The present invention relates to energetic igniters, and more particularly to radio frequency energetic igniters.
Most conventional artillery systems are initiated by use of a center fire based primer housed within a metal casing. Such primers are typically initiated through electrical or mechanical (percussion) means. These systems in particular are used in medium and large caliber gun systems. Advanced artillery systems have explored the use of laser ignition systems wherein the propelling charge is ignited by an external laser emitter located in the breech of the artillery system.
A feature common in many conventional artillery charges is that the ignition impetus occurs at the rear of the charge. Under ideal conditions single point rear ignition spreads progressively forward through the propellant bed. However, predictable progressive ignition does not always occur and the results of which, such as weapon failure, can be catastrophic. In addition, single point rear ignition also requires complex and careful charge design consideration to avoid the generation of rarefaction waves.
As can be appreciated, the location of an ignition system in the breech of an artillery system presents numerous challenges, Among the most difficult of these challenges are those related to making the ignition system sufficiently robust to endure the continuous extreme vibration, shock and thermal excursions produced by the weapon system when fired, as well as the extreme environmental conditions such as long term storage and operation in hot/cold and wet/dry weather conditions.
The present invention relates to a radio frequency ignition system for igniting an energetic via electromagnetic energy.
According to a first aspect of the invention, a radio frequency ignition system includes a radio frequency emitter and one or more radio frequency igniters. The radio frequency emitter emits electromagnetic energy into a resonant cavity. The one or more radio frequency igniters are each attached to an energetic charge located within the resonant cavity. Each of the one or more radio frequency igniters further comprises a first layer, a second layer and an initiating charge disposed between the first layer and the second layer. The first layer further comprises a radio frequency absorption material for receiving the burst of electromagnetic energy and converting it to a stimulus for igniting the initiating charge. The second layer further comprises an adhesive for attaching the radio frequency igniter to the energetic charge.
According to a second aspect of the invention, a radio frequency ignition system includes a radio frequency emitter and one or more radio frequency igniters. The radio frequency emitter emits electromagnetic energy into a resonant cavity. The one or more radio frequency igniters are each attached to an energetic charge located within the resonant cavity. Each of the one or more radio frequency igniters further comprises a radio frequency absorption material for receiving the burst of electromagnetic energy and converting it to a stimulus for directly igniting the energetic charge.
According to a third aspect of the invention, an ignition system for a weapon comprises a radio frequency emitter, a transmitting antenna and a plurality of radio frequency igniter patches. The radio frequency emitter produces a burst of electromagnetic energy. The transmitting antenna protrudes into the breech of the weapon and broadcasts the electromagnetic energy into the breech. The plurality of radio frequency igniter patches are each attached to a propelling charge for the weapon. The radio frequency igniters simultaneously ignite upon reception of the electromagnetic energy. The plurality of radio frequency igniter patches further comprise a first dielectric layer, a second dielectric layer and a initiating charge disposed between the first dielectric layer and the second dielectric layer. The first dielectric layer comprises a metallic film sized and dimensioned to convert the electromagnetic energy to thermal energy of a sufficient quantity to ignite the initiating charge. The initiating charge is positioned to ignite a center core charge of the energetic charge.
The accompanying figures further illustrate the present invention.
The components in the drawings are not necessarily drawn to scale, emphasis instead being placed upon clearly illustrating the principles of the present invention. In the drawings, like reference numerals designate corresponding parts throughout the several views.
The present invention relates generally to the ignition of energetics using radio frequency energy. A radio frequency igniter, such as a patch or localized zone, is designed to convert received electromagnetic energy to heat or electrical energy for the purpose of ignition of an energetic sources, such as pyrotechnic or propellant. One or more radio frequency (RF) devices may be attached upon, printed or embedded in the case of the energetic device. For purposes of clarity, throughout this specification, the RF igniter will be described in the context of igniting artillery charges, such as the Modular Artillery Charge System (MACS) currently fielded by the United States Army; however, the RF igniter is not limited to igniting artillery charges, specifically, or to military applications, in general.
The RF igniter 18 receives the electromagnetic energy 16 and converts it to ignite an energetic charge, such as a propelling charge. The conversion process can be a thermal conversion or a more complex method such as driving of a micro-based laser initiation device or ignition source. In an embodiment of the invention, the RE igniter 18 receives the electromagnetic energy via an RF absorption material, such as an antenna, and initiates the first element 181 of an ignition chain, through dielectric heating, which progresses into the main propellant charge 18. In another embodiment, the RE igniter 18 receives the electromagnetic radiation to produce an electric voltage for powering an ignition device such as a micro-based laser initiation device. In this embodiment, ignition is initiated through a micro-electronic package which may be capable of providing bi-directional communication as well as ignition. For example, in one embodiment, the temperature, age, lot and other attributes of the propellant may be communicated over the bi-directional communication link.
The RF emitter 10 may be external to the artillery piece 20 or may be integral to the artillery piece. The RE emitter 10 produces a burst of electromagnetic energy 16 for a short duration coupled into and through an RE transmission cable 12 or alternatively can be directly coupled to a radiative antenna 14 located within the confines of the breech 201 (or combustion chamber) of the artillery device. For example, the RF emitter 10 may be a high power emission source such as a magnetron that may broadcast energy into the breech at a sufficient level to ensure ignition. In one embodiment, the RE emitter radiates approximately 1 kilowatt (kW) of energy, for a duration of approximately 1 millisecond (ms).
The RF emitter 10 is coupled by a flexible transmission cable 12 to the breech 201 of the artillery system. In an embodiment, the RE transmission cable 12 is disposed in place of the mechanically based percussion primer which are typical of currently available artillery systems.
The transmission cable 12 passes through the breech block 203 and is coupled to an antenna 14 disposed in the breech 201. The transmission antenna 14 may be an exposed limited use antenna 14 or can be covered within a rugged, long life ceramic composite structure. However, the radiating antenna 14 structure is not limited to ceramics but may instead use a combination of various conductive and/or dielectric composites, meta-materials or metals to achieve the same result.
The transmission antenna 14 serves as a pressure seal for the breech 201 thereby allowing for the conduction of RF signals into the breech 201 as well as sealing the pressure vessel. The pressure vessel being made of thick steel and completely sealed ensures that no RF energy 16 escapes or places any personnel at risk from exposure.
The breech 201 of the artillery piece 20 serves as a cavity resonator, radiating the RF energy 16 within the breech 201. RF igniter 18 is coupled to a propelling charge residing in the breech 201. The RE igniter 18 receives the electromagnetic energy 16 and converts it to an electric voltage which initiates the ignition chain of the propelling charge. For example, the RE igniter may directly ignite the propelling charge with the converted electromagnetic energy 16 or may comprise an additional initiating charge 181 which is ignited by the converted electromagnetic energy 16 and which in turn initiates the ignition chain of the propelling charge.
As shown in
Upon reception of the RF energy 16 by the RF igniters 18a, n, each RF igniter 18a, n simultaneously ignites their respective propelling charge 205a, n, thereby providing reliable multipoint ignition. Reliable multipoint ignition ensures ballistic predictability for the propelling round. By simultaneously igniting the multiple charges, the premature detonation of subsequent charges in the propulsion chain is negated as may be experienced in traditional rear ignition systems.
In applications employing one or more relatively longer charges in a single case, it may be advantageous to attach multiple RF igniters 18a, n to a single charge to achieve multipoint ignition within the charge. For example, depending on the type and location of the propellant within the charge, multiple RF igniters can ensure simultaneous ignition of all propellant within the charge thereby providing the benefits described above.
Contained Within the first dielectric layer 183 is RF absorption material 187 for converting the electromagnetic energy 16 into heat, A wide variety of materials may be employed, including metallic films, nano-metallic particles, a printed antenna made from conductive inks, metamaterials and fine steel wool. In the embodiment shown in
An initiating charge 181 is disposed between the first dielectric layer 183 and the second dielectric layer 185. In a preferred embodiment, the initiating charge 181 is not impact sensitive but will ignite when exposed to heat from the RF absorption material 187. For example, the initiating charge 181 may be as simple as a black powder mixed with a thermite or some of the more novel compounds such as MIC, (metastable intermolecular composites). In an alternative embodiment, the initiating charge 181 comprises nano-metallics which function as the RF absorption material 187 thereby negating the need for a distinct antenna component.
An adhesive layer 189 is applied to the outer surface of the second dielectric layer 185 for attachment to the propelling charge 205.
In alternative embodiments, the MACS propelling charges include a center core ignition system comprising a printed conductive ink RI′ antenna on the surface of the center core ignition system material. For example, a foamed celluloid center core ignition system may include a printed RF antenna for initiating ignition of the charge.
The ignition of the radio frequency igniter 18 initiates an ignition chain which includes ignition of the preliminary charge (i.e. core igniter bag or center core ignition) in the center core of the propelling charge and ultimately progressing into the main propellant housed in the propelling charge.
In other embodiments of the invention, the RF absorption material is printed or embedded directly onto the charge case. In such an embodiment, the propelling charge is preferably encased in a container formed of a consumable material such as nitrocellulose or foamed celluloid. The antenna can be printed using a conductive ink, such as silver ink on Kapton™. In such an embodiment, the energetic may be printed or deposited directly onto the antenna and sealed in place using a third printing process. For example, in an embodiment for the next generation munition, the antenna may be printed or placed between each bundle of propellant. Alternatively, the RF absorption material may be embedded into the charge container. For example, in a propelling charge encased in foamed celluloid, the foamed celluloid may be formed around the RF absorption material and initiating charge.
This application is a continuation of U.S. patent application Ser. No. 15/478,557 filed on Apr. 4, 2017, since issued as U.S. Pat. No. 10,107,607, the entire file wrapper contents of which application are hereby incorporated by reference as if set forth at length.
The invention described herein may be manufactured, used, and licensed by or for the U.S. Government for U.S. Government purposes.
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Number | Date | Country | |
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Parent | 15478557 | Apr 2017 | US |
Child | 16136493 | US |