RU2301958C1 - High-explosive non-isotropic warhead - Google Patents

Abstract

FIELD: armament.

SUBSTANCE: the high-explosive non-isotropic warhead has a burster and a blasting device, which includes safety-actuating mechanisms, whose terminal assemblies are radially shifted relative to the burster axis, contact target sensor, radiometric noncontact target sensor for fixing the target and determining the side of flight at large misses, optical noncontact target-sensor designed for determining the side of flight at small misses, as well as an electronic unit for computation of the blast delay time, provided with a device for generation of a command for actuation of the safety-actuating mechanism, whose terminal assembly is shifted to the side opposite the flight side.

EFFECT: enhanced efficiency of warhead action.

1 dwg

Description

The invention relates to defense technology and can be used to create warheads, in particular for high-precision guided missiles or missiles of small and medium caliber.

Known guided missiles and shells of small and medium caliber (100 ... 200 mm) containing warheads that allow for the destruction of air, ground or surface targets, such as aircraft and helicopters, lightly armored and unarmored vehicles, artificial and natural shelters with manpower located in them, etc.

Known high-explosive fragmentation warheads (OFBCH) guided missiles and shells of the class "ground-to-air", "ground-to-ground", "air-to-ground" (see, for example, RF patent №2018779, IPC ⁵ F42В 12/32, publ. 08/30/94, bull. No. 16), containing a bursting charge with a fragmentation shell and an explosive device (WU), which includes a contact target sensor (CDC) and a safety-actuating mechanism connected by an electric circuit. The VU provides the detonation of the explosive charge of the OFBCh by the signal of the CDC at the time the rocket approaches the obstacle (target surface). As a result of the detonation of the explosive charge, a high-explosive fragmentation field is created that ensures the destruction of the above targets.

If the missile provided by the missile guidance system is larger than the target size or if non-contact warhead detonation provides an increase in the efficiency of hitting a target whose size is significantly greater than the miss, then the non-contact target sensor, either acting by the method of parameter registration, is also included in the control unit created by the target physical field (magnetic, electrostatic, thermal), or by the method of recording the optical or radar backlight signal reflected from the target (G. Merill, .Goldberg, R.Gelmgolts (trans. From English.) "Operations Research. Warhead. Start shells." Publishing House of Foreign Literature, Moscow, 1959). At the same time, NDCs that perform target illumination using their own means are called active NDCs and do not require the use of third-party target illumination sources for their work. The use of high-precision guided missiles of small and medium caliber active NDC or NDC as part of warheads, operating by the method of registering the parameters of the target created by the physical field, makes it possible to implement a promising application mode that does not require tracking the target during the entire flight of the rocket: shot-forgot mode .

In particular, it is known (see RF patent No. 2247928 for application 2003118765 from 06.23.2003, MKI ⁷ F42B 12/20) high-explosive fragmentation warhead (OFBCH) containing an explosive charge and an explosive device including a contact target sensor, the sensitivity diagram of which oriented along the axis of the warhead, and active optical non-contact target sensors placed on the side surface of the hull evenly around the circle, the sensitivity diagram of which is oriented perpendicular to the axis of the warhead. When a rocket approaches the target’s surface at angles close to 90 °, the well-known OFBCH is triggered in contact mode by a CDC signal under conditions of optimal approach to the target’s surface, allowing it to cause maximum damage by a joint high-explosive fragmentation effect. When a rocket approaches the target’s surface at angles close to 0 °, the well-known OFDM operates in non-contact mode by the NDC signal reflected from the target’s surface under conditions of air blasting, which can significantly increase the fragmentation damage area as compared to the contact action mode.

The use of active optical target sensors in the control unit, the sensitivity diagram of which is oriented in given directions, allows you to determine the side of the target’s flight, the relative speed of the missile approaching the target, and also to give a signal to detonate explosive warheads of the warhead at the required effective range of the distance to the target .

So, for example, in the German Federal Patent No. 4102772 C1, MKI ⁶ F42В 12/18, 12/10 dated January 31, 91, the design of a guided missile containing a cumulative warhead of a pre-contact detonation is described, the fuse of which is equipped with an optical non-contact target sensor, which, when received, is reflected from of the signal target issues a command to undermine the cumulative charge at a predetermined distance from the obstacle, for example, at a distance optimal for realizing the maximum breakdown ability of the cumulative charge contained in the warhead.

However, the technical solution described above has a significant drawback, namely, a warhead with such a slave has low noise immunity. In particular, if the warhead of a rocket moving at a small height above the surface of the earth or water contains an active optical NDC, the sensitivity diagram of which is directed to the front and / or lower hemisphere, any natural or artificial obstacles located or formed on the trajectory (crowns) can interfere shrubs and trees, camouflage shelters, wave crests, etc.). The optical signal sent by the NDC in a given direction, in particular in the direction of the trajectory of movement, will be reflected from the indicated obstacles with sufficient intensity for the fuse to trigger, the value of which is determined by the reflectivity of the obstacle surface, which is much higher for interference surfaces, especially artificially created, than for the surface of the target, the reflectivity of which is usually reduced by special measures. This can serve as a team for premature (erroneous) operation of warheads.

In addition, active optical target sensors are limited in range by the ratio of the power of the emitted signal and the sensitivity of the receiver of the signal reflected from the target. This leads to the fact that on misses equal to and greater than the range of the NDC selected for the assembly of the aircraft, the accuracy of determining the side of flight and the probability of operation of the aircraft are sharply reduced.

Also known (RF patent No. 2046281, MKI ⁶ F42B 12/10, publ. 10/20/95 bull. No. 29) warhead of the tandem type, which includes an explosive device equipped with safety-actuating mechanisms, an electronic block delay detonation and two acting on different physical principles by target sensors: located in the missile’s head - a contact target sensor and a non-contact target sensor - an electromagnetic (radar) principle of operation.

The radar NDC used in the indicated technical solution makes it possible to distinguish between the interference and the target, the surface of which is usually made of metal, giving a high reflectivity of the radar signal according to the sharply different intensity of the reflected signal.

Known active radar NDCs, the sensitivity diagram of which is oriented in a given direction, containing one or more pairs (transmitting and receiving) antennas that are placed on the surface of the warhead (or missile) with spatial diversity along the axis and around the generatrix of the housing (see, for example, .B. Ramodin. "The influence of the spatial separation of the receiving and transmitting antennas on the operation of non-contact target sensors" / "Bulletin of the Russian Academy of Missile and Artillery Sciences", issue 1 (42) 2005. - M .: Edition RARAN, 2005). The use of such NDCs as part of fuses of warhead guided missiles allows us not only to distinguish the target from the interference, but also to determine the side of the span, which makes it possible to include in the warhead a discontinuous charge of directed or directionally circular action, the detonation of which forms a lesion field oriented in a given direction (cumulative fragmentation or high explosive).

For the prototype as the closest to the claimed invention in terms of technical nature and the achieved technical result, the technical solution is selected, which is described in RF patent No. 2046281, MKI ⁶ F42B 12/10.

Signs of the prototype, common with the claimed design of high-explosive fragmentation warheads of directional circular action: explosive charge, equipped with an explosive device containing a safety-actuating mechanism, a contact target sensor, a non-contact target sensor of a radar type, as well as an electronic unit for calculating the delay time of detonation.

The specified prototype has a number of disadvantages that lead to a decrease in its effectiveness in the composition of the OFBC directional circular action when acting on targets whose defeat is carried out both due to fragmentation and joint high-explosive fragmentation. Namely: the required range of this NDC is provided by the spatial diversity of its emitting and receiving antennas. The implementation of the required orientation of the radiation pattern is carried out by a given sequence of switching the directivity of the action of its constituent antennas. So, for example, in the indicated article, an example of a radar NDC containing two pairs of diametrically opposite linear antennas located in orthogonal planes with an offset along the warhead (missile) axis relative to each other is given. Such NDC, due to the successive switching of the up-and-down directions for one pair of antennas and right-left for another pair of antennas, implements a radiation pattern that allows you to determine the side of the target span with an accuracy of 90 °. However, as noted, in particular, in the cited article, a fuse with such an NDC has a significant drawback, manifested in a decrease in the sensitivity of the NDC, and, consequently, in the accuracy of determining the side of passage with a decrease in the miss value. The use of such a fuse as part of a directional circular operation factor in the case of work on small targets on misses comparable in magnitude to the spatial diversity of the NDC antennas can lead not only to errors in determining the side of the span, but also to a sharp decrease (up to failure) in the probability of operation WU. This will result in a noticeable decrease in the overall effectiveness of the OFBCH, since with the commonly used method of aiming a guided missile at the center of the target, small misses are more likely to occur than large ones.

Another significant drawback in the design of the prototype, seen when there is information about the side of the span, is the lack of the possibility of redistributing the energy of a high-explosive fragmentation field (controlling the characteristics of the field of damage) in the equatorial direction.

Indeed, the use of an explosive device of a warhead prototype of an electronic unit for calculating the delay time of a detonation and a safety-actuating mechanism that do not provide, depending on the realized side of the span, a change in the place of initiation of the detonation of the bursting charge, impedes the implementation of structural schemes of warheads providing fragmentation of energy towards the target high-explosive field of defeat.

In addition, the radar NDC, which makes it possible to distinguish the target from natural interference, nevertheless, may have insufficient protection from the action of artificial interference, since clouds (false targets) specially organized by the interference installers from specially shaped reflectors of radio signals can significantly exceed the target in magnitude of the reflecting area.

Unlike the well-known high-explosive fragmentation warhead containing the main explosive charge, equipped with an electronic blasting delay unit, an additional explosive charge, an explosive device with a contact target sensor and a non-contact target radar sensor, as well as with safety-actuating mechanisms of the main and additional charges, the explosive the device of the proposed high-explosive fragmentation warhead directionally circular action contains two operating in different ranges of electromagnetic spec trail of non-contact target sensors, one of which, radiometric, is designed to fix the target and determine the side of the span for large misses, and the other, optical, is used to fix the target and determine the side of the span in small misses, while the electronic unit for calculating the delay time of the detonation is equipped with a device providing a signal for detonation to the safety-actuating mechanism, the end node of which is radially offset relative to the axis of the charge in the direction opposite to the side of the span of the target.

Technical solutions containing features that distinguish the claimed solution from the prototype are not known and do not follow explicitly from the prior art. This suggests that the proposed solution is new and has a sufficient inventive step.

The essence of the proposed technical solution is illustrated by the graphic image shown in the drawing, which shows a structural diagram of the proposed high-explosive fragmentation warhead of directional circular action and illustrates the process of its operation.

The proposed high-explosive fragmentation warhead of a directional circular action (see drawing) contains a bursting charge (1) and an explosive device that includes safety-actuating mechanisms (2a and 2b), a contact target sensor (3), and a radiometric non-contact target sensor containing a radiating (4) and receiving (5) antennas, designed to fix the target and determine the side of the span for large misses, as well as an electronic unit for calculating the delay time of detonation (6).

The blasting device is equipped with a multi-channel optical non-contact target sensor containing emitting (7a and 7b) and receiving (8a and 8b) channels, designed to determine the side of the span (9) in small misses, while the electronic unit for calculating the delay time of detonation (6) is equipped with a device (10), providing a signal for the operation of the safety-actuating mechanism (2a or 2b), the end node of which is radially offset from the axis of the charge in the direction opposite to the side of the span.

The proposed high-explosive fragmentation warhead directional circular action works as follows.

The radiometric non-contact target sensor, which is part of the fuse, detects the target and, in case of a miss, the magnitude of which exceeds the distance between the radiating (4) and receiving (5) antennas, determines the side of the span with discreteness along the equatorial angle, determined by the number of pairs of radiating and receiving antennas . An optical non-contact target sensor probes the surrounding space to a depth determined by its sensitivity. In the case of a miss, the value of which is less than the limit for the optical NDC, the optical signal sent by its emitting channel 7b, reflected from the target surface (9) and received by the receiving channel 8b, is perceived by the receiving unit of the optical NDC. It also provides the determination of the side of the span with discreteness by the equatorial angle, determined by the number of pairs of emitting and receiving blocks.

Upon receipt of a signal about the appearance of the target and the side of its span, the electronic unit (6) calculates the delay time of the blasting by the values of the relative speed and the angle of the meeting, after implementation, the device (10) issues a command to actuate the safety-actuating mechanism (2b) radially shifted about charge in the direction opposite to the side of the span, corresponding to the equatorial direction of the transmitting and receiving channels 7b and 8b of the optical multi-channel sensor.

Thus, the use of the proposed design of a high-explosive fragmentation warhead of directional circular action leads to an increase in the effectiveness of actions for various purposes for any, even the smallest misses (for example, less than the distance between the radiating and receiving antennas of the radiometric NDC).

Claims (1)

High-explosive fragmentation warhead of directional circular action, characterized by the presence of a bursting charge and an explosive device, including safety-actuating mechanisms, the end nodes of which are radially offset from the axis of the charge, a contact target sensor, a radiometric non-contact target sensor for fixing the target and determining the side of flight on large misses, an optical non-contact target sensor, designed to determine the side of flight on small misses, as well as an electronic time calculation unit the delay of blasting, equipped with a device that provides a command to operate the safety-actuator, the end node of which is biased in the direction opposite to the side of the span.