RU2198454C2 - Collapsible octahedral corner reflector - Google Patents

Abstract

FIELD: polyhedral corner reflectors of magnetic waves emitted by radar antennas. SUBSTANCE: reflector is designed for re-reflecting radar signals in opposite direction to radiation sources distributed in space and functions to simulate images of objects at points of their absence, to enhance reflection capability of barely visible actual objects or to designate location points of these objects, and also it may serve as reference points on terrain. It has central post carrying bushing disposed in mutually perpendicular planes and used for securing stiff supporting facilities and collapsible flexible reflecting faces forming octahedral group reflector in developed position of supporting facilities. Reflector is provided with means for locking its components in working position and controls for setting them precisely in desired position which enlarges its effective dissipation surface by an order of magnitude compared with prior art. Alternative design versions are proposed for bushings securing reflector components to arms and to one another in mutually perpendicular planes and also alternative reflector design provided with telescopic post of smaller size in folded-up position. EFFECT: enhanced precision of given characteristics; enhanced operating reliability. 19 cl, 15 dwg

Description

 The invention relates to the field of electrical engineering, in particular to corner reflectors of electromagnetic waves (EMW) emitted by antennas of radar stations in order to determine the location of real objects, the direction and speed of their movement. Corner reflectors (UR) are also intended for re-reflection of radar signals in the opposite direction to radiation sources distributed in space, simulating the radar characteristics of real objects in their places, increasing the reflectivity of stealth objects or marking the location of such objects, and serve as reference points on the ground.

 To date, there are many options for the use of technical devices for the directional reflection of electromagnetic waves. Known reflector devices containing one, two, four, eight, twenty or more corner reflectors [1, 2, 3], which are rigid metal structures with sector, triangular and square faces.

 In the review [1], a systematic and fairly complete description of the properties of reflectors, the features of their designs, and applications is carried out. A rigid structure is known, which is a group of 20 SD made of triangular faces, the openings of which are located throughout the sphere, forming a regular twenty-sided (icosahedron [4]). The advantage of rigid SD is the ability to ensure high accuracy of the corners during manufacturing, providing the ability to obtain the specified characteristics of the effective dispersion surface (EPR).

 A significant drawback of the metal structures of the UR is their bulkiness.

 Known folding corner reflectors, which are small in the folded state, and therefore more convenient in storage and use.

 For example, US patent [5] is a foldable octagonal corner reflector covering a single square panel of flexible reflective material serving as the base reflecting plane, and eight triangular rectangular panels located four on four sides of the base panel. All panels are attached to their rigid strut and four shoulders with their support in mutually perpendicular planes using flexible elements. The shoulders are pivotally connected to the stand and can adjoin to it. Rigid elements are equipped with spring means for their rotation and fixation in the open position.

 Also known is a folding tetrahedral corner reflector [6], including a rigid composite central strut, many rigid shoulders pivotally mounted on the strut to hold the reflecting panels in mutually perpendicular planes. The rack is equipped with spring means for automatically opening the rigid elements and fixing them in the working position. The reflector is stored in a cylindrical container when folded.

 These known devices are analogues of the claimed reflector. The closest of them to the claimed solution to the problem is a folding octagonal corner reflector according to the US patent.

 The well-known corner reflector [5] is adopted as a prototype. A folding octagonal corner reflector [5] contains a central supporting strut located on the strut: a first sleeve occupying at least two positions near the middle of the strut, spring clips holding the first bush in these positions, four supporting arms attached at one end to the first bush with the possibility of rotation in mutually perpendicular planes passing along the rack, the second sleeve, movably mounted on the rack: in the closed state adjacent to and below the first sleeve, in the open position - near the base of the rack, limited by spring clips. The reflective flexible material, made in the form of a square panel, the corners of which are provided with overlays, is attached: angles to the outer ends of the shoulders, the central section to the first sleeve, the diagonal sections to the indicated shoulders along their length, the four upper rectangular triangular panels of the reflecting flexible material, symmetrically located above the base panel between the stand and the shoulders, each panel is attached: right angles to the first sleeve, second angles to the outer ends of the shoulders supporting them, third angles to the top of a hundred ki, four lower rectangular triangular panels of reflective flexible material, symmetrically located under the base panel between the stand and shoulders, each lower panel is attached: rectangular corners to the first sleeve, second corners to the outer ends of the shoulders supporting them, and third corners to the second sleeve . Each triangular panel has a notch on the hypotenuse side and a tension wire passing through the notch. The tension wires are located in perpendicular planes, pass through the holes (grooves) of the top of the rack and the outer ends of the shoulders, and in the upper panels, stretching from the rack to the shoulders, in the lower panels - from the shoulders to the second sleeve, spring means of rotation are fixed to the second sleeve and to to a fixed point on the central pillar, the said spring means, being adapted to effectively move the second sleeve along the pillar to bring the turned shoulders into a plane at right angles to the pillar, while the spring means are introduced When removing restrictions, the UR automatically transfers from the collapsed position to the deployed working position, means for securing the second sleeve on the rack in the open position, when the shoulders are deployed in a plane at right angles to the rack, whereby the shoulders are deployed in the plane at right angles to the rack .

 As a reflective material, a metallized plastic mesh is used. Available in the design of the prototype spring means when removing restrictions automatically translate the SD in the open position, fixed using a sliding second sleeve on the rack using an additional spring lock.

In the patent description, reinforcing pads are used as means of connecting the corners of the panels of the reflective material to the shoulders. And the tensioning wires and shoulders do not have clamps, so they can be shifted in the grooves of the top of the rack and shoulders during storage and transportation by a random amount. In the process of tension, they can deform inadequately, with a random shift, as a result of which a deviation of the shoulders from the design position is possible, leading to a decrease in the accuracy of the position occupied by the reflecting panels, and therefore to a decrease in the effective scattering surface of the corner reflector. In addition, the pulling force of the opening of the SD to the pulling wires is applied under the corner of 45 ^o and in the wire itself additionally changes by 90 ^o , which additionally leads to an increase in the friction forces in the slots of the shoulders, which, in turn, can reduce the likelihood of the shoulders in design positions and fixation of disclosure in a given position of reflector elements. Marked are significant disadvantages of the prototype, because it is known [1] that the deviation of angles from straight lines by 1 ^o leads to a decrease in the EPR compared to the design up to 30 times.

 The aim of the present invention is to eliminate the noted drawbacks, increase the reliability of the formation and fixation in operation of the elements of a multifaceted folding corner reflector, ensure the accuracy of the specified geometric characteristics of the formed reflector, as well as expand the types of manufactured designs of folding reflectors of high accuracy.

 This goal is achieved by the fact that the following new elements are introduced into the adopted prototype and structural changes are made to the existing elements.

 The top of the rack and the outer ends of the shoulders are made with seats for fixing additionally introduced connecting elements for fastening reflector elements to them and are provided with position locks of the connected elements in their seats, for example, made in the form of screws with gaskets.

 The end parts of the flexible tension wires in the lower part of the reflector are rigid, and for their fastening the outer ends of the shoulders are equipped with bushings having appropriate seats, and the sliding second sleeve is made with seats in mutually perpendicular planes of four articulated rigid elements, the other ends of which are pivotally connected to inserted bushings located on the shoulders. The corners of the square panel are attached to the inserted sleeve sleeves.

 The stand is made up of two parts, telescopic interconnected. The top of the outer part of the rack is equipped with a clamp of tensioning elements, and the first sleeve is fixed on its lower part. The bottom of the inner part of the rack is equipped with a fixed sleeve designed to connect the rigid supporting faces (panels) of the elements, and the inner part of the rack is spring-loaded with a coil spring and equipped with a spring clip.

 Additional differences are in the form of connecting sleeves and their seats, as well as fixing elements of the connected parts. The square reflective panel is made up of four triangular rectangular panels made with notches, legs of which are attached to the arms of the shoulders, their angles are attached to the first sleeve of the rack and to the sleeve of the shoulders.

 Introduced new details and structural changes in the supporting means of reflective panels do not significantly affect the manufacture of reflector elements, however, they significantly increase the accuracy of fixing the position of elements in project planes, and therefore, the accuracy of maintaining the mutual perpendicularity of SD elements, which leads to an increase in the effective scattering surface due to the proposed technical solution tasks 2-3 times.

 The claimed constructive implementation of the central support pillar of the composite increases the inertia of the extendable elements, leading, in turn, to increase the reliability of the disclosure of all elements and their fixation in the open position. In addition, it leads to a decrease in the length of the packaging of the SD in the folded state to 25%.

 The named introduced changes provide the delivery of the technical result, therefore, are essential features.

The figures show schematically embodied by the invention options for the design of corner reflectors and their elements, illustrating their appearance and design:
FIG. 1 and 2 - the appearance of the reflector with clamps for the position of the tension wires and the cross section of the reflector in a longitudinal plane along the strut and shoulders;
Fig.3-8 - the appearance of the bushings and the cross section of the elements of the reflector of the sleeve, fixed near the center of the rack;
Fig.9 is an external view of the second variants of the bushings and their location on the rack;
10 and 11 are an external view and a section of a reflector having second variants of bushings with combined tensioning elements in the lower part of the reflector;
FIG. 12 is an external view of a sleeve with seats for the outer ends of the shoulders, the corners of a square reflective panel with reinforcing plates, the ends of the tensioning elements and the outer ends of the additional rigid shoulders;
Fig - cross section of the reflector with a composite (telescopic) rack;
FIG. 14 and 15 are sections of the bushings for attaching the corners of the square panel and the ends of the flexible and rigid tensioning elements of the reflector to the pivot arm.

In the claimed embodiments of the SD, the central support column 1 consists of a single metal tube having a length slightly greater than the height of the opened SD. In the position near the center of the rack 1, the first sleeve 2 is located and fixedly fixed, having seats for attaching four arms 3 with the possibility of rotation in mutually perpendicular planes intersecting along the center line of the rack 1, so that they can be turned upward against the rack or be turned outward 90 ^o from the stand.

 The reflective material is made chopped, decorated and attached so as to provide a square panel 4, four panels 5 above the square panel and four panels 6 below it, the sliding second sleeve 7 with a limiting lock 8 is located below the square panel 4. To do this, the reflective material is provided two sleeves 9, through the center of which the strut 1 is passed. Each shoulder 3 is also threaded into the sleeve 10, designed for the same purpose. Each top panel 5 is symmetrically located above the square panel between the upper part of the rack 1 and the shoulder 3 in pairs in mutually perpendicular planes and is attached: right angles to the first sleeve, the second corner to the outer end of the shoulder supporting it, and the third corner to the top of the rack. The lower panels 6 are located under the square panel 4 similarly to the panels 5 and are attached: right angles to the first sleeve, second corners to the outer ends of the shoulder, and third corners to the bottom of the rack 1. In addition, the hypotenuse side of each triangular panel has a notch 11 , through the cut-outs of each four panels located in the same plane, a tension wire passes, stretching in the upper panels from the top of the rack to the shoulders, and in the lower panels from the shoulder to the second sleeve, to which the ends of the wires are attached. The wires 12 pass through the notches and through a slit 13 (or the like) at the end of each shoulder and on the top of the rack and are attached to the sliding sleeve 7 with their ends. The purpose of the wires 12 is to help in tensioning the reflector when it is opened outward. Suitable reinforcing means 14 can be adapted for reflective material, where it is in demand, for example, made in the form of overlays of elastic material. For example, additional material 14 may be adapted, where the material is attached to the top of the strut 1, to the ends of each arm 3, to the first sleeve 2 and to the second sleeve 7.

 Four corners below the base are formed in the same way as four corners above the base panel, but instead of attaching to the bottom of the rack, the ends of the wires of the triangular faces 6 passing through the cuttings 11 of the reflective material are fixed to the second sleeve 7 of the central rack 1.

 When the reflector is folded, the second sleeve 7 is adjacent and lower than the fixed first sleeve 2, but when the reflector is open, as shown in FIG. 1 and 2, the sliding sleeve 7 is located at the lower end of the central rack 1 so that the triangular panels 6 forming the corners below the square panel 4 are installed in their operational (working) position. The automatic lock 8 is fitted at the lower end of the strut 1 to hold the second sleeve 7 and the reflector in an open position.

 Instead of rigid engagement, for example, by riveting at a position close to the center of the strut, the first sleeve 2 can be secured in position by a spring clip 15 and, if necessary, the clip 16 can be used to dive into two or more positions for the sleeve so that the clip can be made in some manner, as an engaging latch 8, which may also have two or more holding positions.

 In another embodiment of the design of the UR-pillar 1 is made elongated by the length of the springs 17 and 18 and is equipped with a fixed annular stop 19. These structural changes are designed to provide automatic disclosure of the reflector when removing the restrictions imposed by the closure.

 The top of the rack 1 and the outer ends of the shoulders 3 are provided with clamps 20 for clamping the wires 12 in their slots 13, made, for example, in the form of a screw, and the upper sections of the rack and shoulders are made with internal thread. At the top of the rack, each tension wire 12 is secured by a separate retainer 20 shifted in height. Strengthening the effectiveness of the latch 20 is achieved by introducing a gasket 24 or 21, located at the top of the rack 1 and having mutually perpendicular grooves 22 and 23 of different depths in accordance with the location of the sections of the tension wires 12, and the gasket 24, located on the outer ends of the shoulders 3 and having a groove 25 under wire section 12. Gaskets are pressed to the wires in the slots 13 by screwing the retainer 20.

 Additional versions of corner reflectors embodied by the technical solution are achieved by introducing new fastening elements supporting reflective faces of the means. The outer ends of the shoulders 3 are provided with a sleeve 26 for attaching wires 12 and reinforcing elements 14 of the reflecting faces to them. The second sleeve 7 of the rack 1 is made in the form of a sleeve 27, identical to the first sleeve 2 and equipped with an additional four rigid pulling shoulders 28, made in the form of a shoulder 3, but having a greater length than the shoulders 3. The sleeve 27 in the working position is fixed by a latch 8 ', having single engagement. For attaching additional arms 28 to arms 3, a sleeve 29 is inserted. The arrangement of the bushings 26 and 29 is identical to the arrangement of the bushings 29 shown in FIGS. 10 and 11.

 The sleeve 26 has seats: 30 - for the outer end of the arm 3, 31 - for part of the wire 12, 32 - with a thread for the retainer 20, 33 - for mounting the plates 14 of the square reflective panel 4.

 The sleeve 29 has seats: 34 for the outer end of the arm 3, 35 for the end of the wire 12, 36 for the spacers 14 of the square reflective panel 4, 37 for the outer ends of the arms 28.

The sleeve 38 is an embodiment of the sleeve 2, made with an emphasis 39, limiting the rotation of the shoulder 3 by an angle equal to exactly 90 ^o to the longitudinal axis of the rack 1, as shown in Fig.9 and 11.

 In one of the embodiments of the invention, the rack 1 is made telescopic in the form of an outer part 40 and an inner part 41. The top of the part 40 is equipped with a latch 20 with a gasket 24 or 21, and a sleeve 38 is rigidly fixed to its bottom. The bottom of the inner part 41 is equipped with a sleeve 27, rigidly fixed on her. In their cavity there is a coiled cylindrical spring 42, supported at one end by a gasket 24 or 27, held by the latch 20, and the other end springs the inner part 41. The sleeve 38 and the outer part 40 have aligned windows for the spring latch 43. If necessary, the spring 42 can be extended to sleeve 27.

 The square reflective panel can be made up of four rectangular triangular panels, which are attached with their catheted chopped sides to the sleeves 10 worn on the shoulders 3 of the reflector, and the hypotenuse hemmed sides are equipped with a flexible cord, for example, kapron. The cord along with the lining 14 is designed for mounting panels in the seats of the sleeve 44, located on the shoulders 3.

 The sleeve 44 is made similar to the sleeve 29 and has seats: 45 - for a flexible tensioning wire 12, 46 - for plates 14 with a nylon cord for a square panel 4, made in the form of two holes located in the plane of the shoulders 3, 47 - for the end of the rigid shoulder 28, 48 for the outer end of the shoulder 3, 49 for the hole under the axis of the shoulder 28, as shown in Fig.14.

 The sleeve 50 is made as a variant of the sleeve 26, is mounted on the seat of the shoulder 3 in a known manner, for example, a dowel, stud, screw. It has a reciprocal seat in the form of a hole 51, as well as two holes 52 with a thread 53 for a retainer 54, a flat groove 55, having two outlet holes 56 with a thread 57 for a retainer, interconnected by a groove 58. The retainer 54 is made in the form of a cylinder, having two coaxial cavities of different diameters, a thread on the outer side surface and two holes (or slot 59) on the end part from the side of the larger cavity.

An insert 60 is located in the cavities of the latch 54, made of a composite of two half-cylindrical parts having a shoulder on one end and a longitudinal half-cylindrical groove for the end of the tensioning wire 12. Each wire located in the same plane is made of two identical parts, the ends of which have a cylindrical thickening . One part of them is fixed in the middle on top of the rack 7, and their ends are pulled through the hypotenuse notches 11 of the panels 5 and through the latch 54, are covered by the parts of the insert 60 and inserted into the cavity of the latch 54 of the sleeve 50 of the arm 3. The other part of the wire 12 is attached in the middle to the second sleeve 7, and their ends are pulled through the notches 11 of the panels 6 and are connected similarly to the sleeve 50 of the arm 3. In the other plane, the above-mentioned reflector elements are connected in a similar way. The rotation of the latches 54 carry out the adjustment of the tension of the wires 12, the square panel 4 and the installation of the arms 3 in the plane at an angle of 90 ^o with a given accuracy.

 The bushings 26, 29 and 50 have dimensions determined by the relations: length 1 ~ (2-2.5) d, width s ~ (1.2-1.5) d and height h ~ (1.5-2) d, where d is the diameter of the shoulder 3. The sleeve 44 may have the same length and width. They are equipped with clamps of the connected reflector elements connected with their seats and made, for example, in the form of a screw, stud, wedge, etc. The latches 20 and 54, made in the form of a screw, have two turnkey holes 61 for wrapping, as shown in Fig.5.

 The rigid elements of the reflector are made of light and sufficiently strong alloys or metals having a tubular or profiled cross section, for example duralumin, titanium, steel.

 The reflector panels are made of reflective radio waves of flexible material, for example, metallized plastic films, metal or metallized plastic nets.

 The trimming of the reflecting panels (faces) is carried out by bonding their sides with a strong woven material, for example, a nylon tape, by gluing or sewing to form a cavity to accommodate the tensioning element: wire 12 or shoulder 28.

 The reflector panels 5 and 6 of the reflector are attached to the rack 1 and to the outer ends of the shoulders 3 by means of overlays 14 and tension wires 12 or / and to the rack using nylon sleeves 9, and to the shoulders 3 by means of sleeves 10 by gluing, sewing or looped ligaments. Reinforcing pads 14 of the triangular panels can be fixed together with the tension wire 12.

 When assembling the bushings 2 and 7 are located and fixed in working positions on the rack 1 so that the seats of the connected elements of the reflector are in mutually perpendicular planes coinciding with the slots 13, four shoulders 3 are connected to the seats of the sleeve 2, perpendicular to each other so so that their slots 13 are also in the corresponding planes coinciding with the planes of the slots 13 of the rack 1 and the sleeve 7. The bushes 38 and 27 are located and fixed on the rack 1 similarly to the bushes 2 and 7 while maintaining the orientation of the landing months t in accordance with the location of the reflecting panels in mutually perpendicular planes.

 The accuracy of installing the reflector elements in the design position is made by adjusting the efforts of the tensioning elements and their fastening with screw clamps. For example, at the top of the rack 1, one tension wire 12 is pressed against the wall of the seat by the first latch 20, and the other wire 12, located above the first and perpendicular to it, is fixed by another latch 20. Improving the quality of the fixation can be carried out by introducing a gasket between the wire 12 and the latch 20 24 or 21. The connection of the elements in the inserted bushings 26, 29, 44, and 50 is carried out in a similar way, that is, the fixed ends of the elements are clamped in seats by screw clamps. The pads 14 at the corners of the panels 4, 5 and 6 also have a notch with the possibility of its location in the locking elements, for example, in the form of a retainer 54 or wedges. The corners of the panels with notches are inserted into the grooves of the sleeve bushings or their clamps and clamped in them (not shown). The installation of the shoulders 3 in a mutually perpendicular position to the rack 1 is carried out by adjusting the location and tension of the tensioning elements: wires 12 with a retainer 20 or 54, and the shoulders 3 and 28 with the accuracy of their manufacture. After adjustment, the clamps and the ends of the wires are filled with sealant.

 In accordance with the invention, the reflector can be manufactured in two versions: with manual and automatic opening.

 The operation of the claimed corner reflector is as follows.

 The manufactured reflector folds up for manual storage. The operator presses the spring clip 8 and moves up the second sleeve 7 (27), thereby loosens the tensioning element 12 (28), presses the shoulders 3 to the rack 1 and puts it in a container that holds it in this position.

 The assembled reflector in the folded position, depending on the manufacturing option, is packed in a packaging or launch container and stored until use. The launch container can be mounted on the object and the reflector can be stored in it until the reflector is put into working position.

 The invention provides three options for opening the reflector: one for the manual version and two for the automatic.

 With manual opening, the reflector is removed from the packaging, the rack 1 is fixed at the workplace, and the sliding second sleeve 7 is engaged by the operator by engaging the spring clip 8. The wire 12 rotates the shoulders 3 in a perpendicular plane to the rack 1. The reflector is brought into working position. After the expiration of the need, the reflector can be dismantled, folded, placed in the package and stored in it until the next use.

 Disclosure of the automatic reflector is carried out taking into account the type of object on which it is installed.

 If the reflector is to function on the object, then the container with its base with the reflector stand 1 attached to it is fixed on the object, and the container casing is detachable and has the ability to manually or automatically on command to separate from the base. In the closed state, the container may be as long as necessary. At a given moment, the casing of the container can be removed manually by the operator or separated by his command automatically using the mechanism. The stretched springs 17 and 18, attached to the sliding sleeves 7 (or 27) and the ring 19, will begin to compress. Under their force, the tensioning elements 12 (or 28) begin to shift and turn the shoulders 3 in a perpendicular plane to the rack 1. The turning process ends with the moment of engagement of the named sleeve with a spring clip 8. The reflector takes up its working position and is ready for operation. When necessary, the reflector can be folded and enclosed in a casing and stored until the next use.

 If the reflector should operate outside the object, the container is made with a detachable lid, and the base is equipped with a spring mechanism that supports the bottom of the rack 1 of the reflector associated with the base of the container. The operator manually or at his command automatically opens the lid of the container, and then the rack 1 engages. The spring mechanism pushes the reflector out of the container with speed. After exiting the container, the shoulders 3 of the reflector under the action of the springs 17 and 18 and the tensioning elements 12 (or 28) begin to turn from the rack 1 into the plane perpendicular to it until the sliding sleeve 2 (or 27) engages with the latch 8. The reflector is brought into working position and ready to fly.

 The functioning of the reflector consists in the fact that, once it enters the radiation zone of the radar antenna system, it sequentially reflects the radar beam from the first face to the second face, the second to the third, and the third face in the opposite direction exactly to the radar antenna. The radar station, having received the reflected rays, registers them and determines the coordinates of the object (reflector), its speed and direction of movement from them.

According to [1], an ideal corner reflector with triangular faces of 125 cm at a wavelength of 3.2 cm should have a maximum EPR of about 10 ⁴ m ² . When the angles deviate from the straight lines by 1 ^o, it will have an EPR 30 times less, i.e. only about 300 m ² .

The error in the installation of the shoulders 3 in the prototype can exceed a significantly single-degree value, therefore, when manufactured in such dimensions, it will have an EPR of less than 300 m ² .

The manufacture of a reflector of such dimensions according to the invention allows to reduce the error of setting the shoulders 3 to 10-15 minutes, which will increase its EPR to (3-4) 10 ³ m ² . The manufacture of a reflector with a telescopic stand allows to reduce its length when folded by about 25%.

 The aforementioned indicates that the features introduced into the design allow increasing the EPR of the reflector in comparison with the prototype by an order of magnitude, therefore, the features have significant novelty.

Sources of information
1. V.O. Kobak Radar Reflectors. M .: Soviet radio, 1975.

 2. B. L. Holm. Radar reflector. Patent USA 2721998, Cl. 343-18, filed 1951, patented 1956.

 3. E.K.P. Graham. Reflector for radar purposes. Patent USA 2,763,000, Cl. 343-18, filed 1952, patented 1956.

 4. C. H. Rockwood. Reflective radar target. Patent USA 3039093, Cl. 343-18, filed 1956, patented 1962.

 5. P. A. Lowery Etal. Collapsible octahedral comer reflector, 3152329, Cl. 343-18, filed 1961, patented 1964.

 6. L. E. Wood. Sounding ball u target assembly. Patent USA 3283328, Cl. 4343-706, filed 1963, patented 1966.

Claims (19)

 1. A foldable corner reflector comprising a central support column (1), a first sleeve (2) located near the middle of the column (1), four arms (3) arranged in pairs at right angles to each other, each pivotally attached to one end sleeve (2), a second sleeve (7) mounted on a rack with the possibility of sliding from a closed position below the first sleeve (2) until it is fixed near the base of the rack with a restrictive lock (8), radio-reflecting flexible material in the form of a square panel (4), right angles which are attached to to the outer external ends of the shoulders (3), the center - to the first sleeve (2) and the diagonal parts - to the corresponding shoulders along their length, and eight triangular panels (5, 6) in the form of rectangular triangles, the four upper triangular panels (5) in pairs symmetrically located above the square panel (4) between the stand and the corresponding shoulders (3), the right angle of each upper triangular panel (5) is attached to the first sleeve (2), the second angle to the outer end of the shoulder (3) supporting it, and the third corner - to the top of the rack (1), four lower triangular panels (6) in pairs symmetrically located below the square panel (4) between the stand (1) and the corresponding shoulders (3), the right angle of each lower triangular panel (6) is attached to the first sleeve (2), the second angle to the outer end of the shoulder (3) supporting it , and the third angle is towards the second sleeve (7), the hypotenous side of each triangular panel (5, 6) has a notch (11), two tension wires (12) located in two mutually perpendicular planes, with the middle sections placed in the slots ( 13) the top of the rack (1), and the final part of each is placed in an appropriate the hem (11) of the upper triangular panel (5), the outer end of the shoulder (3), the hem (11) of the lower triangular panel (6) and attached to the second sleeve (7), equipped with springs (17 and 18), attached at one end to the second the sleeve (7), and the other to the annular stop (19) of the rack (1), reinforcing means (14) in the form of overlays of elastic material at the corners of all panels, characterized in that the first sleeve (2) is fixed motionless, and the bounding latch ( 8) the second sleeve (7) is made with the possibility of its fixing in one position near the base of the rack (1), while in column (1) and the outer ends of the arms (3) are formed with seatings, and further provided with retainers (20) disposed therein.  2. A folding corner reflector according to claim 1, characterized in that the latches (20) of the top of the strut (1) and the external ends of the shoulders (3) are made in the form of screws located in the mating thread on the sections of the inner surfaces of their seats.  3. A folding corner reflector according to claim 2, characterized in that between each latch (20) and a portion of the tensioning wire (12) there is a gasket (24) having a rounded groove (25) under the tensioning wire in accordance with its location.  4. A folding corner reflector according to claim 3, characterized in that between each latch (20) of the top of the rack (1) and each tensioning wire (12) there is a gasket (21) having mutually perpendicular grooves (22, 23) of different depths in accordance with the location of the tension wires (12) in their slots.  5. A foldable corner reflector according to claim 3 or 4, characterized in that the latches (20) in the form of a screw and a lining (14) of the square panel (4) are attached to additional inserted bushings (26) located on each outer end of the shoulder (3 ) and having seats (30, 31, 32 and 33) for the outer end of the shoulder (3), the section of wire (12), the clamp (20) and the lining (14) of the square panel (4), respectively.  6. A folding corner reflector according to claim 5, characterized in that the seat (33) of each sleeve (26) for securing the lining (14) of the square panel (4) is threaded and is additionally equipped with a latch (54) made in the form of a cylinder having two coaxial cavities of different diameters, a thread on the outer lateral surface and two holes (61) or a slot (59) on the side of the cavity of a larger diameter, in the coaxial cavities of which there is an insert (60) made of two semi-cylindrical parts having one butt end and longitudinal along lucilindrical groove under the end of the lining (14) of the square panel (4).  7. A folding corner reflector according to claim 5 or 6, characterized in that each tensioning wire (12) is made in the form of two identical parts with thickened ends, the midpoints of which are fixed respectively on the top of the rack (1) and the second sleeve (7), and the end parts are threaded through the cuts (11) of the triangular panels (5, 6), the seats (31) of the bushings (26) of the outer ends of the shoulders (3) and are attached to the additionally inserted clips (20, 54), while the holes of the bushings (26) made with mating thread.  8. A folding corner reflector according to claim 7, characterized in that each external end of the shoulder (3) is provided with a sleeve (50) having a mating seat in the form of an opening (51) for mounting it on the external end of the shoulder (3), two holes (52) with a thread (53) for additionally introduced clamps (54) of the end parts of the tension wires (12), a flat groove (55) having two outlet openings (56) connected by an additional groove (58) and provided with a thread (57) ) under the latches (54) of the trim (14) of the square panel (4).  9. A folding corner reflector according to claim 8, characterized in that the same parts of the tensioning wires (12) located below the square panel (4) are made in the form of two rigid tensioning shoulders (28), the ends of each of them are connected to the sleeve of the outer shoulder (3) with the possibility of rotation and the second sleeve (7) of the rack (1), and the second sleeve (7) of the rack (1) is made with flat grooves to accommodate the four ends of the rigid pulling shoulders (28) with the possibility of rotation in the plane of the shoulder (3) .  10. A folding corner reflector according to claim 9, characterized in that the square panel (4) is made up of four panels in the form of rectangular triangles, each of these panels is located in the plane of the shoulders (3) and is attached with chopped catheter sides to the sleeves (10) adjacent shoulders (3), at right angles to the first sleeve (2) of the strut (1), and the second and third angles to the corresponding external ends of the shoulders (3) by means of a sleeve (44) having a first seat (48) for fixing the sleeve on the outer end of the shoulder (3), the second seat (45) for pulling wire (12), the third seat (46) for the lining (14) of the corresponding panel included in the composite square panel (4), made in the form of two holes located in the plane of the shoulders (3), the fourth seat (47) for connecting the outer end of the rigid tensioning arm (28) with the possibility of rotation, the fifth seat (49) in the form of a hole for the axis of the rigid tensioning arm (28), the second (45) and third (46) seats made with threads for each of these, the corresponding retainer (54), and the hypotenuse side on each panel constituting a square panel (4), has a notch (11) into which, for example, a cord is inserted, portions of which are threaded into the end of the cover (14) and secured by a latch (54) of each sleeve of the outer end of the shoulder (3) by inserts (60).  11. A foldable corner reflector comprising a central support column (1), a first sleeve (2) on the column, four arms (3) arranged in pairs at right angles to each other, each pivotally attached at one end to the first sleeve (2), the second a sleeve (7) mounted on a stand below the first sleeve (2) with the possibility of displacement along the stand from a closed position to an open, radio-reflective flexible material in the form of a square panel (4), the right angles of which are attached to the corresponding external ends of the shoulders (3), center - to the first sleeve (2) and are diagonal e sections - to the shoulders (3) along their length, and eight panels (5, 6) in the form of rectangular triangles, the four upper triangular panels (5) are symmetrically arranged in pairs above the square panel (4) between the stand and the corresponding shoulders (3), the right angle of each upper triangular panel (5) is attached to the first sleeve (2), the second angle is to the outer end of the shoulder (3) supporting it, and the third angle is to the top of the rack (1), four lower triangular panels (6 ) in pairs are symmetrically located below the square panel (4) between the stand and the corresponding by levers (3), the right angle of each lower triangular panel (6) is attached to the first sleeve (2), the second angle to the outer end of the shoulder (3) supporting it, and the third angle to the second sleeve (7), the hypotenous side of each the triangular panel (5,6) has a notch (11), two tension wires (12), the middle sections of which are located in the slots (13) of the top of the rack, and each end part is placed in the corresponding subcut (11) of the upper triangular panel (5), the outer end of the shoulders (3), the sleeve (11) of the lower triangular panel (6) and is attached to the second sleeve (7), reinforcing means (14) in the form of an overlay (14) of elastic material at the corners of all panels (4, 5, 6), and a spring, characterized in that the central support column (1) is made telescopic in the form of an external part (40) and an internal part ( 41), the first (2) and second (7) bushings are rigidly attached to the lower sections of the outer (40) and inner (41) parts of the telescopic rack, and a coil spring (42) is located in their cavities, the parts of the rack have combined windows for placement spring retainer (43) located on the first sleeve (1), combined about a button for entering the protrusion of the spring clip (43) located on the first sleeve.  12. A folding corner reflector according to claim 11, characterized in that the apex of the outer part (40) of the telescopic stand and the outer ends of the shoulders (3) are additionally equipped with clamps (20), for example, made in the form of screws with gaskets (24) located respectively in the mating thread of the inner surface of the apex of the outer part (40) and the outer ends of the shoulders (3).  13. A folding corner reflector according to claim 12, characterized in that the latches (20) located on each outer end of the shoulder (3) in the form of a screw and a cover (14) of the square panel (4) are attached to an additionally inserted sleeve (26) having seats (30, 31, 32 and 33) for the outer end of the shoulder (3), the portion of the tensioning wire (12), the clamp (20) of the position of its end part and the lining (14) of the square panel (4), respectively.  14. A folding corner reflector according to claim 13, characterized in that each seat (33) of each sleeve (26) for securing the lining (14) is threaded and provided with a latch (54) made in the form of a cylinder having two coaxial cavities different diameters, a thread on the outer side surface and two holes (61) or a slot (59) on the end part from the side of the cavity of a larger diameter, in the cavities of which there is an insert (60) made of two parts having a flange and a longitudinal on one end semi-cylindrical groove under the final cha be laths (14) square panel (4).  15. A folding corner reflector according to claim 13 or 14, characterized in that each pulling wire (12) located in the same plane is made in the form of two identical parts with thickened ends, the midpoints of which are fixed respectively on top of the outer part (40) of the telescopic the struts and the second sleeve (7), and the end parts are threaded through the undercut (11) of the corresponding upper (5) and lower (6) triangular panels, are located in the seats (31) of the bushes (26) and secured into them by additionally introduced clamps (20 or 54).  16. A folding corner reflector according to claim 14 or 15, characterized in that each outer end of the shoulder (3) is provided with a sleeve (50) having a mating seat in the form of an opening (51) for mounting it on the outer end of the shoulder (3), two holes (52) with a thread (53) for additionally introduced clamps (54) of the end parts of the tensioning wires (12), a flat groove (55) having two output holes (56), interconnected by an additional groove (58) and made with threaded (57) for additionally introduced latches (54) for fixing the covers (14) of the square panel (4) insertion tool (60).  17. A folding corner reflector according to claim 15 or 16, characterized in that the same parts of the tension wires (12) with thickened ends lying in the same plane and located below the square panel (4) are made in the form of two rigid tensioning shoulders (28) , the ends of each of them are connected to the sleeve (29) of the outer end of the shoulder (3) with the possibility of rotation and the second sleeve (7) of the telescopic rack, and the second sleeve (7) of the rack is made with seats in the form of a flat groove and is equipped with four axes for connecting to them four ends hard tensioning shoulders with the possibility of rotation in the plane of the shoulder (3).  18. A folding corner reflector according to any one of claims 15-17, characterized in that the square panel (4) is made up of four panels in the form of right-angled triangles, each inserted triangular panel is located in the plane of the shoulders (3) and attached to the catheted hewn sides to the sleeves (10) of adjacent shoulders (3), at right angles to the first sleeve (2) of the outer part (40) of the telescopic stand, and the second and third angles to the corresponding external ends of the shoulders (3) by means of a sleeve (44) having a first landing place (48) for the outer end of the shoulder (3), in a third seat (45) for the tensioning wire (12), a third seat (46) for the lining (14) of the inserted triangular panels, made in the form of two holes located in the plane of the shoulders (3), a fourth seat (47) for connecting a rigid pulling shoulder (28) with the possibility of rotation, the fifth seat (49) in the form of a hole for the axis of the rigid pulling shoulder (28), and the second (45) and third (46) seats are threaded for insertion into each latch (54 )  19. A folding corner reflector according to claim 18, characterized in that the hypotenuse side of each panel in the form of a rectangular triangle of a composite square panel (4) has a notch (11), in which there is a cord, sections of which are threaded into the end parts of the patch (14) square panel (4) and secured by a latch (54) of each sleeve of the outer end of the shoulder (3) by means of an insert (60).

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