RU2512041C1 - Projectile fin - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to military equipment, particularly to guided projectiles. Proposed fin includes a shell, vanes mounted on pins in the shell, and locking device. Locking device includes case, front cover, inertial load with a through orifice where a central screw is installed and fixated by a nut at the cover side, and recoil springs placed in blind holes of inertial load as thrusts between the inertial load and central screw cap. At the front end of central screw cap, an annular pad out of easily deformable material is installed with cylindrical grooves on its side surface, where recoil springs propped against the front end of central screw cap are placed. External diameter value of the nut prevents cap deformation under a force applied onto the nut by inertial impact on central screw cap, and nut height for which supporting area of the nut is calculated so that a force applied via the nut to the cap under impact does not exceed cap material fluidity.

EFFECT: enhanced reliability of fin functioning under intense barrel stress.

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Description

The present invention relates to the field of military equipment, in particular to artillery shells.

Known artillery shell 3OF39 (152-mm round 3VOF64 (3VOF93) with high-explosive guided projectile 3OF39 and charge number 1 (reduced variable charge). Technical description and instruction manual ZVOF64.00.00.000TO (3VOF93.00.00.000TO), M .: Military Publishing House, 1990, p.21-23). The 3OF39 projectile stabilizer block contains four blades fixed to the axes with a groove on the upper edge and a locking mechanism. The locking mechanism consists of a housing, a stepped inertial load, a cylindrical hook placed between the housing and the load, a split ring, return springs and a cover. In the body and inertial load, longitudinal symmetrical grooves are made, which are aligned with each other for the entry of the blades. When assembling, the hook enters the grooves of the stabilizer blades and holds the blades in the folded position. A chamfer is made on the outer diameter of the split ring from the end face in contact with the hook. The corresponding chamfer is made on the inner diameter of the hook.

When fired under the action of inertia forces, the cargo moves back to the stop in the body. The split ring, under the action of forces acting on the chamfer side of the hook, is compressed and buried in the annular groove of the load. When the load moves, the return springs are compressed and at the end of the movement, the split ring, unclenching, enters the inner groove of the hook, connecting it to the load. When the projectile enters the muzzle brake, the inertia forces sharply decrease and under the action of the return springs the load moves together with the split ring and the hook forward to the stop in the cover. The hook leaves the grooves of the blades and the stabilizer blades open.

In this case, in the case of the impact on the stabilizer block of high barrel overloads, from the impact of the load into the body, the body is deformed, which can lead to the blades not being opened.

Also known projectile stabilizer according to patent 2397434 (application 2009118306 with priority dated 05/14/2009), which is the prototype of this proposed invention.

The projectile stabilizer comprises a housing fixed in the housing on the axes of the blades with grooves and a locking mechanism, including the housing, a stepped inertial load, a cylindrical hook installed between the housing and the inertial weight and included in the grooves of all the blades, a split ring, return springs installed in blind holes the inertial load, and the front cover, in the inertial load of the locking mechanism, a central through hole is made in which a central screw is mounted, fixed on the side of the front cover of the nut in this case, the return springs abut against the front end of the central screw head, and a nut with an outer diameter equal to the outer diameter of the inertial load is installed on the threaded surface from the front end of the inertial load so that an annular groove is formed between the rear end of the nut and the inertial load which is placed a split ring, and in the cylindrical hook from the front end side is made an open inner groove covering the split ring, the cylindrical hook is installed all the way to the core the hub of the mechanism, and the rear end of the hook is made protruding from the central screw.

When fired under the influence of barrel overload, the inertial load moves together backwards, all the way to the front end of the central screw head. The split ring, under the action of the force exerted by the hook, is compressed and buried in an annular groove. When the inertial load moves, the return springs are compressed and at the end of the movement, the split ring is opened, connecting the hook with the inertial load. When the projectile enters the muzzle brake, the inertia forces sharply decrease and under the action of the return springs the inertial load moves together with the hook and the split ring until the nut screwed onto the load stops in the front cover. In this case, the hook comes out of the grooves of the blades, the blades open and, turning on the axes, open.

In modern conditions, there is a need to increase the artillery firing range, this problem is solved, first of all, by increasing the initial throwing speeds of artillery shells, which leads to an increase in barrel loads.

When the stabilizer block is exposed to high barrel overload, a hard dynamic inertial load hits the front end of the central screw head, which can lead to its deformation, as well as to the deformation of the moving parts of the whole mechanism and their jamming during movement, which will entail the non-disclosure of the stabilizer blades.

The objective of the invention is to increase the reliability of the stabilizer of the projectile when exposed to intense barrel overloads.

This is achieved by the fact that in the projectile stabilizer comprising a housing fixed on the blades axes and a locking mechanism including a housing, a front cover, an inertial load with a through hole in which a central screw is installed, fixed with a nut on the front cover side, and return springs placed in the blind holes of the inertial load in disagreement between the inertial load and the central screw head, a ring made of easily deformable material is installed on the front end of the central screw head a gasket, on the side surface of which cylindrical grooves are made, in which return springs are located, abutting against the front end of the central screw head, and the central screw shaft passes through the central hole of the ring gasket, and the nut fastening the central screw from the front cover side is made with increased height and diameter.

The technical problem is solved by introducing into the design the locking mechanism of the ring gasket, fixed, for example, with glue, on the front end of the screw head, and increasing the height and diameter of the nut securing the central screw from the side of the cover.

The introduction of an annular gasket made of easily deformable material (for example, copper) mounted on the front end of the central screw cap concentrically with the cap makes it possible to absorb the impact force of the inertial load in the central screw cap at the moment of the impact of the barrel overload. The area of the annular gasket is selected so that upon impact of the rear end of the inertial load, the front end of the annular gasket is crushed. In the lateral surface of the annular gasket there are four cylindrical grooves, which include return springs, this allows you to save all the characteristics of the return springs used in the prototype.

Fixing the central screw from the side of the cover with a nut of an increased (in comparison with the standard nut used in the prototype) outer diameter avoids the deflection of the cover from the force transmitted to the nut through a threaded connection with the central screw when an inertial load hits the head of the central screw. The support area of the nut is designed so that the force transmitted through it to the cover when the inertial load hits the head screw cap does not exceed the yield strength of the cover material. Increasing the height of the nut allows you to increase the number of working turns of the thread and, thereby, to avoid crushing of the thread connecting the nut and the central screw under maximum load.

The invention is illustrated graphic material: figure 1, 2 and 3.

Figure 1 presents a General view of the stabilizer of the projectile, figure 2 shows the position of the parts of the locking mechanism after it is triggered, figure 3 shows the location of the damping ring gasket.

The projectile stabilizer includes a housing 1, fixed in the housing 1 using the axes 2 of the blade 3 and the locking mechanism 4.

The locking mechanism consists of a housing 5, an inertial load 6, a cylindrical hook 7 mounted between the housing 5 and the inertial load 6, a nut 8, a split ring 9, a central screw 10 and a front cover 11. In the blind holes of the inertial load 6, disputes between the load and the front end of the screw head 10, four return compression springs 12 are installed. From the front cover 11 side, the central screw 10 is fixed with a nut 13 with increased height and outer diameter, flats are made on both sides of the nut 13, which allow yayut tighten the nut standard key. An annular gasket 14 with cylindrical grooves 15 is installed at the front end of the cap of the central screw 10, while the return springs 12 are located in the grooves of the annular gasket. When screwing the nut 8 onto the inertial load 6, an annular groove 16 is formed in which the split ring 9 is placed. The outer surface of the split ring 9 is completely located in the inner ring groove 17 made in the cylindrical hook 7 from the side of its front end. The rear end of the hook 7 protrudes beyond the central screw 10 and enters the grooves of all the blades 3, fixing them in the folded position.

When fired under the influence of barrel overload, the inertial load 6 moves together with the nut 8 backward, all the way into the ring gasket, while the front end of the ring gasket is crushed, reducing the impact force of the inertial load 6 into the head of the central screw 10. The split ring 9 under the action of force, acting from the hook 7 side, is compressed and buried in the annular groove 17. When the inertial load 6 moves with the nut 8, the return springs 12 are compressed and, at the end of the movement, the split ring 9 is opened, connecting the hook 7 with the inertial load 6. When the projectile enters the muzzle brake, the inertia forces sharply decrease and under the action of the return springs 12 the inertial load 6 moves together with the hook 7 and the split ring 9 until the nut 8 screwed onto the load rests in the front cover 11. The hook leaves the grooves of the blades 3, the blades 3 open and, turning on the axes 2, open.

Thus, the use of a damping ring gasket in the stabilizer locking mechanism, which reduces the force of impact of the inertial load in the central screw head, the introduction of a nut with increased height and outer diameter, which excludes the deflection of the locking mechanism cover, avoids deformation or destruction of the locking mechanism during firing and increases the reliability of operation projectile stabilizer when exposed to intense barrel overloads.

Claims (1)

A projectile stabilizer comprising a housing fixed on the blade axes in a housing and a locking mechanism including a housing, a front cover, an inertial load with a through hole in which a central screw is installed, fixed with a nut on the front cover side, and return springs located in the inertial blind holes load in opposition between the inertial load and the central screw head, characterized in that an annular protrusion made of easily deformable material is installed on the front end of the central screw head a lining with cylindrical grooves on the side surface, in which return springs are located, abutting against the front end of the central screw head, the shaft of which passes through the central hole of the ring gasket, while the nut fastening the central screw on the front cover side is made with an outer diameter, the size of which eliminates deflection the cover from the effect of the force transmitted to the nut upon impact of the inertial load on the head of the central screw, and the height at which the nut bearing area is calculated so time that the force transmitted through the nut on the lid during impact, does not exceed the yield strength of the cover material.

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