The present invention relates in general to the field of devices for disarming bombs and ordnance. In particular, the present invention relates to an adapter that enables projectiles of different sizes to be used in a single dearmer.
One technique for rendering an explosive ordnance device safe is to de-arm that device by rendering its fuze mechanism inoperative. This can be accomplished by destroying or damaging that fuze mechanism so that its firing pin will not be able to contact the detonator device. In this manner, the detonator will not set off the warhead of the ordnance device. De-arming an explosive ordnance in this manner requires the propulsion of a fuze destroying device against the fuze, with enough power to sufficiently damage the fuze and render it inoperative.
This result is generally accomplished by firing a projectile (or a slug) from a dearmer aimed, for example, at the fuze of the target, with enough velocity to impact a portion of the fuze extending out over the ordnance case. This impact bends the whole fuze body rendering the firing pin movement impossible, or in some cases, actually decapitating a portion of the ordnance item.
Currently available dearmers (de-armers or disrupters) are designed to be exclusively used with projectiles of predetermined sizes. As more clearly illustrated in
What is therefore needed is an adapter that enables projectiles of different sizes to be used in a single dearmer. The adapter should allow the dearmer to impart the appropriate amount of energy to the various projectiles, in order to propel them along the properly orientation. Furthermore, the adapter should guide the projectile toward the target. However, the adapter itself should not impart significant energy or damage to the target. Prior to the advent of the present invention, the need for such an adapter has heretofore remained unsatisfied.
The present invention satisfies this need, and describes a multi-petal adapter for use in conjunction with a dearmer. The adapter enables projectiles of different sizes to be used in a single dearmer. The adapter includes a plurality of petals that are secured, in a detachable way, to a base.
The main function of the base is to secure the petals until the projectile is fired from the dearmer. Whereupon, the adapter will start petalling until the petals become detached from the base, so that the adapter imparts minimal or no energy or damage to the intended target.
The adapter fully regulates the energy imparted to the various projectiles, by allowing propellant gases to bleed through channels that are formed between the petals. As a result, the present adapter fully supports a proper projectile launch and ensures its proper orientation toward the target.
The above and other features of the present invention and the manner of attaining them, will become apparent, and the invention itself will be best understood, by reference to the following description and the accompanying drawings, wherein:
Similar numerals refer to similar elements in the drawings. It should be understood that the sizes of the different components in the figures are not necessarily in exact proportion or to scale, and are shown for visual clarity and for the purpose of explanation.
A dearmer 100 of the present invention and its methods of assembly and use will now be described with reference to
In this particular example, which is shown for illustration purpose only, it is desired to use a projectile (or slug) 160 having a ⅜-inch outer diameter, in a larger size body 120 with a 1-inch inner diameter forward bore 125. It is further desired to use a cartridge case 140 of a uniform caliber that can be used to propel projectiles 160 of different sizes, without compromising the efficiency of the dearmer 100.
The cartridge case 140 is inserted into a rearward bore 840 inside the body 120, through the aft end 124, and is then threadably locked in position with a breech 180. The projectile 160 is fitted into a multi-petal adapter 111, and the projectile (160)/adapter (111) assembly is then inserted into the body 120, through the forward end 122.
Considering now the adapter 111 in greater detail with respect to
The petals 501, 502, 503, are secured at their aft ends to a base 555. While in this particular example, the base 555 is shown as being cylindrically shaped, it should be clear that the dimensions and shape of the base 555 may vary. In the present illustration, the outer diameter of the base 555 is approximately 0.415 inch, and its height is approximately 0.125 inch.
The main function of the base 555 is to secure the three petals 501, 502, 503, until the projectile 160 is fired from the dearmer 100 or until the projectile 160 impacts a target 900 (
An important feature of the adapter 111 is to allow some propellant gases to bleed (or escape) through the adapter 111, upon firing of the cartridge case 140, in order to control the energy imparted onto the projectile 160 (via the adapter 111). To achieve this goal, the three petals 501, 502, 503 are separated by three axial gas escape channels 511, 512, 513, so that the adjacent petals (e.g., 501, 502) are separated by a channel (e.g., 511). In the present illustration, the width of each channel is constant along its entire length and is approximately 0.125 inch.
Considering now an exemplary design of the representative petal 501, in connection with
The petal 501 further includes two generally similar, flat external sides 560 and 561 that extend from the arcuate front edge 562 to a flat bottom edge 570 (
The arcuate front edge 562 extends internally, downwardly, toward the bottom edge 570, into a flared flange 564 that is defined by two sides 574, 576, and that terminates in an internal arcuate edge 572. The angle of inclination, a, between the arcuate front edge 562 and each side 574, 576 is approximately 45°.
As further illustrated in
The internal arcuate edge 572 defines, in combination with the corresponding internal arcuate edges of the other two petals 502, 503, and the gas escape channels 511, 512, 513, the inner diameter of the adapter 111. In this illustration, the inner diameter of the adapter 111 is approximately 0.375 inch, in order to accommodate the ⅜-inch outer diameter projectile 160.
The two external sides 560, 561 and the flared flange 572 extend internally, into an arcuately shaped, bore section 568. The bore section 568 along with the bore sections of the other two petals 502, 503, form an inner chamber 800 (
In a preferred embodiment, the adapter 111 is made of heat and pressure resistant material, such as polymers. It should however be understood that other suitable material may alternatively be used.
The adapter 111 may be made as an integral unit, by machining or molding. With reference to
The assembly of the adapter 111 within the dearmer 100 will now be described in connection with
In this position, and as illustrated in
When the projectile (160)/adapter (111) assembly is secured within the body 120, the adapter 111 defines an internal energy release chamber 890 within the cavity 850. One of the functions of the energy release chamber 890, in combination with the channels 511, 512, 513, is to reduce the pressure behind the adapter 111, in order to further control the exit velocity of the adapter 111 and consequently that of the projectile 160.
By manually reducing or expanding the volume of the energy release chamber 890, the user is capable of regulating the amount of energy imparted to the projectile 160. As an example, if the projectile 160 has much smaller dimensions than the projectile for which the bore 800 was dimensioned, the energy required to propel the projectile 160 would need to be minimized. The volume of the energy release chamber 890 is controlled by the seating position of the adapter 111 in the body 120. As a result, the user has the option to either expand or reduce the volume of the energy release chamber 890 by changing the seating position of the adapter 111. This provides a controllable degree of adjustment of the chamber volume which affects the exit velocity of the projectile (160)/adapter (111) assembly.
The operation or use of the dearmer 100 of the present invention, will now be described with further reference to
In a preferred embodiment, when the air contacts the funnel 888, the petals 501, 502, 503 start to pivot outwardly, about the 700, until the time of impact of the projectile 160 with the target 900. It is possible that during flight, some or all the petals 501, 502, 503 become detached from the base 555; however, in the preferred embodiment, it the impact shock causes all the petals 501, 502, 503 that have not already broken away from the base 555 during flight, to separate therefrom at the attachment section 700.
In the present embodiment, the bore 850 of the body 120 is smooth, and the petals 501, 502, 503 are designed with corresponding smooth outer surfaces. It should however be clear that, in order to accommodate rifled bores, rifling grooves could be cut into the petals 501, 502, 503 of the adapter 111. These grooves, when used in a rifled disruptor or dearmer 100, will impart spin to the adapter 111 and slug 160 during flight.
Although the present safety dearmer 100 has been described in connection with one exemplary application, it should be clear that the dearmer 100 may have multiple commercial applications, including but not limited to law enforcement.
The invention described herein may be manufactured and used by, or for the Government of the United States for governmental purposes without the payment of any royalties thereon.
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