1. Field of the Invention
The invention is in the field of air vehicles, and systems and methods for steering air vehicles.
2. Description of the Related Art
Missiles and other air vehicles have used various steering methods and mechanism for course correction, such as when steering to intercept a target, for example an incoming weapon. Steering using vectored thrust and cruciform divert thrusters has been used. There is a continual need for improvement in such steering methods.
According to an aspect of the invention, an air vehicle includes a pair of diametrically-opposed bilateral thrusters that are used to steer the air vehicle.
According to another aspect of the invention, an air vehicle rotates, and radial thrust from diametrically-opposed divert thrusters is asymmetrically imposed for steering purposes, when the divert thrusters are arrange in a desired rotational orientation.
According to yet another aspect of the invention, an air vehicle includes: a thrust system that includes a pair of diametrically-opposed divert thrusters that provide thrust having radial components in opposite radial directions; a rotation system for rotating the divert thrusters circumferentially about a longitudinal axis of the air vehicle; and a control system operatively coupled to the thrust system and the rotation system. The control system controls the thrust system to provide thrust from the divert thrusters to provide steering thrust on the air vehicle, for steering the air vehicle.
According to still another aspect of the invention, a method of steering an air vehicle includes: rotating at least diametrically-opposed bilateral divert thrusters of the air vehicle about a longitudinal axis of the air vehicle; and varying thrust from the divert thrusters as a function of rotational position of the divert thrusters about the longitudinal axis, to provide thrust in a radial direction to steer the air vehicle.
To the accomplishment of the foregoing and related ends, the invention comprises 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.
The annexed drawings, which are not necessarily to scale, show various aspects of the invention.
An air vehicle, such as a missile or a steerable submunition released from a missile or another air vehicle, has a bilateral thrust system for steering. The thrust system includes a pair of diametrically-opposed divert thrusters that provide thrust having radial components in opposite radial directions. In order to control the direction of thrust, the air vehicle controls rotation of the divert thrusters and/or timing of the firing of the thrusters. The air vehicle (or some part of the air vehicle that includes the divert thrusters) may be discretely rolled to position the divert thrusters to produce desired steering thrust. Alternatively, the air vehicle or part of the air vehicle may be continuously rolled, with the steering controlled by timing the thrust to the divert thrusters, such as by allocating thrust between the diametrically-opposed thrusters. Pressurized gas for the thrusters may be provided by burning solid fuel, and allocation of thrust between the two thrusters may be accomplished by use of pintle valve to control the relative allocation of pressurized gas between the two thrusters. The use of a bilateral divert thruster system allows reduction in weight, cost, and separate components, as well as simplifying control.
The thrust system 12 includes a pair of bilateral divert thrusters 14 and 16. The divert thrusters 14 and 16 are diametrically opposed on opposite sides of a fuselage 18 of the air vehicle 10, and expel pressurized gas in directions having radial components in opposite radial directions, to create thrust. The thrusters 14 and 16 may receive the pressurized gas from the same pressurized gas source, and may expel the pressurized gas through nozzles of the thrusters 14 and 16.
The divert thrusters 14 and 16 may be located at a longitudinal location along the fuselage 18 at or close to a center of mass of the air vehicle 10. This minimizes pitch of the air vehicle 10 due to firing of the divert thrusters 14 and 16.
The air vehicle 10 may also include a sensor or seeker 20 in a nose 22. The sensor 20 may be used in tracking a target, to provide information used in steering the air vehicle. The sensor 20 may be any of a variety of known types of sensors, such as optical sensors or radar sensors. The air vehicle 10 may also have the ability to detect its orientation, for example using inertial measurement units and/or roll sensing devices, utilizing sunlight or magnetism for example to keep track of the roll orientation of the air vehicle 10.
The air vehicle 10 may include a lethality enhancement device such as a warhead, a net, or a mechanism for increasing the effective impact area of the air vehicle 10. The lethality enhancement device may be used to increase the likelihood of the air vehicle 10 impacting a target in a hit-to-kill function.
The air vehicle 10 also includes a rotation system 30 that rotates at least the part of the air vehicle 10 that includes the divert thrusters 14 and 16. In the illustrated embodiment the rotation system 30 includes rotational thrusters 34 and 36 that are used to rotate the entire air vehicle 10 about its longitudinal axis 38. The rotational thrusters 34 and 36 supply thrust in a circumferential direction, rolling the air vehicle 10 in order to vary the location of the divert thrusters 14 and 16, to allow thrust to be applied in an appropriate radial direction to change the course of the air vehicle 10 as desired. The rotational thrusters 34 and 36 may be operated to produce continuous rotation (roll) of air vehicle 10, such as rotation about the longitudinal axis 38 at a steady angular rate (or continual rotation about the axis 38 at a non-constant rotation rate). Alternatively, the rotation thrusters 34 and 36 may be operated to provide discrete rotation of the air vehicle 10 for positioning the divert thrusters 14 and 16 to desired positions to provide desired thrust for steering. Both of these alternatives are discussed in greater detail below.
The air vehicle 10 (or part thereof) can be rotated about the axis 38 clockwise by ejecting pressurized gases from the nozzles 42 and 46. For counterclockwise acceleration the nozzles 44 and 48 are used. Pressurized gas for supplying rotational thrust may be supplied by one or more gas sources (not shown). The pressurized gas may be supplied by a pressurized gas source used by the divert thrusters 14 and 16, an example of which is described below, by separated dedicated pressurized gas source or sources, and/or by a pressurized gas source used to provide axial thrust to the air vehicle 10. The pressurized gas for the rotational thrusters 34 and 36 may be provided by burning of fuel, or by alternative sources, such as pressurized gas stored in one or more containers (not shown) within the fuselage 12. One or more valves (not shown) may be used to control flow of pressurized gas to the nozzles 42-48.
Other arrangements for the rotational thrusters 34 and 36 are possible. For example, the rotational thrusters 34 and 36 may only have one nozzle each, enabling rotational thrust in only a single direction. Control surfaces, such as fins, are another alternative for rotating the air vehicle 10, usable in situations where the air is sufficiently dense to generate lift for rotation.
Flow of pressurized gasses from the gas generator is controlled by a pintle valve 70, with a pintle 72 able to translate back and forth within a cavity 74 to control the relative amounts of the pressurized gas that are directed to the nozzles 64 and 66 of the divert thrusters 14 and 16. In operation the gas generator 60 may continuously emit pressurized gas while it is operating. If no divert thrust is required, the pintle 72 is placed in a neutral, central position, sending equal amounts of pressurized gas out of each of the divert thruster nozzles 64 and 66. This produces no net force on the air vehicle 10. Translation of the pintle 72 up or down results in more gas being sent through one of the divert thrusters 14 and 16, producing a net thrust on the air vehicle 10 that steers the air vehicle 10.
Many alternative arrangements for providing pressurized gas are possible. However, the illustrated arrangement simplifies operation and reduces the complexity and number of parts. No shutoff valve is required if the gas generator 60 can continuously produce and expel pressurized gas during operation. The only moving part is the pintle 72. The position of the pintle 72 may be controlled by any of a number of suitable mechanisms, such as well-known mechanical or electromechanical mechanisms. In addition, pressurized gas from the gas source 60 may be used for other purposes, such as for forward thrust in an axial direction, or for rolling of the air vehicle by the rotation system 30.
One possible operation mode involves continuous rolling of air vehicle 10. In such an operation, once the rolling has been established, the control system 80 mainly controls the steering by controlling the timing of changes in the thrust output of the thrust system 12. Thrust from the bilateral thrusters 14 and 16 is suspended (or the thrust from each is made equal) except when the thrusters 14 and 16 are close to the position where one of the thrusters 14 and 16 is positioned in the circumferential position such that thrust would be in the desired direction for steering. At that point pressurized gas may be preferentially directed to the appropriate of the divert thrusters 14 and 16. As the air vehicle 10 rotates the divert thrusters 14 and 16 alternate which provides the steering thrust, as the thrusters 14 and 16 alternately get into the position to provide the steering thrust. The control of the thrust system 12 by the control system 80 takes into account time lags in the system, such as a time lag between sending signals to the thrust system 12 and changes in thrust from the divert thrusters 14 and 16. This mode of operation has the advantage of requiring little in the way of operation of the rotation system 30; once the rotation of the air vehicle 10 (or part of the air vehicle 10) is set up, no further actuation of the rotation system 30 is necessary. The roll rate may be about 1-10 Hz, for example.
An alternative operation mode involves only rotating the air vehicle 10 as needed to position the divert thrusters 14 and 16 properly for steering. In this sort of operation the control system 80 controls the operation of the rotation system 30 to position the air vehicle 10 such that one of the divert thrusters 14 and 16 is in a position to deliver divert thrust in a desired direction for steering the air vehicle 10. After positioning of the divert thrusters 14 and 16 the control system 80 is used to preferentially direct pressurized gas to the divert thruster that is in a position to deliver the steering thrust. The control system 80 therefore controls operation of the rotation system, and the timing of the firing of the thrust system 12. The control may take into account time lags in various parts of the system.
Although the invention has been shown and described with respect to a certain preferred embodiment or 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 elements (components, assemblies, devices, compositions, etc.), the terms (including a reference to a “means”) used to describe such elements are intended to correspond, unless otherwise indicated, to any element which performs the specified function of the described element (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiment or embodiments of the invention. In addition, while a particular feature of the invention may have been described above with respect to only one or more of several illustrated 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.
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