RU2688712C1 - Method of hitting aerial target with ammunition with non-contact target sensor - Google Patents

Abstract

FIELD: weapons.SUBSTANCE: invention relates to weapons and military equipment and can be used in fuses for ammunition for hitting aerial targets. Method of hitting an aerial target with ammunition with a contactless target sensor consists in the fact that the ammunition is fired into the zone of its meeting with the target. Non-contact target sensor emits and receives radio signals, analyses parameters of radiation and reception of signals during the flight of the ammunition and based on this analysis, steps of protecting the detonating fuse as the ammunition approaches the target. Infrared radiation ahead of the ammunition in the wavelength range higher than two micrometers is detected using the non-contact target sensor. At the moment of radiation level increase above the value at the initial moment of flight the next stage of ammunition protection is removed. Moment when the radiation level reaches the maximum value is recorded. Command is sent to the computing device of the non-contact target sensor to find the ammunition at the minimum distance from the target. Optimum moment for ammunition blasting is selected by specified algorithm.EFFECT: invention makes it possible to reliably identify a target flying with supersonic speed and to increase noise immunity of a non-contact target sensor from the effect of various radio interference.1 cl, 3 dwg

Description

The invention relates to weapons and military equipment and can be used in fuses for ammunition to destroy air targets.

Known methods of destruction of air targets using ammunition using proximity sensors target. These are various anti-aircraft ammunition and missiles, in which the main element of the fuse is a proximity sensor of the target. As a rule, these proximity sensors use the principles of radar. To avoid triggering the fuse from a false target, they use various devices for cocking and protection based on complex information processing algorithms from various elements of the fuse, which provide different stages for protecting the ammunition from premature detonation, and which ensure the ammunition to operate at an optimal distance from the target aircraft).

The need for continuous improvement of proximity sensors of the target is caused by the continuous change in the parameters of the targets, as well as by the presence of complex means of protection against their detection by means of radar. Serious difficulties in detecting targets also arise from the powerful counteraction of electronic warfare devices mounted on aircraft that create various interferences.

Also known target sensors, which register the thermal radiation from the target and on the basis of registration data is controlled by a rocket. Such target sensors are called thermal homing heads. The source of thermal radiation for these sensors is radiation from aircraft engines. To date, there are many solutions for the use of homing thermal heads in rockets, for example, the solution presented in the description of the Russian patent for invention 2419060.

Also known is a radio fuse for salvo blasting of delayed-action ammunition with an optoelectronic device confirming the presence of the "chord-2k" target (RF Patent No. 2216709), which, in addition to the radio channel, is equipped with an optical infrared receiving device. The output of the optical infrared receiving device is connected to the second input of the AND circuit, the first input of which is connected to the “Undercuted” electric signal shaper from a Doppler radio fusing device. The device provides for undermining the ammunition at the moment when electrical signals appear at the outputs of the infrared receiver and the Doppler radio fuse.

Self-homing thermal heads and a radio-fuse device according to the patent of Russian Federation №2216709 are exposed to false targets, the so-called “heat traps” (the temperature of such “heat traps” exceeds 1000 ° K) that are fired by the aircraft, and therefore do not allow to determine the optimal position of the munition relative to the aircraft under the action of radio interference and heat traps, which in practice act simultaneously. In addition, when installing such an optical infrared receiver (RF patent No. 2216709), a projectile detonator flying at a speed greater than the speed of sound in air will continuously record an electrical signal of a high alternating level in the IR range, caused by infrared radiation from the air itself. projectile (the level of infrared radiation depends on the air density and velocity of the projectile, which are variable in flight), which does not allow to create a workable device for detecting other thermal targets.

Therefore, the process of creating new devices and algorithms for processing information from various devices installed in proximity sensors of a target continues (A. B. Borzov, K. P. Lihodenko, V. B. Suchkov. QUESTIONS OF TECHNOLOGY AND TECHNOLOGY OF ON-BOARD Non-Contact Sensors of the Millimeter Range Diapason Bulletin of Moscow State Technical University named after NE Bauman. Ser. "Mashinostroenie". 2010, p. 160-170).

In this technical solution, in order to increase the efficiency of proximity sensors of a target, it is proposed to use a combined method of radar, namely, in addition to the traditional scheme of building sensors, it is proposed to add a passive location of electromagnetic radiation from the aircraft and the missile itself (projectile). The proposed method (based on measuring infrared radiation) can also be independently used in rockets and other munitions to detect and hit targets flying in an atmosphere of air, including at hypersonic speed.

The main aspects of this technical solution are discussed below.

As it is known, when the bodies move in the atmosphere with speeds higher than the speed of sound, shock waves arise in the body movement zone. In such waves, the air is rapidly compressed to large quantities and naturally heats up. In accordance with the known laws of physics, heated objects, depending on the heating temperature, emit electromagnetic waves of various length into the surrounding space. These physical processes are proposed to be used to detect objects moving in the atmosphere of air.

The proposed technical solution is illustrated by drawings. FIG. 1. Photos of high-speed ammunition in flight. FIG. 2. The dependence of the spectral density on the wavelength of the radiation of an absolutely black body at different temperatures (temperature in ° K). FIG. 3. The change in the intensity of current I on the photodetector when the ammunition is approaching and passing through a relatively fast target: I _B is the intensity of the current from the radiation of the ammunition on which the proximity sensor is mounted; P - the optimal point of undermining.

FIG. Figure 1 shows a well-known photograph of the registration in the air of high-speed ammunition (target). In this photo clearly visible zones of disturbance (zones of occurrence of shock waves) in the form of conical surfaces, which are called "cone of disturbance".

Observations of a number of researchers show that the typical width of a shock wave in air is 10 ^-4 mm (of the order of several free paths of molecules). The perturbed air volume around the body considerably exceeds the size of the body. And since the disturbed volume has a high temperature (due to compression), taking it as a radiation source, we can conclude that the “radiating antenna” in the form of a “disturbance cone” from this volume has considerable dimensions and must have a significant radiation intensity.

The process of formation of shock waves continuously accompanies the body, flying at supersonic speeds. The heat source (source of electromagnetic waves) that originated in the shock wave zone continuously moves with the body and reflects the coordinates of this body in space.

Practical observations of the heating of bodies moving at supersonic speeds (within 4–5 Mach units) show that these bodies heat up to 800–900 ° K.

Radiation from such bodies is subject to the well-known law of wine. FIG. 2 shows the known qualitative data on the registration of radiation of bodies heated to different temperatures. From FIG. 2 that when the body temperature is less than 900 ° K, radiation occurs at wavelengths greater than 3 microns.

Based on the above, it can be assumed that during supersonic movement of aerial targets, the maximum of electromagnetic radiation caused by shock waves from them will occur at wavelengths in the range (2-8) μm.

The use of passive proximity sensors of the target with recorders of electromagnetic radiation in the wavelength range of 2-8 microns, in the air defense systems used, will increase their effectiveness when working against hypersonic aircraft, by providing the ability to select the optimal position of the munition relative to the aircraft at undermining ammunition. And as one of the methods of passive determination of the distance to the target, it is proposed to use the method of recording electromagnetic radiation generated by an aircraft when it moves in the Earth’s atmosphere at supersonic speeds. The main aspects of the physics of electromagnetic radiation by shock waves arising from the motion of bodies in the Earth’s atmosphere are known. They can be formulated as follows:

- when a body moves in the atmosphere of the Earth at a speed exceeding the speed of sound, shock waves appear;

- the area of the shock wave around the body is much larger than the body;

- due to the compression of air in the shock wave zone, the latter heats up;

- air heating temperature depends on the speed of the body, and for known designs of aircraft moving at a speed of less than 6M, does not exceed 900 ° K;

- The range of wavelengths emitted by aircraft at speeds of less than 6M, is (2-8) microns;

- The range of wavelengths for hypersonic aircraft covers the visible part of the emission spectrum.

As it is known, the main element for registration of electromagnetic radiation is the receiver of such radiation. By the principle of operation, such receivers are divided into two large groups: thermal and photon. Heat receivers are based on changes in certain properties, with a change in temperature, which is formed under the influence of the incident radiant flux, regardless of its spectral composition. In photon receivers there is a direct interaction between the falling photons and the electrons of the material of the sensitive element. Photodiodes are common among photon receivers. The electronic component base market offers a wide range of photodiodes suitable for use in devices for recording electromagnetic radiation from bodies moving in the Earth’s atmosphere at supersonic speeds.

To increase the sensitivity of receivers to the detected radiation, it is advisable to use lenses-refractors, which allow focusing the radiation directly on the photosensitive area of the photodiode.

Germanium can be used as a lens material for operation in the wavelength range of 2–8 μm.

The non-contact target sensor with an IR radiation receiver is a miniature device that is installed in a rocket or projectile head fuse (proximity sensor of the target).

The algorithm of such a device will be in continuous radar and registration of infrared radiation during the flight of ammunition from the launch point to the target. In this case, the IR receiver will also register its own radiation of its carrier (I _B in Fig. 3), since it also moves in the atmosphere of air at supersonic speeds. Radiation will be registered by the IR receiver after the instrument power supply starts. At this point, the ammunition will fly away from the launch point for a certain distance and pick up supersonic speed. With a constant speed and a rise in height, the radiation intensity in the area of the munition will decrease due to air dilution. From the moment when the infrared radiation from the target reaches the sensor (including the radiation emitted by the ammunition and reflected from the target), the intensity of the current at the IR receiver will increase. And, if the ammunition and the target come closer, then this intensity will increase until the moment when the ammunition and the target diverge (miss), after which the intensity will begin to decrease. This moment, namely, the moment of transition of intensity through a maximum, is proposed to be used in the proximity sensor of the target, as an additional parameter determining the position of the munition in relation to the target. Such a technique allows the computing device of the proximity sensor of the target (fuse) to work out the commands for the optimal undermining of the ammunition. Correction of the trajectory of the munition after passing through the intensity of radiation through a maximum (slip) at supersonic speeds of movement of the munition and the target is almost impossible. FIG. 3 is a diagram of the change in the intensity of current I on the infrared receiver installed in the main fuse of the ammunition in time t. The moment of optimal detonation of the munition is indicated by the dot P. With this method of determining the position of the target relative to the munition, the influence of radio interference on decision making is excluded.

Confirmation of the possibility of creating such an IR system are the data of studies performed by the authors of the work - Golovkov VA, Emelyanov VN, Salk SV. Detection of heated moving small-sized objects in the infrared range // IZV. Universities. Instrument making. 2013. V. 56, No. 5, p. 40-44. In their work, the problem of detecting artillery shells in the infrared range using optical systems and uncooled thermal imagers of the bolometric type was considered. The studies used the bolometric module, which docked with the telescope. The basis of the bolometric module was the photodetector module BP-2M based on a semiconductor bolometer; The spectral range of BP-2M operation is 2 ... 15 microns. Experiments were conducted on the registration of thermal radiation from an artillery high-explosive fragmentation projectile with a caliber of 152 mm, with an initial velocity of 800 m / s.

It is shown that with the help of the installation considered above it is possible to fix the temperature field of the flying projectile at distances up to 6 km.

Thus, the above technical solution shows that using a non-contact target channel sensor for measuring infrared radiation in a wavelength range of more than 2 μm allows you to reliably identify a target flying at supersonic speeds and improves noise immunity of a non-contact target sensor from various interference.

The stated information about the claimed invention, described in the independent claim, testifies to the possibility of its implementation using the described in the application and known means and methods. Therefore, the claimed method meets the condition of industrial applicability.

Claims (1)

The method of hitting an air target with an ammunition with a non-contact target sensor, is that the ammunition is fired into its meeting area with a target, using a non-contact target sensor, emit and receive radio signals, analyze the parameters of radiation and reception of signals during the flight of the ammunition, based on this analysis fuse protection stages as the ammunition approaches the target, select the optimal position of the ammunition relative to the target and undermine the ammunition, characterized in that it additionally tact sensor target register infrared radiation in front of the munition in the wavelength range above two micrometers, at the moment of increasing the radiation level relative to the recorded at the beginning of the flight remove the next stage of protection of the munition, record the moment of reaching the radiation level of the maximum value the minimum distance from the target and according to a predetermined algorithm, choose the optimal moment for undermining the munition.

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