PL207163B1 - Plate impeller mechanism, especially for securing and fusing of impact fuse with automatic delay adjustment - Google Patents

Description

Description of the invention

The subject of the invention is a disc rotor mechanism, in particular for securing and arming an impact fuse with automatic delay adjustment. A disc rotor mechanism for securing and setting up ammunition fuses is not known to date.

A disc rotor mechanism, especially for securing and setting up an impact fuse with automatic delay adjustment, according to the invention, is characterized in that it comprises a disc rotor with an axis of rotation perpendicular to the front plane of the rotor, a spring driving the disc rotor, a sliding element that blocks the movement of the rotor under tension, o an axis parallel to the axis of the disc rotor, an additional movable element blocking the movement of the rotor under tension, with an axis perpendicular to the axis of the disc rotor, and has holes in the lower part to unlock another cooperating mechanism.

The spring driving the disc rotor is a taut spiral spring, a sliding element blocking the movement of the rotor under tension, with an axis parallel to the axis of the disc rotor, a bolt with a cap safety device, and an additional movable element blocking the movement of the rotor under tension, with an axis perpendicular to the axis of the rotor plate, there is a centrifugal bolt with a flat spring and a fixing screw. The rotor disc mechanism also has a movement limiter cooperating with a circumferential groove, and the openings for securing another cooperating mechanism are located axially on the inner cylindrical surface of the seat with the inner abutment surface.

In its upper part, the disc rotor has a spindle with a groove in which the spring driving the disc rotor is mounted, and in its lower part it has an outer abutment surface, and in the circumferential, outer surface of the disc rotor, it has an opening cooperating with the bolt with a hood fuse and an opening cooperating with a centrifugal bolt, and the disc rotor driving spring has fastening means and a cover.

The subject matter of the invention has been shown in the embodiment in the drawing, in which fig. 1 shows a rotary disk mechanism for securing and arming a mechanical impact fuse with automatic delay adjustment, in general view, fig. 2 - the mechanism from fig. 1 in longitudinal section, placed in fuse body and fig. 3 the mechanism of fig. 1 in longitudinal section in a plane perpendicular to the section plane of fig. 2.

As shown in the figure, a disc rotor mechanism for securing and arming a mechanical impact fuse with automatic delay adjustment consists of a disc rotor 1 with an axis of rotation perpendicular to the front plane of this rotor 1, coinciding with the longitudinal axis of the fuse, spiral spring 2 of the rotor, cover 3 , a bolt 4 with a safety catch 5, a centrifugal bolt 6 with a flat spring 7 and a screw 8 and a travel stop 9. In its upper part, the disc rotor 1 has a pin with a groove in which a spiral spring 2 is mounted, and in its lower part it has a stop surface 10, which rests against the fuse body and has a seat with an abutment surface 11 which bears against the spike holder of the fuze firing mechanism. Moreover, in the lower part, the disk rotor 1 has two opposite axial holes 12 and a circumferential groove 13 cooperating with the travel stop 9. In the side surface of the disk rotor 1 there is a hole cooperating with the bolt 4 and an hole cooperating with the centrifugal bolt 6. The spiral spring 2 of the disk rotor it has two rivets 14 securing it to the fuse body.

After the spiral spring 2 of the disc rotor 1 is tensioned, the whole system is blocked by the bolt 4 and secured with the centrifugal bolt 6. Bolt 4 is supported on the safety catch 5 and cannot unlock it until it is subjected to an axial inertia force. The centrifugal bolt 6 rests on the arm of a flat spring 7, fixed to the hull with a screw 8.

When the fuze is in the secured (transport) state, the disc rotor 1 is in a tensioned condition and is able to perform a rotary motion due to the tensioned spiral spring 2 of the rotor. However, it is locked by a bolt 4 and secured by a centrifugal bolt 6. In the tensioned and locked condition, the disk rotor 1 is positioned such that its two opposite openings 12 do not coincide with the protrusions of the ring securing the fuse's firing mechanism before its unlocking.

At the moment of the shot, when the fuse begins to be affected by an axial force and the inertia directed along the longitudinal axis of the fuse and the rotating disc mechanism, it causes movement

The bolt 4, which pierces its lower part with a smaller diameter, the safety catch 5 and remains in the lower position. The disc rotor 1 cannot rotate in relation to the fuse body under the influence of rotational inertia and the torque of the spiral spring 2, because it is affected by an axial force of inertia pressing it against the fuse body and is additionally immobilized by a centrifugal bolt 6.

This is due to the moment of the frictional forces between the rotor 1 and the fuse body and the firing pin holder which is greater than the torque of the spiral spring and the torque of rotational inertia.

As soon as the projectile cuts with its ring leading into the thread of the barrel, it begins to rotate and centrifugal force begins to act on the elements of the fuse. When its structurally assumed values are reached, the movement begins with the centrifugal bolt 6 blocking the movement of the rotor 1. The centrifugal bolt 6 deflects under the influence of centrifugal force the arm of the flat spring 7. At this point, the rotor 1 is completely unlocked - two independent security levels have been removed. As long as the projectile is in the barrel, the rotor 1 rotates together with the entire fuse.

After the projectile exits the barrel, it is affected by the force of the gunpowder gas effect. Accordingly, the elements of the fuse are still subject to an axial inertia force and the rotor 1 cannot rotate under the influence of the spiral spring. The centrifugal bolt 6 is all the time deflected by the centrifugal force.

When the post-exhaust effect of the gunpowder gases on the bottom of the projectile ceases, the axial inertia force present at the moment of the shot phenomenon disappears and the torque is greater than the moment of frictional forces. At this point, the rotor 1 starts the movement under the influence of the spring. The rotor 1, under the influence of the helical spring 2 of the rotor, turns through an angle of 160 ° and stops in the extreme second position, bearing the end of the circumferential groove 13 against the projection of the movement limiter 9. In this position, the rotor 1, its the two opposite holes 12 overlap with the two opposite projections of the ring securing the fuse's firing mechanism, making it possible to unlock it.

The parameters of the helical spring 2 of the rotor are selected in such a way that, taking into account the technical parameters of the rotor 1, the friction force, the travel distance and the time of the post-exhaust effect of the gunpowder gases, the time of rotor 1 rotation from the moment of the onset of the shot to the moment of arming is from 40 to 50 ms. This is the time that guarantees arming the fuse at a given distance.

Claims (9)

Patent claims A disc rotor mechanism, in particular for securing and setting up an impact fuse with automatic delay control, characterized in that it comprises a disc rotor (1) with an axis of rotation perpendicular to the face of the rotor (1), a spring (2) driving the disc rotor (1) ), a sliding element (4) blocking the movement of the rotor in the tensioned state, with an axis parallel to the axis of the disc rotor (1), an additional movable element (6) blocking the movement of the rotor under tension, with an axis perpendicular to the axis of the disc rotor (1) and has in the lower part, holes (12) unlocking another cooperating mechanism. 2. A rotor plate mechanism according to claim 1. Device according to claim 1, characterized in that the spring (2) driving the disc rotor (1) is a biased spiral spring. 3. A rotor plate mechanism according to claim 1. A bolt according to claim 1, characterized in that its sliding element (4) blocking the movement of the rotor in the tensioned state, with an axis parallel to the axis of the disc rotor (1), is a bolt with a safety catch (5). 4. A rotor plate mechanism according to claim 1. A centrifugal bolt (6) with a flat spring (7) and a fastening screw (8) as an additional movable element (6) blocking the movement of the rotor in the tensioned state, with an axis perpendicular to the axis of the disc rotor (1). 5. A rotor plate mechanism according to claim 1. A travel stop (9) for engaging a circumferential groove (13) as claimed in claim 1. A rotor plate mechanism according to claim 1. A device as claimed in claim 1, characterized in that the openings (12) for unlocking the other cooperating mechanism are arranged axially on the inner cylindrical surface of the seat with the inner abutment surface (11). PL 207 163 B1 A rotor plate mechanism according to claim 1. Device according to claim 1, characterized in that the disc rotor (1) has in its upper part a pin with a groove in which the spring (2) driving the disc rotor (1) is mounted, and in its lower part it has an outer abutment surface (10). 8. A rotor plate mechanism according to claim 1. A device according to claim 1, characterized in that in the circumferential, outer surface of the disc rotor (1) it has an opening cooperating with the bolt (4) with a cap safety lock (5) and an opening cooperating with the centrifugal bolt (6), and the spring (2) driving the disc rotor (1) ) has fasteners (14). 9. A rotor plate mechanism according to claim 1. The apparatus of claim 1, characterized in that it has a cover (3).