RU2046281C1 - Guided missile - Google Patents

Abstract

FIELD: anti-tank and anti-aircraft guided missiles. SUBSTANCE: missile body accommodates shaped-charge warhead 1 with lens assembly 5, leading shaped charge in body 9. The blasting device has target sensing switch 6 in the form of two insulated contacts 7 and 8, target non-sensing switch operating on the electromagnetic principle, safety- actuator mechanisms 4, electronic delay unit 10. Control compartment 11, reflector 13, damping unit 14 have central duct 15 with parallel tube 16 installed in it. Stepped tube 16 has steps whose diameter decreases to leading shaped charge 2. The missile can be furnished with fragmentation warhead 1. EFFECT: improved design. 8 cl, 10 dwg

Description

 The invention relates to the field of military equipment and can be used in the design of anti-tank and anti-aircraft anti-tank guided missiles.

 Known anti-tank guided missiles TOW, Milan, containing the main cumulative warhead (OKBCH), consisting of a body, explosive charge (BB) and cumulative lining, control compartment installed behind the warhead, leading cumulative charge (LKZ), an explosive device with a block electronic delay (BDZ) and special structural elements for protecting the main cumulative warhead from the effects of the leading cumulative charge (LKZ extension mechanism, protective screens.

 Special structural elements of protection make the missile heavier, increase its length, therefore, increase the cost of the missile, and with limited dimensions reduce the efficiency of the OKCH.

 Also known is a guided missile containing a cumulative warhead with a lens unit, a leading cumulative charge in the body, an explosive device with a non-contact target sensor, safety-actuating mechanisms, an electronically delayed unit and electrical circuits, a control compartment located between the cumulative warhead and the leading cumulative charge and blocked from the leading cumulative charge side by a reflector made in the form of a block of electronic equipment, moreover, in the control compartment n central channel bounded by a cylindrical tube, by the shaped-charge warhead is mounted a damping unit formed by a solid base with fixed on it by the elements leading charge munition.

 This design has several disadvantages associated with the features of the layout of the rocket, negatively affecting the cumulative effect, in addition, the rocket has a low efficiency in air chains, since its warhead does not have a fragmentation shirt.

 The aim of the invention is the creation of light, small-sized, cheap anti-tank and anti-aircraft anti-tank missiles, providing high efficiency of destruction of both armored and air (anti-aircraft missiles) targets by increasing the functional load on the components and elements of the missile.

 This is achieved due to the fact that in a guided missile containing a cumulative warhead with a lens unit located in the housing, a leading cumulative charge in the housing, an explosive device with a target sensor, with safety-actuating mechanisms, an electronic delay unit and electric circuits, a control compartment, the head fairing, while the control compartment is located between the cumulative warhead and the leading cumulative charge, is blocked from the side of the leading cumulative charge by a reflector, for example, in de of the electronic equipment unit, and on the side of the cumulative warhead, a damping unit, and in the control compartment and damping unit, a central channel is made with a cylindrical tube installed in it, the target sensor is made contact in the form of two isolated contacts, the reflector is made with the central channel, and the cylindrical tube is inserted into the specified channel and is equipped with a membrane and a diaphragm.

 The cylindrical tube is made stepwise with a decrease in the diameter of the steps to the leading cumulative charge.

 The reflector is made with a diameter smaller than the internal diameter of the rocket body and equal to 1.5.2 diameters of the leading charge.

 The damping block is formed by a set of structural elements held together by a bonding material.

 As a binder, vixint was used.

 The housing of the leading cumulative charge is made of plastic, one of the insulated contacts of the contact sensor of the target is fixed on it, and the other is the fairing, and the isolated contacts are connected via electrical circuits to the safety-executive mechanism of the leading charge.

 The head fairing is made of plastic, and an electrically conductive layer is applied on its inner surface.

 The fragmentation warhead is placed without a gap behind the cumulative warhead and is connected to an explosive device, the lens unit is located in the fragmentation warhead at the end face adjacent to the cumulative warhead, while the non-contact target sensor is made on an electromagnetic principle, installed at a distance from the fragmentation warhead 3,5,4,5 caliber rockets to perform the function of a reflector and is included in the electric circuit of the fuse in parallel with the contact sensor of the target.

In FIG. 1 shows a longitudinal section of a guided missile, where 1 is a cumulative warhead; 2 leading cumulative charge; 3 safety-executive mechanism; 4 cumulative charge; 5 lens unit; 6 pin target sensor; 7.8 isolated contacts; 9 body of the leading cumulative charge; 10 block electronic delay; 11 control compartment; 12 head fairing; 13 reflector; 14 damping unit; 15 central channel; 16 handset; 17 membrane or diaphragm; in FIG. 2 rocket, in which the diameter (d) of the reflector is less than the internal diameter (D) of the body of the rocket 19; in FIG. 3 rocket, in which the reflector 20 is made in the form of a block of electronic equipment filled with a binder material; in FIG. 4 rocket, in which the damping block is made in the form of a solid base 21 with elements of the rocket 22 fixed to it from the leading charge side; in FIG. 5 rocket, in which the damping block is made of a set of structural elements of the rocket 24 and the binder material 24; in FIG. 6 rocket, in which one of the isolated contacts of the contact sensor of the target head fairing 25, and the other 26 is mounted on the housing 27 of the leading cumulative charge made of plastic; in FIG. 7 a rocket in which the head fairing 28 is made of plastic, and an electrically conductive layer 29 is applied on its inner surface; in FIG. 8 missile, in which the cumulative fragmentation warhead consists of sequentially located fragmentation 31 and cumulative 30 warheads, while the cumulative charge enters the fragmentation warhead to the depth of the lens unit 33, and the reflector is made in the form of a non-contact sensor block of the target 34, made on electromagnetic principle; distance c is equal to 3.5. 4.5 caliber rockets; in FIG. 9 a rocket in which a cylindrical tube 18 is made stepwise with a reduction in the diameter of the steps from the cumulative warhead d ₁ to the leading charge d ₂ .

 The proposed design works as follows.

 When the guided missile interacts with the armored vehicles, isolated contacts 7 and 8 or 25 and 26 (Fig. 6) or the conductive layer 29 and the inner contact 26 (Fig. 7) of the target 6 contact sensor, which gives the command for the operation of the safety-actuating mechanism 3, are closed the leading cumulative charge 2 and the electronic delay unit 10. The detonation products generated from the explosion of the leading charge 12, after interacting with the reflector 13 and the membrane or diaphragm 17 are “discarded” in the radial direction, and the fragments are ter speed, and it is possible to destroy the reflector 13, which can be made both in the form of a rocket compartment with its elements filled with filler 20 (Fig. 3), and in the form of a non-contact sensor block of the target 3, 4, made on the electromagnetic principle (Fig . 8).

 The secondary stream of fragments generated during the destruction of the reflectors 13, 20, 34 is extinguished on the structural elements of the control compartment 11 and finally trapped by a damping block 14, which can be made in the form of a rocket block consisting of structural elements 24, the space between which is filled with filler 23 (Fig. .5), or a solid base 21 on which rocket blocks 22 are mounted (Fig. 4). If the reflector 13 is made with a diameter smaller than the internal diameter of the rocket body 19 (Fig. 2), then the damping unit 14 reflects the weakened flow of detonation products breaking into the gap between the rocket body 19 and the reflector 13 (Fig. 2). Thus, the effect on the cumulative charge 4 (Fig. 1) is completely eliminated. After a specified time, the electronic delay unit 10 gives a signal for the operation of the safety-actuating mechanism 3 of the cumulative warhead 1. The lens unit 5 forms a detonation wave front converging to the axis, a cumulative stream is formed from the cumulative charge 4, which moves along the channel 15 in the damping unit 14, the control compartment 11 and the reflector 13, protected from collapsing structural elements by the tube 16. If the tube is made stepped 18 (Fig. 9), then in the process of moving the jet along the tube 18 it is "calibrated" , i.e. smoothing of radial errors due to excessive pressure inside the tube. After exiting channel 15, the jet interacts with an obstacle.

 In the case of air targets being struck at the time of the missile’s flight at a minimum distance from the target, the non-contact target sensor 34 is triggered (FIG. 8), which gives a command to trigger the safety-actuating mechanism 35 if the non-contact target 34 sensor is connected in parallel with the target 6 target sensor (FIG. 10), the actuation of the safety-actuating mechanism 35 occurs after a delay time determined by the electronic delay unit 10, which is selected so that the fragmentation warhead 31 moves to the place of the non-contact target sensor 34 and is consistent with the necessary delay time, i.e. at a distance c, and is at a minimum distance from the air target, at this moment the safety-actuating mechanism 35 is triggered and the fragmentation warhead 31 is detonated.

 Since the most lightweight and small-sized control compartments are using free air flow as an energy carrier, they are installed in front of the control compartment in the air intakes in the zone where the leading charge is installed, the diameter of the reflector can be less than the internal diameter of the housing equal to 1.5.2 diameters of the leading charge, which will ensure the reflection of the detonation products of the leading charge in the radial direction.

 To completely isolate the cumulative warhead from the influence of the leading charge, a damping unit is installed between it and the control compartment, made in order to preserve the dimensions and mass of the rocket from its elements (battery, electronic amplifier, etc.) and binder material, which can easily fill the space between them, e.g. vixint. Such a damping unit picks up secondary fragments formed during the partial destruction of the control compartment, and reflects a significantly weakened flow of detonation products.

 The execution in the control compartment, the damping unit and the reflector of the channel causes the passage through them without loss of a cumulative stream. The channel must be protected by a tube from possible splinters falling into it from collapsing rocket structural elements. In this case, the tube thickness is insignificant and amounts to 1.2 mm, since it is located along the axis parallel to the main high-speed stream of fragments formed by the leading charge and reflector. Secondary fragments moving in the radial direction have little energy. To exclude the influence of the leading charge on the cumulative warhead, the channel is blocked by a diaphragm or membrane. The thickness of the membrane is chosen so that after exposure to detonation products, it maintains its integrity and remains stationary, if a membrane of considerable mass and thickness is required, a diaphragm is installed instead of the membrane, achieving partial pressure relief through its openings, thereby reducing the mass of the diaphragm and its thickness. The thickness of the membrane is usually 0.1.0.2 of the diameter of the leading charge.

 When a cumulative jet passes through a tube, a so-called channel effect occurs, caused by an increase in pressure inside the tube as a result of reflection of a shock wave from it emanating from the nose of the cumulative jet. Moreover, the pressure decreases in the direction from the walls to the center of the tube.

 Since the axes of the tube and the cumulative jet do not coincide (there is, as a rule, a small displacement of 0.1.0.3 mm), the cumulative jet will experience a one-sided radial effect, leading to its destruction.

 For the negative effect of this effect on the cumulative jet, the diameter of the tube opening should be 0.2.0.4 of the diameter of the cumulative charge. This leads to a decrease in net volume, especially if the tube has a significant length. In this case, it is possible to perform it stepwise with decreasing diameter in the direction of the cumulative jet movement (from the main cumulative charge to the leading one). In this case, at the first stage (the diameter of which is 0.2.0.4 of the cumulative charge of the main warhead), the axis of the jet is gradually aligned with the axis of the tube, and at the next stages, due to the comprehensive compression of the jet by internal pressure in the tube, its small radial defects are smoothed out , which helps to increase armor penetration. The ratio of the diameter of the step to its length is selected in the range of 0.1.0.5, depending on the diameter of the jet.

 In anti-aircraft missiles, along with a contact target sensor, a non-contact target sensor is installed, usually made on the basis of the reflection of laser beams from the target, such non-contact target sensors are expensive and have relatively large dimensions. The use of a non-contact target sensor, made according to the electromagnetic principle, makes it possible to significantly reduce its cost, and on the other hand to use its rather massive and robust mechanism as a reflector when installing a reflector between the control compartment and the leading cumulative charge. At the same time, the dimensions of the rocket are saved, and a partial increase in mass (electromagnetic compared to the laser non-contact target sensor) is compensated by the exclusion of the reflector from the design. It should be noted that other elements of the rocket that have sufficient mass, strength and continuity, such as plastic-flooded electronics, etc., can be used as a reflector.

 Since the leading charge and the contact sensor of the target are installed in the head of the rocket, their weight is important, since it determines the mass that presses on the rocket elements located behind them, and therefore through strength, their dimensions and mass. Thus facilitating the contact sensor of the target and the leading charge allows disproportionately reducing the mass of the rocket.

 Of all the contact sensors of the target, the most simple, reliable and easy is the sensor, made in the form of two isolated contacts. The combination of the plastic housing of the leading charge with a conductive contact allows, on the one hand, to reduce the mass of the leading charge, and on the other to isolate the contact and solve the problem of its fastening. The fairing can also be made of plastic by applying a very thin conductive layer to its inner surface.

 The use of the invention in anti-aircraft anti-tank missiles makes it possible to establish, by reducing the dimensions and weight of the carrier, full-sized cumulative and fragmentation warheads and to ensure their effectiveness at the level of special anti-aircraft and anti-tank missiles. To reduce the dimensions, the warheads have a common explosive device, and the lens unit of the cumulative warhead is partially buried in the fragmentation warhead. Such a deepening of the lens unit practically does not reduce the fragmentation effect, since the inert body of the lens unit is installed in place of the missing bottom of the fragmentation warhead. The detonation from the fragmentation warhead is transmitted to the cumulative warhead directly from one charge to another, since they are installed without a gap.

 The location of the fragmentation warhead behind the cumulative warhead removes it from the non-contact target sensor by a distance equal to 3.5.4.5 caliber rockets, which can lead to a decrease in the effectiveness of fragmentation actions (most of the fragments pass by the target) when setting the non-contact target sensor to the maximum level signal (this greatly simplifies the design of the sensor). However, connecting a non-contact target sensor to the fuse circuit parallel to the contact target sensor allows this problem to be solved by using an electronic delay unit as a matching time device, i.e. during the delay, the fragmentation warhead will move to the place of the non-contact target sensor.

 Thus, the application of the proposed technical solution will allow you to create light, small-sized, cheap anti-tank and anti-tank anti-tank missiles that provide high efficiency of destruction of both armored and air (anti-tank anti-tank missiles) targets by increasing the functional load on the components and components of the missile.

Claims (8)

 1. CONTROLLED ROCKET, containing a cumulative warhead with a lens assembly located in the hull, a leading cumulative charge in the hull, an explosive device with a target sensor, safety-actuating mechanisms, an electronic delay unit and electric circuits, a control compartment, a head fairing, and a control compartment placed between the cumulative warhead and the leading cumulative charge, blocked from the side of the leading cumulative charge by a reflector, for example, in the form of a block of electronic equipment, and from the side of the cumulative warhead, a damping block, and in the control compartment and the damping block, a central channel is made with a cylindrical tube installed in it, characterized in that the target sensor is made contact in the form of two isolated contacts, the reflector is made with the central channel, and the cylindrical tube is inserted into the specified channel and is equipped with a membrane or diaphragm.  2. The rocket according to claim 1, characterized in that the cylindrical tube is made stepped with a decrease in the diameter of the steps to the leading cumulative charge.  3. The rocket according to claim 1, characterized in that the reflector is made with a diameter smaller than the internal diameter of the rocket body and equal to 1.5-2 diameters of the leading charge.  4. The rocket according to claim 1, characterized in that the damping block is formed by a set of structural elements fastened with a binder material.  5. The rocket according to claim 4, characterized in that vixint is used as a binder material.  6. The rocket according to claim 1, characterized in that the leading cumulative charge body is made of plastic, one of the insulated contacts of the target contact sensor is fixed on it, and the cowl is the other, and the isolated contacts are connected via electrical circuits to the safety-executive mechanism of the leading charge .  7. The rocket according to claim 1, characterized in that the head fairing is made of plastic, and an electrically conductive layer is applied on its inner surface.  8. The missile according to claim 1, characterized in that it is equipped with a fragmentation warhead located without a gap behind the cumulative warhead and connected to an explosive device, the lens unit is placed in the fragmentation warhead at the end face adjacent to the cumulative warhead, additionally introduced non-contact the target sensor is made on the electromagnetic principle, installed at a distance from the fragmentation warhead, equal to 3.5-4.5 caliber rockets, to perform the function of a reflector and is included in the electrical circuit of the steam explosive device allel contact sensor goals.

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