Dual safety fuze for grenade

Abstract

A hand grenade fuze includes a secondary safety feature in the form of a trigger pin inserted through the striker lever. One end of the trigger pin has an undercut portion. A slide bar is disposed in the fuze body and has a keyhole opening at one end for selectively engaging the undercut portion of the trigger pin. A trigger has one end connected to the slide bar and another end rotatably fixed to the fuze body. A spring biases the trigger away from the fuze body. When the trigger is depressed, the slide bar translates and releases the trigger pin, which releases the restraint on the striker lever.

Claims

1. A grenade fuze, comprising: a fuze body; a striker lever rotatably mounted to the fuze body; a rotor assembly rotatably mounted to the fuze body; a spring that torsionally biases the rotor assembly; a pull ring having a pull pin that is inserted through the striker lever to restrain rotation of the striker lever and the rotor assembly; a trigger pin having a longitudinal axis and inserted through the striker lever to restrain rotation of the striker lever, one end of the trigger pin including an undercut portion; a slide bar disposed in the fuze body and having a keyhole opening at one end for selectively engaging the undercut portion of the trigger pin; a trigger having one end connected to the slide bar and another end rotatably fixed to the fuze body; and a second spring that biases the trigger away from the fuze body.

2. The fuze of claim 1, wherein the keyhole opening includes a small opening and a large opening and further wherein engagement of the undercut portion of the trigger pin with the small opening restrains translation of the trigger pin with respect to the slide bar in a direction along the longitudinal axis of the trigger pin.

3. The fuze of claim 2, wherein placement of the trigger pin in the large opening of the keyhole opening does not restrain translation of the trigger pin with respect to the slide bar in the direction along the longitudinal axis of the trigger pin.

4. The fuze of claim 1, wherein, in an unactuated position of the trigger, the slide bar prevents translation of the trigger pin with respect to the slide bar in the direction along the longitudinal axis of the trigger pin.

5. The fuze of claim 4, wherein, when the trigger is depressed, the slide bar does not prevent translation of the trigger pin with respect to the slide bar in the direction along the longitudinal axis of the trigger pin.

6. A method of activating a grenade fuze, comprising: providing the grenade fuze of claim 1; depressing the trigger; and removing the pull pin from the striker lever.

7. The method of claim 6, wherein depressing the trigger includes translating the slide bar such that the undercut portion of the trigger pin is disengaged from a smaller opening of the keyhole opening.

8. A grenade fuze, comprising: a fuze body; a striker lever rotatably mounted to the fuze body; a rotor assembly rotatably mounted to the fuze body; a spring that torsionally biases the rotor assembly; a translatable trigger pin having a longitudinal axis and inserted through the striker lever to restrain rotation of the striker lever, one end of the trigger pin including an undercut portion; a translatable slide bar disposed in the fuze body and having a keyhole opening at one end for selectively engaging the undercut portion of the trigger pin, the keyhole opening including a small opening and a large opening; a trigger having one end connected to the slide bar and another end rotatably fixed to the fuze body; and a second spring that biases the trigger away from the fuze body; wherein engagement of the undercut portion of the trigger pin with the small opening restrains translation of the trigger pin with respect to the slide bar in a direction along the longitudinal axis of the trigger pin and wherein placement of the trigger pin in the large opening of the keyhole opening does not restrain translation of the trigger pin with respect to the slide bar in the direction along the longitudinal axis of the trigger pin.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the drawings, which are not necessarily to scale, like or corresponding parts are denoted by like or corresponding reference numerals.

(2) FIG. 1 is a side sectional view of one embodiment of a novel grenade fuze assembly in a safe or unarmed state.

(3) FIG. 2 is a perspective view of the grenade fuze assembly.

(4) FIG. 3 is a perspective view showing the striker lever in rotation.

(5) FIG. 4 is an enlarged view of a trigger pin and slide bar.

(6) FIG. 5 is an enlarged view showing the trigger pin in a locked position in the slide bar.

(7) FIG. 6 is an enlarged view showing the trigger pin in an unlocked position in the slide bar.

DETAILED DESCRIPTION

(8) A novel grenade fuze includes dual safety features. The dual safety features include a fuze pull ring, such as a conventional fuze pull ring, and a secondary safety feature. The secondary safety feature operates in parallel with the pull ring to restrain the fuze lever in its safe position. The safe position of the fuze lever is the position of the fuze lever when the pull ring has not been removed and the secondary safety feature is engaged.

(9) FIG. 1 is a side sectional view and FIG. 2 is a perspective view of one embodiment of a novel grenade fuze assembly 10 in a safe (unarmed) state. Fuze assembly 10 includes a fuze body 12 with a striker lever 14 rotatably mounted thereon. A rotor assembly 16 including a firing pin 18 is rotatably mounted to body 12. A spring 20 torsionally biases rotor assembly 16 and striker lever 14 in a counterclockwise direction (as viewed in FIG. 1). Lever 14 and rotor assembly 16 are restrained from rotation by a pull pin 22 fixed to a pull ring 24. Lever 14 is also restrained from rotation by a trigger pin 26 inserted through the lever 14. When the pull pin 22 is removed and the trigger pin 26 is released, the firing pin 18 will rotate counterclockwise and impact the primer 28, thereby beginning the explosive initiation sequence of the grenade (see FIG. 3).

(10) The construction and operation of the pull pin 22 and pull ring 24 are known.

(11) The trigger pin 26 is inserted through the lever 14 and the fuze body 12. As seen in FIGS. 3-6, one end 30 of the trigger pin 26 engages one end of a translatable slide bar 32. The other end of the slide bar 32 engages one end of a trigger 34. Another end of trigger 34 is rotatably fixed to fuze body 12 by, for example, pivot pins 36. A spring 38 is disposed between fuze body 12 and trigger 34. Spring 38 biases trigger 34 away from fuze body 12. Trigger 34 is preferably located on the side of fuze body 12 opposite the side of strike lever 14 so the user can grip the strike lever 14 in the palm of the hand and simultaneously use a finger to operate trigger 34.

(12) Slide bar 32 includes a keyhole opening 40 having a small opening 42 and a large opening 44. End 30 of trigger pin 26 includes an undercut portion 46. Undercut portion 46 has a diameter small enough to fit in small opening 42 and the non-undercut portion of trigger pin 26 is too large to fit in small opening 42. When undercut portion 46 is disposed in small opening 42 (FIG. 5), translation of trigger pin 26 with respect to the slide bar 32 in the direction along the longitudinal axis A of the trigger pin 26 is restrained. In a safe or unactuated position of the fuze assembly 10, undercut portion 46 is inserted in small opening 42. The safe position is maintained by the bias of spring 38 on trigger 34.

(13) When trigger 34 is depressed against spring 38, slide bar 32 translates and trigger pin 26 is positioned in large opening 44 of slide bar 32 (FIG. 6). With trigger pin 26 in large opening 44, trigger pin 26 is no longer locked to bar 32 and is free to translate out of large opening 44 and out of slide bar 32 (FIG. 4). Trigger 34 may be depressed by a user's finger.

(14) To arm the fuze assembly 10, trigger 34 is squeezed or depressed so that trigger pin 26 is released from slide bar 32. Then, pull ring 24 is pulled. With trigger 34 depressed and pull ring 24 pulled, the user may release lever 14 by, for example, throwing the grenade. When lever 14 is released (FIG. 3), lever 14 and rotor assembly 16 are free to rotate so that firing pin 18 rotates and impacts primer 28. If the trigger 34 is not depressed and pull ring 24 is pulled, the lever 14 and rotor assembly 16 cannot rotate because of the restraint of trigger pin 26. The trigger pin 26 is a secondary safety feature for the fuze assembly 10.

(15) 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.