RU2526720C1 - Artillery round throwing charge of separate loading - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: proposed round comprises tubular powder charges of two types and igniters, both fitted in flammable shells. Igniter extends over the charge length. Powder elements are composed of seven-channel and one-channel equal-length gun-cotton tubes their weight being uniformly distributed over several bundles and their volume and related as m7/m1=18…21. Every bundle is configured to make central bore and fitted in flammable powder bag furnished with elements for connection with other powder bag of other bundles. Central bore of every bundle accommodates the igniter. Gun-powder of one-channel tubes contains fire-killing additives.

EFFECT: higher efficiency, simplified design.

4 cl, 4 dwg

Description

The present invention relates to the design of artillery rounds, namely, to the construction of one of their main components - artillery propelling charges (MH), mainly to the propelling charges of shots of a separate shotgun loading. The proposed propellant charge design can be used as part of modern artillery rounds, including with guided projectiles.

The well-known "Combined artillery propelling charge" (RF patent No. 2074375, IPC F42B5 / 16, application No. 94010941 from 03/29/1994). The combined MZ contains an initiator, an igniter, and a charge consisting of two types of powder elements: the first type of powder elements have a neutral burning surface and are made in the form of plates, whose end surfaces are reserved, and the second type of powder elements are made in the form of microcharges having successively placed areas of neutral and progressive combustion, all external surfaces of micropollars are armored, with the exception of the side entrance strip of the neutral combustion section, and progressive combustion of microcharges is made in the form of two cylindrical sectors connected in the region of their peaks and one of the side surfaces with a neutral combustion section.

In this combined MZ due to the use of two types of powder elements of the above-described design, an increase in the ballistic efficiency of an artillery shot is achieved by increasing the fill factor of the area of the pressure indicator diagram in the projectile space of the gun barrel, i.e. projectile speed. This is achieved by temporarily programming the intensity of the gas entry into the projectile space. However, the technological difficulties of manufacturing fine-grained powder elements associated with the need to book them on certain surfaces significantly limit the use of the MOH of this design, as evidenced by the early termination of the patent.

Also known is the "Separate loading shot for medium and large caliber guns" (RF patent No. 2320951, IPC F42B5 / 38, application No. 2006103577 dated 02/07/2006), the propelling charge of which was taken by the applicant and the authors for the prototype. Separate loading shot includes a shell, shell and propellant charge containing a sample of tubular ballistic powder in an airtight burning shell. A suspension of tubular pyroxylin powder is placed around the periphery of the sample of ballistic gunpowder, the mass of pyroxylin powder being 8-20% of the mass of ballistic powder, and the strength of ballistic powder is 1.1-1.3 pyroxylin powder. In special cases of MOH execution, a sample of ballistic gunpowder can be made of tubular elements with a cut and with a ratio of the diameter of the channel of the tube to the thickness of the burning arch of the tube 0.25-0.8. With such a design of the tubular elements of ballistic powder in the propellant charge, a sample of tubular pyroxylin gunpowder can be placed coaxially with a sample of ballistic gunpowder, while the mass of pyroxylin powder is 5.5-20% of the mass of ballistic gunpowder. In addition, the MOH may contain an additional charge located on the cusp of the projectile in a sealed combustible shell, and the mass of the additional charge is 0.4-1.0 of the mass of the main charge. As follows from the graphic materials (figure) explaining the description of the invention, the igniter MZ is made spaced along the length of the charge and consists of the lower and upper igniters located at the lower and upper ends of the charge, respectively.

The use of high-energy ballistic gunpowder in this Ministry of Health is aimed at increasing the power of an artillery shot. However, the use of high-energy ballistic gunpowders as part of the MZ is significantly limited by their low mechanical strength, which is insufficient to maintain the integrity of the powder elements when exposed to operational loads and gas-dynamic loads during their ignition and subsequent combustion without performing certain design measures. So, in the Ministry of Health of the shot taken above as a prototype, in addition to tubular elements from ballistic high-energy powder, tubular elements of more durable pyroxylin powder are also used, which serve as a supporting band and a power rod for less durable tubular elements of ballistic powder.

The use of two types of tubular gunpowders in this MOH, which differ in their chemical composition and are not chemically inert with respect to each other, requires the use of a sealed combustible shell, in which a sample of tubular ballistic gunpowder is placed, which complicates the design of the MZ (to ensure the tightness of the shell and its combustibility without residues that impede subsequent firing, in a short shot time it is quite difficult to constructively perform in conditions of serial and mass production). The use of single-channel tubes of relatively large elongation as powder elements is also not always justified. Firstly, when using gunpowder single-channel tubes in guns with elongated combustion chambers for guns with a relatively large elongation at the moment of ignition and initial combustion, the so-called erosive combustion develops in the tube channel, which leads to a sharp increase in pressure in the tube channel, which can lead to destruction. In this case, the pressure in the combustion chamber increases, which negatively affects the strength of the gun and can lead to its failure. To eliminate the erosion effect, it is necessary to increase the diameter of the channel of the powder tube, which reduces the charge density and thereby limits the mass, and therefore reduces the power and efficiency of the MZ.

In the particular case of performing the above MOH, apparently, also to exclude erosive combustion, a longitudinal groove is performed in ballistic tubes. But at the same time, the loading density also decreases and the strength and stability of the already fragile ballistic tubes decreases.

Secondly, the above MH (as can be seen from the description) is designed to complete tank shots, where, unlike artillery shots, a variable mass charge is not required to ensure firing in a wide range of ranges, since firing is mainly carried out on a direct direct fire path. Those. the use of this MH in relation to artillery is possible, but for a narrow range of ranges of combat use, which vary depending on the elevation angle of the gun and at the same time it is not possible to vary the range over a wide range.

The task to be solved by the alleged invention is aimed at increasing the efficiency and expanding the functionality of the proposed propellant charge while simplifying its design.

The solution to this problem is achieved by the fact that in the well-known propellant charge of an artillery shell of separate loading, including tubular powder elements of two types and an igniter placed in combustible shells, the igniter is made spaced along the length of the charge, the powder elements are made in the form of seven-channel and single-channel pyroxylin tubes of the same length weight of which is uniformly distributed over several beams and their size and are in a ratio of ₇ m / m ₁ = 18-21, wherein: m ₇ - mass seven-channel n roksilinovyh tubes; m ₁ is the mass of single-channel pyroxylin tubes, each bundle is formed with the formation of a central channel and placed in a combustible cap equipped with elements for sequential coaxial joining of other bundles with cartridges, while an igniter is placed in the central channel of each bundle, and the pyroxylin gunpowder of single-channel tubes contains flame retardant additives.

In special cases of execution, the propelling charge can be performed with a variable number of beams, and the elements for sequential coaxial joining of the bundle caps can be made in the form of longitudinal ribbons arranged uniformly around the circumference on the outer surface of the caps, fastened to the lower cap in its lower part, passed through loops made on the outer surface of each cap opposite the longitudinal ribbons, and fastened together with each other at the end of the upper bundle by a detachable connection, while on the cap marking beams made non propellant.

In addition, in the propellant charge, the igniter of each beam can be made integral and consisting of a sample of fine-grained pyroxylin gunpowder placed between two identical weights of smoky gun powder, which, when the bundles are combined, are opposite the corresponding weights of smoky gun powder of adjacent beams. The mass of the sample of fine-grained pyroxylin powder of the igniter refers to the mass of two samples of smoky gunpowder of the ignitor as: m _pp / m _drp = 2-3, and the total mass of seven-channel and single-channel pyroxylin tubes in the beam refers to the mass of the ignitor of the beam as: m ₇ + m ₁ / m _pp + m _drp = 42-46.

The use of two types of tubular powder elements based on pyroxylin in the proposed MOH does not require a hermetic separation of them from each other and allows them to be placed in a single cap, thereby simplifying the design of the MOH. Since the largest part of the MOH mass is made up of seven-channel tubes with a high charge density and a progressive combustion surface over time, the diagram of the ballistic pressure in the gun’s barrel during the movement of the projectile along it is more full, i.e. ceteris paribus increases the speed of the projectile, and therefore, increases the efficiency of the MOH. The use of single-channel pyroxylin tubes in the MZ, in addition to seven-channel pyroxylin tubes, makes it possible to equalize the pressure along the charge length during their ignition (especially for MZ used in guns with elongated combustion chambers) and thereby avoid wave processes in the combustion chamber that adversely affect projectile strength and guns.

The implementation of the MZ component of several equivalent beams, the number of which can be changed, expands the functionality of the MZ by providing the possibility of changing the firing range over a wide range. In addition, the compilation of MZ from several equivalent beams, the length of the powder tubes in which is significantly shorter than the length of the combustion chamber of the gun, eliminates the effect of erosive combustion with increasing charge density of the MZ, and therefore, increase the power and efficiency of the MZ.

Placing in the central channel of each igniter beam and providing, when the beams are sequentially combined, the alignment of their central channels, and therefore, the igniters, improves the stability of the ballistic characteristics of the charge due to the simultaneous ignition through the combined central channels of all the beams.

The invention is illustrated in graphic materials. Figure 1 schematically shows the proposed MOH. Figure 2 shows a view of the MOH in the direction of arrow B. Figure 3 schematically shows a cross section of one of the beams of the MOH. Figure 4 schematically shows a three-dimensional image of one of the beams in the cap.

The proposed MOH 1 includes tubular powder elements of two types, which are made in the form of seven-channel 2 and single-channel 3 pyroxylin tubes and the masses of which are uniformly distributed over several beams 4 and their volume. The mass of seven-channel tubes exceeds the mass of single-channel tubes by 18-21 times. Each bundle 4 is formed with the formation of the central channel 5 and placed in a combustible cap 6, made in the form of a torus. An igniter 7 is placed in the central channel 5 of each bundle 4. The bundles 4, placed in the cap 6, have elements for their sequential combination, made, for example, in the form of longitudinal ribbons 8 arranged uniformly around the circumference on the outer surface of the cap 6, fastened (sewn or glued) with a lower cap in its lower part 9 and passed through loops 10, made on the outer surface of each cap opposite the longitudinal ribbons 8. At the end 11 of the upper bundle, the longitudinal ribbons 8 are fastened together with a detachable unity, e.g. legkorazvyazyvayuschimsya node (nodes) 12. In the fastener of the "Velcro" may be used as the detachable connection of longitudinal ribbons 8. The igniter 7, located in the Central channel 5, can be made in the form of a sample of an igniter composition, filled in a combustible cap. In the particular case of execution, the igniter 7 is made integral and consisting of a sample 13 of fine-grained pyroxylin gunpowder placed between two identical weights 14 of smoky gunpowder (DRP), which, when the cartridges 6 are bundled 4, are located opposite the corresponding weights 14 of the smoky gunpowder of adjacent beams. The cap of the composite igniter 7 is placed in the central channel 5 and sewn to the cap 6 of the corresponding beam 4. Position 15 indicates the marking of the propellant charge number.

The work and functioning of the proposed MOH is as follows. An artillery shell and the proposed MH of the corresponding number with the number of beams selected on the basis of the combat mission in terms of firing range are subsequently sent to the gun’s barrel, the bolt is closed and the initiator, for example, an ignition tube, is triggered. The force of the flame from the initiator ignites a sample of the DRP 14 located opposite it, which in turn ignites the sequentially located samples 13 and 14 of the respective beams. At the same time, weights of the DRP of 14 adjacent beams located opposite each other reliably and without delay transmit an igniter pulse along the entire length of the MZ. The presence of a DRP igniter in the ignitor and its uniform distribution along the length of the MZ allows you to evenly create numerous ignition centers of pyroxylin tubes uniformly along the entire charge length, since up to 50% of solid hot particles are contained in the combustion products of the DRP. The presence of a fine-grained pyroxylin gunpowder (sample 13) in the igniter in addition to the DRP ensures that during its combustion a pressure tool is created in the chamber at which reliable ignition and stable combustion of the pyroxylin tubes takes place. The proposed design of the composite igniter, its uniform placement in the central channel 5 along the entire length of the MZ, the mass ratio of fine-grained pyroxylin gunpowder and DRA of the igniter, as well as the mass ratio of the pyroxylin tubes (single-channel + seven-channel) and the igniter, provide reliable, uniform and stable ignition of the seven-channel and single-channel tubes. In this case, the pressure equalization along the charge length occurs through the channels of single-channel tubes. In the process of burning MZ pyroxylin tubes, the pressure in the chamber of the gun rises, and the artillery shell, accelerating, moves along the bore and leaves it. Considering that the bulk of the MZ is made up of seven-channel tubes, which, compared to single-channel ones, have a higher loading density and a progressive combustion surface over time, then, ceteris paribus, the velocity of the projectile increases and, consequently, the efficiency of the MZ. Flame retardant additives present in the pyroxylin gunpowder of single-channel tubes reduce the flame on the muzzle of the gun barrel after the projectile leaves it and thereby reduce the unmasking factor of the shot.

Depending on the combat mission to be performed and the need to change the firing range, the knot 12 of the ribbons 8 is untied and after removing the required number of sacks 6 with bundles 4, the ribbons 8 are again tied to the knot 12.

Thus, the proposed propellant charge, in comparison with the prototype, allows to increase the efficiency and expand the functionality of the MOH while simplifying its design.

Claims (4)

1. The propellant charge of an artillery shell of separate loading, including tubular powder elements of two types and an igniter placed in combustible shells, the igniter is made spaced along the length of the charge, characterized in that the powder elements are made in the form of seven-channel and single-channel pyroxylin tubes of the same length, mass which are uniformly distributed over several beams and their volume and are in the ratio m ₇ / m ₁ = 18 ... 21, where: m ₇ is the mass of seven-channel pyroxylin tubes; m ₁ is the mass of single-channel pyroxylin tubes, each bundle is formed with the formation of a central channel and placed in a combustible cap equipped with elements for sequential coaxial joining of other bundles with cartridges, while an igniter is placed in the central channel of each bundle, and the pyroxylin gunpowder of single-channel tubes contains flame retardant additives. 2. The propellant charge according to claim 1, characterized in that the number of beams of the propellant charge is variable, and the elements for the sequential coaxial association of the tufts of the bundles are made in the form of longitudinal ribbons arranged uniformly around the circumference on the outer surface of the capes, fastened to the lower cap in its lower parts passed through loops made on the outer surface of each cap opposite the longitudinal ribbons and fastened to each other at the end of the upper bundle by a detachable connection, while on the cap chkov performed marking numbers propellant. 3. The propellant charge according to claim 1 or 2, characterized in that the igniter of each beam is made up of a sample of fine-grained pyroxylin gunpowder placed between two identical weights of smoky gun powder, which, when the bundles are combined, are opposite the respective weights of the smoky gun powder of adjacent beams. 4. The propellant charge according to claim 3, characterized in that the weight of the sample of fine-grained pyroxylin powder of the igniter refers to the mass of two samples of smoky powder of the igniter as: m _pp / m _drp = 2 ... 3, and the total mass of seven-channel and single-channel pyroxylin tubes in the bundle to the mass of the beam igniter as: (m ₇ + m ₁ ) / (m _pp + m _drp ) = 42 ... 46.

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