RU2197708C1 - Method of target destruction by predominantly guided missile and missile for its implementation - Google Patents

Abstract

FIELD: military equipment, development of missiles of bulk-detonating action. SUBSTANCE: method of target destruction consists in initiation of live charge close to target and in action on target with energy of blast of live charge. Bulk-detonating charge is employed as live charge, it is transferred in direction of target and is simultaneously activated with subsequent ignition by encounter with oxygen of air on target. Transfer is carried out through injector. Salient feature of missile lies in use of bulk-detonating charge and ignition-blasting charge in its warhead and in execution of injector in the form of axial conduit in its sustainer engine oriented towards nose section and smoothly matched with recess of nozzle unit of engine into which part of shell of warhead enters and where ignition-blasting charge is buried in bulk-detonating charge. EFFECT: enhanced efficiency of use of warheads of bulk-detonating action in mix of missiles. 2 cl, 1 dwg

Description

 The invention relates to the field of military equipment and can be used in the development of rockets, mainly guided, equipped with a volume-detonating charge.

 Currently, anti-tank guided missiles are widely used in the armies of all countries.

 The progress of the development of anti-tank missiles tracked the constantly improved protection of tanks, first by simply increasing the caliber, mass and focal length of their cumulative warhead charge (LHV), and then equipping them with a leading cumulative charge (LKZ), which would initiate dynamic defense blocks on the armor of tanks before undermining the Blade.

 As a result of this, guided missiles acquired a peculiar structure, on the one hand, optimal for hitting modern heavy tanks, and on the other, preventing the effective use of warheads with volume-detonating charges, for example, from single-cycle thermobaric mixtures, the need for which is constantly growing due to the increase in the density of settlements in theaters of possible military operations and, as a result, the decrease in the role and number of all types of tanks.

An analysis of the current situation shows that equipping anti-tank guided projectiles with volume-detonating warheads while ensuring their maximum efficiency is relevant for the following reasons:
- the industry of the militarily advanced countries is focused on the production of guided anti-tank shells with KBZ;
- the main firepower of the likely enemy will be located in large bulk buildings and structures of residential, economic and industrial buildings of settlements where the role of tanks is negligible;
- volume-detonating charges are capable of completely destroying large-volume buildings and structures of any building, including fortifications, as well as lightly armored and other equipment with the destruction of everything in them.

 As an analogue of the proposed technical solution, the design of the known guided missile projectile [1], containing the leading cumulative charge placed in the hulls, the steering drive unit with aerodynamic rudders and the main warhead, can be used. In this case, the leading cumulative charge is installed at the end of the steering drive unit, the housing of which in the front part is made cylindrical with holes along the rudder axis. The rear part of the body of the block of the steering drive is made in the form of a truncated cone installed with the formation of a closed volume with a cumulative funnel of the main warhead and equipped with a corrugated elastic cuff fixed to it with a conical outer surface, in the cavity of which a gas generator with an electric igniter is installed. The projectile is equipped with a pipe mounted on the body of the steering drive unit with the possibility of movement relative to the body of the warhead, and on the rear of the tube and the front of the main body of the warhead mounted elements of direction and fixation, made in the form of a split spring ring with conical hooks, placed in the pipe wall , and a guide ring on the body of the warhead with seats for hooks, made in the form of two conical surfaces forming a sharp rib. At the same time, two guide pins are installed on the pipe, and a groove with a tapered inlet section is made on the guide ring.

In the design of a guided missile, the following disadvantages should be noted:
- the implementation of the head compartment sliding forward at start to ensure the necessary focal length of the KBZ from the target obstacle complicates and makes the design heavier;
- the presence of a gas generator with an electric igniter in the cumulative funnel KBZ can lead to damage to the surface of the funnel when the gas generator is triggered to ensure that the steering drive unit and other elements of the head compartment are advanced forward and reduces the reliability of the projectile as a whole;
- to exclude a significant deviation of the KBZ axis during the delay in its operation after hitting the target from the projectile axis, the structural elements of its connections with other projectile compartments must be indestructible, which significantly complicates the design.

 The method of hitting a target with this projectile is to extend the leading cumulative charge to the focal length for the KBZ at the start and undermining of the KBZ with the direction of part of its energy, as a rule, 15-20% in the form of a jet on the target surface.

 The noted disadvantages of the analogue are largely eliminated in the design of a guided missile [2], taken as a prototype of the proposed technical solution. This missile contains a head compartment, a marching rocket engine, a cumulative warhead with a charge, a leading combat charge, a rocket launch engine, and a steering gear unit. The design of the projectile provides for the placement of the KBZ between the mid-flight and the starting rocket engines, with the through channel being made along the axis of the main engine providing a free passage of the KBZ cumulative jet towards the target. The rear end of the engine provides a protective partition, and the longitudinal gap between this partition and the front end of the KBZ for the normal formation of the cumulative jet of the latter is 1.3 ... 1.8 of the diameter of its cumulative funnel (or its caliber).

The above missile design has the following advantages:
- the necessary focal length for the KBZ is provided due to the head compartment and the marching jet engine, which eliminates the need for forward forward LKZ and head contacts;
- the power design of the mid-flight engine protects the KBZ from the LKZ detonation products, which allows to increase the mass of the LKZ;
- a decrease in the creeping (i.e., destructive) mass of a projectile upon impact on an obstacle in the KBZ reduces the load on its shell, which reduces the strength and mass of the shell, which, in turn, allows to increase the mass of the KBZ.

 The method of hitting a target with this shell is simpler and therefore more reliable than that of an analogue, since it does not require the leading cumulative charge to be extended to the focal length for KBZ.

An analysis of the known anti-tank guided shells in terms of deploying warheads with space-detonating charges (ODZ) instead of KBZ in them shows that they do not satisfy this, because:
- the effectiveness of the high-explosive and high-explosive impact of warheads with special forces on the target increases with a decrease in the strength of their hull and their approach to the surface of the target (reaches its maximum value in an explosion directly on the surface of the target);
- increased efficiency is observed with a decrease in the effort of destruction upon impact on the target of the communications of warheads with neighboring rocket compartments.

 The technical problem, the solution of which the present inventions are connected by a single inventive concept, is to increase the efficiency of the use of warheads with volume-detonating charges in rockets.

 To solve the problem in a method of hitting a target with a rocket, mainly controlled, including initiating its warhead at the target and exposing the target to energy with the explosion of a warhead, according to the invention, a volume-detonating charge is used as a warhead, which is pumped towards the target by the injector and simultaneously activates him for his subsequent initiation of oxygen by air on the target.

 To solve this problem, it is proposed the construction of a jet charge, mainly controlled, containing a head compartment, a mid-flight rocket engine with an axial channel, a warhead with a bottom fuse installed behind the mid-flight engine, and a tail compartment. At the same time, a volume-detonating charge is placed in its warhead, and a volume-detonating charge injector is formed between the warhead and the head compartment, formed on the side of the head compartment with the axial channel of the mid-flight engine smoothly interfaced with the recess made in the bottom of the sustainer engine, and on the side warhead - the front of its hull, partially or completely recessed in the recess of the bottom of the marching engine and partially or completely filled with a volume-detonating charge and an ignition-explosive charge, fastened m one end face with a bottom housing the warhead on its axis, and the other - in recessed space-detonating charge.

 The essence of the invention is illustrated in the drawing, which shows in the context of a missile containing a head compartment 1 with head contacts 2, a mid-flight rocket engine 3, a warhead with a space-detonating charge 4 in a thin-walled body 5, a tail compartment 6. The warhead is equipped with a bottom fuse 7 and axial ignition-explosive charge 8, bonded to the bottom of the housing 5 and recessed in charge 4 from the side of the main engine. In this case, the warhead body is made with a conical section 9 from the side of the mid-flight engine 3. To pump part of the mass of the warhead 4 to the target surface, an injector device formed by the channel of the axial tube 10 of the mid-flight engine is mounted, one output of which is oriented into the cavity of the head compartment 1, and the other smoothly mates with a conical recess 11 in the nozzle block 12 of the main engine. The conical section 9 of the warhead body is partially or completely recessed in the conical recess 11 of the nozzle block and is also partially or completely filled with charge 4. The individual parts of the projectile are connected by thin-walled cylinders 13 using screws 14, passed through the through holes of the cylinders and screwed into the threaded holes of the respective compartments .

 The operation of the described design of a missile is as follows: when the missile hits the head compartment 1 about the target, the head contacts 2 close and a command is issued to fire this fuse 7, which initiates the ignition-bursting charge 8. During the delay time in closing the head contacts 2 in operation fuse 7 and ignition-explosive charge 8, which is determined mainly by the strength of the target surface, there is a crushing of a thin-walled head compartment and a thin-walled cylinder 13 to m When the marching engine 3 begins to collapse and the conical part 9 of the warhead 5 is bent into the conical recess 11 of the marching engine 3 under the influence of the pressing mass of the warhead and the tail compartment 6, ensuring their alignment.

 The initiation of an ignition-bursting charge 8 of a volume-detonating charge 4 starts from the bottom of the warhead and causes a detonation wave in the ODZ, directed perpendicularly to the surface of the ignition-bursting charge, i.e., to the side wall of the hull 5 and toward the main engine 3. The closer to to the marching engine, the larger the front of the shock wave from the ignition-bursting charge in the DLD deviates towards the marching engine. Due to this, the bulk of the mass of the volume-detonating charge 4, guided by the conical part 9 of the housing 5 and the conical recess 11 through the channel of the tube 10, is ejected into the cavity of the head compartment 1, i.e. directly to the surface of the target. In this case, due to the volumetric compression of the ODZ and its friction against the conical surfaces of the main engine housings and the warhead and the surface of the tube 10, the ODZ under conditions of an almost complete absence of oxidizing agent (air oxygen) is heated to self-ignition temperature. Activated in this way, the DLD is fully activated on the surface of the target, providing the most effective effect on it. In addition, when passing a large number of ODZ 4 through the tube 10, destruction of the latter and the main engine body 3 can occur with the formation of a large number of fragments directed both at the target surface and along it.

 Obviously, such a constructive solution for placing a volume-detonating charge both in a guided missile and in an uncontrolled one allows achieving its greatest effect on the target.

SOURCES OF INFORMATION
1. Guided missile - analogue. RF patent 2084809 for 1994, MKI 6 F 42 B 15/00.

 2. Guided missile - prototype. RF patent 2125230 for 1998, MKI 6 F 42 B 15/00.

Claims (2)

 1. A method of hitting a target with a missile, mainly controlled, including initiating its combat charge at the target and exposing the target to energy with the explosion of a combat charge, characterized in that a volume-detonating charge is used as a combat charge, which is pumped in the direction of the target by an injector and at the same time is activated him for his subsequent initiation of oxygen by air on the target.  2. A missile, mainly controlled, containing a head compartment, a mid-flight rocket engine with an axial channel, a warhead with a bottom fuse mounted behind the mid-flight engine, and a tail compartment, characterized in that a volume-detonating charge and its ignition are placed in its warhead a bursting charge, and a volume-detonating charge injector is mounted between the warhead and the head compartment, formed on the side of the head compartment with the axial channel of the mid-flight engine, smoothly interfaced with the recess, at the bottom of the marching engine, and from the side of the warhead - the front part of its body, partially or completely recessed in the recess of the marching engine and partially or completely filled with a volume-detonating charge, and an ignition-explosive charge, fastened at one end to the bottom of the warhead body along its axis, and the other - recessed into a volume-detonating charge.