a steerable projectile is provided. The steerable projectile comprises a pressure chamber to hold gas in a pressurized state; and a body section coupled to the pressure chamber, the body section having a flight system to use the pressurized gas for adjusting a trajectory of the projectile. The pressure chamber comprises an orifice in a wall of the pressure chamber; and a check valve corresponding to the orifice, the check valve configured to allow gas that results from ignition of a propellant to enter the pressure chamber via the corresponding orifice and to prevent the gas, once inside the pressure chamber, from exiting the pressure chamber via the corresponding orifice.
Understanding that the drawings depict only exemplary embodiments and are not therefore to be considered limiting in scope, the exemplary embodiments will be described with additional specificity and detail through the use of the accompanying drawings, in which:
In accordance with common practice, the various described features are not drawn to scale but are drawn to emphasize specific features relevant to the exemplary embodiments.
In the following detailed description, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration specific illustrative embodiments. However, it is to be understood that other embodiments may be utilized and that logical, mechanical, and electrical changes may be made. The following detailed description is, therefore, not to be taken in a limiting sense.
The embodiments described below provide pressurized gas for use in an air-actuated control system of a guided projectile, also referred to herein as a steerable projectile. In particular, the embodiments described below have a practically limitless self-life. In addition, the embodiments described below substantially reduce the complexity of the gas generation system as compared to typical chemical gas generators.
The projectile 101 includes a body section 102 and a pressure chamber 104. The body section 102 includes flight system 105 and navigation or guidance system 107. Notably, flight system 105 and guidance system 107 are depicted in
Flight system 105 is configured to alter or adjust the flight path of projectile 101 based on information received from guidance system 107. In particular, the flight system 105 is an internal air-actuated control system which releases pressurized gas from one or more orifices 115 in the projectile 101 to control the trajectory of the projectile 101. For example, the release of the pressure may be a jet of gas that deflects the projectile as it exits orifices 115. In other embodiments, the pressurized gas is used to pop out a fin/control surface which steers the projectile 101. Suitable air-actuated flight control systems are known to one of skill in the art of guided projectiles. The guidance system 107 can be a laser-guided system, a radar-based tracking system, an infrared tracking system, an inertial measurement unit, a global positioning system (GPS) sensor, or any combination thereof, as known to one of skill in the art. In addition, one of skill in the art is aware of other appropriate guidance systems which can be used to implement guidance system 107.
The projectile 101 also includes a pressure chamber 104 which holds the pressurized gas used by flight system 105 to maneuver the projectile 101. The pressure chamber 104 includes an orifice 106 located along a center axis 107 of the pressure chamber 104. The orifice 106 is disposed in an external wall of the pressure chamber to permit gas from outside the pressure chamber 104 to enter the pressure chamber 104. In particular, when a propellant is ignited to propel the projectile 101 out of a tube, such as a gun barrel, an artillery cannon or a missile launch tube, the gas produced by the ignited propellant enters the pressure chamber 104 through the orifice 106. As used herein, a propellant is an explosive substance which produces a force when ignited that imparts motion to a projectile.
Hence, the projectile 101 does not need a chemical reaction gas generator as used in conventional guided projectiles. Since, the projectile 101 uses pressurized gas from the ignited propellant, the projectile 101 essentially has an unlimited shelf-life as long as the propellant can be ignited. In addition, the relative simplicity of the pressure chamber 104, as compared to typical gas generators, reduces the cost of manufacturing the projectile.
The cover 208 is configured to prevent gas from entering or leaving the pressure chamber 104 when it covers the orifice 106. In particular, based on its spring constant, the spring 212 provides a force on the cover 208 which causes the cover 208 to cover or block the orifice 206. When a propellant is ignited, the pressure from the explosion provides enough force to overcome the force applied on the cover 208 by the spring 212. Thus, the pressure from the ignited propellant moves the cover 208 to open the orifice 106 and allow gas to enter the pressure chamber 104. Gas continues to enter the chamber 104 until the pressure of the gas reaches a desired range. In particular, if the pressure in the chamber 104 is too low, the projectile 101 will not steer well. However, if the pressure is too high, the pressurized gas can rupture the wall of the pressure chamber 104. Once the desired range is reached, the spring 212 will then cause the cover 208 to press against and cover the orifice 106 to prevent entry or exit of more gas through the orifice 106. Since the ignition of the propellant will generally produce more than sufficient pressure, the lower pressure limit is controlled by the spring 212 and cover 208 which prevent the pressurized gas from exiting the pressure chamber 104. The upper pressure limit is controlled by the diameter of the orifice 106, the value of the external pressure produced by ignition of the propellant, and the time the external pressure is applied.
In addition, the pressure chamber 104 optionally includes a filter 210. The filter 210 is needed in embodiments in which particles in the gas from the propellant could clog or block channels in the flight system 105 through which the pressurized gas travels. For example, in the embodiment of
Furthermore, although a single orifice 106 is shown in
As shown in the cross-sectional view of
The primer 618 is used to ignite the propellant 616 located in the casing 614 as known to one of skill in the art. The pressure that results from igniting the propellant 616 forces the projectile 601 out of the casing 614 and out of a tube such as a gun barrel or artillery canon. In addition, the projectile 601 includes a body section 602 and a pressure chamber 604 similar to the exemplary embodiments of a body section and a pressure chamber described above. In particular, the pressure that results from igniting the propellant 616 also causes the pressure chamber 604 to be filled with gas as described above. The projectile 601 then uses the pressurized gas in pressure chamber 604 for controlling the trajectory of the projectile 601 during flight as described above.
The firing mechanism 720 causes the propellant to ignite which propels the projectile 701 out of the tube 722. For example, in some embodiments, the tube 722 is implemented as a gun barrel and the projectile 701 is a bullet. In such a case, the firing mechanism is a hammer which strikes the primer 718 to ignite the propellant 716. The ignition of the propellant 716, thus, causes the bullet to be propelled out of the barrel. In other embodiments, the tube 722 is an artillery canon and the projectile 701 is an artillery shell. The gas produced by the ignition of the propellant 716 enters the pressure chamber 704, as described above.
A flight system in the projectile 701 uses the pressurized gas to adjust the trajectory of the projectile 701, as described above, and known to one of skill in the art. Hence, as described above, the projectile 701 has a substantially limitless shelf-life since it does not depend on chemical reactions to generate the pressurized gas as in typical guided projectiles. In addition, the projectile 701 is relatively less expensive to manufacture by leveraging the pressure produced by the ignited propellant 716 to fill the pressure chamber 704 with pressurized gas.
Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement, which is calculated to achieve the same purpose, may be substituted for the specific embodiments shown. Therefore, it is manifestly intended that this invention be limited only by the claims and the equivalents thereof.
