RU181869U1 - ANCHOR RADAR SIMULATOR - Google Patents

Abstract

The utility model relates to means of simulating the physical fields of targets located on a water surface and can be used in engineering equipment of false floating bridges, as well as distortion of characteristic water landmarks, when the enemy conducts aerospace and ground reconnaissance by means of radar reconnaissance, The technical result is a simulation of surface targets with improved performance. This result is achieved due to the fact that the simulator case is represented by a flat square base at the edges of which, from the outer surface, through 90 °, spring-loaded rods are pivotally mounted with transport rings at their outer ends and triangular-shaped float stabilizers are rigidly fixed, for example, from a foam polymer, has on the side of the inner surface two opening mechanisms installed through 180 °, each of which contains a small case, a spring-loaded lock, a sugar fuse and a safety lock a body cap, a hollow rod fixed perpendicularly to its outer surface at the geometric center, with a pin spring-loaded in its upper part, and a cylindrical-shaped float chamber with foam filling with a through central hole symmetrically fixed to the inner surface, the reflector is made in the form of a four-cell design, each cell consists of vertical and horizontal planes, while the vertical planes are represented by a metallized polymer film, the side ends which are fixed to the rod by loops, and the lower ends are rigidly fixed to the spring-loaded rods, horizontal planes consist of two parts connected together by a tension device consisting of plates to which planes and spring systems are fixed, the anchor is made in the form of a cylindrical closed from the bottom side a hollow vessel, with holes in its upper part for the diameter of the constipation, is equipped with paws and contains a discharge spring and an anchor cord, the other end of which is rigidly fixed to its inner lower part akreplen to the spring-loaded pin. 6 ill.

Description

The utility model relates to the field of military affairs, and more specifically to means of simulating the physical fields of targets located on the water surface and can be used in engineering equipment of false floating bridges, as well as distortion of characteristic water landmarks, when the enemy conducts aerospace and ground reconnaissance by means of radar reconnaissance .

Known device pneumatic reflector "Sphere-PR", used to simulate military bridges and hide certain sections of the water surface from radar surveillance - analogue (Efimov V.A., Kolchevsky BE, Chermashentsev S.G. Disguise. Part I. Textbook M., VIA Publishing House, 1971, pp. 266 ... 268. A total of 347 pp.), consisting of a waterproof casing (shell), four-cell corner reflector (radio fabric), an anchor (packing) bag and an anchor cord.

The disadvantages of such a device are:

- the complexity of the preparation and installation. The need for a compressor to bring into working position or with the help of a foot fur, which will require up to 10 minutes to deploy only one device;

- the need for skills and abilities of the involved calculation to use the temperature nomogram, as well as the filling table in accordance with the reference scale;

- the need for monitoring during operation (with stable weather after 5 days, with unstable - 3 days), while the pressure deviation inside the rubberized shell changes the angle between the sides of the reflector, which must be strictly 90 °, which leads to a significant decrease in the effective dispersion area ;

- the need to comply with the storage conditions of the rubberized shell (temperature, humidity) and transportation - the slightest damage (puncture, rush) including the foot fur will disable the device.

Closest to the claimed solution is the device of a metal corner reflector "Pyramid", designed to distort characteristic water landmarks and create false bridges and crossings - a prototype (Efimov V.A., Kolchevsky V.E., Chermashentsev S.G. Disguise. Part I Textbook M., published by VIA, 1971, p. 264, 265. A total of 347 p.), Consisting of a block of panels, supports with an anchor winch, floats and anchors.

The disadvantages of this technical solution are:

- poor transportability, only 14 reflectors fit into one freight transport vehicle;

- the mass of one reflector assembly is 120 kg;

- deployment time of 3 people is 5 minutes, which, taking into account their required number to simulate such a linear object as a bridge and subsequent towing by boats or landing boats to the installation site, increases significantly.

The objective of the proposed technical device is its application to simulate surface targets, ensuring the stable formation of a backscatter pattern of the reflector in the upper hemisphere and in the lateral directions, when the enemy conducts radar reconnaissance and improves operational characteristics due to the possibility of its early installation and a significant reduction in the time for putting into working position in automatic mode.

The solution to this problem is achieved by the fact that in the proposed utility model, the anchor radar simulator in it the housing is represented by a flat square base along the edges of which, from the outer surface, through 90 °, spring-loaded rods are pivotally mounted with transport rings at their outer ends and float stabilizers are rigidly fixed triangular in shape, for example from a foam polymer, has two opening mechanisms on the side of the inner surface installed through 180 °, each of which contains a small core mustache, spring-loaded lock, sugar fuse and safety cover, hollow rod fixed perpendicular to its outer surface at the geometric center, with a pin spring-loaded in its upper part, and a cylindrical-shaped float chamber filled with foam polymer with a through central hole symmetrically fixed , the reflector is made in the form of a four-cell structure, each cell consists of vertical and horizontal planes, while the vertical planes of the are covered by a metallized polymer film, the lateral ends of which are fixed to the rod by loops, and the lower ends are rigidly fixed to the spring-loaded rods, the horizontal planes consist of two parts connected in a single unit by a tensioning device consisting of plates to which the planes and spring systems are fixed, the anchor is made in closed cylindrical hollow vessel closed from the bottom side, with holes in its upper part for the diameter of constipation, equipped with paws and contains rigidly fixed to its inner lower part spring and throwing the anchor cable, the other end of which is fixed to the spring-loaded pin.

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

- in FIG. 1 shows a general view of an anchor radar simulator (with a notch) in the transport position;

- in FIG. 2 shows an anchor radar simulator in operating position;

- in FIG. 3 ... 6 show a top view, nodes and a section explaining its design.

The proposed anchor radar simulator 1 (Fig. 1 ... 6), comprises a housing 2, a reflector 3, an anchor cord 4 and an anchor 5. In the anchor radar simulator 1, the housing 2 is represented by a flat square base 6 along the edges of which, from the outer surface, through 90 °, spring-loaded rods 7 are pivotally mounted with transport rings 8 at their outer ends and triangular-shaped float stabilizers 9 are rigidly fixed, for example, of a foam polymer, has two opening mechanisms on the side of the inner surface installed through 180 °, each of which contains a small case 10, a spring-loaded lock 11, a sugar lock 12 and a safety cover 13, a hollow rod 14, fixed perpendicular to its outer surface at a geometric center, with a pin 15 spring-loaded in its upper part, and a float is symmetrically fixed to the inner surface a chamber 16 of a cylindrical shape with a filler of a foam polymer 17 with a through central hole 18. In the anchor radar simulator 1, the reflector 3 is made in the form of a four-cell structure, each cell consists of vertical and horizontal planes, while the vertical planes 19 are represented by a metallized polymer film, the side ends of which are fixed to the rod by loops 20, and the lower ends are rigidly fixed to the spring-loaded rods 7, the horizontal planes 21 consist of two parts connected into a single unit by a tension device, consisting of plates 22 to which the planes and spring systems 23 are fixed. In the anchor radar simulator 1, the anchor 5 is made in the form of a cylindrical void closed from the bottom the logo of the vessel, with holes 24 in its upper part for the diameter of the constipation, is equipped with paws 25 and contains a discharge spring 26 and an anchor cord 4, the other end of which is fixed to the spring-loaded pin 15, rigidly fixed to its inner lower part.

In the transport position, the simulator body 2, overcoming the resistance of the ejection spring 26, is inserted into the anchor 5. The anchor cord 4 is laid in advance on its bottom. The constipation 11 of the opening mechanism enters the holes 24, which are on the outside of the anchor. Sugar fuses 12 (included in the simulator as separate operating materials) are inserted into small casings 10 and the safety caps 13 are screwed.

Bringing the anchor radar simulator into position is as follows. Using floating means, the simulator is delivered to the installation site, the safety covers 13 are removed, and it is dumped into the water. After entering the aqueous medium, water begins to flow into the opening mechanisms, gradually dissolving the sugar preservatives 12. The dissolution time of the sugar preservatives depends on the water temperature and ranges from eight minutes at plus 30 ° C to two and a half hours at 0 ° C (http: / /www.history-guns.net.ru/mines/mines_prdes_pdm-lm.htm). This dependence allows, knowing the average daily fluctuation of the temperature of the aquatic environment, to calculate in advance the time spent by the simulator in the buried position and its inclusion in the calculated time range depending on the tasks facing the simulation object. Under the action of the springs, the locks 11 exit the holes 24 in the anchor 5, and the ejection spring 26 pushes the housing 2, which using float stabilizers 9 and the float chamber 16, which give it positive buoyancy, floats up to the surface with acceleration, while unwinding the anchor cord 4 . At the time of reaching the water surface, under the action of the buoyancy force of water, the cord snatch and lower the spring-loaded pin 15, thereby releasing the transport rings 8 of the spring-loaded rods 7, with 9 lavkovymi stabilizers triangular shape. The stabilizers under the action of the springs are lowered into the water, while simultaneously turning the horizontal 21 and pulling the vertical plane 19 of the reflector.

The use of the proposed technical device as an anchor radar simulator, in comparison with the prototype, facilitates its operation and installation (discharge from boats or from a helicopter, while the float stabilizers folded in the transport position, having a structural similarity to the bomb stabilizer, give it a vertical position when dropped) . The use of sugar fuses makes it possible to install a simulator in advance, which, after a certain amount of time, automatically operates and starts to simulate the physical field of a target located on a water surface. The presence in the body structure of spring-loaded rods to which the vertical planes of the reflector are attached, as well as tensioning devices in horizontal planes, can guarantee that the angle between its faces (sides) is strictly 90 °, eliminating the deformation of the reflector and thereby reducing the effective scattering area.

The readiness of the proposed technical device for implementation is characterized by the availability of production facilities for the manufacture of used metal parts and assemblies (industrial enterprises with the presence of turning and milling workshops, repair enterprises of automotive and tractor equipment, park equipment of military units), the presence of polymer products and materials (OJSC Vladimir Chemical Plant »), As well as metallized polymer film commercially available by industrial enterprises without any special treatment quipment.

Theoretical studies carried out in the process of developing the proposed utility model have confirmed that in modern conditions, the proposed technical solution has indicators approximately 2 ... 3 times higher than the known ones according to the main tactical and technical characteristics and the evaluation criterion “combat effectiveness - cost” analogues.

Claims (1)

An anchor radar simulator comprising a housing, a reflector, an anchor cord and an anchor, characterized in that the housing is represented by a flat square base along the edges of which, from the outer surface, through 90 °, spring-loaded rods are pivotally mounted with transport rings at their outer ends and rigidly fixed triangular-shaped float stabilizers, for example made of foam polymer, have two opening mechanisms on the side of the inner surface installed through 180 °, each of which contains a small housing, a spring nennoe constipation, sugar fuse and safety cover, a hollow rod fixed perpendicular to its outer surface at the geometric center, with a pin spring-loaded in its upper part, and a cylindrical-shaped float chamber filled with foam polymer with a through central hole symmetrically attached to the inner surface, a reflector made in the form of a four-cell structure, each cell consists of vertical and horizontal planes, while the vertical planes are represented by lysed polymer film, the lateral ends of which are fixed to the rod by loops, and the lower ends are rigidly fixed to the spring-loaded rods, the horizontal planes consist of two parts connected together by a tensioning device consisting of plates to which the planes and spring systems are fixed, the anchor is made in closed in the form of a cylindrical hollow vessel closed on the lower side, with holes in its upper part for the diameter of the constipation, equipped with paws and contains a spring rigidly fixed to its inner lower part throwing and anchor cord, the other end of which is fixed to the spring-loaded pin.

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