RU2130581C1 - Artillery shell - Google Patents

Abstract

FIELD: ammunition for smooth-bore artillery. SUBSTANCE: artillery shell includes body with explosive and fuze, means of longitudinal stabilization in the form of longitudinal blades and central rod of nose part anchored on body. Butt of rod is normal to axis of shell and has coaxial protrusions over periphery. Central rod is provided with at least one disc stage. Nose butt of shell body is manufactured in the form of blank conical casing. Body of shell also carries blades of gas-dynamic turbine. EFFECT: improved aerodynamic properties of shell, increased range and accuracy of firing. 4 cl, 4 dwg

Description

 The invention relates to ammunition for smooth-bore artillery, and more particularly, to devices for improving the aerodynamic properties of shells, stabilizing and increasing the flight range using inclined grooves and rotation created by the action of powder gases.

 In artillery systems with rifled barrels, the longitudinal stability of the projectile on the flight path is ensured by giving the projectile an angular velocity of rotation about its axis as a result of the product twisting when moving along the barrel rifles through leading devices - gyroscopic stabilization (1, 2).

 In smooth-bore artillery, the longitudinal stability of the projectile on the flight path is ensured by aerodynamic means, mainly blade stabilizers with blade plumage pivotally mounted on the body (3).

 To increase the accuracy of the battle and the firing range, combined means are used to ensure the longitudinal stability of the projectile in flight to the target: the bottom plumage and the head central rod at the blunt end of the hull normal to its longitudinal axis (4).

 The central rod of the warhead in the known projectile, selected by the number of matching features as the closest analogue to the proposed projectile, provides a significant reduction in drag, which increases the flight range with a lower propellant charge. A free flow breaks off from the surface of the central rod of the head part and a positive gradient arises in the boundary layer due to the inhibition of the flow in front of the projectile.

 The straight end profile of the blunted head of the projectile body, compared with the lively one of the analogues, provides an increase in the filling ratio, that is, the power of the ammunition.

 The central rod of the warhead additionally performs the functions of a telescopic antenna that provides projectile detonation at a predetermined distance from the obstacle, strictly maintains the focal length between the piezoelectric fuse and the projectile explosive to form a cumulative jet.

 On the periphery of the head end face of the hull, longitudinal projections are made, coaxial with the tail blades for organizing stabilized air flows and a stable position of the projectile on the flight path.

 However, the longitudinal stability of the projectile of a given caliber on the trajectory depends, in particular, on the speed of flow around the air stream, the aerodynamic shape of the projectile, the ratio of its geometry parameters, the length of the central rod of the warhead and the mass distribution of the loaded ammunition. So, due to the supersonic air flow around the blunt head part of the projectile body with a sufficiently short central core, the gas mass balance is disturbed in the stagnant zone on the central head core with a return flow from the body end and a curvilinear shock wave occurs at the periphery of the end face, the parameters of which pulsate, which leads to undamped vibrations of the warhead (nutation), which impede automatic self-control by flight, slow down the projectile and lead it away from the calculated trajectory with trunks. This is all corrected by the aerodynamic stabilizer blades.

 Aerodynamic stabilization by means of expanding stabilizer blades across the shell of the shell after firing a gun, firstly, complicates the design and increases the cost of manufacturing and assembly technology, reduces the functional reliability of the disclosure mechanisms and the product as a whole, and secondly, significantly reduces the performance characteristics, this decreases the filling coefficient due to the ballast (up to a third of the projectile volume) folded stabilizer.

 The problem to which the present invention is directed is to eliminate the noted drawbacks, as a result of which the power of the ammunition increases while improving accuracy and increasing the firing range of a smooth-bore gun with a projectile with a new structural scheme for combined stabilization of its longitudinal stability on the flight path.

 The required technical result is achieved by the fact that in a known artillery shell containing a case with filling, a fuse and combined means of longitudinal stability, including blades mounted on the body and the central rod of the head part, the end face of which is made normal to the axis and provided on the periphery with coaxial protrusions, according to the invention on the central rod of the head part there is at least one disk stage, the protrusions of the head end of the body are an annular blind shell, and fall in projectile caliber height rigidly fixed longitudinally, being mounted on the housing inclined vanes gazodinamicheskoj turbine made profiled. The proposed projectile is characterized in that the height of the disk stage of the central rod of the head part exceeds five thicknesses of the boundary layer in front of it; the distance l from the head end of the casing with caliber D to the disk stage is selected from the relation D = (1.7 - 1.9) l; the diameter d of the Central rod of the head part is selected from the ratio l / d = 2-3; and the profiled surfaces of adjacent blades form, between themselves, in the channels of the gas-dynamic turbine, a Laval jet nozzle.

 Each of the essential features is necessary, and their combination is sufficient to achieve the novelty of quality, that is, a new super-effect, and not the sum of the effects, which manifests itself in a positive technical result when implemented, which is inherent in parts of their disunity.

 Distinctive features ensured the longitudinal stability of the projectile on the flight path due to combined stabilization: gyroscopic by means of gas-turbine spinning of the projectile in the barrel channel by propellant gases of a propellant charge and aerodynamic head suppressing nutation (angular pulsations), which ultimately improves the accuracy of the battle and increases the aiming range.

 Performing a disk stage with a height of more than five thicknesses of the boundary layer in front of it ensured the separation of the return circulation flow into parts by the formed shock wave from its perimeter and the formation of a “liquid cone” conjugated to the head end of the housing, inside of which there is a gas damper to counter nutation.

 In the volume between the disk step of the central rod of the head part and the undercut of the annular peripheral shell of the head end face of the housing, a quasi-stationary return flow of compressed air of the incoming supersonic flow with a large positive pressure gradient of the counterflow inside the conical shape of the stagnant zone combined with the end face of the body is organized, where the pressure is much lower, which is noticeably reduces the drag of the projectile.

 The implementation of profiled turbine blades with a height not exceeding the caliber of the projectile allows them to be used to form the reactive movement of powder gases through the nozzle channels between them, creating the necessary torque when the axial movement of the projectile in the barrel channel. The profiled surface of the blades creates jet nozzles in the channels of the gas-dynamic turbine, which increases the speed of the outflow of jet flows of powder gases from the guide vanes on the bottom of the projectile and forms traction, and therefore, the necessary twist and, together with an increased initial velocity of the projectile, increase its flight range with longitudinal stability.

 The proposed design scheme for the combined stabilization of the flight of the projectile provides a rational shift of the center of pressure to the stern of the projectile, and the center of mass to the head, in particular, the redistribution of additional volumes of explosive and body metal instead of the expanding stabilizer blades and its bottom and the shortened central core of the head, which longitudinal stability of the projectile on the flight path to the target.

 In addition, the guide blades and turbine blades provide a given crushing of the body into fragments due to the oriented attenuation of the cross section, being stress concentrators of its material.

 The projectile according to the invention, compared with a standard one of equal caliber, is characterized by increased power of the main action: high-explosive and fragmentation, with structural simplification and cheapening of manufacturing technology.

 The proposed geometric relationships of the essential structural features of the invention reduce drag and reduce the pressure of the incoming air flow on the head of the product with stable circulation of the local air flow on the central shaft of the head behind the disk stage in front of the blunt front end of the housing that controls the self-oscillating process before attenuation, and therefore reducing projectile buildup on the flight path behind the muzzle.

 The proposed projectile is not known from available sources of information of the prior art, does not explicitly follow from it for a specialist ammunition and can be industrially implemented in serial production, that is, meets the criteria of patentability.

The invention is illustrated in the drawing, which shows:
in FIG. 1 - general view of the projectile;
in FIG. 2 is a section along AA in FIG. 1;
in FIG. 3 is a view along arrow B in FIG. 1, a scan of an embodiment of a turbine;
in FIG. 4 is a flow diagram of a supersonic air stream.

 An example embodiment of the invention is illustrated by a 125 mm high-explosive fragmentation projectile (Fig. 1) to the D-81 tank carcass. The shell 1 of the projectile, filled with explosive 2, associated with a lead inertial fuse 3 of brand B-429E, is equipped with a central shaft 4 of the head with a disk stage 5, a gas-dynamic turbine 6 and guide longitudinal blades 7, the diameter of which is equal to caliber D (Fig. 2 and 4) with their height and the height of the blades 6, comparable with the thickness of the boundary layer 8, equal to 5.5 mm

 The central rod 4 of the head part with a diameter d of 30 mm and a length of 73 mm is reinforced in the undercut 9 with a depth of 7-10 mm of the front front end of the housing 1, normal to the axis of the projectile, which forms a peripheral shell with a conical projection 10 inclined inward.

 A disk step 5 with a thickness of 9 mm protrudes 15 mm above the lateral surface of the central shaft 4 of the head. The disk stage 5 is mounted at a distance l from the head end of the housing 1, depending on the speed of the projectile, its aerodynamic shape, angle of attack, etc., which is determined from the relation: D = (1.7-1.9) l, and the distance l is functionally related to the diameter d of the central rod 4 of the head part l / d = 2-3.

 In the bottom of the housing 1 is fixed a latch 11 with spring supports for holding the projectile and fixing when loading.

 The forming surfaces of the blades of the turbine 6 with a thickness of 5 mm are profiled and form channels 12 in the form of a Laval jet nozzle (Fig. 30).

 When fired, the energy of the gaseous products of combustion of a propellant charge, the pressure of which in the bore is 3.3-4.0 thousand atm, is supplied orientally by means of longitudinal guide vanes 7 to the inclined blades of the turbine 6. When moving along the barrel, the projectile spins around its axis to speed 16000 rpm The initial linear velocity of a projectile weighing 23 kg reaches 900 - 950 m / s, which increases the maximum firing range to 12 km.

 Structural scheme of straightening powder gas flows by means of guide longitudinal blades 7 onto inclined profiled blades of a gas-dynamic turbine 6 of the shell 1 of the projectile, the diameter of which is equal to the caliber D, compared to a standard projectile ind. 30F26, allows, firstly, by eliminating the master device, to eliminate acceleration losses during insertion, directing the energy of the powder gases directly to accelerate and twist the projectile, and secondly, to reduce the pressure gradient along the length of the barrel, which increases the propelling impulse and reduces barrel wear .

 When a projectile flows around a projectile with a supersonic air stream (Fig. 4), an shock wave 13, which is characterized by a system of subsequent shock waves 14, 15, 16 and restructuring of the perturbed stream, departs from the end of the central rod 4 of the head part on the external flight path.

 When the air flow is separated from the periphery of the disk stage 5, a "liquid cone" 17 is formed, which contacts the protrusion 10 of the annular shell of the head end of the housing 1.

 In the area between the shock wave 14 and the disk stage 5, a stagnant zone 18 with a return flow occurs when the flow is inhibited at the front end of the disk stage 5, and inside the cone 17, the circulation flow conic surface of the protrusion 10 of the undercut 9, unloading the shell body 1, that is, the disk stage 5 performs the functions of a turbulator (5).

 On the contact surface of the cone 17 with the protrusion 10, the incoming flow is divided to form a shock wave 16, a boundary layer 8 and a turbulent circulation flow 19, sealed by rotation of the replaced air.

 The protrusion 10 of the annular shell of the undercut 9 forms a counterflow in zone 19, due to the inhibition of the flow and a large positive gradient, due to the attachment of the air flow without disturbing the gas mass balance in zone 19, flowing along the curved shock wave 16 of the seal and into the boundary layer 8.

 The gas damper of zone 19, formed inside the "liquid cone" 17, is elastically connected to the housing 1 by undercutting 9 and provides negative feedback that dampens the self-oscillations of the projectile head that stabilizes its axial orientation.

 Consequently, a circulating quasi-stationary stream of compressed gas 19 is purposefully organized inside the “liquid cone” 17, which has constant velocity and pressure with a balance of flow and recharge of air to automatically control the longitudinal stability of the projectile in flight, like a gyroscope.

 The projectile of the proposed rational aerodynamic shape has a 1.5 times higher filling coefficient, containing at least 5 kg of explosive, and 30% lower drag, compared with a standard high-explosive fragmentation projectile, and the initial velocity increased by 50 - 100 m / s .

References:
1. Magnus K. Gyroscope, theory and application. - M .: Mir, 1974, 360 p.

 2. Okunev B.A. Rotational movement of an artillery shell. - M. - L .: Gostekhizdat, 1943, 254 p.

 3. 100-mm anti-tank gun T-12. - M .: Military Publishing House, 1969, p. 93.

 4. Handbook of artillery ammunition. - M .: SP "Nova", 1992, p. 94 and 95.

 5. Directory of aviation technology. - M .: Military Publishing House, 1974, p. 148.

Claims (5)

 1. An artillery shell containing a shell filled with explosive, a fuse, combined longitudinal stability means in the form of blades fixed to the body and the central rod of the head, the end of which is made normally to the axis of the shell with coaxial protrusions around the periphery, characterized in that its central rod the head part is made with at least one disk stage, the head end of the shell body is made in the form of an annular blind shell, while the blades are made in height in caliber e of the projectile and are fixed longitudinally, and profiled inclined blades of the gas-dynamic turbine are mounted on the shell of the projectile.  2. The projectile according to claim 1, characterized in that the height of the disk stage of the central rod of the head part exceeds five thicknesses of the boundary layer in front of it.  3. The projectile according to claim 1 or 2, characterized in that the distance l from the head end of the casing with caliber D to the disk stage is selected from the relation D = (1.7 - 1.9) l.  4. The projectile according to any one of claims 1 to 3, characterized in that the diameter d of the Central rod of the head part is selected from the ratio l / d = 2 - 3.  5. A projectile according to any one of claims 1 to 4, characterized in that the profiled surfaces of adjacent blades form a Laval jet nozzle between the channels of the gas-dynamic turbine.

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