The embodiments generally relate to insensitive munitions.
It is to be understood that the foregoing general description and the following detailed description are exemplary and explanatory only and are not to be viewed as being restrictive of the embodiments, as claimed. Further advantages of the embodiments will be apparent after a review of the following detailed description of the disclosed embodiments, which are illustrated schematically in the accompanying drawings and claims.
Embodiments may be understood more readily by reference in the following detailed description taking in connection with the accompanying figures and examples. It is understood that embodiments are not limited to the specific devices, methods, conditions or parameters described and/or shown herein, and that the terminology used herein is for the purpose of describing particular embodiments by way of example only and is not intended to be limiting of the claimed embodiments. Also, as used in the specification and appended claims, the singular forms “a,” “an,” and “the” include the plural.
Embodiments generally relate to insensitive munitions (IM) improvements, especially with respect to cook-off mitigation systems. Some embodiments employ an outgassing pad in the nose of the munition. Additional embodiments employ a releasable (two-part) charging well. Further embodiments combine these approaches with a releasable tail closure mechanism.
Although the embodiments are described in considerable detail, including references to certain versions thereof, other versions are possible. Examples of other versions include orienting and/or attaching components in different fashion. Therefore, the spirit and scope of the appended claims should not be limited to the description of versions included herein.
Components and Materials Used
In the accompanying drawings, like reference numbers indicate like elements.
Reference characters 100, 400, and 500 are used to depict various embodiments. Several views are presented to depict some, though not all, of the possible orientations of the embodiments. Some figures depict section views and, in some instances, partial section views for ease of viewing. The patterning of the section hatching is for illustrative purposes only to aid in viewing and should not be construed as being limiting or directed to a particular material or materials. Unless stated otherwise, components depicted are dimensioned to be close-fitting and to maintain structural integrity both during storage and while in use.
Components used in several embodiments, along with their respective reference characters, are depicted in the drawings. Reference character 100 depicts an outgassing pad. In some embodiments, the outgassing pad 100 includes a shell 102 and an outgassing agent 104, such as a powder and binder mix. The shell 102 can be an elastomeric shell such as silicone, rubber, or silicone-rubber. The outgassing agent 104 is a powder and binder mix. The elastomeric shell 102, may also be referred to as an outgassing shell, container, or bladder, and can be used to house the outgassing agent 104 as a technique for controlled fragmentation, enhanced gas containment, and as a reduction in compatibility concerns. A person having ordinary skill in the art will recognize the term compatibility concerns to be synonymous with assuring that chemicals coming in contact with an explosive fill are chemically compatible.
In other embodiments, the shell 102 can be a non-elastomeric shell such as plastic. In yet other embodiments, the shell 102 can be eliminated. In embodiments without a shell 102, the outgassing pad 100 is the outgassing agent 104, as discussed further below. The surface contours of the outgassing pad (reference character 100) with a shell (reference character 102) as well as the outgassing pad without the shell are the same. Section views best illustrate the outgassing pad 100 embodiments. Generically, the outgassing pad is depicted with reference character 100. Reference character 100A depicts the section view of an outgassing pad with a shell, as shown in
The shell 102 has unique geometrical configurations, including surface contours having a sigmoid shape, ogee shape, or a cyma recta shape. A person having ordinary skill in the art will recognize that ogee and cyma recta are understood to be types of sigmoid shapes. A person having ordinary skill in the art will recognize that a sigmoid shape is a shape similar to the letter S. Likewise, a person having ordinary skill in the art will recognize that an ogee shape is descriptive of an S-shape and, moreover, is characteristic of two curves meeting at a point. Additionally, a person having ordinary skill in the art will recognize that a cyma recta shape is descriptive of double curvature, combining both convex and concave features. A person having ordinary skill in the art will also recognize, after viewing
Likewise, the surface contour shapes are also applicable to the embodiment depicted in
Selection of the outgassing agent 104 is based on several factors including volume-to-mass ratio of decomposition products, activation temperature, compatibility and stability, cost, material availability, and environmental concerns. The outgassing agent 104 is a powder-binder mix. Suitable powders for the outgassing agent 104 include a blowing agent mixed with an activator. Suitable blowing agents include oxydibenzenesulfonyl hydrazide (OBSH) or azodicarbonamide (ADC), due to their cell structures. The blowing agent is mixed with the activator to tune the decomposition temperature and rate. In the embodiments, zinc oxide is a suitable activator. Depending on application-specific requirements, other activators can also be used. Additionally, in other embodiments, an activator may not be needed depending on the blowing agent selected or other system requirements. Suitable binders for the outgassing agent 104 include wax, tar, or an energetic binder. Binder formation includes melt cast methods for waxes, cast-curing from a mold, and press-molding for the powder-binder mixes.
In the unconfined embodiment (100B in
The powders in the outgassing agents 104 will compact appreciably during target penetration, which is undesirable. Adding the binder to create a powder-binder mix eliminates this concern because the binder fills the void spaces between the particles of the powder which constitutes the powder, thus reducing the compaction. The mixture of the powder-binder is determined based on application-specific conditions. In some embodiments, the powder (azodicarbonamide and zinc oxide) is a range of about 66 to about 68 percent and the binder is 30 percent. The variation in constituents is from varying percentages of additive(s) used to tune the peak exothermal temperature.
Instances having different ranges are also possible and can be dependent on the processing of the material such as particle size, particle geometry, packing fraction, and wettability. Additionally, the cost of manufacturing/processing the material can drive one process over another which can correspondingly change the requisite ranges. Based on this, in other embodiments, the range is about 60 percent to about 70 percent powder, and a binder range of about 30 to about 40 percent, with the remaining constituents being additive(s) used to tune the peak exothermal temperature. Likewise, when tuning the powder-binder mix to expel a munition's explosive billet, the unique characteristics of that specific munition can drive the percentages. As such, a larger/different range can be beneficial in addressing the maintaining of the mass properties of a munition system by adjusting the powder-binder mixture to closely match the density of the munition's main explosive billet, thus avoiding changes to flight or performance characteristics.
Reference character 400 depicts a charging well that is housed entirely in the munition casing 504, with no portion inside the explosive fill. The charging well 400 employs a charging well component 408, fasteners 414, a cutting device 415, sometimes referred to as a cutter, knife blade or other variation, and a eutectic charging tube extension 413. The charging well component 408 is generically depicted because the embodiments are applicable to a variety of charging well components without detracting from the merits or generalities of the embodiments. The charging well component 408 is contoured to match the munition case 504 interior contours, defined by a cavity 402 in the munition case 504. Additionally, a person having ordinary skill in the art will recognize the specific components used in charging wells. The charging well component 408 is a structural material and, in most embodiments, is steel. A protective liner 411 is shown in some embodiments. Suitable liner materials include asphaltic hot melt, wax coating, and plastic.
Additional components are shown for orientation purposes and to assist in understanding operating environments. In particular,
Apparatus and System Embodiments
An outgassing pad for cook-off mitigation is depicted by reference character 100 in
Referring to
Outgassing pad 100 positioning and, therefore, the shell 102, such as in the embodiment depicted in
The shell 102 has at least two sides 210A & 212A, synonymous with the first and second portions mentioned above, that are diametrically-opposed to each other with one of the two sides being adjacent to the interior nose end 510 of the munition 502. Viewing
Similarly, the outgassing pad without a shell (reference character 100B in
Referring to
Referring to both
Referring to
An explosive fill 508 is generically shown in
The cutter/cutting device 415 is positioned adjacent to the eutectic charge tube extension 413 and is attached to the charging well component 408 by fasteners 414. Other attachment methods can be used including adhesives. The eutectic melt temperature of the eutectic charging tube extension 413 is less than the outgassing temperature of the outgassing agent. The cutter/cutting device 415 is held in a fixed position and is configured to cut the cable(s) inside the conduit 518 and eutectic charge tube extension 413 after the eutectic charge tube extension has melted during a cook-off event. This prevents the cable(s), conduit 518, and any portion of the eutectic charging tube extension 413 remaining to move toward the tail end 505.
Void spaces 420A & 420B are shown in
A spring ring 618 is concentric about the eutectic ring 610. The spring ring 618 has a slot 620 that is dimensioned to engage the rib 616 on the eutectic ring 610. Suitable materials for the spring ring 618 include steel and spring back steel. The rib 616 and slot 620 engagement prevents axial movement of the spring ring 618 about the eutectic ring 610. A retainer ring 622 has a plurality of apertures 624 that are thru-holes in the retainer ring. Suitable materials for the retainer ring 622 include steel. When assembled, the retainer ring 622 is abutted against the hub ring 602, the eutectic ring 610, and the spring ring 618. A plurality of screws 626 fasten the retainer ring 622, the spring ring 618, the eutectic ring 610, and the hub ring 602 together by being inserted through the plurality of apertures 624, through the retainer ring 622, and into the plurality of threaded recesses 608 on the distal side 606 of the hub ring 602. The screws 626 can be steel or steel alloy cap screws.
Theory of Operation
Outgassing pad 100 positioning in the interior nose end 510 in conjunction with the defined geometry, described herein, aids in containing decomposition products to more effectively control the expulsion of explosive billet 508 out of the munition 502 after the release of the tail closure mechanism 512 and charging tube extension 413. Less outgassing agent 104 can be used and provides for a more focused outgassing environment. Outgassing agent 104 quantity can change due to the quantity of gases needed to expel the explosive billet 508. Positioning the outgassing pad 100 in the nose end 503 of the munition 502 reduces the risk of shock initiation of the explosive fill 508 in hard target penetration munitions.
The outgassing pad 100 location, geometry, and outgassing agent 104 selection is based on the anticipated gaseous products and reaction temperature for a specific munition. Employing an elastomeric shell 102 allows contained expansion and uniform pressure upon the explosive billet 508 until the elastomeric shell ruptures. Decomposition of the outgassing agent 104 occurs prior to reaction of the explosive fill (at a temperature range of about 280 degrees F. to about 320 degrees F. for some explosive fills and about 280 degrees F. to 350 degrees F. for other explosive fills).
The selected shape of the outgassing pad 100 is such that it expands as a wedge and obturates the explosive fill 508. One having ordinary skill in the art will recognize that obturate is a term for sealing by expanding. Thus, the outgassing pad 100 expands as a wedge and further expands the portion of the explosive billet 508 at the interior nose end 510 against the interior wall 506, further sealing the expanding gas at rupture. Silicone is used for the elastomeric shell 102 to allow for contained expansion at elevated temperatures and uniform pressure upon the explosive billet 508 until the elastomeric shell ruptures.
To avoid possible detrimental fragmentation effects to the nose end 503 of the munition 502, the outgassing pad 100 and, especially the elastomeric shell 102, can also contain fragmentation control patterns to contour the explosive charge and influence preferential fragmentation. With the internal pressure created by the outgassing agent 104, the explosive billet 508 can be expelled from the munition 502 using the releasable tail closure mechanism 512 prior to ignition of the explosive billet. Thermal release of the eutectic devices occurs at a range of about 280 degrees F. to about 320 degrees F. This allows the explosive billet 508 to burn totally unconfined, thus producing a passing reaction by reducing the severity of the munition reaction to standardized IM cook-off testing, often referred to as slow cook-off (SCO) and fast cook-off (FCO). The cook-off temperatures are greater than the munition's operational temperatures. One skilled in the art will recognize that insensitive munitions testing includes identifying the system's response to standardized testing. Munitions responses are assessed depending on multiple variables and an acceptable reaction, sometimes referred to as a passing reaction or passing test.
The charging well 400 is configured to remain functional at operational temperatures but weaken at cook-off temperatures, allowing for the unimpeded expulsion of the explosive billet 508. The eutectic charge tube extension 413 is a eutectic material, that maintains structural integrity of the eutectic charge tube extension during operation through munition 502 impact, but will soften and/or melt before the outgassing pad 100 outgasses. The eutectic charge tube extension 413 in one embodiment is bismuth, tin, and indium. In other embodiments, the charge tube extension 413 does not have to be eutectic provided that it softens at a high temperature, such as a polymer. The cutting device 415 will cut the eutectic charge tube extension 413 (if needed) and cables (not shown) in the conduit 518 as the explosive billet 508 is pushed toward the tail end 505 of the munition case 504 when the outgassing pad 100 outgases. Additionally, the entire charging well cavity 402 and component 408 is outside of the explosive billet 508, as shown in
In an embodiment employing an unconfined/uncanistered outgassing pad 100B, as depicted in
The sealing device 700 can be used to reduce leakage of gas and to push the explosive billet 508. A steel ring holder 701 with O-Ring 702 pushed all the way to the forward transition between the full inside diameter and ogive of the munition case 504 before the protective liner 411 is applied. The location of the sealing device 700 is at the transition of the interior wall 506 from being straight (having a constant internal diameter) to the portion of the interior wall having a tapered internal diameter due to the ogive shape of the munition 502. The sealing device 700 is as an extra safety measure in case the outgassing pad 100 does not expand as a wedge. In those instances, the sealing device 700 will obturate and influence the explosive billet 508 to move to the tail end 505 during cookoff events.
While the embodiments have been described, disclosed, illustrated and shown in various terms of certain embodiments or modifications which it has presumed in practice, the scope of the embodiments is not intended to be, nor should it be deemed to be, limited thereby and such other modifications or embodiments as may be suggested by the teachings herein are particularly reserved especially as they fall within the breadth and scope of the claims here appended.
The invention described herein may be manufactured and used by or for the government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
Number | Name | Date | Kind |
---|---|---|---|
5786544 | Gill | Jul 1998 | A |
5813219 | Gill | Sep 1998 | A |
5939662 | Bootes | Aug 1999 | A |
6523477 | Brooks | Feb 2003 | B1 |
6615737 | Bonnel | Sep 2003 | B2 |
6619029 | Solberg | Sep 2003 | B2 |
6752085 | Roach | Jun 2004 | B2 |
7353755 | Aumasson | Apr 2008 | B2 |
7472653 | Hays | Jan 2009 | B1 |
7930975 | Cotet | Apr 2011 | B2 |
9829297 | Graswald | Nov 2017 | B2 |
10088285 | Hardt | Oct 2018 | B1 |
10101139 | Hardt | Oct 2018 | B1 |
10175034 | Hardt | Jan 2019 | B1 |
10228223 | Hardt | Mar 2019 | B1 |
20060016360 | Eches | Jan 2006 | A1 |
20060081149 | Salizzoni | Apr 2006 | A1 |
Number | Date | Country | |
---|---|---|---|
Parent | 15380679 | Dec 2016 | US |
Child | 16113786 | US |