RU2100758C1 - Composite artillery shell case - Google Patents

Abstract

FIELD: ammunition, in particular, design of composite artillery shell cases, can find a wide application in production of composite artillery shell cases with a plastic body. SUBSTANCE: in the known shell case, having a plastic body, metal bottom plate and a retaining ring, the ring in the section located above the bottom plate shoulder and not overlapped by other components, has sealing gasket in the section between the bottom wall and its mating part of the body decreases in thickness to the periphery to a value not exceeding 0.35 of the thickness of the body wall in the section, corresponding to the gasket cut; the bottom plate in the area of contact with the body bottom has one or several ring bosses of a tapered, rectangular or oval profile equal to 0.2 to 0.35 of the body bottom thickness; body under- cutting in the section passing through the plane of the bottom plate open butt end equals 1.00 to 1.20 of the bottom plate wall in the area of the open butt end. EFFECT: improved design. 4 cl, 3 dwg

Description

 The invention relates to the field of ammunition, in particular to the design of prefabricated artillery shells, and can be widely used in the manufacture of prefabricated artillery shells with a plastic case.

 The most important requirements for prefabricated artillery shells with a plastic case are to ensure the tightness and assembly and strength of the assembly elements.

 The peculiarity of the use of these shells is that they are supplied to complete the shots of separate loading of medium and large caliber artillery systems.

 Closest to the invention in terms of technical nature and the achieved positive effect is a prefabricated sleeve with a plastic case (US patent N 3026802, claimed 16.12.1958, NKI 102-43), containing a plastic case, a metal tray, a retaining ring and a sleeve.

However, the known sleeve has the following disadvantages:
when firing at a temperature of -50 ^o C there were breaks in the plastic case;
inadequate chambering of the sleeve into the gun chamber and chipping of extractor hooks;
deflection of the retaining ring and, as a result, violation of the strength of the connection of the pallet and the housing;
lack of tightness during operation.

 The study showed the following that, when the case is manufactured by the progressive method of extrusion-blow molding from plastic, the minimum diameter of the hole in the bottom of the case is limited by the plastic possibilities of the material, therefore, to compensate for the gap between the ring and the pallet, a step with a height slightly less than the thickness of the bottom of the case is made on the inner surface of the bottom of the pallet. However, due to the presence of a guaranteed gap between the ring and the ledge of the pallet with an increase in the pressure of the powder gases during firing, it is possible to deflect the ring with a weakening of the fastening and movement of the body relative to the pallet. With increasing shot pressure, it is necessary to increase the thickness of the retaining ring, while the requirements for strength during operation remain unchanged. So, mining experience has shown that to ensure the strength of the fastening of the details of the sleeve during official handling (transportation, handing guns into the chamber, etc.), a 4 mm thick ring is sufficient, while a ring with a thickness of at least 8 is necessary when firing and subsequent extraction mm

 Naturally, such an increase in thickness is undesirable from an economic point of view, since it entails an increased consumption of metal, increases the complexity of manufacturing, the mass of the sleeve and, in addition, leads to a decrease in the internal volume of the sleeve.

To ensure tightness, a rubber gasket is used. The location of the sealing element between the housing and the pallet through a single connector between the details of the prefabricated sleeve, connected directly to the external environment, is the most reliable method of sealing. When an annular rubber gasket of constant thickness was placed between the body and the pallet at a charge temperature of -50 ^° C during firing, the phenomenon of notching the lower part of the plastic body at the cut of the gasket was detected due to a sharp decrease in the plasticity of the plastic during cooling.

 When the thickness of the gasket is of the same order (1.5 to 2.0 mm) with the thickness of the plastic case (3.5 to 4.2 mm), the material of the latter experiences deformation at the shear of the gasket that is close to or even exceeds the allowable elongation.

 At the same time, it is not possible to solve the problem of improving the functioning conditions of the lower part of the housing by a usual decrease in the thickness of the gasket due to the restrictions imposed by the tightness requirements.

 To cover irregularities of a certain height with a decrease in the thickness of the gasket, an increase in the relative compressive strain is required, which is limited by industry standards for rubber goods under the conditions of guaranteeing the shelf life. In addition, an increase in the degree of deformation of the gasket requires an increase in the force on the fasteners. For example, when fastened with a nut screwed onto the nipple of the pallet, an increase in the torque on the nut leads to the deflection of the pallet, i.e. additional corrective surgery is required.

 Another solution, which consists in increasing the wall thickness of the casing, is limited by stringent requirements imposed on reducing the sleeve volume, charge capacity and internal ballistic requirements.

 The presence of a sealing gasket greatly complicates the assembly process, i.e. mechanization and automation. When the bottom thickness of the pallet is 9 mm or more, the tightness of the connection is carried out by introducing ring protrusions made on the flat bottom of the pallet into the bottom of the plastic case.

 When carrying out acceptance tests (PSI) by shooting, in some cases there was a non-closing of the wedge when the sleeve was sent into the gun’s chamber. Due to the fact that there is a necessary initial gap between the sleeve and the gun chamber, which serves for free loading, the alignment between the sleeve and the gun chamber is not ensured. This leads to the fact that the contact between the sleeve and the chamber does not occur on the entire surface of the plastic case, but only on a small area. A slight skew occurring during such a re-entry leads to the fact that the pallet protruding beyond the plastic case fits into the flange of one of the extractors with a cut, i.e. the sleeve "does not fit" on the hooks of the extractors with a flange, as it should be in order to ensure free movement of the wedge. As a result of this, when reloading, the sleeve protrudes beyond the breech section of the barrel (is not sent) by an amount equal to the height of the pallet, and thereby prevents "closing the wedge", which leads to a delay in firing.

 Due to the fact that when a medium or large caliber sleeve is re-inserted (reload speed 2 m / s and weight 10 15 kg), the pallet strikes the extractor hook with a wall shear, brittle failure of the hook occurs, i.e. fast failure of extractors.

In contrast to the prototype in the proposed team sleeve:
the ring in the area located above the ledge of the pallet and not blocked by other elements is made with holes evenly spaced around the circumference;
the sealing gasket in the section between the wall of the pallet and the lower part of the body mating to it is made decreasing to the periphery of a thickness to a value not exceeding 0.35 of the wall thickness of the body in the corresponding section of the gasket section;
one or more annular protrusions of a pointed, or rectangular, or oval profile with a height equal to 0.2 0.35 day thickness of the case are made on a pallet in the contact zone with the bottom of the body;
the undercut of the body in the section passing through the plane of the open end of the pallet is made equal to 1.00 1.20 thickness of the wall of the pallet in the area of the open end.

 Common signs of a well-known sleeve with the proposed authors is the presence of a plastic case, a metal tray and a clamping ring.

 These features distinguishing the invention from the prototype and to which the requested amount of legal protection applies are sufficient in all cases.

The proposed design has advantages over the prototype:
a locking ring in the area located above the ledge of the pallet and not blocked by other elements, made with holes evenly spaced around the circumference, reduces metal consumption while ensuring strength;
the sealing gasket in the area between the pallet wall and the lower part of the body mating to it, made decreasing to the periphery with a thickness not exceeding 0.35 of the body wall thickness in the corresponding section of the gasket, prevents the lower part of the plastic case from being cut at -50 ^o C on the cut of the sealing gasket;
one or more annular protrusions of a pointed or rectangular, or oval profile with a height equal to 0.2 0.35 of the thickness of the bottom of the body, made on a pallet in the area of contact with the bottom of the body, simplify the assembly process, i.e. automation and mechanization with ensuring tightness;
undercut of the body in the section passing through the plane of the open end of the pallet, made equal to 1.00 1.20 thickness of the wall of the pallet in the area of the open end, provides unhindered reloading of the sleeve into the chamber of the gun and "closing the wedge".

 This allows us to conclude that there is a causal relationship between the totality of the essential features of the claimed technical solution and the achieved technical results.

The objective of the invention is to ensure the tightness of the assembly and the strength of the assembly elements during operation of cartridges and firing in the temperature range from 50 ^o C to -50 ^o C.

The invention consists in that:
prefabricated artillery sleeve containing a plastic case, a metal pallet and a retaining ring, in contrast to the prototype, has a retaining ring in the area located above the ledge of the pallet and not covered by other elements, made with holes evenly spaced around the circumference;
the prefabricated artillery shell according to claim 1, in contrast to the prototype, has a sealing gasket in the area between the pallet wall and the lower part of the body mating to it;
the prefabricated artillery shell according to claim 1, unlike the prototype, has one or more annular protrusions of a pointed, or rectangular, or oval profile with a height equal to 0.2 0.35 of the thickness of the bottom of the body, made on a pallet in the area of contact with the bottom of the body;
the prefabricated artillery shell according to claim 1, in contrast to the prototype, has an undercut of the body in the section passing through the plane of the open end of the pallet, made equal to 1.00 1.20 thickness of the wall of the pallet in the open end zone.

 In FIG. 1 (longitudinal section of the proposed sleeve) shows a plastic housing 1, a metal pallet 2 with a step "b", a retaining ring 3, made with holes "a" located evenly around the circumference, nut 4, gasket 5, "c" the gap between the ring 3 and step "b" of the pallet 2.

 In the fixing ring 3 in the area located above the central annular ledge "b" of the inner surface of the pallet 2 and not covered by other elements (deformable nipple, nut, etc.), holes "a" are made. In this case, they are arranged evenly around the circumference. The number and size of them are selected empirically in each case. Through them, the cavity of the gap "c" between the ring 3 and the ledge "b" is connected with the internal volume of the sleeve. As a result, when fired, the pressure on the ring 3 from both sides is balanced, accordingly, the load on it is reduced and it becomes possible to reduce the thickness of the ring 3 without compromising operational reliability. The bending loads acting on the ring are reduced to a minimum, and the thickness of the ring 3 is independent of pressure.

The invention according to claim 2 is illustrated in the drawing (Fig. 1), where T _to the wall thickness of the plastic housing 1 in the section corresponding to the cut of the strip 5; g wall of the pallet.

In FIG. 2 shows a sealing gasket 5 prior to assembly, made on a portion l between the wall of the pallet r and the lower part of the housing 1 mating to it, decreasing to the periphery of a thickness t _p not exceeding 0.35 of the wall thickness of the housing 1 in the corresponding section of the gasket.

 The sealing gasket 5 is proposed to perform a variable thickness, decreasing from the center to the edge. Since the gasket 5 must have a constant thickness between the outer surface of the bottom of the housing 1 and the inner surface of the bottom of the pallet 2, a smooth transition to the thin part of the gasket is performed in the area adjacent to the inner surface of the wall of the pallet g. Changing the thickness of the gasket 5 can be made, for example , according to a linear law.

 The decrease in the thickness of the gasket is determined by the value of the permissible degree of deformation of the material of the body at the cut of the gasket under conditions of negative temperatures and high loading speeds.

 The amount of deformation of the body is equal to the thickness of the strip along the slice.

где T_k толщина стенки корпуса в сечении, по срезу прокладки;
t_п толщина прокладки по срезу;
[E_k] допустимая степень деформации материала корпуса.Hence the degree of deformation (E _k )

where T _{k the} thickness of the wall of the housing in cross section, along a section of the gasket;
t _{p the} thickness of the strip along the slice;
[E _k ] permissible degree of deformation of the body material.

).Since the permissible degree of deformation of the casing from ordinary 400 600% (at normal temperature) at -50 ^o C and a loading speed of 4 m / s is reduced to 35%, the thickness of the gasket on the cut should not exceed 0.35 of the casing wall thickness (

)

When t _p more than 0.35 T _k possible destruction of the body when firing at a charge temperature of -50 ^o C and breaking it along the cut of the gasket.

The invention according to claim. 3 is explained in the drawing (FIG. 3), which shows a plastic housing 1, metal pan 2 with annular protrusions g, retainer ring 3, the nut 4, the thickness T _d floor of the casing, _a height t of the projections.

 When the bottom thickness of the pallet 2 is 9 mm or more, to simplify the assembly process and to reduce the elements in the assembly, the tightness of the connection is carried out by introducing the annular protrusions g of the pallet 2 into the bottom of the plastic casing 1. The axial insertion force to ensure guaranteed tightness is not less than 5500 kgf, which with a bottom thickness the pallet 2 less than 9 mm bends the canvas of the pallet 2, which is unacceptable, as this can lead to difficult or incomplete "closing" of the shutter of the gun and failure of the capsule sleeve when firing.

 The amount of deformation of the body is equal to the height of the protrusion of the pallet.

,
где T_д толщина дна корпуса;
t_в высота выступа поддона;
[E_k] допустимая степень деформации материала корпуса.Hence, the degree of deformation (E _k ) is equal to

,
where T _{d the} thickness of the bottom of the housing;
t _{in the} height of the protrusion of the pallet;
[E _k ] permissible degree of deformation of the body material.

The permissible degree of deformation of the body at -50 ^o C and the loading speed of 4 m / s from 400 600% is reduced to 35% and the maximum height of the roughness of the profile R _max (from processing) of the adjacent surface of the bottom of the plastic housing 1 is 0.7 mm, which is at a minimum the bottom thickness T _d 3,5 mm is 20% i.e. the height of the protrusions t _in should be within 0.2-0.35 of the thickness of the bottom "t _d " of the housing 1.

When t _in more than 0.35 T _d may cause cracks in the bottom of the plastic housing 1 with a breakthrough of powder gases for the official cut of the gun.

When t _in less than 0.2 T _d possible leakage of the connection, i.e. in this case, t _is less than R _max .

The invention according to claim 4 is illustrated by a drawing (FIG. 3), in which T _p is the magnitude of the undercut of the housing 1; t _c the wall thickness of the pallet in the open end zone.

When T _p equal to 1.00 -1.20 t _{c, the} protrusion of the pan 2 beyond the housing 1 is eliminated and, as a result, the impact of the protruding tray 2 on the hooks of the extractors is eliminated.

When T _p less than 1.00 t _c there is a protrusion of the pallet 2 for the housing 1.

Performing T _p more than 1.20 t _c leads to a decrease in the wall of the body and its possible destruction during firing.

 During retraction due to the absence of a ledge between the pallet and the body, the wedge closes after the sleeve "sits" on the extractor hook with a flange, as it should be, to ensure free movement of the wedge.

 The functioning of the sleeve is as follows.

 After the projectile is sent to the barrel bore, a shell with a charge is sent to the gun chamber. Due to the fact that there is no ledge between the pallet 2 and the housing 1, the wedge closes after the sleeve "sits" on the extractor hook with a flange. After pressing the trigger, the capsule sleeve is triggered, the powder charge in the sleeve ignites, and a shot is fired. Due to the fact that the gap cavity between the ring 3 and the pallet 2 is connected to the internal volume of the sleeve by openings, and the pressure of the powder gases on the ring 3 is balanced on both sides and does not deform it.

Under the influence of the pressure of the powder gases, the plastic casing is adjacent to the rubber gasket 5, and since at the cut of the gasket the permissible degree of deformation of the casing material is greater than the actual deformation, destruction of the casing when fired at charge temperatures in the range from 50 ^o C to -50 ^o C does not occur.

 The introduction of the annular protrusions g of the pallet 2 into the housing 1 ensures the tightness of the assembly during operation and obturation of the powder gases during firing.

 Thus, the combined use of new technical solutions and their dimensional parameters in the proposed sleeve made it possible to obtain an increment (compared with the prototype) of a positive effect during its operation.

 At the same time, an experimental batch of the proposed artillery shell was manufactured and tested with positive results, on the basis of which a decision was made to use it in mass production.

Claims (4)

 1. A prefabricated artillery sleeve containing a plastic case, a metal pallet and a retaining ring, characterized in that in it the ring in the section located above the ledge of the pallet and not blocked by other elements is made with holes uniformly spaced around the circumference.  2. The sleeve according to claim 1, characterized in that therein the sealing gasket in the section between the wall of the pallet and the lower part of the body mating to it is made decreasing to the periphery with a thickness not exceeding 0.35 of the wall thickness of the body in the corresponding section of the gasket.  3. The sleeve according to claim 1, characterized in that it contains one or more annular protrusions of a pointed, or rectangular, or oval profile with a height equal to 0.2 0.35 of the thickness of the bottom of the housing.  4. The sleeve according to claim 1, characterized in that the undercut of the body in the section passing through the plane of the open end of the pallet is made equal to 1.00 1.20 of the wall thickness of the pallet in the open end zone.

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