RU2224212C2 - Artillery shell - Google Patents

Abstract

FIELD: military equipment, in particular, shells with an unfolding tail assembly. SUBSTANCE: the shell has a body with a driving band on which bosses are made corresponding to the rifles of the gun bore. Grooves are made in the contour of the outer surface of the leading band across the shell longitudinal axis, the depth of the grooves is less than a half of the width of the bosses, and the leading band is made in the form of a ring, elastic- deformable in the radial direction, and installed in a recess on the body with a clearance in the axial direction providing for turning of the leading band relative to the shell longitudinal axis. EFFECT: enhanced reliability of obturation. 4 dwg

Description

 The invention relates to defense equipment, and more particularly to artillery shells.

 In traditional artillery shells (with a copper lead belt), designed for loading from the breech of the gun, the obturation of propellant propellant gases occurs during the launch of the projectile due to the compression of copper in the grooves of the barrel.

 In mines intended for loading from the muzzle of the barrel of the mortar, lead belts are used with ready-made rifling, corresponding in shape to the rifling of the barrel, but made with a guaranteed clearance along the entire contour. The presence of a gap between the leading belt and the rifling of the barrel does not make it possible to provide an obturation of the powder gases of the propellant charge.

 So in the well-known French mortar MO 120-RT-61, PR14 mines are used (see JANE'S AMMUNITION HANDBOOK Fifth Edition 1996-97, p. 453, 120-mm PR14 mines), which have the outline of an artillery shell with a leading belt, on which the cuts are pre-made corresponding to the cuts of the mortar barrel channel, and to ensure obturation on the conical tail of the mine installed ring plastic obturator.

 When loading, the protrusions of the leading belt are combined with the rifling of the muzzle of the channel and the mine sinks down the barrel. When fired, a propellant is ignited, the obturator moves along the tail of the mine and stops behind the lead belt, working as a sealing device.

 However, this technical solution is not suitable for implementation in artillery shells having a tail opening, because after the projectile leaves the gun barrel, a plastic obturator, with the possibility of free movement, can shift to the tail and prevent its disclosure or normal functioning.

 The objective of the proposed technical solution is to provide an obturation of artillery shells equipped with leading belts with ready-to-cut rifles and an open tail unit.

 For this, in an artillery shell containing a housing with a leading belt, on which protrusions are made corresponding to the cuts of the gun barrel, grooves are made along the contour of the outer surface of the leading belt across the longitudinal axis of the projectile, while the depth of the grooves is less than half the width of the protrusions, and the leading belt is made in in the form of a ring, elastically deformable in the radial direction, and mounted in a recess on the housing with a gap in the radial and axial direction, allowing the belt to rotate relative to the longitudinal axis of the projectile.

 The pressure of the flowing powder gas through the leading girdle acting on the outer surface of the leading girdle decreases when flowing from the grooves into the grooves, which are made along the contour of the outer surface of the leading girdle across the longitudinal axis of the projectile, the larger the number of grooves, the greater the effect of the reduction pressure, the better the obturation of the powder gases.

 The pressure of the powder gases acting on the inner surface of the lead belt, made in the form of a ring, elastically deformable in the radial direction, and installed in the recess of the shell of the shell due to the radial and axial clearance, which allows the belt to rotate relative to the longitudinal axis of the shell and free flow of the powder gas from the shell space remains equal to the pressure of the powder gases in the projectile space, resulting in (due to the pressure difference from the effects of the powder gases on outer and inner surface of the girdle) a resultant force arises that extends the girdle towards the rifling and fields of the gun barrel, which also increases the reliability of the obturation, since the gaps between the rifling of the girdle and the gun barrel are reduced, which reduces the flowing powder gas through the girdle.

 In FIG. Figures 1–4 show a general view of an artillery shell and its elements. On the housing 1 with the leading belt 2, protrusions 3 are made corresponding to the cuts of the channel of the gun barrel. Along the contour of the outer surface 4 of the driving belt 2, grooves 6 are made across the longitudinal axis 5, the depth of which is less than half the width of the protrusions 7. The driving belt 2 is made in the form of a ring elastically deformable in the radial direction and is installed in the recess 8 on the housing 1 with a radial clearance 9 and axial direction, allowing the belt to rotate relative to the longitudinal axis 5 of the projectile.

 When firing an artillery shell from the channel of the gun’s barrel, powder gases act upon the shell 1 of the artillery shell and on the lead belt 2. When the propellant burns, the mass of the leading belt is significantly less than the mass of the shell, belt 2 is ahead of the shell when moving along the gun’s bore (when firing) and is pressed against the front end 10 of the recess 8. When the powder gases flow through the grooves 6, the pressure of the powder gases acting on the outer surface of the belt drops sharply and the pressure of the powder gases acting on the inner surface of the girdle (due to the pressing of the girdle 2 to the front end 10 of the recess 8 and the presence of a gap 9) remains equal to the pressure of the powder gases in the projectile space, the girdle ok unclenches toward the rifling 11 and the fields 12 of the channel of the gun barrel 13, the gaps between the rifling of the belt and the channel of the gun barrel (Fig. 3) decrease, the reliability of the obturation increases.

 The projectile when exposed to the end face 10 of the leading belt 2, made in the form of a threaded ring rotating in the recess 8, receives an angular velocity of rotation around the longitudinal axis 5 at the outlet of the gun barrel 13, which is substantially lower compared to the rigid version of the installation of the belt on the body. This makes it possible to use artillery shells stabilized by plumage for firing from rifled guns (with the stabilizer blades opening after the projectile leaves the gun barrel channel).

 The proposed technical solution has successfully passed the stages of prototyping and experimental testing on several developed models of artillery shells, has confirmed its high efficiency and will soon be introduced into the national economy.

Claims (1)

An artillery shell containing a housing with a leading belt, on which protrusions are made corresponding to the cuts of the gun barrel channel, characterized in that grooves are made along the contour of the outer surface of the leading belt across the longitudinal axis of the projectile, while the depth of the grooves is less than half the width of the protrusions, and the lead the belt is made in the form of a ring elastically deformable in the radial direction, and is mounted in a recess on the housing with a gap in the radial and axial directions, allowing the relative belt to rotate but the longitudinal axis of the projectile.

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