RU2482424C2 - Support unit for shell retention in weapon barrel charged from breech, and method of its fixation - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: support unit (6) comprises a support element (8) with a board edge (7) and a trigger mechanism for ignition of the main cap of a mortar shell (1), and also comprises a connecting facility (10) for fixation of the connecting element (8) on a tail assembly (4) of the mortar shell (1). The connecting facility (10) for fixation of the support element (8) on the tail assembly (4) of the mortar shell (1) comprises at least one elastic part (13, 20, 30), made for fixation on the tail assembly (4) of the mortar shell (1) with the help of elastic forces.

EFFECT: increased reliability of shell retention.

6 cl, 7 dwg

Description

Field of Invention

[0001] The present invention relates to a support assembly according to the preamble of claim 1, and in particular, to a support assembly for holding a projectile in the barrel of a gun charged from a breech. The support unit comprises a support element with a flange and a trigger for igniting the main capsule of the mortar shell, and also includes connecting means for fixing the support element to the tail unit of the mortar shell. The present invention also relates to a method for securing a support element on the tail unit of a mortar shell according to the preamble of claim 10, wherein a support unit that contains a support element is mounted on the tail unit of the mortar shell and the support unit is connected to the tail unit of the mortar shell.

BACKGROUND OF THE INVENTION

[0002] The mortar can be mounted on a suitable movable base, for example, on an armored vehicle, which can advantageously be conveniently moved from one position to another and can also be quickly moved from a firing position to a safe place. When it becomes necessary to use the mortar for firing vertically or downward, the problem is that the mortar shell does not remain in place in the smooth barrel of the mortar, but can slide forward along the barrel so that it cannot be fired. US 5,503,080 discloses a support assembly that is mounted on guiding stabilizers of the tail of a mortar shell using friction forces. In the technical solution described in this patent, extremely accurate execution of the dimensions of both the tail of the projectile and the support assembly itself is required to ensure at least acceptable reliable operation.

SUMMARY OF THE INVENTION

[0003] An object of the present invention is to provide a support assembly and a method for securing it to a mortar shell in a gun barrel. The purpose of this invention is achieved by the construction of the support node, according to the characterizing part of paragraph 1 of the claims, characterized in that the connecting means for securing the support element on the tail unit of the mortar shell contains at least one elastic part that holds the tail unit of the projectile using elastic forces . The purpose of the invention is also achieved by the method according to the characterizing part of claim 10, characterized in that when the support assembly is fixed on the tail unit of the mortar shell and / or on one or more guide stabilizers forming part of the tail unit of the mortar shell and / or on the reciprocal part mounted on the tail of the mortar shell using one or more elastic parts so that when receiving the tail of the specified elastic part directs the elastic force to shnyuyu surface of the mortar shell and / or on one or more guide stabilizers, and / or on the mating part of the mortar shell tail.

[0004] Preferred embodiments of the present invention are disclosed in the dependent claims.

[0005] The present invention is based on fastening a mortar shell to a support assembly using connecting means that directs elastic force to the outer surface of the tail unit of the mortar shell. In other words, the connecting means comprises an elastic part, by means of which the tail unit of the mortar shell is fixed to the support unit. The elastic part according to this invention fixes the tail of the mortar shell in such a way as to direct elastic force to the outer surface of the tail of the mortar shell, or to one or more guiding stabilizers forming part of the tail of the mortar shell, or as to the outer surface of the tail of the mortar projectile, and one or more guiding stabilizers. Alternatively, the tail of the mortar shell may have a mating part, to which the elastic part is pressed by elastic force.

[0006] In the present invention, the fastening of the support assembly on the tail of the mortar shell is based on elastic force, and this fastening is more reliable than the fastening based on the friction force of the breech. Also, the possible size dispersion in the manufacture of a mortar shell does not affect the value of the fixing forces, and fixing in place of the support unit is not as critical as with a technical solution based on the friction force of the breech. The technical solution according to this invention makes it relatively easy to adjust the pressing forces. In addition, the advantage of this invention is that the support unit can be mounted on a mortar shell easily and quickly, even in difficult conditions.

[0007] According to an embodiment of the present invention, the support assembly is provided with an elastic ring which is adapted to receive a mortar shell. While receiving the tail unit of the mortar shell, the spring ring is deformed, while directing elastic force to the tail unit of the mortar shell. The spring ring can be made so that the elastic force is directed to the outer surface of the tail unit of the mortar shell. Also, the spring ring may contain one or more slots for receiving guide stabilizers that form part of the tail of the mortar shell so that the guide stabilizer, which is included in the specified slot, forces the spring ring to compress, while the slot directs elastic force to the guide stabilizer and secures the mortar projectile on the reference node.

[0008] According to another embodiment of the present invention, the support assembly is provided with a multilayer ring that is configured to receive the tail of a mortar shell. The multilayer ring is designed in such a way that it directs elastic force to the outer surface of the tail unit of the mortar shell. In other words, the tail of the mortar shell is designed in such a way that it is located in the space formed by the multilayer ring, and this ring is at least partially deformed when receiving the tail of the mortar shell and directs elastic forces to the outer surface of the tail of the mortar shell.

[0009] In another embodiment of the present invention, the support assembly is provided with an elastic connecting part that serves to receive a mating part mounted on the tail unit of the mortar shell. The elastic connecting part can be made, for example, in the form of an elastic sleeve designed for deformation in the transverse direction to its axis when receiving the reciprocal part and direct elastic forces to the reciprocal part when fixing the mortar shell on the supporting unit.

Brief Description of the Drawings

[0010] The invention will be described in more detail below with examples of embodiments with reference to the attached drawings, where

Figure 1 is a General view of the projectile held in the gun’s barrel by means of a support node, in accordance with an embodiment of the present invention;

Figure 2 is an embodiment of securing the support assembly on a mortar shell using a spring ring according to the present invention;

Figure 3 is a second embodiment of securing the support assembly on a mortar shell using a multilayer ring, according to the present invention;

FIG. 4 is a cross-sectional view of an embodiment for securing a support assembly to a mortar shell using a multilayer ring according to the present invention; FIG.

Figure 5 - multilayer ring of Figure 4;

6 is an embodiment according to the present invention for securing a support assembly on a mortar shell using an elastic part and a reciprocal part located on the mortar shell;

FIG. 7 is an embodiment of FIG. 6 when the support assembly is secured to a mortar shell using an elastic member.

DETAILED DESCRIPTION OF THE INVENTION

[0011] Figure 1 schematically shows a mortar shell 1 held in the gun barrel 2 by means of a support assembly 6 in accordance with an embodiment of the present invention.

[0012] The mortar shell 1 is located in the barrel 2 of the gun charged from the breech. The gun may be a mortar in which the inner surface of the barrel 2 is substantially smooth. The end part of the mortar shell 1 comprises a tail tube 3 and a tail unit 4. The tail unit 4 contains one or, as a rule, more guiding stabilizers 5 for specifying the path of the mortar shell 1. The design details of the mortar shell 1 may differ from the structure shown in the drawing. In order to achieve greater clarity, the breech of the gun and other details are not shown.

[0013] The support unit 6, according to this invention, is mounted on the tail unit 4 to hold the mortar shell 1 in place in the barrel 2 until the shot. The dimensions of the outer casing 12 of the support element 8, which is part of the support node 6, is chosen so that at least part of the tail unit 4 of the mortar shell 1 can be placed inside it. The side edge 7 in the support unit 6 prevents forward movement along the barrel 2 of the mortar shell 1 when the barrel 2 is directed horizontally or even when the barrel 2 is directed downward. The dimensions of the support node 6 is chosen so that it can withstand not only the loads caused by the mass of the mortar shell 1, but also any forces caused by vibration and accelerations. The supporting element 8 also contains a connecting means 10, with which a mortar shell 1 is fixed on the supporting node 6.

[0014] The connecting means 10 may be connected to the support element 8, for example, by means of a threaded connection or other mechanical connection, which is preferably detachable and optionally non-detachable. Also, the connecting means 10 can be connected to the supporting element 8 motionless.

[0015] Figure 2 schematically shows an embodiment in accordance with this invention when the connecting means 10 located in the connecting element 8 contains a spring ring 13. The spring ring 13 is designed so that it can receive the tail unit 4 mortar shell . In accordance with FIG. 2, the spring ring 13 forms an opening in which the end of the tail tube 3 can be accommodated. The opening of the spring ring 13 is configured such that when the tail tube 3 is placed in the hole, the spring ring 13 is compressed and compressed, directing the force of the spring ring on the outer surface 14 of the tail tube 3, i.e., on the tail of the mortar shell, and elastic forces force the mortar shell 1 to be fixed on the support node 6. In other words, the spring ring 13 serves as an elastic element ment directing the force of the ring on the tail unit 4 of the mortar shell 1 to fix the mortar shell 1 on the support node 6.

[0016] The spring ring 13 may have slots made to receive the guiding stabilizers 5, which are part of the tail unit 4 of the mortar shell 1. These slots allow the tail tube 3 to be placed opposite the bottom of the support element 8. Also, the spring ring 13 can be made so that mortar shell 1 can be easily pushed into the hole bounded by the spring ring 13, but at the same time removing it requires much greater effort so that the connection does not open before the shot. In accordance with FIG. 2, the spring ring 13 directs elastic forces to the outer surface 14 of the tail 4 in sections between the guiding stabilizers 5. Between the slots or other corresponding holes, claw-shaped spring elements 18 or other reed elastic parts in the spring ring 13 protrude when receiving tail unit 4 mortar shell. In other words, the opening of the spring ring 13 is smaller than the diameter of the tail tube 3 of the mortar shell 1, so when the tail tube 3 is pushed into the spring ring 13, its spring elements 18 are compressed so that the hole in the spring ring 13 increases in size. At the same time, the spring elements 18 are compressed and direct elastic force to the outer surface 14 of the tail tube 3 of the tail unit 4 of the mortar shell 1 placed in the opening of the spring ring 13, as shown in FIG. 2. Also in accordance with FIG. 2, the spring elements 18 are shaped so that their ends are bent towards the end of the support element 8, while the tail unit 4 of the mortar shell can be easily placed in the spring ring 13, but due to the arising spring force, the mortar is removed the projectile 1 of the spring ring 13 requires significantly greater effort.

[0017] In another embodiment of the spring ring 13 shown in FIG. 3, the slots can be made so that they contract when they accept the guiding stabilizers 5 and direct elastic forces to the guiding stabilizers 5. In other words, while receiving the guides the stabilizers 5, the slots open, directing elastic forces to the surface of the guiding stabilizers 5, which are in the direction of the longitudinal axis of the mortar shell 1. Also in this case, the spring elements 18 can be shaped so that the tails The empennage of the 4 mortar shell could easily fit inside the spring ring 13, but due to the action of the elastic forces arising, the extraction of the mortar shell 1 from the spring ring 13 requires significantly greater efforts. Thus, the slots of the spring ring 13 take the guide stabilizers 5 relatively easily, but at the same time, the spring ring 13 directs elastic forces to the guide stabilizers 5, so removing the mortar shell 1 from the spring ring 13 requires much greater effort.

[0018] In yet another embodiment, the spring ring 13 may be configured such that the aforementioned embodiments are combined, in which case placing the tail tube 3 in the opening of the spring ring 13 creates elastic forces directed to the outer surface 14 of the tail 4 and simultaneously guide stabilizers 5 in the slot 16 creates elastic forces directed on the guide stabilizers 5. Based on the foregoing, it should be noted that the spring ring 13 can be of any type, generating elastic force directed to the tail unit 4 of the mortar shell 1 when receiving at least part of the tail unit 4 of the mortar shell 1.

[0019] FIG. 4 shows another embodiment in accordance with this invention in which the connecting means comprises one or more multilayer rings 20. In the embodiment of FIG. 4, the connecting means of the support member 8 comprises a fastening sleeve 21 and attached to an elastic sleeve 23. The fastening sleeve 21 may be fastened to the support member 8, for example, by means of a threaded connection or rigidly, or by other mechanical connection. 4, two multilayer rings 20 are placed in a space inside the elastic sleeve 23. One or more support plates or base plates (not shown) can be placed between the multilayer rings either on the front or on the back side. The hole diameter of the elastic sleeve 23 is sufficient to accommodate the tail tube 3 of the mortar shell 1 or the head portion 25 of the tail tube. An embodiment with a multilayer ring 20 is shown in FIG. The diameter of the hole 24 of the multilayer ring 20 inside the elastic sleeve 23 is less than at least a little of the outer diameter of the tail tube 3 of the mortar shell 1 or the head part 25. Thus, when the mortar shell 1 is pushed into place in the supporting element 8, the multilayer ring 20, and essentially, its plates 22 are compressed and direct elastic efforts to the tail tube 3 of the mortar shell 1 or the head part 25, while elastic forces fix the mortar shell 1 to the support element 8. The diameter of the holes of the base plates and base plates The maneuvers essentially correspond to the outer diameter of the tail tube 3 of the mortar shell 1 or to the outer diameter of the head part 25, while they do not exert any resistance or force to the mortar shell.

[0020] As shown above, the connecting means 10 preferably contains one or more multilayer rings 20, depending on the magnitude of the required elastic force or the force required to secure the mortar shell. The inner surface of the multilayer ring 20, according to Figure 5, is divided into adjacent plates 22, capable of springing. The number of plates 22 and, accordingly, the length in the direction of the outer surface and in the direction of the outer radius may vary depending on the required elastic force. The multilayer rings 20 may be made of a steel plate by cutting or in some other way or from another material.

[0021] Figure 6 shows an embodiment according to the invention in which the connecting means 10 of the support member 8 comprises an elastic part 30. In addition, a mating part 32 is provided at the end of the tail tube 3 of the tail unit 4 of the mortar shell 1. The elastic part 30 made with the possibility of receiving the response part 32. The response part 32 is made on the tail 4 of the mortar shell, essentially at the end of the tail tube 3 in accordance with Fig.6. In this embodiment, the resilient member 30 is comprised of several claw-like parts made in a circle to provide a connecting part in the form of a sleeve.

[0022] In the embodiment of FIG. 7, the connecting part 30 in the form of a sleeve receives the response part 32 inside. The response part 32 is conical in the direction from the tail unit 4 of the mortar shell. This taper helps the proper placement of the mortar shell 1 in the support unit 6. Also, the conical surface of the mating part 32 is pressed against the inner walls of the connecting part 30 in the form of a sleeve when the mating part 32 is placed inside the connecting part 30. When the mating part 30 is placed mating part 32 for fixing the mortar shell in the support node 6, then from squeezing and compression, the connecting part 30 becomes loaded and at the same time directs elastic forces to the outer surface of the reciprocal part 32. To achieve To this end, the mating part 32 is made with an outer diameter of at least slightly larger than the inner diameter of the connecting part 30, while the connecting part 30 expands when the mating part 32 is placed inside it. In a preferred embodiment, the connecting part 30 extends far into the mating part 32 so far that the upper surface of the connecting part 30 covers the conical surface of the mating part 32. Thus, the connecting part 30 in the form of a sleeve fits snugly on the mating part 32 and cannot be detached. The conical shape of the mating part 32 also allows the mating part to lock in place inside the connecting part 30, as shown in FIG. 7, while the mortar shell cannot easily detach from the supporting member 8.

[0023] The counterpart 32 may be formed at the end of the tail tube 3 of the tail unit 4 of the mortar shell, in which case it is an extension of the tail tube 3 or part of the tail tube 3. In another embodiment, the counterpart 32 may simply be the end of the tail tube 3 left by the hollow when it forms a mating part 32.

[0024] The elastic force directed to the counterpart 32 through the connecting part 30 can be further increased by one or more resilient elements (not shown) mounted on the connecting part. The elastic elements can be separate elements placed on the outer surface of the connecting part 30. In addition, the mating part 32 can be made so that it is placed around the connecting part 30, while the elastic forces of the elastic connecting part 30 are directed to the inner surface of the mating part 32. The response part 32 may be the end portion 25 of the tail unit 4 of the mortar shell 1.

[0025] Referring to the foregoing, it should be noted that both the spring ring receiving the tail of the mortar shell or part of its internal volume, and the elastic connecting part placed around it, as well as the mating part made on the tail tube, can be made and vary in various ways and have a variety of forms. In other words, it is essential for the present invention that the mortar shell is configured to be fixed to the support assembly using elastic forces. Elastic forces are created by means of an elastic part made in the support member and contracting when the mortar shell is fixed to the support assembly. Further, it should be noted that in some cases, the mortar shell may be secured to the support member 8 in accordance with two or more of the embodiments described above.

[0026] It will be apparent to one skilled in the art that as the technology advances, the basic idea of the present invention can be embodied in various ways. Thus, the present invention and its embodiments are not limited to the above examples and may vary within the scope of the claims.

Claims (6)

1. A support unit (6) for holding a projectile (1) in the barrel of a gun charged from a breech section, comprising a support element (8) with a flange (7) and a trigger for igniting the main capsule of a mortar shell (1), connecting means ( 10) for fixing the support element (8) on the tail unit (4) of the mortar shell (1), which contains guide stabilizers (5), characterized in that the connecting means (10) for fixing the support element (8) on the tail unit (4) ) mortar shell (1) contains at least one elastic de al (13, 20, 30) adapted for guiding resilient forces to one or more guide stabilizers (5) forming part of the tail (4) of the mortar shell (1). 2. The support node (6) according to claim 1, characterized in that the elastic part (13, 20, 30) is made to direct elastic forces to the outer surface (14) of the tail unit (4) of the mortar shell (1). 3. The support node (6) according to claim 2, characterized in that the elastic part is a spring ring (13) made to receive the tail unit (4) of the mortar shell (1) so that the elastic forces are directed to the outer surface (14) tail unit (4) mortar shell (1). 4. The support node (6) according to claim 2, characterized in that it contains one or more multilayer rings (20), which are made with two or more adjacent plates (22) for receiving the tail unit (4) of the mortar shell (1) as follows so that the elastic forces of adjacent plates (22) of the multilayer rings (20) are directed to the outer surface (14) of the tail unit (4) of the mortar shell (1). 5. Support node (6) according to claim 3, characterized in that the elastic part is made in the form of a spring ring (13) with slots used to receive one or more guiding stabilizers (5) forming part of the tail unit (4) of the mortar shell (1) so that the elastic forces are directed at one or more guiding stabilizers (5) forming part of the tail unit (4) of the mortar shell (1). 6. A method of attaching a support assembly to a mortar shell, wherein: install a support assembly comprising a support member; and
fixing the support unit on the tail unit of the mortar shell, characterized in that the support unit is mounted on one or more guiding stabilizers forming part of the tail unit of the mortar shell using one or more elastic parts so that when receiving the tail unit of the mortar projectile the parts were directed to one or more guiding stabilizers, forming part of the tail of the mortar shell.

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