RU2765485C1 - Radar and thermal purpose simulator - Google Patents

Abstract

FIELD: military affairs.

SUBSTANCE: invention relates to the field of military affairs, and more specifically to means of imitation of moving military equipment and can be used in engineering equipment of false routes for the advance of troops from the location areas. To achieve the effect, the radar reflector is biconical, in the form of two truncated cones connected at right angles by smaller bases, the support belt, worn on the upper end of the mounting rack, is installed inside the radar reflector at the junction of the truncated cones, the obturator is installed on the large base of the upper truncated cone, at the same time, a rotation regulator is hinged on the obturator, which has a handle and a system of flaps, 3/4 of the outer surface of the large base of the lower truncated cone contains a dielectric coating, with each quarter of the coating having its own thickness.

EFFECT: ensuring the imitation of moving equipment with an expansion of the operating frequency range and an increase in operational characteristics by reducing the dependence of the design on the influence of external factors.

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Description

The invention relates to the field of military affairs, and more specifically to means of simulating moving military equipment and can be used for engineering equipment of false routes for the advancement of troops from areas of location, to the lines of attack (counterattack), to places of false crossings and on them, as well as in false areas concentration and initial in the interests of ensuring the demonstration of the vital activity of troops when the enemy conducts aerospace and ground reconnaissance by means of infrared (thermal) and radar reconnaissance with selection of moving targets.

A device for a moving equipment simulator is known - an analogue (P.S. and a source of electricity (power plants).

The disadvantage of this device is the dependence on an external power source (serviceability of the supply cables, connectors, the availability of fuel for the power plant, the mandatory provision of the necessary parameters, such as voltage, current strength and frequency). In addition, its design makes it possible to simulate unmasking signs only in the radar range of the electromagnetic wave spectrum (hereinafter referred to as EMW).

A device for a simulator of moving military equipment is known - a prototype (Utility Model Patent RU154830), consisting of corner radar reflectors mounted on rods, catalytic wick furnaces (sources of thermal radiation), a woven re-radiator made in the form of a cone-shaped hollow truncated socket, a frame on which re-emitter, base plate and mounting rack are installed.

The disadvantages of such a device are:

- dependence of the angular velocity of rotation of the corner reflectors on air resistance, gusts of wind, falling (adhering) snow, etc.;

- the inability to simulate objects moving at high speeds;

- the inability to simulate the movement of equipment in the decimeter range of the EMW spectrum.

It must be borne in mind that when conducting reconnaissance in the decimeter EMW range, the corner reflectors currently accepted for supply do not work, and in order for them to imitate military equipment, they must be made significant in their overall dimensions, which will lead to an increase in metal consumption, windage of the structure and an increase in its mass as a whole.

The aim of the invention is to provide an imitation of moving equipment with the expansion of the operating range up to decimeter inclusive, and increase performance due to the design, which reduces the dependence on external factors.

This goal is achieved by the fact that in the proposed technical solution of the radar-thermal simulator of moving equipment, it contains a radar reflector made of a biconical shape, in the form of two truncated cones connected at right angles by smaller bases, a support belt worn on the upper end of the mounting rack, installed inside the radar reflector at the junction of the truncated cones, the obturator mounted on the large base of the upper truncated cone, while the rotation regulator is pivotally mounted on the obturator, having a handle and a system of flaps, 3/4 of the outer surface of the large base of the lower truncated cone contains a dielectric coating, while each quarter of the coating has its own thickness L, which varies through 90° and is determined from the ratio:

,

,

where C is the speed of light;

ε _r - absolute permittivity;

W is the carrier frequency of the radio signal;

N - 1, 2, 3.

The essence of the proposed technical solution is illustrated by the following images:

- in Fig. 1, 2 shows a general view of the target simulator;

- in Fig. 3 ... 6 shows the nodes and sections that explain its design solution.

The proposed radar-thermal target simulator 1 (Fig. 1 ... 6) consists of catalytic wick furnaces 2, a frame 3, a re-emitter 4 made of woven material with a cone-shaped socket 5, a base plate 6, a mounting rack 7, a support belt 8, an obturator 9 and a radar reflector 10. In the proposed radar-thermal target simulator 1, the radar reflector is made of a biconical shape, in the form of two truncated cones connected at right angles by smaller bases, the support belt 8, worn on the upper end of the mounting rack 7, is installed inside the radar reflector at the junction truncated cones, the obturator 9 is mounted on the large base of the upper truncated cone 11, while the rotation regulator 12 is pivotally mounted on the obturator, having a handle 13 and a system of flaps 14. In the proposed radar-thermal target simulator 1, 3/4 of the outer surface of the large base of the lower truncated cone contains a dielectric coating 15, while each i quarter of the coating has its own thickness L, which changes through 90° and is determined from the ratio:

,

,

where C is the speed of light;

ε _r - absolute permittivity;

W is the carrier frequency of the radio signal;

N - 1, 2, 3.

The assembly and folding of the radar-thermal target simulator is carried out by analogy with the prototype.

The target simulator works as follows. The rotation of the biconical radar reflector 10 in the horizontal plane occurs due to the upward heat flow from the catalytic wick furnaces 2 (the temperature of the furnaces reaches 600 ° C), passing through the re-emitter with a cone-shaped socket and obturator 9 (Artobolevsky I.I. Mechanisms in modern technology. Reference manual Volume 6 - M.: ed. Nauka, 1981), mounted on a large base of the upper cone 11, as well as through the rotation regulator 12, pivotally mounted on the obturator. The rotation regulator has a handle 13 and a system of flaps 14, which, rotating around the pivot axis on the obturator 9, can partially or completely open (close) the obturator holes, which allows you to change the angular velocity of the reflector, thereby simulating the movement of equipment at different speeds. The radar signal, hitting the biconical surface of the reflector, produces a back reflection, and, since the reflector rotates, the signal will alternately be reflected both from the surface of the lower cone without a dielectric coating, and with a dielectric coating of various thicknesses. Considering that the speed of EMW propagation in different media is different and depends on the dielectric and magnetic permeability, we will determine the time of its delay with the simulator running.

The speed of propagation of EMW in the air: V=C.

In a dielectric, the EMW speed is:

where M _r is the absolute magnetic permeability.

The decrease in the EMW speed is estimated by the coefficient n.

то есть

, но в свою очередь

,Considering that in the dielectric M _r =1, we obtain

that is

, but in turn

,

where L is the EMW path traversed in the dielectric;

t ₃ - EMW delay time.

We get:

Considering the general expression of an amplitude-modulated radio signal as:

where w is the carrier frequency;

t - current time;

ϕ _OT - initial phase;

A(t) - radio signal envelope,

we will select the coating material for the absolute dielectric constant to the loss tangent (Stepanov Yu.G. Anti-radar masking. - M .: ed. "Soviet radio", 1968).

Consider special cases of the proposed simulator:

a) no coverage, L=0

electromagnetic wave:

b) the coating has a thickness L ₁

тоbecause

then

c) the coating has a thickness L ₂

d) the coating has a thickness L ₃

We get a general picture of the simulator:

When reflected from the simulator, the magnitude of the EMW phase shift increases discretely with a step of π/2, while the interval of shift changes is from 0 to 2π; repeats periodically.

From here, the thickness of the dielectric coating is determined as:

The use of the proposed technical device in comparison with the prototype makes it possible to simulate the unmasking signs of moving military equipment by expanding the radar range of the EMW spectrum in which enemy radars operate with selection of moving targets. The presence of a rotation regulator on the obturator makes it possible to change the angular velocity of rotation of the reflector and thereby simulate the movement of equipment at different speeds of its movement along the column tracks. The design of the reflector in a biconical shape ensures the constancy of dynamic loads at any angular speed of rotation. This is especially important at the present time, since it is a condition for ensuring the survivability of troops by increasing the speed of movement of columns of equipment in open areas of the terrain.

The presence of a dielectric coating deposited on the surface of the lower cone, which has its own thickness on each sector of π / 2, provides a Doppler frequency shift, according to which a moving target is selected by radar reconnaissance equipment, in contrast to a stationary one located on the ground. Comparing the design and size of the biconical reflector and reflectors of the prototype, we can conclude that the moment of inertia of the prototype exceeds the moment of inertia of the proposed solution, since the distance to the center of the rotating masses is different, and, therefore, the design of the prototype is more inert, all other things being equal. This advantage allows the reflector to operate in the decimeter range of EMW radiation in the traditional way. The development of thermal means of reconnaissance allows the enemy to recognize the simulator (prototype) as a decoy, since practically all gas exhaust manifolds of military equipment are of considerable size, in contrast to the dimensions of the prototype obturator. Therefore, the creation of an obturator, comparable in size to the collector of real equipment and installed on a large base of the upper cone, significantly increases the efficiency of its use. In this case, the temperature of the obturator, reflector and re-emitter will have different parameters, which also corresponds to reality.

The readiness of the proposed technical device for implementation is characterized by the presence of production facilities for the manufacture of used metal parts and assemblies (industrial enterprises with the presence of turning and milling shops, repair enterprises of automotive and tractor equipment, park equipment of military units), woven materials with a high coefficient of thermal conductivity. The scope of such materials is diverse. They are used for tailoring overalls and covers, as technical fabrics and are produced in a wide range by the domestic industry, as well as the presence of a dielectric (polystyrene, epoxy resins (LLC NPP YarLi, Yaroslavl) and catalytic wick furnaces KFP-1-180.

Theoretical studies carried out in the process of developing a technical device have confirmed that in modern conditions, according to the main tactical and technical characteristics and according to the evaluation criterion "effectiveness of combat use - cost", the proposed technical solution has indicators approximately 1.5 ... 2.0 times higher in terms of compared with known analogues.

Claims (6)

Radar-thermal target simulator, containing catalytic wick furnaces located in a frame on which a re-emitter made of woven material with a cone-shaped socket is installed, a base plate with a mounting rack is installed between the catalytic wick furnaces, located in the cone-shaped socket of the re-emitter, a radar reflector and an obturator, characterized in that that the radar reflector is made of a biconical shape, in the form of two truncated cones connected at a right angle by smaller bases, the support belt, put on the upper end of the mounting rack, is installed inside the radar reflector at the junction of the truncated cones, the obturator is installed on the large base of the upper truncated cone, at the same time, a rotation regulator is pivotally mounted on the obturator, having a handle and a system of openers, 3/4 of the outer surface of the large base of the lower truncated cone contains a dielectric coating, while each quarter of the coating has its own thickness L, which is changed through 90 ° and is determined from the ratio:

, where C is the speed of light; ε _r - absolute permittivity; W is the carrier frequency of the radio signal; N - 1, 2, 3.

Images