The invention relates in general to munitions and in particular to firing and data link interconnections for cannon-fired munitions.
Internally-controlled or “smart” munitions have been used for over twenty-five years. Smart munitions launched by cannons have been in development for about five years. Cannon-launched smart munitions may be, for example, 105 mm cartridge case rounds, 120 mm metal stub base/consumable case rounds, or other rounds fitted with contact rings on their breechblock contacting surfaces. In cannons, the traditional firing circuit and breechblock geometry to support the rear quarter access of the firing circuit is over fifty years old.
Cannon-launched rounds may be electrically fired. That is, an electrical contact on the breechblock of the cannon makes contact with the firing plug on the primer of the round. An electrical current is applied to the primer, creating a spark to ignite the black powder, which ignites the propellant located in the round. A data link, for example, a Universal Munition Data Link (UMDL), can support bi-directional communication and transmission of power to some cannon-launched rounds using a set of two pins. Known cannons that launch smart munitions may use UMDL pins and circuits that are packaged separately and independent of the legacy firing circuit. Legacy firing circuits require breechblocks with relatively complex machined geometry. This geometry may include deeply drilled, tight tolerance (<0.002 inches) holes.
Known smart munitions, such as air-launched missiles and bombs, receive fire control instructions via an electrical cable with a quick-disconnect interconnection that disconnects when the smart munition is launched. The electrical cable (data link) supports electrical power transmission and bi-directional communications for the smart round. However, the design of both smart rounds and cannons do not support the quick-disconnect electrical cable type of interface. It may be possible to wirelessly communicate between the cannon and a smart round, but there are major disadvantages, such as external signal jamming, signal attenuation due to the large mass of the metal cannon surrounding the smart round, and the inability to support the power needs of the smart munition.
Traditional cannon firing circuits utilize complicated links and cams to actuate the firing pin that is in contact with the firing plug on the primer of a round. These firing circuits require extensive slots and cuts in the breechblock, which reduce the structural integrity and fatigue life of the breechblock and introduce numerous tightly toleranced linkage components. If a method similar to the traditional firing circuit were used for a cannon data link device, the resulting circuit would add many slots and cuts to the breechblock. As a result, the breechblock may not function as a part of the pressure vessel of the cannon. In addition, maintenance of the firing circuit, especially the firing pin, is a frequently performed procedure. In known firing circuits, there is no easy access to the firing pin cavity in the front of the breechblock.
One aspect of the invention is a breech assembly for a cannon. The cannon has a barrel with a central longitudinal axis and a breech ring fixed to one end of the barrel. The breech assembly includes a sliding breechblock disposed in the breech ring and translatable in the breech ring in a direction normal to the central longitudinal axis of the barrel. An insert assembly is disposed on a muzzle side of the breechblock and translatable in the breechblock in the direction normal to the central longitudinal axis.
The insert assembly includes a muzzle side, a breech side, and at least one electrical pin module. The insert assembly is removable from the breechblock without removing the breechblock from the breech ring. Mating portions formed on the breechblock and on the insert assembly prevent displacement of the insert assembly with respect to the breechblock in a direction along the central longitudinal axis of the barrel. The mating portions may include slots and rails that are parallel to the direction normal to the central longitudinal axis. The slots may be formed in the breechblock and the rails may be formed on the insert assembly.
The at least one electrical pin module may include a firing pin module and at least one data link module. In an installed position of the insert assembly in the breechblock, the firing pin module may be substantially coaxial with the central longitudinal axis of the barrel. The at least one electrical pin module may include a forward contact biased outwardly through the muzzle side of the insert assembly and a corresponding rear contact biased outwardly through the breech side of the insert assembly. The at least one electrical pin module may include a double-acting spring disposed between the forward and rear contacts. The insert assembly may include a removable cover on the breech side and the rear contacts may penetrate the removable cover.
At least one threaded fastener may fix the insert assembly in the breechblock. The at least one threaded fastener may displace the insert assembly from the breechblock when the fastener is rotated opposite to the fixing direction.
Electrical contacts on the muzzle side of the breechblock may electrically connect with the firing pin module and the at least one data link module, in an installed position of the insert assembly in the breechblock. A flexible circuit board may contain the electrical contacts.
The invention will be better understood, and further objects, features and advantages of the invention will become more apparent from the following description, taken in conjunction with the accompanying drawings.
In the drawings, which are not necessarily to scale, like or corresponding parts are denoted by like or corresponding reference numerals.
A novel cannon breechblock insert assembly uniquely packages the firing circuitry and data link circuitry in an easily removable block for maintenance, cleaning, and replacement. The data link circuitry may include, for example, a Universal Munition Data Link (UMDL). Compared to conventional breechblocks, the novel breechblock: 1) has reduced stress-inducing machined features, thereby increasing the fatigue life of the breechblock; 2) has fewer deep, tight tolerance holes, thereby reducing the machining time and the cost of manufacturing the breechblock; 3) enables removal of the breechblock insert assembly in either the open or closed position of the breechblock; 4) enables quicker access to the firing pin and data link pins for maintenance and replacement procedures; 5) includes hardened pin tips that are in continuous contact with both the base of the cannon round and the breechblock using a spring-loaded translation; 6) accommodates various mechanisms to keep the cannon round from falling back out of the cannon tube chamber after loading; and 7) is expandable so that additional data link circuits may be added for future munition upgrades.
The novel breechblock insert assembly bundles together a data link device (for example, a UMDL) and a cannon's firing circuits into an easily removable part. The UMDL facilitates data and power transmission with the smart munition using the same set of two pins. The firing circuit allows for power to be applied to the primer of the smart munition. The insert assembly may be used for different caliber cannons, breechblock configurations, and munition requirements.
Insert assembly 24 includes a main body 36. Body 36 is generally solid and is made of, for example, a heat-treated steel alloy. A pair of projections or ears 38 may extend from body 36. Threaded fasteners 44 may extend through ears 38 and into threaded openings 42 (
Mating portions are formed on breechblock 22 and on insert assembly 24 to prevent displacement of insert assembly 24 with respect to breechblock 22 in a direction along central longitudinal axis A. In the embodiment shown, the mating portions on insert assembly 24 are opposing rails 32 (
If cannon 10 uses an autoloader, a cartridge catch mechanism 48 may be included to prevent loaded rounds from backing out of barrel 12 in elevated positions.
The interior of insert assembly 24 includes at least one electrical pin module. In the embodiment of
Firing pin module 50 transfers electrical power from a contact 76 (
Data link modules 52 allow for data and power transmission from contacts 78, 80 (
As shown in
Insert assembly 124 includes muzzle and breech sides 128, 130 and opposing rails 132 for mating with opposing slots 134 (
The novel cannon breechblock insert assembly provides an easily accessible and compact package for both the firing contact and the data link contacts needed to fire smart munitions from cannons. The breechblock insert assembly enables the breechblock to be manufactured with many less stress-inducing machined features and fewer deep, tight tolerance holes. Unlike known breechblocks, the novel insert assembly with the firing pin and data link modules contained therein may be removed in either the open or closed position of the breechblock for faster and more efficient access for maintenance and replacement.
While the invention has been described with reference to certain embodiments, numerous changes, alterations and modifications to the described embodiments are possible without departing from the spirit and scope of the invention as defined in the appended claims, and equivalents thereof.
The inventions described herein may be manufactured, used and licensed by or for the United States Government.
Number | Name | Date | Kind |
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4329908 | Rowlands | May 1982 | A |
5233902 | Bernardes | Aug 1993 | A |