RU2141096C1 - Cartridge for hunting gun ( versions ) and process of manufacture of bullet jacket - Google Patents

Abstract

FIELD: hunting guns with rifled tubes. SUBSTANCE: in agreement with first version cartridge has case, propelling charge inside case, percussion cap and bullet. Head part of bullet has cut of jacket at vertex with free space under cut open on side of cut and longitudinal grooves in internal surface of jacket. Process of manufacture of bullet jacket includes cutting and rolling of cap, multipass drawing with clamping, punching of hole in vertex of semi-finished product and stamping of grooves. Novelty in manufacture of cartridge lies in sequence of operations for fabrication of jacket: punching of hole in vertex and stamping of grooves with the use of changed tool and change of shape of grooves, reduction to optimal size of diameter of hole in vertex across cut coaxially arranged with regard to case, reduction of diameter of cut of vertex of bullet and increased length of its head part. According to second version cartridge of same structure has bullet, jacket, shell and core. EFFECT: increased killing power of cartridge. 10 dwg

Description

 The invention relates to hunting cartridges for firing a weapon with a rifled bore [hereinafter referred to as "cartridges"] containing a sleeve, a propelling charge, an igniter capsule and a bullet.

 Cartridges are widely known, mass production and steady use. Their device and characteristics are given in various reference and special materials, for example, in [1], [2], [3], patent, including - [4], [5] and others.

 The type of cartridge is determined by its purpose and the required effectiveness of the shot [the action of the bullet on the target, range, accuracy, rate of fire, etc.]. The action of a bullet after a shot determines the effectiveness of the shot while providing ballistic conditions for the shot with the required efficiency based on the result of firing from a weapon having the established parameters of the barrel channel, which is produced by all components of the cartridge - a sleeve, a propelling charge, an igniter capsule and a bullet.

 For shooting animals that are objects of hunting, cartridges with bullets that are non-deformable and deformable are used [1].

 Examples of the performance of cartridges with non-deformable bullets - cartridges 7.62 x 51B or 7.62 x 51F, B [6].

 Examples of cartridges with deformed bullets: half-shell - cartridges with an index "A" according to [6], cartridges with a bullet according to [7]; cartridges with bullets having grooves on the shell according to [8], with bullets having notch shells according to [9] and [10], with bullets having an open cavity in the head according to [11]; cartridges 7.62 x 39 - 8 according to [12] with bullets according to [13] or [14] having a softening of the head part by longitudinal grooves on the inner surface of the shell made by the method of [15].

 The nature of the deformation or non-deformation of bullets in the respective cartridges during firing depends on the design of the shell, and the design, in turn, is inextricably linked with the method of manufacturing the shell. Methods for the manufacture of shells for cartridges with the indicated types of bullets according to [4] - [11] are well known and their description is available in the technical literature, for example, according to [16]. The common features of all known methods are the manufacture of shells with parts corresponding to the head, lead and tail parts in bullets, and in non-deforming bullets the head part has no softening, and in deforming bullets the head part or its section has softening, i.e. reduction in strength characteristics due to the design: an open core on the side of the tip of the bullet has a lead core, grooves and cuts on the head of the shell, a cavity on the side of the tip of the head, etc. The damage parameters are significantly higher for cartridges with deforming bullets, including for shooting of such large animals as moose, deer, wild boar, etc., and the penetration ability is higher for cartridges with bullets that are not deformed under the same conditions of the shot.

 In bullets of a deformed bullet shell, they are open from the apex side and closed from the tail, and also open or softened from the apex side and open from the tail.

 Shells made according to the known method of manufacturing closed from the tail end and open from the apex side are used in cartridges with bullets according to [4] - [11]. Most of the bullets used in cartridges, the shell of which is made in this way, consists of two elements - the shell from the core. The lack of rounds of ammunition with the indicated bullets is the relatively short range of reliable destruction, the increase of which requires increasing the energy parameters of the bullets on the trajectory, which is not unlimited.

 Shells made according to the known manufacturing method [15] open from the tail end and from the tip side are used in cartridges [12] with bullets according to [13] and [14].

 The cartridge according to [13], selected as a prototype, contains a sleeve with open ends along the bottom of the housing closed on one longitudinal axis, a propellant charge inside the sleeve, an igniter capsule, firmly inserted in the center of the closed end of the sleeve housing on the same longitudinal axis , and a bullet located on the open end of the sleeve on the same longitudinal axis with it, consisting of a shell and a shirt and core placed in it, and made with open tail and lead parts that go into the sleeve, as well as a seamless head with a cut to the top Inca, free volume under the slice, open from the side of the slice, and softening longitudinal grooves located on the inner surface of the shell.

 A method of manufacturing a shell of a bullet for a hunting cartridge, open from the side of the tail part and from the side of the apex made with an adjacent head part, including the manufacture of a semi-finished shell by cutting and convolving a hollow hood, as well as multi-junction hoods with crimps, punching a through hole in the top of the head semi-finished product by means of a matrix and a smooth punch from the side of the inner cavity of the semi-finished product, with a decrease in the length of the head part and the total length of the semi-finished shell, stamping on the inner surface of the head part from the side of the inner cavity of the semi-finished longitudinal grooves of variable depth by means of a die and a punch having blades on the side surface of the working part.

The positive quality of the cartridges according to [12] with the bullets according to [13] and [14], the shells of which are made according to the method of [15], the range of reliable destruction is increased by 2–3 times when compared with cartridges, the bullets in which, for example, are half-shell , in case of firing with the same initial conditions of the shot. Cartridges with bullets of the prototype successfully fulfill their purpose, but, as calculations and tests showed, they can be improved by improving the aerodynamic qualities of bullets by reducing the drag force, as a result of which the descending branch of the trajectory is shorter than the ascending one. And this means that when comparing the cartridges of the improved and improved under the same initial conditions of the shot - see [2], p. 33 - at the second, the difference in the velocity of bullets measured at two points of the trajectory [V ₂₅ and V ₁₀₀ or V ₂₅ and V ₂₀₀ , etc.] decreases, the flight time of the bullet between these points decreases, the loss of kinetic energy on the trajectory decreases, the trajectory of the bullet becomes more persistent, the range of the direct shot and the range of the bullet when firing cartridges increase, resulting in increased parameters of the lesion [17] and increases the stopping effect of the bullet, determined by the impact of the shock state on the animal’s body, since the result shot causes an increase in the rate of deformation bullets animal tissues, t. e. as a result of increasing the lethal effect of improved cartridge bullet when firing cartridges being compared with the results of measurements on the same ranges.

 It should be noted that the diameter of the hole that opens the free volume under the slice, and the corresponding diameter of the slice at the tips of bullets in the cartridges according to the prototype, are determined by the diameter of the punched through hole at the tip of the semi-finished shell made by the method [15], the value of which during subsequent installation of the bullet / and cartridge / does not change.

 The technical task is to increase the lethal effect of the cartridge as a result of the shot by improving the aerodynamic qualities of the bullet.

 The problem is solved due to the fact that in the cartridge according to the first embodiment of the invention, containing a sleeve with open ends and closed along the bottom of the body on one longitudinal axis, a propellant charge inside the sleeve, an igniter caps inserted in the center of the closed end of the sleeve on that the same longitudinal axis, and a bullet located on the open end of the sleeve on the same longitudinal axis with it, consisting of a shell and a core placed in it and made with parts of the open tail and leading that go into the sleeve, as well as according to the invention, the free volume under the cut in the tip of the bullet is opened by an opening coaxially located relative to the sleeve, the diameter of the opening being cut off; according to the invention, the free volume under the cut at the apex, the free volume under the cut, open on the side of the cut, and softening longitudinal grooves located on the inner surface of the shell smaller than the diameter of the same hole from the free volume side under the cut, the portion of the bullet head adjacent to the cut is elongated towards the cut with a groove length of not more than length g Karlovna part.

 According to a second embodiment of the invention, the cartridge contains a bullet consisting of a shell and a shirt and a core placed therein with the indicated distinguishing features.

 In both versions of the cartridges, the bullet can be made with a composite core.

 The problem is also solved by the fact that in the manufacture of the shell of a bullet of a hunting cartridge, open on the side of the tail part and on the side of the apex, made with an adjacent head part, including the manufacture of a semi-finished shell by cutting and convolving a hollow hood, as well as multi-junction hoods with crimps, punching a through hole in the apex of the semi-finished product head by means of a matrix and a smooth punch from the side of the internal cavity of the semi-finished product with a decrease in the length of the head and the overall the lengths of the semi-finished shell, stamping on the inner cavity of the semi-finished shell, stamping on the inner cavity of the semi-finished longitudinal grooves of variable depth by means of a die and a punch having blades on the side surface of the working part, according to the invention, the hole is punched before stamping after the last crimping of the semi-finished shell, and the hole is punched coaxially located relative to the outer surfaces of the semi-finished product, while the matrix is made for punching the hole and with a central through hole and a working part, the geometrical parameters of which are determined by the geometrical parameters of the predominantly outer surface of the semi-finished product head, and the smooth punch is made of a profile, for stamping grooves, the matrix is made blind with a profiled working part, the geometrical parameters of which are determined by the geometrical parameters of the outer surface of the predominantly head part semi-finished product with a smooth transition to the area that forms the contour of the vertex and the adjacent area the head of the semi-finished product, and the punch is made profile and has blades dulled in the area located from the end of the working part, and when stamping the outer surface of the head of the semi-finished product is abutted in the corresponding section of the profile part of the matrix and the blades of the working part of the punch on the wall of the head of the semi-finished product, what form the outflow of the material of the semi-finished product in the area adjacent to the hole in the tip of the semi-finished product, between the walls of the deaf matrix and the surfaces formed by blunting by pressing the punch blades toward the direction of movement of the punch during the stroke, which increases the length of the head and the total length of the semi-finished product, reduces the diameter of the hole along the slice in the head of the semi-finished product with a corresponding decrease in the diameter of the cut at the apex of the head of the semi-finished product, reduces the wall thickness of the semi-finished product in the grooves towards the cut in the area of the impact of the stamping punch blades without dulling and increase the wall thickness of the semi-finished product in the grooves by ION shear effects at the site stamping punch blade dulling.

 It is the claimed method of manufacturing the shell of the bullet cartridge provides, according to the design of the cartridges, the location relative to the sleeve of the hole that opens the free volume under the cut at the tip of the bullet, the size and shape of the specified hole, the shape adjacent to the cut section of the head of the bullet, the length of the softening grooves relative to the length of the head of the bullet and the achievement goals of inventions. This allows us to conclude that the claimed invention is interconnected by a single inventive concept.

The invention is illustrated by drawings, which show:
FIG. 1 is a General view of the cartridge according to the first invention, containing a sleeve, a propelling charge, an igniter capsule and a bullet consisting of a shell and a core placed therein;
FIG. 2 is a general view of a cartridge according to the first invention, comprising a sleeve, a propellant charge, an igniter capsule and a bullet consisting of a shell and a composite core placed therein;
FIG. 3 is a general view of a cartridge according to the second invention, comprising a sleeve, a propellant charge, an igniter capsule and a bullet consisting of a shell and a shirt and a core placed therein;
FIG. 4 is a general view of a cartridge according to the second invention, comprising a sleeve, a propellant charge, an igniter capsule and a bullet consisting of a shell and a shirt and a composite core placed therein;
FIG. 5 is a general arrangement of the working tool and the prefabricated shell of the last crimp before punching a through hole at the tip of the semifinished product in the manufacture of a shell for a bullet in a cartridge by the method of the third invention;
FIG. 6 is an enlarged view of the circuit of FIG. 5 as an external element;
FIG. 7 is an enlarged image of the same section of the circuit of FIG. 5, as in FIG. 6 [as an external element], but after punching a through hole in the tip of the semi-finished product;
FIG. 8 is a general arrangement of a working tool and a prefabricated shell [prefabricated - after performing the operation of FIG. 7] before stamping on the inner surface of the head of the semi-finished product of the longitudinal grooves in the manufacture of the shell for the bullet in the cartridge by the method according to the third invention;
FIG. 9 is an enlarged view of the circuit of FIG. 8 as an external element;
FIG. 10 is an enlarged image of the same section of the circuit of FIG. 8, as in FIG. 9 [as an external element], but after performing the stamping operation to form longitudinal grooves on the inner surface of the head of the semi-finished product.

In the drawings, the following notation:
L ₁ - the length of the head of the semi-finished shell of the last crimp before punching a through hole in its apex;
L ₂ - the length of the head of the semi-finished shell of the last crimp after punching a through hole in its apex;
L ₃ - the length of the head of the semi-finished shell after the stamping operation;
Δ ₁ is the size by which the length of the head of the semi-finished shell of the last crimp after punching a through hole in it is reduced;
Δ ₂ - the size by which the length of the head of the semi-finished shell after stamping is increased;
Δ ₃ - size for debugging the magnitude of the stroke of the stamping punch [with blades];
D ₁ - the diameter of the through hole punched in the tip of the semi-finished shell of the last crimp;
D ₂ - the diameter of the through hole on the slice at the tip of the semi-finished shell after stamping.

 The cartridge of FIG. 1 contains a sleeve 1 with open ends and a bottom closed, a propellant charge 2 placed inside the sleeve, a primer 3 inserted firmly in the center of the closed end of the sleeve, and a bullet 4 consisting of a shell 5 and a core 6 inserted into the sleeve from the open end. The sleeve, the primer and the bullet are located on the same longitudinal axis.

 The sleeve combines all the elements of the cartridge — the propellant charge, the igniter capsule and the bullet, provides the obturation of the powder gases from the rear section of the barrel during firing and, together with the bullet, isolates the propellant charge and the shock composition of the igniter capsule from the external environment. In FIG. 1 sleeve - seamless, bottle type [with a ramp], with a protruding flange and securing the bullet in the barrel, for example, by tightening when mounting the bullet into the sleeve and crimping [or rolling] the barrel by cutting the sleeve. According to the invention can be applied to the sleeve and another design known from the central location of the igniter capsule.

 The propellant charge is a source of energy of the bullet’s movement during firing. According to the invention, a propellant charge from gunpowder of any known or newly developed type used in similar small arms cartridges can be used, but according to the results of a ballistic solution in the development of a specific design.

 The igniter capsule ignites the propellant charge in the cartridge as a result of the dynamic compression of its impact composition by the brisk impact mechanism of the weapon on the anvil. According to the invention, the igniter capsule is a central battlefield, with or without its own anvil [in the latter case, the anvil is located on the sleeve]. The impact composition in the igniter capsule is from the conventional.

 The bullet is made with the tail, leading and head parts. The tail and leading parts are included in the sleeve. In the tail section, the bullet shell is open, which makes it possible to use the design of the tail section of any type known for bullets with an integral head portion, which ensures the core is retained in the shell without removing the bullet from inertial loads when the bullet moves along the barrel bore during a shot. The leading part of the bullet according to the drawing is made smooth, but if necessary it can have a transverse groove on the outside if it is necessary to increase the force for extracting the bullet from the sleeve when crimping or rolling the barrel dule along the cut in a particular cartridge design. The bullet head is seamless, made with a cut of the shell at the apex and free volume under the cut, an open hole on the cut side. The diameter of the hole along the cut is smaller than the diameter of the same hole from the free volume side under the cut, because the portion of the head adjacent to the cut is elongated towards the cut during the manufacture of the bullet shell. The front end of the core is the bottom of the free volume. On the inner surface of the head of the shell there are longitudinal grooves softening the bullet of variable depth, not more than the length of the head part, while the strength conditions of the shell at the base of the head of the bullet are not violated when fired, because according to [2, p. 29 and p. 111] the wall thickness of the shells in the bullets of small arms, at least at the base of the warhead, is in the range of [0.06 - 0.08] d, and the depth of the grooves in the bore [1.02 - 1.04] d, where d is the caliber of the weapon. The difference in shell size in thickness after cutting a bullet into rifling is [0.04 - 0.07] d. The longitudinal grooves at the base of the head of the shell of the bullet are only beginning to be outlined and practically do not affect the thickness of the shell, as well as its strength at this point.

 After mounting the cartridge, the opening that opens the free volume under the cut at the tip of the bullet is coaxial with respect to the sleeve, and the diameter of the cut at the tip of the bullet is larger than the diameter of the hole at the cut due to the blunting of sharp edges along the cut when the bullet is sent to the sleeve when inserting the cartridge [the same blunting occurs when mounting a bullet].

 The operation of the cartridge of FIG. 1 is as follows. After the weapon is destroyed by the impact mechanism, the igniter capsule ignites the propellant, resulting from hot powder gases, the amount of which creates a high pressure in a small volume, eject the bullet from the barrel and the bullet flies to the target along a certain path. Due to the fact that the head of the bullet is weakened, the bullet, when it hits the target and penetrates the animal’s tissue, is deformed from the side of the head or, depending on the purpose, is completely or partially destroyed, showing the required parameters of the lesion, which determine the lethal effect.

 In a specific embodiment of the cartridge according to the invention, a sleeve, a propelling charge, an igniter capsule and a bullet in a complex should provide the required firing conditions and its results.

 If a specific embodiment of the claimed cartridge is intended for firing from a weapon of a known and practical model, then the cartridge length, despite the increase in the length of the bullet head, is set to no more than the analogue - one of the requirements according to [3].

 In the weapon-cartridge system, when the cartridge is in the chamber and at the initial stage of the shot, the sleeve determines the alignment of the bullet surfaces with the barrel channel, which reduces the movement of the side perturbations of the surface air resistance forces caused by the bullet in the barrel channel and on the trajectory asymmetry of the geometric shape of the bullet and its location relative to the sleeve, for example, due to manufacturing tolerances. The coaxial location relative to the sleeve of the hole that opens up the free volume under the cut at the tip of the bullet, reducing the diameter of this hole at the cut and, accordingly, the diameter of the cut of the shell at the tip of the bullet, combined with the increased length of the head of the bullet in the area adjacent to the cut at the tip, make the claimed cartridge more streamlined when moving in air, which, taking into account the reduction in the area of the hole and the cut in the apex, reduces the drag force along the flight path of the bullet, while the coaxial th location of said hole relative to the sleeve stabilizes the total air resistance force from shot to shot.

 The cartridge of FIG. 2 is made as a special case of the cartridge of FIG. 1, contains the same sleeve 1, propellant charge 2 and the primer 3, as well as a bullet 7 with a shell 5 and a core made integral, i.e. consisting of several parts, for example, from two - 8 and 9, located one after another. The core composition, design, size, weight and material of its components, plasticity and hardness of the material are selected depending on the purpose of the cartridge according to the results of a shot when the target [animal is the object of the hunt] and the degree of deformation of the bullet. Other features are the same as in the cartridge of FIG. 1.

 The cartridge of FIG. 3 contains, as the cartridge of FIG. 1, the same sleeve 1, propellant charge 2 and the primer 3, as well as a bullet 10 with a sheath 5, a jacket 11 and a core 12. When fired, the shirt cuts the bullet into the grooves of the barrel channel and reduces abrasion of the surface of the barrel channel when the core has a relatively low ductility and relatively high hardness of the material, as for example, when the core is made of steel [in hunting cartridges - non-heat treated]. The core can also be made of lead with a hardness that differs in value from the hardness of the shirt, or aluminum, as well as alloys based on it, or other materials. Shirt material, usually lead with various additives, may be plastic. The front end of the core may be jacketed [as shown in FIG. 3] or not closed by it. A core with increased strength characteristics that require the use of a shirt in a pool is used when firing, which results in a deeper penetration of the bullet or its elements into animal tissue with a devastating effect on bone tissue. Other features in the cartridge of FIG. 3 are the same as in the cartridge of FIG. 1.

 The cartridge of FIG. 4 is made as a special case of the cartridge of FIG. 3, contains the same sleeve 1, propelling charge 2, primer 3, and also a bullet 13 with a sheath 5, a jacket 11 and a composite core, as shown in FIG. 4 consisting of two parts 14 and 15, located one after the other. Other features are the same as in the cartridge of FIG. 3.

 In the bullets of the claimed cartridges, a method for manufacturing a bullet shell is implemented.

The general arrangement of the working tool and the semifinished product of the shell of the last crimp before punching a through hole at the tip of the semifinished product of FIG. 5 contains a punch 16 entering during the operation together with the semifinished product 17 having a head part of length L ₁ into the matrix 18. The punch has a smooth shaped outer surface with a guiding section, the geometric parameters of which are determined by the geometric parameters of the inner surface of the predominantly head part of the semi-finished product 17, and the working a section made in the form of a cylindrical protrusion, the diameter of which is consistent in size with the diameter of the central through hole in the matrix. When performing the operation, the punch passes through the shooting ring 19. The particle separated from the semi-finished product 17 after punching holes in it passes through the through hole in the matrix. The working part of the matrix in the profile has geometric parameters determined by the geometric parameters of the mainly outer surface of the head of the semi-finished product 17 [within the tolerances for the manufacture of the semi-finished product and matrix], which ensures the extraction of the semi-finished product from the matrix with a punch when moving the latter in the opposite direction to the working one. To ensure the alignment of the semi-finished product 17 with the matrix 18 and the punch 16 in the working position [in order to ensure the alignment of the head and cylindrical - the corresponding leading part in the pool - parts in the newly obtained semi-finished product 20], it is possible to manufacture in the matrix a small section in height, in the profile diameter which is equal to the outer diameter of the cylindrical part of the semi-finished product 17. But at the same time, the crushing force of the semi-finished product 17 in the matrix 18 after punching holes in it should be less than the force of shooting the semi-finished product from the punch shooting ring 19.

 The arrangement of the tool and the semi-finished product of FIG. 5 - the punch 16 during the working stroke sent the semi-finished product 17 to the stop of its outer surface of the head part in the profile [working] part of the matrix 18, the further movement of the semi-finished product 17 in the direction of movement of the punch 16 has stopped, but the movement of the punch 16 will continue while continuing the movement of the punch 16 will begin punching a through hole at the tip of the semi-finished product 17.

 The remote element A of the circuit of FIG. 5 [enlarged view of FIG. 6] is given for a more visual representation of the location of the tool used.

 The general arrangement of the working tool and the manufactured prefabricated shell 20 after punching a through hole in the apex, shown in FIG. 7 [only the location of the extension element A of FIG. 5, enlarged image], has a punch 16 located in the extreme position after completion of the stroke. In FIG. 7 between the lower end of the guide portion of the punch and the inner corresponding surface of the semifinished product 20, a gap is not indicated, but it can be - it is enough to adjust the length of the working stroke of the punch after punching a through hole in the apex. The process of punching a hole in a semi-finished product occurs in the same way as in [15]. The part [grit] separated from the semifinished product 17 after punching the hole in the diagram of FIG. 7 is not specified.

As a result of the operation of FIG. 5 - 7, the length of the head of the semi-finished product 17 is reduced by Δ ₁ and in the semi-finished product 20 has become equal to the value L ₂ = L ₁ -Δ ₁ .

After the punch 16 completes the working stroke, the manufactured semifinished product 20 with the through hole of diameter D ₁ formed at the apex fits snugly on the surface of the punch 16, when it moves backwards, it moves with it, leaves the matrix 18 and is removed from the punch by a shooting ring 19.

The general arrangement of the working tool and the prefabricated shell [prefabricated - after performing the operation of FIG. 5 - 7] before stamping on the inner surface of its head part of the longitudinal grooves with the simultaneous extrusion of the material of the semi-finished product in the area adjacent to the tip of the semi-finished product, according to FIG. 8 has a punch 21, the course of which is incomplete, with blades for forming grooves, blunted on a section located from the end of the working part, passing through the ring-shot 19 and entering during stamping together with the semi-finished product 20, which has a through hole of diameter D ₁ at the apex, in the matrix 22. The design of the punch 21 is based on the construction of a similar punch according to [15], including the profile contour of the blades, on which, in contrast to the punch according to [15], the indicated blunting from the end face of the working part was performed, and blunting can be performed but both in the form of a flat surface, and in the form of a figured one. The limiting value of the diameter of the cylindrical part of the punch 21, which enters into the semi-finished product 20, and the diameter of its part from the beginning of the formation of the blades to the beginning of the section of the profile part of the blades, formed along the radius towards the end of the working part, is the inner diameter of the cross section of the semi-finished product 20 at the base of its head parts with the least permissible outer diameter and the largest wall thickness of the semi-finished product [taking into account tolerances for the manufacture of semi-finished products]. Under this condition, traces [in the form of scratches] of the beginning of the longitudinal grooves may appear at the base of the head of the semi-finished product, which is observed during the production of a part of some products [semi-finished shell 23] after performing the operation to form longitudinal grooves. When checking firing after mounting cartridges with bullets having shells with the actual beginning of the longitudinal grooves from the base of the warhead, no dismantling of bullets was observed.

 The matrix 22 of FIG. 8 is made blind and in the profile has the same geometric parameters as in the matrix 18 of FIG. 5 - 7 except the top. The geometrical parameters of the profile of the working part of the matrix 22 are subject to the same requirements as the matrix 18. In this case, the transition of the profile of the matrix 22, which forms the head of the semi-finished product 23, into the profile that forms its apex, is predominantly smooth. In FIG. 8, the profile in the matrix forming the vertex corresponds to the vertex in the semi-finished product of the last crimp 17 and the adjacent surface and is formed by the radius, which in the matrix has the shape of a hemisphere. If necessary, the surface of the working part of the matrix corresponding to the vertex, as well as adjacent to it, along which the outflow of the material of the semi-finished product occurs during stamping, can be polished so that the working part of the matrix is slightly deepened and the volume for the outflow of material inside the matrix is performed during the stamping operation. The shape of the head of the bullet, and before that - the shell of the bullet and the prefabricated shell, is formed by the radius [2, p. 26]. Polishing the matrix within certain limits can somewhat disrupt this shape, which can be allowed if the symmetry of its working surfaces relative to the longitudinal axis is preserved.

 The arrangement of the tool and the semi-finished product of FIG. 8: the punch 21 in the course of the working stroke sent the semi-finished product 20 to the stop of its outer surface of the head part in the profile [working] part of the matrix 22, the further movement of the semi-finished product 20 in the direction of movement of the punch 21 stopped, but the movement of the punch 21 continues and with its subsequent moving on the inner surface of the head of the semi-finished product will begin the formation of longitudinal grooves with the simultaneous outflow of the material of the semi-finished product in the area adjacent to the cut in the apex, in the places of impact on the floor a blunting product on the punch blades.

 The remote element B of the circuit of FIG. 8 [enlarged view of FIG. 9] is given for a more visual representation of the location of the tool used.

 General layout of the working tool after stamping and formation of longitudinal grooves on the inner surface of the head of the semi-finished product with simultaneous extrusion of the semi-finished material in the area adjacent to the hole punched at the tip of the semi-finished product, in the places where the dulls on the blade of the punch act on the semi-finished product and the product forms 23 shell bullets declared cartridges shown in FIG. 10 [only the location of the extension element B of FIG. 8, an enlarged image] and has a punch 21 located in the extreme position after the execution of the stroke. The process of groove formation in the prefabricated shell in the area where the blades are not blunt is similar to that specified in [15] and the shape of the grooves is the same. In the blunting region of the punch blades, most of the semifinished material flows out in the direction of the punch moving into the free volume between the punch and the die, filling it incompletely while maintaining a through not necessarily cylindrical hole in the tip of the resulting shell 23 [in principle, as yet a semi-finished shell], increasing slightly by stretching the portion in the front of the semi-finished product adjacent to the previously punched hole. The shape of the grooves in the blunting section of the blades has their imprint, the depth of the grooves decreases [increases the wall thickness of the semifinished product] towards the cut, and on the walls of the through hole after stamping, as a rule, traces of longitudinal grooves remain.

As a result of the operation of FIG. 8-10 through hole with a diameter D _{1 of the} semi-finished product 20 of FIG. 9 is reduced to a diameter D _{2 of the} shell 23 of FIG. 10, and the length of the head of the semi-finished product 20 is increased in the shell 23 by Δ ₂ and is equal to L ₃ = L ₂ + Δ ₂ . The length of the semi-finished product 20 is also increased by the same value of Δ _2. In the operation of FIG. 8-10, it is necessary to debug the working stroke of the punch 21 - its non-profit to the extreme point of the working part of the matrix 22 by Δ ₃ , otherwise the punch blades can break through the wall of the shell 23.

 After completion of the working stroke by the punch 21, the formation of longitudinal grooves and the final design of the through hole and the portion adjacent to the sheath cut at the apex, the fabricated shell 23 adheres tightly to the surfaces of the punch 21 at the points of interaction and, with the reverse stroke of the punch, moves with it, leaves the matrix 22 and is removed from the punch by a shooting ring 19.

 The fabricated shell 23 of FIG. 10 takes the final shape of the shell 5 after mounting the bullet 4 of FIG. 1, the bullets 7 of FIG. 2, the bullets 10 of FIG. 3 or bullets 13 of FIG. 4. Since pushers are used to mount bullets to remove them from the matrices [the pusher acts on the bullet or its semi-finished product from the vertex side] after performing the corresponding operation, the sharp edge at the cut in the tip of the shell 23 on the shell 5 of these bullets is the same as in the prototype of cartridges according to [12] with a bullet according to [13], but the diameter of the cut, which is directly dependent on the diameter of the hole on the cut of the shell 23, will be clearly smaller than in the prototype of the cartridges.

 The claimed method of manufacturing a shell of bullets for hunting cartridges can improve the aerodynamic quality of bullets in the claimed cartridges by reducing the drag force.

 Hunting cartridges, the specific performance of which was made using a combination of features within the limits declared for any of the claimed inventions and variants, the shells of bullets in which are made by the claimed method, as a result of a shot when a bullet hits a target [animal - object of hunting] in terms of hydrodynamic impact on animal tissue and parameters of the wound canal in combination with explosive, fragmentation [with at least partial destruction of the bullet in the animal’s tissues] and energy properties, due to improved aerodynamics amic parameters on the flight path of the bullets will provide more effective shooting of large, medium and relatively small animals by the effective range of shooting in hunting conditions due to the increase in slaughter action when compared with similar shooting conditions at the same range and the same initial conditions of the shot, which from the technical point of view increases the likelihood of reliable destruction of the animal - the object of hunting.

 Changing the volume of the loading chamber by replacing the cartridge case, such as in cartridges 9.3 x 53 according to [1], 9.3 x 64 or 9.3 x 74 according to [3], allows changing the energy parameters of bullets [as well as changing the mass of the bullet without changing its design] declared cartridges depending on the conditions and objects of hunting and increase the similar parameters of known cartridges under the same initial conditions of the shot.

Literature
1. Blum M.M., Shishkin I.B. Shotgun. - M .: Forest industry, 1983, 216 p.: Ill.

 2. Kirillov V. M., Sabelnikov V. M. Cartridges of small arms. - M.: Central Research Institute of Information, 1980, 372 pp., Ill.

 3. Permanent International Commission [PMK] for the testing of handguns // Table of sizes of cartridges and chamber. - 24th session of the PMK. - Brussels [M .: Gosstandart].

 4. Patent N 4015079, F 42 B 5/02, 1991, Germany.

 5. Patent N 4210204, F 42 B 5/02, 1995, Germany.

 6. GOST 21169-75. Hunting cartridges 7.62 x 51. Types and main dimensions.

 7. Copyright certificate of the USSR N 328319, F 42 B 11/04, 1970.

 8. US patent N 3426685, F 42 B 11/10 [102 - 91], 1969.

 9. U.S. Patent No. 3,138,102, 102-92.5, 1964.

 10. US patent N 3143966, 102-91, 1963.

 11. US patent N 3157137, 102-91, 1964.

 12. The magazine "Hunting and hunting economy", N 6, 1991, p. 26.

 13. USSR patent N 1753962, F 42 B 12/02, 1990 (prototype).

 14. RF patent N 2003033, F 42 B 12/02, 1992.

 15. RF patent N 2015495, F 42 B 12/34, 1991 (prototype).

 16. Malov A.N. Production of small arms cartridges - M .: Oboronprom, 1947, 416 pp., Ill.

 17. Hunting shooting / per. from German., E. Balthrush et al. - M .: All-Union Center for the Translation of Scientific and Technical Literature and Documentation, 1978, N A23860, 354 pp., ill.

Claims (5)

 1. Hunting cartridge, containing a cartridge case with open ends along the bottom of the housing closed on one longitudinal axis, a propellant charge inside the cartridge case, a primer inserted in the center of the closed end of the cartridge case on the same longitudinal axis, and a bullet located on the open the end of the sleeve on the same longitudinal axis with it, consisting of a shell and a core placed in it and made with open tail and leading parts that go into the sleeve, as well as a seamless head with a cut in the apex, free volume under the cut, open washed from the cut side, and softening longitudinal grooves located on the inner surface of the shell, characterized in that the free volume under the cut to the tip of the bullet is opened by a hole coaxially located relative to the sleeve, and the diameter of the hole along the cut is less than the diameter of the same hole from the free side volume under the cut, the portion of the bullet head adjacent to the cut is retracted toward the cut with a groove length of not more than the length of the head.  2. The cartridge according to claim 1, characterized in that it is made with a bullet containing a composite core.  3. A hunting cartridge containing a cartridge with open ends along the bottom of the housing on one longitudinal axis, a propellant charge inside the cartridge, a primer inserted in the center of the closed end of the cartridge housing on the same longitudinal axis, and a bullet located on the open the end of the sleeve on one longitudinal axis with it, consisting of a shell and a shirt and core placed in it and made with parts of the open tail and lead that go into the sleeve, as well as a seamless head with a cut in the apex, free volume under the middle zom open from the side of the cut, and softening longitudinal grooves located on the inner surface of the shell, characterized in that in it the free volume under the cut at the tip of the bullet is open with a hole coaxially located relative to the sleeve, and the diameter of the hole along the cut is less than the diameter of the same hole with side of the free volume under the cut, the portion of the bullet head adjacent to the cut is elongated towards the cut with a groove length of not more than the length of the head.  4. The cartridge according to claim 3, characterized in that it is made with a bullet containing a composite core.  5. A method of manufacturing a shell of a bullet of a hunting cartridge, open from the side of the tail part and from the side of the apex, made with an adjacent head part, including the manufacture of a semi-finished shell by cutting and convolving a hollow hood, as well as multi-junction hoods with crimps, punching a through hole in the apex the head of the semi-finished product by means of a matrix and a smooth punch from the side of the inner cavity of the semi-finished product with a decrease in the length of the head and the total length of the semi-finished shell, stamping on the inner surface of the head part from the side of the inner cavity of the semi-finished product of longitudinal grooves of variable depth by means of a matrix and a punch having blades on the side surface of the working part, characterized in that the hole is punched before stamping after the last firing of the semi-finished shell, and the hole is punched coaxially located relative to the outer surfaces of the semi-finished product, while for punching the hole the matrix is made with a Central through hole and working part, the geometrical parameters of which are determined by the geometrical parameters of the predominantly outer surface of the semi-finished product head, and the smooth punch is made of a profile, for stamping grooves, the matrix is made blind with a profiled working part, the geometrical parameters of which are determined by the geometrical parameters of the outer surface of the predominantly semi-finished product head with a smooth transition to the section, making out the contour of the vertex and the adjacent portion of the head of the semi-finished product, and the punch it is filled with a profile and has blades dulled in a section located from the end of the working part, and when stamping the outer surface of the head of the semi-finished product is abutted in the corresponding section of the profile part of the matrix and the blades of the working part of the punch act on the wall of the head of the semi-finished product, which form the outflow of the material of the semi-finished product in the section adjacent to the hole in the tip of the semi-finished product, between the walls of the blank matrix and the surfaces formed by the blunting of the stamping punch blades, in the direction of This means that the punch moves during the execution of the working stroke, as a result of which the length of the head part and the total length of the semifinished product are increased, the diameter of the hole in the slice in the head of the semifinished product is reduced with a corresponding reduction in the diameter of the cut in the apex of the head of the semifinished product, and the wall thickness of the semifinished product in the grooves is reduced in the direction of the cut by the impact area of the stamping punch blades without blunting and increase the wall thickness of the semi-finished product in the grooves towards the cut on the impact area of the blades stamping punch with blunting.

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