Pyrotechnic grenades of a variety of types are known, including flash grenades and smoke grenades. Smoke grenades generate a volume of smoke after initiation, and are principally used for signalling, and concealment of movement. They are used in a variety of contexts, including military, maritime (as distress flares) and recreational (for example, in battle simulation or “paintball” or “airsoft” games).
Typical design consists of a container with emission holes to allow smoke release when the grenade is ignited. The filler consists of smoke composition (typically potassium chlorate, lactose, and a dye). The reaction is exothermic, and considerable heat is generated during smoke release.
To use the grenade, the smoke mixture must be ignited, and this is generally achieved by means of a fuse. Types of fuses known in the art include friction strike fuses, in which a primer button is provided with a cap whose outside surface is partially coated with a friction-ignitable material. This friction-ignitable material is in turn covered with a removable cover provided with a striking plate or section covered with red phosphorus or an abrasive material. To ignite this type of device the user must first remove the cover from the friction-ignitable material. The end of the cover with the scratch material is then rubbed or struck quickly across the friction-ignitable material to ignite the flare mixture.
A further type of ignition mechanism is generally referred to as a pull-wire. One type consists of an elongated tube, having an inner wall coated with friction-ignitable material. A pull-wire runs through the channel and the free end projects out of one end of the tube, while at the other end the wire is attached to a plunger coated with scratch material. To operate the fuse, the user pulls the free end of the wire, causing the plunger to travel down the tube, causing frictional force between the plunger and the friction-ignitable material, and combustion of the latter. This, in turn, ignites a primer charge and ultimately the smoke mixture.
A further type of pull-wire igniter includes a wire which passes through a hole in a metal cup, with one end of the wire coiled or bent adjacent to the open side of the cup, and the other protruding out of the cup and attached to a ring-pull. The cup contains an ignition mixture. On pulling the ring-pull, the wire is pulled through the hole in the ignition mixture and cup straightening it and generating heat through friction, which ignites the ignition mixture.
A problem with both the strike ignition and pull-wire type fuses is that the device is in the hand of the operator when ignition commences. This is a burn hazard for the user, and additionally it may be undesirable in certain circumstances for smoke generation to commence at the location of the operator, who may for tactical reasons desire to throw the device so as not to disclose their location.
One solution to this problem is shown in
The fuse mechanism in the grenade (10) includes a safety pin (11) inserted through a hole (12). The safety pin (11) in the hole (12) holds a safety lever (13) against the side of the grenade body (14). The safety lever (13) in position against the body (14) of the grenade (10) holds a spring loaded lever (15) against the top of the canister containing the smoke material (16). The spring loaded lever (15) is attached to one end of a pull-wire (20), the other end of which forms a coil (17) inside metal cup (18). Metal cup (18) contains a pyrotechnic composition, typically a chlorate/fuel mixture.
Removal of the safety pin (11) permits release of the safety lever (13), which then has to be held against the body (14) of the grenade (10) to prevent ignition. Once the grenade (10) is thrown, the pressure on the safety lever (13) is released, and the spring loaded lever (15) is forced to rotate on its axis by the spring (19), throwing off the safety lever (13). The spring loaded lever (15) then exerts an upward force on the pull-wire (20), forcing the coiled portion (17) through an aperture in the metal cup, which generates heat and in turn ignites the friction-ignitable material and ultimately the smoke material (16).
Although this type of fuse overcomes certain limitations inherent in pull-wire type fuses, it nevertheless has drawbacks. In particular, the force exerted on the pull-wire can be hampered by the safety lever, leading to unreliable ignition. Further, the spring exerts a significant upforce on the safety lever, which can result in a significant “kick” when the primed grenade is thrown, leading to inaccuracies in deployment and potential ignition failures.
In addition, as soon as the safety lever (13) starts to move away from the body of the grenade (14), the spring loaded lever (15) also starts to rotate. If the safety lever (13) is released slowly, the spring loaded lever (15) also rotates slowly pulling the pull-wire (20) with insufficient speed or force to generate sufficient friction to ignite the friction-ignitable material within the metal cup (18). This causes a significant unreliability in the ignition of the smoke material (16).
The present invention seeks to overcome these and other limitations of prior art devices.
According to a first embodiment, there is provided a fuse assembly for igniting a charge, comprising
The safety lever (21) is pivotally attached via pivot (27) sitting within seat (23) to fuse housing (28). The safety lever (21) is held in position by safety pin (30), which passes through the fuse housing (28), and prevents rotation of safety lever (21) about pivot (27).
Striker lever (31) is of generally elongate form, and is provided with a pivot hole (32) towards a first pivoted end (33) and a second free end (34). In the embodiment shown, second free end (34) has a rounded profile.
The striker lever (31) is pivotally attached via pivot (37) passing through pivot hole (32) to fuse housing (28). A torsion spring (38) is wound about pivot (37), and in the configuration shown the torsion spring (38) is held under compression. Striker lever and safety lever (21) pivot about separate points, and in opposite directions. The second free end (34) of the striker lever (31) is in contact with cammed portion (22) of the safety lever, which prevents rotation of striker lever (31) in an upwards direction.
A metal wire (36) is attached at one end to a stud (40) provided on the upper surface of striker lever (31). The wire passes through a hole in a metal cup (41), and has a coiled portion (42) which sits within or below the metal cup (41). Metal cup (41) contains a pyrotechnic mixture (43). The body of the device to which the assembly is attached contains a primer composition (44) and pyrotechnic charge (45).
In use, the operator holds handle (25) against the body of the munition (20), and removes the safety pin (30). The munition is thrown or released, which releases the restraining pressure on handle (25).
Removal of the safety pin (30) and release of the handle (25) enables deployment of the fuse assembly, as shown in
Spring-loaded striker lever (31) is urged upwards by the force of torsion spring (38). Contact between the free end (34) of the striker lever (31) exerts a rotational force on cammed portion (22). The safety lever (21) rotates away from the body of the munition (20). Rapid upward movement of the striker lever (31) is prevented at this stage by contact of the free end (34) with the cammed portion (22).
Further rotation of the safety lever (21) occurs until point A where the cammed portion (22) is no longer in contact with the striker lever. This is shown in
Ultimately, once the safety lever (21) has rotated beyond a certain extent, the free end of the striker lever (31) is no longer in contact with the cammed portion (22), and the striker lever is urged rapidly away from the body of the munition (20). This pulls the coiled portion of the wire through the hole in the metal cup (41). The heat generated causes the pyrotechnic composition (43) to ignite, and ultimately results in ignition of the primer (44) and pyrotechnic charge (45). The safety lever (21) is able to detach from the device. This is shown in
It has been found that the cammed profile of the safety lever results in the constant contact between cam and striker lever (31) during the rotation of the safety lever (21), holding the striker lever (31) in position until the point when the striker lever (31) is suddenly released. The sudden and rapid release of the striker lever (31) rather than gradual release as seen in known devices allows for greater heat generation through friction which allows superior ignition of the fuse mechanism and a lower proportion of fuse mechanism failures and a lower “kick” experienced by the operator. This invention has the added advantage that the rapid release of the striker lever at point A is not dependant on deployment of how the device is deployed, resulting in fewer operator error malfunctions of the munitions.
The fuse is applicable to any type of munition, particularly those which are thrown by hand. Accordingly, the invention also relates to a munition featuring a fuse of the type described. Such munitions include smoke devices, flash devices, explosive devices, tear gas devices, and whistle or other noise-making devices.
Number | Date | Country | Kind |
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1603695.6 | Mar 2016 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2017/050374 | 2/13/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/149270 | 9/8/2017 | WO | A |
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2393861 | Miller | Jan 1946 | A |
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20060278115 | Juy | Dec 2006 | A1 |
Number | Date | Country |
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158004 | Feb 1921 | GB |
837766 | Jun 1960 | GB |
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Entry |
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PCT International Search Report for PCT International Patent Application No. PCT/GB2017/050374, dated Apr. 24, 2017. |
Number | Date | Country | |
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20190049224 A1 | Feb 2019 | US |