RU2478183C1 - Method of transforming artillery projectile tail compartment in flight, and device to this end - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: proposed method consists in accumulation of gases of free space behind the shot in accumulation chamber of projectile aft-section, its elongation by deforming radially corrugated membrane for it to be shaped to cone. Note here that membrane deformation is performed by sequential loading. Note that, first, axial load is applied to membrane central part and, then, it is loaded by internal pressure. Proposed device comprises accumulation chamber, throttling device, thrust rifled disc and radially corrugated membrane. Membrane is laid on appropriate rifled section of thrust disc and secured thereto. Throttling device is mounted at the center of aforesaid disc and secured to said radially corrugated membrane. Additionally, said accumulation chamber houses extending pusher. The latter is tightly jointed with central part of radially corrugated membrane. Extending pusher consists of telescoping sleeves arranged to displace axial against the stop at thrust disc inner end surface.

EFFECT: increased range of fire.

4 cl, 2 dwg

Description

The invention relates to defense equipment, in particular, to a method for increasing the firing range of artillery shells by reducing their bottom resistance on the trajectory sold in shells with a transformable aft compartment in flight.

A known method of increasing the flight range of an artillery shell [RF Patent No. 2251068 in class F42B 10/38 with a priority of 12/08/2003, publ. 04/27/2005

g.], which consists in the fact that during the movement of the projectile along the barrel channel some of the gases of the projectile space are accumulated in the storage cavity of the projectile, and after the projectile leaves the barrel, the aft part of the projectile is lengthened in the storage chamber, giving it a conical shape. This method in the presented group of inventions is specified by a device for increasing the flight range of an artillery shell in the form of a telescopic retractable device that uses the described energy to transform in flight. This device has significant drawbacks in that it requires an axial lock for each drawer. In this case, the outer surface of the formed retractable fairing will always have ledges in the joints of the telescopic rings, which will negatively affect the quality of its flow around the air stream. In addition, the mass of such a device will be much larger than a thin-walled continuous shell, which can be obtained by deformation of, for example, a corrugated membrane using the described method of energy exposure. In the considered group of inventions, it is impractical to use gas pressure as a force for forming a retractable fairing, both in terms of its effectiveness and the need to maintain pressure inside the fairing throughout the flight. In this case, you can use a simpler energy method - the transformation of a telescopic device due to the elastic deformation of the compression spring, as implemented in patent GB 2394029 A.

The closest analogue of the proposed group of inventions is an artillery shell [RF patent for utility model No. 92169 in class F42B 10/38 with a priority of 16.10.2009, publ. March 10, 2010], in which the considered method is used in terms of generating stem gas energy for transforming a deformable element in the form of a corrugated membrane into a thin-walled shell of a feed cone of a conical or similar shape. In this case, the use of the accumulated energy of stem gases is quite justified, because It is required to create a very significant force of deformation of the membrane element.

The artillery shell described in this patent has a transformable aft compartment with a device for increasing flight range, comprising a storage chamber and a throttle device, while the device for increasing flight range is equipped with a support corrugated disk and a radially corrugated membrane superimposed on the corresponding profile corrugation of the disk and mounted on it the outer surface, and in the center of the disk there is a throttle device with the possibility of axial movement and mounted on the membrane, at The corrugated membrane is made in the form of a coaxial combination of zigzag corrugations with rounded ends, between which there are cylindrical sections.

, т.е. они увеличиваются к основанию конической оболочки и уменьшаются к ее вершине при одинаковой толщине материала мембраны (здесь ρ - внутреннее давление, r_x - осевой радиус оболочки на расстоянии х от ее основания, δ_x - толщина оболочки в данном сечении). Это приводит к тому, что гофры мембраны наименьшего диаметра не смогут раскрыться полностью, так как им не будет хватать усилия деформирования, формируемого внутренним давлением, при предельно допустимых напряжениях в оболочке на ее больших диаметрах, и, следовательно, форма трансформируемого кормового обтекателя не будет в полной мере соответствовать заданной, т.е. плавно обтекаемой.The above prototype has a significant drawback - the same internal pressure generated in the volume between the support disk and the membrane by the gas from the storage chamber leads to uneven stresses in the corrugated membrane of constant thickness when it is deformed into a conical shell. In this case, both the meridional σ _m and the circumferential stresses σ _t in each section of the fairing shell during its transformation under the influence of internal pressure are proportional

, i.e. they increase towards the base of the conical shell and decrease towards its apex at the same thickness of the membrane material (here ρ is the internal pressure, r _x is the axial radius of the shell at a distance x from its base, δ _x is the thickness of the shell in this section). This leads to the fact that the corrugations of the membrane of the smallest diameter cannot fully open, since they will not have enough deformation forces generated by internal pressure at maximum permissible stresses in the shell at its large diameters, and, therefore, the shape of the transformed feed fairing will not be fully comply with the given, i.e. smoothly streamlined.

The technical task of this group of inventions is to increase the flight range of an artillery shell by improving its aerodynamic quality by reducing the bottom drag by giving the aft part of the projectile in flight smoothly streamlined by the incoming air stream, without changing the standard dimensions of the projectile before firing and with a minimum mass of the transformed aft compartment .

The problem is solved in such a way that in the method of transforming the artillery shell in the stern compartment in flight, which consists in the fact that when the projectile moves along the bore, some of the gases of the projectile space are accumulated in the storage chamber of the stern compartment, and after the projectile leaves the barrel due to the accumulated energy of the gases extend the aft compartment of the projectile by deforming the corrugated membrane, giving it the shape of a conical shell, deforming the membrane is carried out sequential, two-stage re pressing it, while first creating an axial effect on the central part of the corrugated membrane with which the corrugations of the smallest diameter are opened, and then continuing its loading with internal pressure, which finally transforms the corrugated membrane into a conical shell.

In this case, the transition from axial loading to the effect of internal pressure is carried out when moving the central part of the membrane by 0.25 ... 0.3 of the total longitudinal-axial deformation of the membrane, and the parameters of the sequential loading of the corrugated membrane are chosen so that the meridional stresses from the axial force the inner corrugation of the membrane correspond to similar stresses in the outer corrugation of the membrane created by the internal pressure of the gases in the closed volume of the completely deformable membrane, ranging 0.9 to 1.1.

A device for implementing the described method of transformation in flight of the aft compartment of an artillery shell, comprising a storage chamber, a throttle device, a support corrugated disk, a radially corrugated membrane superimposed on the corresponding profile corrugation of the support disk and mounted on its outer surface, and a throttle device mounted in the center of the support of a corrugated disk with the possibility of axial movement and fastened with a radially corrugated membrane, while in the storage chamber a retractable pusher is placed flush, hermetically connected to the central part of the membrane through a throttle device, and consisting of telescopic inner and outer bushings that seal each other and are installed with the possibility of their axial sequential movement until they stop in the inner end surface of the support disk, with radial openings for the exit of gas from the storage chamber into the cavity between the support corrugated disk and the radially corrugated membrane.

The group of inventions is illustrated by drawings, in which Fig. 1 shows a combined axial section of a device for transforming the aft compartment of an artillery shell with a retractable pusher in the bore (upper part) and after the projectile leaves the barrel (lower part) at the end of the axial action of the retractable pusher on the radially corrugated membrane - the first stage of deformation and the final state of the aft compartment after the implementation of the second stage of deformation of the radially corrugated membrane with internal pressure in onic shell.

Figure 2 shows the shape of the feed fairing obtained by deformation of a radially corrugated membrane of constant thickness when exposed to it during deformation only by internal pressure without axial influence (lower part), and in the upper part the corresponding device for transforming the aft compartment without a sliding pusher is shown.

The in-flight transformation device of the artillery shell aft compartment includes: a housing 1 and a support corrugated disk 2, which form a storage chamber 3, a radially corrugated membrane 4, the outer edge of which is rigidly fixed on the support disk 2 and its corrugations are tightly supported by its corrugations, and in the central the non-corrugated part of the membrane is hermetically fixed to the throttle device 5, which connects the charging space 6 with the accumulation chamber 3 through the check valve 7, while a retractable chamber is placed inside the accumulation chamber a pusher consisting of telescopic, sealing each other inner 8 and outer 9 bushings. In this case, the inner sleeve 8 is hermetically connected to the throttle device, and the outer sleeve 9 is mounted on a sliding fit in the inner hole of the support disk so that the inner sleeve 8 can slide in it until the limiting protrusions touch. The length of the generatrix of the radially corrugated membrane 4 is calculated from the condition of its transformation upon deformation into a conical shell of a given taper from the condition of providing an uninterrupted flow around the lump fairing with the flow of incoming air. To obtain the desired shape of the feed fairing, it is necessary to properly organize the loading regime of the corrugated membrane during its transformation into a conical shell, taking into account the peculiarities of elastic-plastic deformation. As the results of numerical modeling showed, with a constant thickness of the membrane, it is necessary to implement a two-stage mode of loading - first, the axial action on the central part of the membrane with an axial pusher, and then internal pressure on the entire opening shell. In this case, it will be possible to obtain a shell of maximum elongation with a streamlined external surface (see Fig. 1), and both are necessary to minimize the aerodynamic drag of the projectile. The arrows in the drawings show the gas movement during the operation of the transformation device (p _st is the gas pressure in the barrel, p _nk is the pressure in the storage chamber and pusher and p _nn is the pressure under the membrane in free flight).

A device for transforming an artillery shell in flight in the aft compartment, taking into account the above description, is as follows. When fired propellant gas pressure p _v of the projectile acceleration produced in the trunk and simultaneously through the throttle device 5 is an accumulation of the high pressure gas _nc p in the storage chamber 3 formed by a base cut projectile body 1 and the reference plate 2. The radially fluted corrugated membrane 4 during projectile finding in the trunk under the influence of high pressure, p _st is pressed against the supporting corrugated disk 2, therefore, to ensure the necessary structural strength, a large thickness of its walls is not required. After the projectile leaves the barrel, the ambient pressure (pressure behind the bottom cut of the projectile) becomes much lower than the gas pressure p _nk in the accumulation chamber 3, while this creates the possibility of axial movement of the throttle device together with the inner telescopic sleeve 8 and the central part of the radially corrugated membrane 4 axial force generated by pressure inside the outer and inner sleeves 8 and 9. With this movement, the inner corrugations of the radially corrugated membrane 4 begin to deform more than a degree, since they create the greatest stress. In the process of movement, the inner sleeve engages with its outer collar the corresponding protrusion of the outer sleeve, and it begins its axial movement inside the supporting grooved disk 2 until it abuts against it by an external limiting protrusion. After that, the radial openings of the outer sleeve provide the flow of gases from the storage chamber into the cavity formed by the supporting corrugated disk and partially deformed radially corrugated membrane. As a result of this, the pressure in this cavity rises, which ultimately leads to the complete deformation of all the corrugations of the membrane and the formed shell takes on a predetermined shape.

The proposed method for the transformation of the aft fairing of an artillery shell and a device for its implementation will ensure the transformation of the radially corrugated membrane into the aft fairing in an optimal way, because will allow the most uniform loading of all corrugations of the membrane in the process of its deformation. Ultimately, this will make it possible to obtain a feed fairing with a high quality external surface and to fully satisfy the conditions for ensuring an uninterrupted flow of air around the aft part of the projectile and, therefore, significantly reduce its aerodynamic drag, and thereby increase the flight range.

As shown by the results of numerical simulation, the use of the proposed method for transforming the feed fairing and the device that implements it will reduce the coefficient of total aerodynamic drag of an artillery shell by 25-30%, which will lead to an increase in the range of the projectile by at least 15-20%.

Claims (4)

1. The method of transformation in flight of the aft compartment of an artillery shell, which consists in the fact that when the projectile moves along the bore, some of the gases of the projectile space are accumulated in the storage chamber of the aft compartment, and after the projectile leaves the barrel due to the accumulated energy of the gases, the aft compartment of the projectile is extended by deformation radially corrugated membrane, giving it the shape of a conical shell, characterized in that the deformation of the membrane is carried out by a sequential two-stage mode of loading I, at the same time, first create an axial effect on the central part of the radially corrugated membrane, with which the corrugations of the smallest diameter are opened, and then continue to load it with internal pressure, while finally transforming the radially corrugated membrane into a conical shell. 2. The method according to claim 1, characterized in that the transition from axial to internal pressure loading is carried out by moving the central part of the radially corrugated membrane by 0.25 ... 0.3 of the total longitudinal-axial deformation of the radially corrugated membrane. 3. The method according to claim 1, characterized in that the parameters of the sequential loading of the corrugated membrane are selected in such a way that the meridional stresses from the axial action in the inner corrugation of the membrane correspond to similar stresses in the outer corrugation of the membrane created by the internal gas pressure in the closed volume of the completely deformed membrane , ranging from 0.9 to 1.1. 4. The in-flight transformation device of the artillery shell aft compartment, comprising a storage chamber, a throttle device, a support corrugated disk, a radially corrugated membrane superimposed on the corresponding profile corrugation of the support disk and fixed to its outer surface, and a throttle device mounted in the center of the support corrugated disk with the possibility of axial movement and fastened with a radially corrugated membrane, characterized in that in the storage chamber an additional extension is placed a pusher hermetically connected to the central part of the radially corrugated membrane through a throttle device and consisting of telescopic inner and outer bushings that seal each other, mounted with the possibility of their axial sequential movement until they stop in the inner end surface of the support disk, while the outer sleeve has radial openings for the exit of gas from the storage chamber into the cavity between the support disk and the radially corrugated membrane.

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