RU2768257C1 - Method of masking antenna device by means of ground antenna shelter - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to the field of masking ground-based antennae, in particular to antenna shelters (AS), disguised as an installation object or surrounding landscape. Technical result is achieved by the fact that on external surfaces of three-coordinate angular posts (TCAP), sections of coordinate intermodule-step expanders (CISE), internal groove panels (IGP), semi-tongue-and-groove panels (STGP) are camouflaged in a planar or volumetric manner, the type of which is determined by the installation object or the surrounding landscape.

EFFECT: creation of camouflaged AS by planar or volumetric camouflage of external surface of AS, identical to installation object, radio transparent frameless modular type with a function of modular expansion with a constant pitch on any size: length, width, height.

13 cl, 15 dwg

Description

The invention relates to the field of camouflage of antennas and antenna systems (AK), namely to camouflage under the installation object or the surrounding landscape with protective radio-transparent dielectric antenna shelters (AU) of a modular type with the functions of expanding dimensions with a constant step for any overall size (length, width, height ) stationary ground and mobile AKs in order to create visual perception, in which the camouflaged AK was perceived identical to the object of its installation or the terrain, and can be used on objects, for example, in the form of ground structures, structures on the roofs of buildings, on car trailers, in the back trucks, on railway platforms.

Radiotransparent dielectric AC AK with masking elements have a wide range of applications.

So, for example, AU AK can be installed: - on the roof of buildings, for example, in the form of a superstructure, or in the form of a ventilation pipe or a chimney pipe, while masking is carried out by painting or a three-dimensional decorative finish made on the outer surface of the AU emitting a building structure and harmoniously fitting in the architecture of the building; - on the ground in urban or rural areas, while camouflage is carried out, for example, under a change house, or a garage, or under an outbuilding with an appropriate exterior finish in the form of painting or a three-dimensional decorative finish; - on the ground in a park or forest area, while camouflage is carried out, for example, under the surrounding landscape; - in the back of cars (pickup type), trucks or special vehicles, on car trailers or platforms, for example, under a change house or a residential trailer; - on railway platforms, for example, disguised as a passenger or freight car.

AK, located outside any protective shelter or camouflage, have visual unmasking features that can be used to determine: - type of antenna and its dimensions, and hence the frequency range; - the width of the main lobe of the radiation pattern (DN); - orientation in azimuth and elevation of the direction of the main lobe of the AP; - the level of the side lobes (BL) and the angles of their orientation in space with respect to the main lobe of the AP; - polarization; - the possibility of changing the position of the antenna in space, namely electrical or electromechanical scanning, or a stationary position.

Knowledge of these parameters makes it possible to determine the true purpose of the AK, which allows, if necessary, to carry out either the physical destruction of the AK, or to carry out a destructive targeted effect on the AK, for example, in the direction of the main lobe of the DN and in the direction of the BL, by destructive electromagnetic fields, or, for example, the setting of polarization interference, which is currently widely and effectively used in electronic warfare tasks and which is difficult to identify as targeted interference, or short magnetic or electromagnetic pulses, as well as electromagnetic fields based on new physical principles, such as longitudinal electric and magnetic waves: longitudinal electric waves (in direction E); longitudinal magnetic waves (in the direction H); torsion waves (along H with a vortex component E); Tesla waves (along with the vortex component H).

For example: Electronic resource: [Access mode] (zhu-nal.lib/ru/e/etkin_w_a/prodolnyevolnykaksledstvieuravneniymaksvella.shtml); (www.prometeus.nsc.ru/partner/zarubin/waves.ssi).

A destructive effect on AC can lead, for example, to temporary electromagnetic blindness with subsequent restoration of functioning or burning out of AC input circuits, i.e. physical destruction.

A known method of creating protective radio-transparent AU frame type, performed dome-shaped in the form of a sphere based on fiberglass, for example, for large ground-based reflector antennas. The sphere is assembled from the correct form of geometric segments, for example, triangular or hexagonal, mounted on a frame, which, as a rule, is made of metal. The frame structure consists of hundreds of homogeneous metal beams, pins and connecting mechanisms that are assembled into a single structure. (For example: Electronic resource: [Access mode] (https://locplayer/ru/47442744-Ukrytiya-antennyh-ustroystv-dioprozrachnye/html).

Such AU designs have only a protective function from external climatic and mechanical influences, while there are two unmasking signs: the first is the AU, and the second - the frequency range can be approximately determined by the diameter.

A known method of creating a frameless radio-transparent AU to protect antennas of spherical shape. For example (RF patent No. 2419927 MPK H01Q 1/42, "Radio-transparent shelter for antennas, method of its manufacture and fastening"). Radiotransparent AU has a one-piece one-piece design and is made of multilayer composite materials, which is based on fiberglass and epoxy resin. The AU design is made for a certain type of antennas and certain sizes and is attached to a carrier platform or base.

The main function of such AC is protection only from external climatic and mechanical influences. Such AUs are used, for example, for reflector antennas or truncated parabolic antennas, for phased antenna arrays.

Such AU designs have two unmasking signs: the first is AU, and the second - the frequency range can be roughly determined by the diameter.

A known method of masking AK from the means of visual observation using radio-transparent camouflage nets located on the frame. For example (RF patent No. 2546470, MCP F44H 3/00).

This method of AK camouflage is used as a temporary and severely weather-limited operation and, as a rule, is used for short-term camouflage under the terrain.

Known methods of camouflage in the open space of AK, presented in the foreign press, in particular, as one of the areas of application - this is the camouflage of communications, camouflaged as bushes, antennas, for example, in the Arizona desert, the type of camouflage fits into the surrounding landscape. Also, for example, in other conditions, trees, rocks can serve as masking antennas. For example: Electronic resource: [Access mode] (https://novostel.ru/2017/10/24/ American operators disguise antennas as cacti), Electronic resource: [Access mode] (http://pageperso.aof.fr/ tsf70/images/fox/drol47_3.ipg).

Known methods of masking the antenna under the elements of buildings, for example, water towers, church crosses, church bell towers, ventilation pipes on the roof of the building, chimneys, like speakers, flagpoles. For example: (Electronic resource: [access mode] (www.radioscanner.ru/forum/topic22958.html).

There are known methods of masking antennas in the form of a super-tree, in the form of a palm tree, in the form of a flagpole in Texas, the tower and bell tower of the Episcopal Church in Dallas, a tree trunk in Arizona, in a brick-like window frame in Sopot Poland, as a work of art a decorative tower, under a cross at Lac Worth Florida Church, in the form of a bell tower in LaVista New England. For example (Electronic resource: [access mode] (https://bigpicture.ru/?p=318259).

The considered masking methods are not universal and are used only for ground stationary AK under vegetation, a building structure or a fragment attached to a building structure, and are used for a very limited type of AK antennas, for example, vibrator antennas, non-protruding rhombic antennas, flat phased antenna arrays.

Such masking methods by their design are not collapsible universal and are made specifically for the AK and the installation object, in addition, they cannot be used to mask a wide class of large-sized (volumetric) antennas, for example, reflector antennas.

It follows from the analysis carried out that there are no known technical solutions for the construction of ground-based AUs that simultaneously meet the requirements of a wide range of camouflage options and versatility in the formation of type-sizes for a wide range of AKs installed inside such AUs.

The AU versatility lies in the frameless and modular step-by-step expansion, with a constant step for any overall size (width, length, height), design, which makes it possible to form the AU for a wide range of types and sizes of AK antennas without expanding the range of type sizes of structural elements, but simply a corresponding increase in their number. Such versatility of the AU construction allows masking both low-profile antennas and antennas of significant dimensions, for example, reflector antennas.

The modular expansion step is determined by the dimensions of the base module, the dimensions of which depend on: - dimensions of the antenna; - antenna installation locations at the facility; - methods of delivery to the object (by automobile, passenger or freight transport, aviation, sea container); - assembly method (manual or using lifting mechanisms). The best option is the versatility in choosing the size of the base module for a wide range of dimensions of AK antennas, delivery and assembly, which greatly simplifies production and reduces the cost of AU production. In this case, the type of masking - a planar or three-dimensional pattern on the outer surface of the AC must be made specifically for the installation site.

At the same time, sufficiently stringent requirements are imposed on the radio-transparent dielectric material for the execution of all structural elements of the AU, namely: - the value of the relative dielectric permittivity of the order of (2.0-3.0); - the value of the tangent of the dielectric loss angle of the order of 10 ^-3 in the frequency range from the medium wave range to tens of GHz; - resistant to a wide range of external climatic influences in the temperature range of ± 50 ° C and air humidity up to 100%; - resistant to ultraviolet radiation and increased solar radiation; - resistant to snow, rain, sandstorms, aggressive environments (chemical rain); - resistant to dry thunderstorms and increased air electrification, which allows not to use grounding; - have thermal insulation properties; - it is easy to be mechanically processed by the cutting tool; - the ability to perform a three-dimensional drawing on the outer surface of the AC to create a three-dimensional masking; - the ability to perform gluing of AC parts, similar to the method of cold welding; - have high adhesion when painting with special paint.

Electronic resource: [Access mode] (GOST 30299-95 Interstate standard. Fiberglass structures. Radio-transparent covers for antenna devices. General technical requirements.).

The technical objective of this invention is to create a method for masking AK without visual unmasking signs by using a universal protective, frameless modular expandable with a constant step equal to the size of the base module (BM), AU made of a radio-transparent dielectric material and a device for its implementation with the following properties: - AU is modular frameless design with a minimum range of type sizes of structural elements; - with the possibility of expanding by the amount of BM according to any size (length, width, height) of the AU, by increasing the number of BM without increasing the range of structural elements, and the BM internal tongue and groove connection provides protection from external climatic influences; - the presence of a door or a hatch in the side wall of the AC provides access to it; - the external surfaces of the BM AU are made with a planar or three-dimensional pattern that imitate a wide range of objects on which it is installed and harmoniously fit into it, or the environment, while not creating unmasking signs.

The technical result is achieved by the fact that the method of masking the AC by using a protective radio-transparent modularly expandable with a constant step along any of the coordinates OX, OY and OZ of the sides of the dielectric ground AC, made entirely of one type of radio-transparent dielectric material, on the outer surfaces of which masking is made in the form of a decorative finishing that imitates the external appearance of an object or landscape, where the AU is installed and harmoniously fits into it, consisting in a frameless assembly by installing on three-coordinate corner posts (TKUS), the same for the base module (MO) and the roof module (MK), forming an expansion step along any coordinate OX, OY and OZ, at least two sections of coordinate intermodule-step expanders (KMShR) for each coordinate, sheet pile base modules (SBM), which are made in the form of square panels and are subdivided into intra-sheet pile panels (ITP) same for side walls, for module p ola (MP) both for the roof module (MK) and on the half-tongue panels (PSHP) for the hatch or for the side access door inside the AC, while the depth and thickness of the internal sheet pile of the VSHP and the half-tongue of the PSHP are the same, and are interconnected by external intermodular tongues ( VMMSH), which are made in the form of a rectangular plate, the length of which is equal to the length of the side of the SHBM, and the width and thickness are equal to twice the depth and thickness of the internal tongue of the SHBM, respectively, while masking and assembling the AC is carried out with the following steps:

- camouflage is carried out in the form of decorative finishing of the external surfaces of the SHBM, TKUS and sections of the KMShR in a planar or volumetric design, emitting the appearance of the object or landscape where the AC is installed;

- the formation of MO AC along the coordinates OX and OY is carried out by installing four TKUS in the four corners of the MO, respectively, each TKUS of the MO is located in its own rectangular coordinate system, while the TKUS is made of three identical bars located at the coordinates OX, OY and OZ of the rectangular system coordinates, respectively, the bars are made of square cross-section, the side of the square of which is equal to the thickness of the IDT, and the length is equal to half the length of the IDT, while in three coordinate planes ZOX, ZOY and XOY on the bars of each TKUS along the longitudinal axis three identical L-shaped plates are made, respectively , which consists of a plate of a horizontal branch and a plate of a vertical branch, and on each TKUS in the XOY plane there are plates of four branches oriented horizontally, and in the ZOY plane and in the ZOX plane there are one plate of branches oriented vertically, while the plates of the horizontal and vertical branches of the plate L-shape s are made of the same length and equal to half the length of the IDT, and the width and thickness of the plates of the horizontal and vertical branches are equal to the depth and thickness of the internal sheet pile of the IDT, respectively, and are external sheet piles for the SBM, while along the OX coordinate and along the OY coordinate between the horizontal bars of four TKUS MO installed in each of the four openings, at least two sections of KMShR, which is made in the form of a bar of square cross-section, the side of the square of which is equal to the thickness of the IDT, and the length is equal to the length of the side of the IDT, while on two adjacent sides of the KMShR section, in the center along the longitudinal axis, two identical rectangular plates are made, the length of which is equal to the length of the side of the IDT, and the width and thickness are equal to the depth and thickness of the internal sheet pile of the IDT, respectively, while the mutually perpendicular plates of the section are external sheet piles for the SBM, and the external sheet piles of the KMShR sections are combined with external sheet piles TKUS MO, forming four openings MO and four openings of the side walls to;

- the assembly of the MP AC contour is carried out by installing on the outer horizontal sheet piles of each opening of the MO with internal sheet piles, thereby forming the MP;

- the formation of the first row of side walls of the AC with a hatch or side access door is carried out by installing on the outer horizontal and vertical sheet piles TKUS and sections KMShR of each opening of the side walls with internal sheet piles, while at least one side opening is installed at least , one PSHP,

- the formation of four openings of the side walls of the full height of the AC is carried out by setting the OZ coordinate of each TKUS MO on a vertical bar, at least two sections of the KMShR, while the outer tongues of the sections of the KMShR are aligned with the outer tongues of the corresponding TKUS MO;

- the formation of the side walls of the AC of full height is carried out by installing in four openings of the side walls of the full height on the outer sheet piles of the KMShR sections and on the VMMSH of the first row of the VSHP, the VSHP of the subsequent rows and at least one PSHP on the PSHP of the first row are installed, while the number of rows of SHBM up to the full height, the AC is equal to the number of sections of the KMShR, and in the area of \u200b\u200bthe connection of the end walls of adjacent IDTs and the connection of the end walls of neighboring IDTs with IDTs, MMMShs are installed;

- the assembly of the base of the MK is carried out, which consists in installing in vertical, along the coordinates OZ, and horizontal, along the coordinates OX and OY, the internal sheet piles of the last row of the IDT of four corner joints of the KMShR with external sheet piles of four TKUS, respectively, and sections are installed in the openings between the horizontal bars of four TKUS KMShR, the number of which is equal to the number of KMShR on the corresponding side of the MO;

- assembly of the MC is carried out, which consists in installing the closing TKUS and sections of the KMShR on the outer horizontal sheet piles with the internal sheet piles of the MC until the MC is completely closed, and in the area of \u200b\u200bconnection of the end walls of adjacent DShPs, VMMSHs are installed;

- SHBM is rigidly fixed to each other through VMMSH, SHBM is fixed with TKUS and SHBM is fixed with KMShR, which consists in a threaded connection by means of dielectric studs and / or dielectric bolts and / or cold welding.

Threaded holes for installing dielectric studs or bolts are made blind in order not to disturb the external appearance of the AU, i.e. disguise.

The use of cold welding with glue in conjunction with dielectric studs or dielectric bolts can significantly increase the strength of the AC structure, especially to wind loads.

AU masking can be done in two ways.

The first masking method is carried out by performing planar drawings by applying radio-transparent paint to the outer surfaces of the SHBM, to the outer surfaces of the TKUS bars and to the outer surfaces of the KMShR sections.

The second method of masking is carried out by performing a three-dimensional pattern by mechanical processing, for example, milling or installing by cold welding (on glue) dielectric panels on the outer surfaces of the ShBS, on the outer surfaces of the TKUS bars and on the outer surfaces of the KMShR sections, and the shape of the three-dimensional pattern (dielectric panels ) must match the appearance of the object or landscape, and the color of the dielectric panels must match the natural color of the dielectric or with subsequent application of radio-transparent paint to the surface.

At the beginning, the object and installation site of the AC are determined and, depending on this, the masking method is determined - planar or volumetric and color.

The technological operation for the implementation of AC masking elements is optimally performed during production. However, if necessary, these operations can also be performed at the installation site, while carrying out these works at the facility has a revealing factor.

The method consists in connecting half-tongue panels of a door or a hatch with inner-tongue panels, and / or with three-coordinate corner posts, and / or with sections of coordinate intermodule-step expanders using dielectric loops, which are fixed using dielectric studs and / or bolts, and / or cold welding.

The door or access hatch into the inside of the AC is assembled from at least one SHP and can be connected to the SHP and / or to the TKUS, and / or to the KMShR sections using dielectric loops, which are fixed using dielectric bolts and / or cold welding, At the same time, the VMMSH VSHP for the PSHP in the places of their installation act as an internal bounding box. If a door or a hatch is made of several SHPs, then they are connected to each other by VMMSH and fixed with dielectric bolts or studs, and additionally fixed by cold welding.

A hatch or, as a rule, a door of an AC made according to this method can be installed practically on one or several side walls at the same time, if there are several of them. The peculiarity of this AC design is the possibility, if necessary, not to assemble or disassemble at the assembly stage, with the structure already assembled, one side wall with a door, while the integrity of the AC is not violated. Such an operation is performed at the stage when it is necessary to install bulky equipment inside the AC. In this case, the equipment is installed and then this side wall is assembled.

If the equipment in terms of dimensions can be installed through a door or a hatch, then disassembly of the AC is not required.

It is possible to partially or completely close the MP AU by installing an IDT in the free openings of the MP contour, while in the area of connection of the end walls of adjacent IDTs, MMDS are installed.

Partial or complete closure of the MP VSHP is determined by the conditions of the installation object and / or the operating conditions of the AC.

The contour of the base of the MP AU, formed from the VDT, allows for fastening, for example, with anchor bolts to the foundation of the object, or bolts to the car body.

The AU design according to this method can be performed with an arbitrary expansion step by CMSR sections along any coordinate OX, OY and OZ, which ensures the versatility of the design in terms of overall dimensions, which means the possibility of using masking a wide range of large antennas.

Since, in practice, the dimensions of the AU can be quite large, for example, when using reflector antennas and with the possibility of installation inside the equipment, and given the fact that the IDTs are connected to each other by the VMMSH, and in the corners through the KMShR, it is necessary to increase the rigidity of the structure.

The method consists in strengthening the rigidity of the connection, on the inside of the AU, the end walls of adjacent IDT side walls, IDT MP and IDT MK by installing dielectric intermodular stiffeners (MMUZH), which consists of a rectangular base plate, and located on it perpendicularly along the longitudinal axis of the plate reinforcement, wherein the width of the base plate is equal to the width of the VMMSH, and the length of the base plate and the length of the plate of the stiffener are equal to or less than the length of the VMMSH, and the base plate of the MMUZH is attached to the studs of the rigid fixation of the VDShP.

Optimal is the location of the MMUZH on the vertical end connections of the adjacent SHBM side walls, and the MMUZH MP and MK are their continuation, respectively. If necessary, it is possible to install MMUZH on horizontal joints of the side walls, MP and MK.

The method consists in strengthening the rigidity of the connection, on the inside of the AC, IDT MP with IDT side walls through KMShR and IDT side walls with IDT MK through KMShR by installing dielectric intermodular corner amplifiers (MMCU), one face of which is installed on the connection area of the end walls of adjacent IDTs side walls, and the other face is installed on the connection area of the end walls of adjacent IDT MP and MK, respectively, and one and the other faces of the MMCU are attached to the studs of rigid fixation of the IDT MP, IDT side walls and IDT MK, respectively.

If necessary, strengthening the rigid connection with studs can be additionally used with cold welding.

There are two possible ways to perform MMCU.

One way is to make the MMUU in the form of a bearing plate of ⊥-shaped form, which is one face of the MMUU, in the center of the vertical beam of which a thrust post is perpendicularly installed, which is the other face of the MMUU and is made in the form of a rectangular plate, while the length of the horizontal beam of the carrier plate ⊥- of the shaped form is equal to the length of the side of the IDT, and the height of the vertical beam and the length of the thrust post are equal to half the length of the IDT, and the vertical beam of the carrier plate of the ⊥-shaped form is installed on the connection area of the IDT of the side walls with the CMSR.

Another way is to make the MMCU in the form of a right dihedral angle, one and the other faces of which are made in the form of rectangular plates, while on the MMCU face from the side of the inner right angle, an L-shaped corner amplifier plate is installed perpendicularly in the center, the length of the horizontal and vertical beams which is equal to the length of the face of the right dihedral angle on which it is installed, and the length of the plate of one and the other face is less than or equal to half the length of the VMMSH, and the width of the plate of one and the other face is equal to the width of the VMMSH, while one and the other of the MMUU faces are attached to the studs of the rigid fixation of the VMMSHP MP, IDT side walls and IDT MK, respectively.

In both ways of performing MMCU, the faces of MMCU MP and MMCU MK are installed symmetrically on the connection area of the corresponding IDTs and, as a rule, are attached to them on studs that have already been used to connect the corresponding IDTs with TKUS and MMDS.

The location of the MMUZH along the vertical end connections of the SHBM of the side walls and the MMCU with MP and MK form a U-shaped stiffening rib.

The method consists in strengthening the rigidity of the vertical corner joint, on the inside of the AU, the IDT of adjacent side walls connected through the KMShR by installing dielectric vertical internal corner stiffeners (VUUZh) of the side walls, made in the form of a right dihedral angle, one and the other faces of which are made in the form rectangular plates, while the length of the face of the dihedral angle is equal to or less than the length of the VMMSH, and the width is equal to or greater than half the width of the VMMSH, while on the inside of the right dihedral angle VVUZH there is a dielectric at least one angular spacer in the form of a plate, the outer contour of which is made in the form of an equilateral hyperbola, the asymptotes of which are mutually perpendicular, while one and the other branches of the outer contour of the corner spacer are installed on one and the other plates of the inner faces of the VVUZH, respectively.

(for example - “Equilateral hyperbola”, I.N. Bronshtein and K.A. Semendyaev, Handbook of Mathematics, M .: Nauka, 1967, p. 210)

The method consists in reinforcing the MC AU by installing at least one dielectric horizontal carrier beam installed symmetrically between one and the other side walls, the ends of the carrier beam being fixed on the MMF VDT of one and the other side walls, while between the horizontal carrier beam and the MMF VSHP MK installed dielectric slopes in the form of plates, forming triangular trusses that form a floating ceiling.

For example: (Electronic resource: [Access mode] (yan-(yan-dex.ru/search/?text=frame%20floating%20ceiling%20%20hangars&lr=2 13)

This design of the floating roof eliminates the possibility of sagging and thus eliminates the possibility of accumulation of precipitation in the form of water.

The method consists in power amplification of the AU by installing in the corners of the upper row of the IDT and/or in the lower rows of the IDT from the outer and/or inner side of the AU of the braces.

Guy fixators are made of dielectric with holes for fastening guy ropes.

The method consists in creating a forced or natural air exchange of the internal volume of the AC by making ventilation holes in the IDT. Fans or air ducts, for example, from an air conditioning system, can be installed in the holes.

The invention is illustrated by the following drawings.

In FIG. 1 - shows a general view of the AU in assembled form, for example, with the same extension along each coordinate of width, length and height with three IDTs and with an open side access hatch, for example, made of two IDTs, and a planar masking of the AU in the form of a continuous one-color coating, for example, paint;

in fig. 2 - a general view of the AC (Fig. 1) with planar masking of the outer side walls and a side access hatch, for example, under building blocks;

in fig. 3 - a fragment of the AC side wall (Fig. 1) is shown with volumetric masking of the outer side walls, for example, under brickwork, when the imitation of bricks is made of dielectric plates installed on the IDT side walls, and external fixators of the guys installed in the corners of the upper row of the IDT side walls;

in fig. 4 - shows a general view of the AC (Fig. 1), with a closed side access hatch and external fixators of the guys installed in the corners of the upper row of the IDT side walls;

in fig. 5 - a fragment of the MO AU assembly is shown, for example, with two sections of the CMSR on each side of the MO, and four side openings formed by four TKUS, with installed IDTs along the inner perimeter of the MP and with installed MMCU MP, made in the form of a ⊥-shaped plate;

in fig. 6 - a fragment of the assembly of the first row of the AC side walls (Fig. 5) is shown, with MOs installed in four side openings on the outer sheet piles TKUS and KMShR IDT and a side access opening formed inside the AC, with a width equal to the width of the IDT;

in fig. 7 - a fragment of the final assembly of the first row of IDT of the AC side walls (Fig. 6) for installing the next row of IDT of the side walls, with four TKUS installed at the corners in one section of the KMShR, with the VMMSH installed in the first row of end connections of the IDT, with the VMMSH installed in internal horizontal sheet piles of the first row of IDT side walls;

in fig. 8 - a fragment of the assembly of the second row of IDT side walls of the AC (Fig. 7) with the installation of the VMMSH on the vertical end connections of the IDT of the side walls and the installation of the MMF from the outside of the end connections of the IDT of the side walls is shown;

in fig. 9 - a fragment of the final assembly of the second row of IDT side walls of the AU (Fig. 8) is shown, for installing the next row of IDT side walls, with four TKUS installed at the corners in one section of the KMShR, with VMMSh installed in the second row of end connections of the IDT, with VMMSH installed into the inner horizontal sheet piles of the second row of the IDT of the side walls, with the side walls of the MMUZH installed on the adjacent IDT of the side walls;

fig. 10 - a fragment of the assembly of the third closing row of IDTs of the AC side walls (Fig. 9) with a side access opening inside the AC with a size equal to two CSPs, with the IDSHs installed in the internal tongues of the IDTs of the side walls forming a side access opening, with side walls installed on adjacent IDTs MMUZH;

in fig. 11 - a fragment of the assembly of the MC AU (Fig. 10) is presented, consisting of four TKUS, with two sections of the CMSR on each side of the MC and nine IDT connected to each other by the MMMS;

in fig. 12 - shows a general view of the AU (Fig. 11) assembled with the installed MC;

in fig. 13 - a general view of the AU (Fig. 11) assembled from the side of the MP, where you can see the installed MMSF on the side walls and the MC and the installed MMCU between the IDT of the side walls and the IDT of the MK;

in fig. 14 - a general view of the reinforcement structure of the MK AU (Fig. 1) is shown by installing horizontal load-bearing beams between opposite side walls and the ends of the IDT fixed on the MMUZh and the dielectric slopes installed on them in the form of plates, fixed at one end to the load-bearing beam, and the other end to MMUZH MK, thus forming triangular trusses of the floating ceiling, and installed MMUZH and VVUZH side walls;

in fig. 15 - a general view of the AU in assembled form with an extension, for example, of six IDTs and side access in the form of a door mounted on dielectric hinges.

The AU masking method and its implementation are as follows.

Camouflage AU 1 is a decorative finish of the outer surface, which can be performed in two forms: planar or volumetric.

A planar decorative finish is available as a solid, solid color of paint over a flat surface, or as a pattern that mimics a building material such as brickwork, block masonry, wood paneling, siding, and other building materials.

Volumetric decorative finishing is performed in the form of a three-dimensional pattern and can be technologically performed, for example, mechanically by milling the outer surface, or by cold welding using special glue, overlay elements made of a dielectric material similar in electrophysical parameters and electrodynamic characteristics, and subsequent decorative finishing either by selecting the color of the dielectric material or by painting.

Works on decorative finishing of AC 1 are carried out, as a rule, in production during the manufacture of its structural elements.

Decorative finishing AU 1 is performed on external surfaces: VSHP 2 side walls, TKUS 3, PSHP 4 doors or hatches, KMShR 5.

Decorative finishing of the external surfaces of VSHP 2 MK 6 can be performed both by the planar method, by painting, and by the three-dimensional method, by making a three-dimensional pattern with a profile identical to the profile of the coating material used, for example, corrugated or sheet iron, metal tiles, andulin, stekloizol, and subsequent painting.

The design of AC 1, implemented by the bottom method, for example, is made with the expansion of two sections KMShR 5 for each coordinate OX, OY and OZ, which corresponds to three IDT 2.

In FIG. Figure 1 shows an example of AC 1 with planar masking in the form of a decorative monophonic finish, with TKUS 3 and the same extension with two KMShR 5 for each coordinate of width, length and height, which corresponds to three VSHP 2, and a side access hatch 7, for example, made of two PSHP 4 and is presented in the open state.

In FIG. 2 shows an example of AU 1 with planar masking, made by painting to look like building blocks, VSHP 2 of the side walls and PSHP 4 of the side access hatch 7.

In FIG. Figure 3 shows a fragment of one side wall of AC 1 with a volumetric decorative finish of the VDT 2 of the side walls, made, for example, under brickwork, an imitation of brick 8 is made, for example, of thin dielectric plates the size of a brick, installed by cold welding on the VDT 2, and the seam, in the form of a mortar of brickwork, done with paint, Guy fixators 9 are installed on the side walls of AC 1, for example, along the top row of VDT 2.

Decorative finishing TKUS 3 and KMShR 5, in relation to the finishing of the side walls, can be both volumetric and planar.

The general view of the AC 1 in the assembled state with a flat MC 6, with a closed side access hatch 7 and external fasteners of the guys 9 installed in the corners of the upper row of the IDT 2 of the side walls, with a planar decorative finish, is shown in Fig. 4.

The assembly of AC 1 (Fig. 5) begins with the assembly of MO 10, which consists in installing four TKUS 3 at the corners of MO 10, respectively, and with the expansion along each side of MO 10 with two KMShR 5, as a result, four side openings 11 are formed, while on external sheet piles TKUS 3 and KMShR 5 along the entire closed perimeter of MO 10 are installed by VSHP 2 forming MP 12, on which MMCU 13 is installed, made in the form of a ⊥-shaped plate.

On the formed MP 11 of Fig. 5, the assembly of the first row of side walls of AC 1 of FIG. 6, which consists in installing the VDT 2 on the outer sheet piles TKUS 3 and KMShR 5 in four side openings 11 while forming the opening of the hatch 7 of the side access inside the AC 1, with a width equal to the width of one VDT 2.

In the first row of vertical end connections of the VSHP 2 of the side walls of the AS 1, in the vertical sheet piles of the VSHP 2 forming the opening of the hatch 7 of the side access and in the horizontal internal tongues of these VSHP 2, VMMSH 14 is installed, and at the corners of four TKUS 3, one section of the KMShR 5 is installed, forming thereby extending the four side openings 11 as shown in FIG. 7, which corresponds to the final assembly of the first row of AC 1.

On the formed first row of side walls of AC 1 in four side openings 11, as shown in Fig. 7, the assembly of the second row of IDT 2 side walls of the expansion in height is carried out, shown in FIG. 8, which consists in installing on the external sheet piles VMMSH 14 with internal sheet piles VShP 2 in four side openings 11, while on the inside of the AU 1 on the vertical end connections of the VShP 2 side walls are installed MMUZH 15.

The stage of the final assembly of the second row of side walls along the height of AC 1, shown in Fig. 9 is similar to the assembly of the first row of AC 1 shown in FIG. 7.

The stage of assembling the third closing row of side walls along the height of AC 1, shown in Fig. 10, which is similar to the assembly of the second row (Fig. 8), while the opening of the hatch 7 is formed with the size of two CSR 2.

Thus, collected AU 1 with a given extension of two KMShR 5 at the base (coordinate OH and OY) and height (coordinate OZ).

The final stage in the assembly of AU 1 is the formation of MK 6.

There are two options for the formation of MK 6: the first option - MK 6 is assembled separately and then installed on the closing third row of IDT 2 of the side walls, as shown in Fig. eleven; the second option - consecutive installation of four TKUS 3 external piles and two on each side of the KMShR 5 into the internal sheet piles of the VDT 2 of the closing third row of side walls, followed by the installation of the VDT 2 in the MK 6 and the connected VMMSH 14, as shown in Fig. 12.

Strengthening the rigidity of the AC 1 structure is carried out from the inside in several ways, while the design solutions for strengthening the rigidity do not create unmasking signs.

Strengthening the rigidity of the structure of the AU 1 is possible by installing the MMCU 13 between the VDT 2 MP 11 and between the VDT 2 side walls, and between the VDT 2 side walls and the VDT 2 MK 6, while together with the MMUZH 15 side walls a closed semi-ring of rigidity is formed, as shown in Fig. . 13 - view from MP 11.

Additional strengthening of the structural rigidity of the AC 1 is possible by installing the VVUUZh 16 in the area of the corner connection of the VSHP 2 of adjacent side walls through the KMShR 5.

In the fully assembled AU 1, sagging of the VSHP 2 MK 6 is possible both under its own weight and under possible snow cover, and water accumulation is also possible.

Possible sagging VSHP 2 MK 6 can be minimized by strengthening MK 6, which consists in installing, between opposite VSHP 2 side walls, horizontal load-bearing beams 17, the ends of which are fixed on MMUZH 15 VSHP 2, respectively, and installing slopes 18 in the form of plates, fixed at one end to the carrier beam 17, and at the other end to MMUZH 15 MK 6, thus forming triangular trusses of the floating ceiling. All structural elements of the floating ceiling are made of a dielectric material;

Installation on AC 1 VVUUZh 16 and reinforcement, in the form of a floating ceiling, MK 6 is shown in Fig. fourteen.

General view of AC 1 in assembled form with planar masking, with an extension along the base, for example, five KMShR 5 along one coordinate and four KMShR 5 along another coordinate, while the VSHP 2 MK 6 and the VSHP 2 of the side wall along the expansion of four KMShR 5 are made with camouflage for wall blocks, and a double-leaf door 19, each half of which is made of four PSHP 4 and mounted on dielectric hinges 20, is shown in Fig. 15.

The tongue-and-groove connection of all elements of the AU 1 among themselves creates a kind of monolithic structure and, in addition, provides high waterproofing of the joint joints. Additionally, it is possible to improve the waterproofing of MK 6 by sealing the joints of the VSHP 2 joint with silicone sealant.

Claims (22)

1. A method for masking an antenna device by using a protective radio-transparent modularly expandable with a constant step along any of the coordinates OX, OY and OZ of the sides of a dielectric ground-based antenna shelter, made entirely of one type of radio-transparent dielectric material, on the outer surfaces of which masking is made in the form of a decorative finish , imitating the appearance of the object or landscape where the antenna shelter is installed, and harmoniously fitting into it, consisting in a frameless assembly by installing on three-coordinate corner posts, the same for the base module and the roof module, forming an expansion step along any coordinate OX, OY and OZ , at least two sections of coordinate inter-module-step expanders for each coordinate, sheet pile base modules, which are made in the form of square-shaped panels and are subdivided into intra-sheet pile panels, the same for side walls, floor module panels and panels of the cr and on the half-tongue panels of the hatch or side access door inside the antenna shelter, while the thickness of the inner tongue and groove panels is the same, and the depth and thickness of the inner tongue of the inner tongue and groove panels are the same, and are interconnected by external intermodular tongues, which are made in the shape of a rectangular plate, the length of which is equal to the length of the side of the sheet pile base module, and the width and thickness are equal to twice the depth and thickness of the inner sheet pile of the sheet pile base module, respectively, while the masking and assembly of the antenna shelter is carried out with the following steps: - masking of the outer surfaces of sheet pile base modules, three-coordinate corner posts and sections of coordinate inter-module-step expanders in the form of a planar or volumetric decorative finish that imitates the appearance of the object or landscape on which the antenna shelter is installed is carried out; - the base module of the antenna shelter is formed along the coordinates OX and OY by installing four three-coordinate corner posts, respectively, in the four corners of the base module, each three-coordinate corner post of the base module is located in its rectangular coordinate system, while the three-coordinate corner post is made of three identical bars, located along the coordinates OX, OY and OZ of the rectangular coordinate system, respectively, the bars are made of square cross-section, the side of the square of which is equal to the thickness of the sheet pile base module, and the length is equal to half the length of the sheet pile base module, while in the three-coordinate planes ZOX, ZOY and XOY on the bars of each of the three-coordinate corner post, three identical L-shaped plates, respectively, are made along the longitudinal axis, which consists of a horizontal branch plate and a vertical branch plate, and on each three-coordinate corner post in the XOY plane there are plates of four branches oriented horizontally, and in the ZOY plane and in the ZOX plane there is one plate of branches oriented vertically, while the plates of the horizontal and vertical branches of the L-shaped plate are made of the same length and are equal to half the length of the sheet pile base modules, and the width and the thickness of the plates of the horizontal and vertical branches are equal to the depth and thickness of the inner sheet pile of the sheet pile base module, respectively, and are external sheet piles for sheet pile base modules, while along the OX coordinate and along the OY coordinate between the horizontal bars of the four three-coordinate corner posts of the base module, they are installed in each of the four openings , at least two sections of the coordinate intermodule-step expander, which is made in the form of a bar of square cross-section, the side of the square of which is equal to the thickness of the sheet pile base module, and the length is equal to the length of the side of the sheet pile base module, while on two adjacent hundred on the sides of the section of the coordinate intermodule-step expander, two identical rectangular plates are installed in the center along the longitudinal axis, the length of which is equal to the length of the side of the sheet pile base module, and the width and thickness are equal to the depth and thickness of the inner sheet pile of the sheet pile base module, respectively, while the mutually perpendicular plates of the coordinate section inter-module-step expander are external tongues for tongue-and-groove base modules, and the outer tongues of the sections of the coordinate inter-module-step expanders are aligned with the external tongues of the three-coordinate corner posts of the base module, forming four side openings; - the contour of the floor module of the antenna shelter is assembled by installing on the external horizontal tongues of the base module along the entire perimeter with internal tongues of the tongue and groove panels, thereby forming a floor module, while in the area of connection of the end walls of adjacent tongue and groove panels, external intermodular tongues are installed, which are made in the form of rectangular plates, the length of which is equal to or less than the length of the side of the tongue and groove panel, and the width and thickness are equal to twice the depth and thickness of the inner tongue of the tongue and groove panel, respectively; - the formation of the side walls of the first base row of the antenna shelter with a hatch or side access door is carried out by installing three-coordinate corner posts and sections of coordinate inter-module-step expanders with internal tongues of the inner sheet pile panels in four side openings on the outer horizontal and vertical tongues, while at least in one side opening, at least one semi-tongue panel is installed, while external intermodular tongues are installed in the inner tongues of the first base row of the inner tongue and groove panels; - the height of the side openings of the antenna shelter is formed by installing along the OZ coordinate on a vertical bar of each three-coordinate corner post of the base module, at least two sections of the coordinate inter-module-step expander, while the outer tongues of the sections of the coordinate inter-module-step expanders are aligned with the external tongues the corresponding vertical bars of the three-coordinate corner posts of the base module; - the formation of the full height of the side walls of the antenna shelter is carried out by installing in four side openings on the outer sheet piles of the sections of the coordinate intermodule-step expanders and on the external intermodule sheet piles of the sheet pile base modules, and the number of rows of additional rows of sheet pile base modules along the height of the opening is equal to the number of sections of the coordinate intermodule - stepping expanders, while installing all the tongue and groove panels or the tongue and groove panels; - the assembly of the base of the roof module is carried out, which consists in installing in vertical, along the coordinates OZ, and horizontal, along the coordinates OX and OY, in the inner tongues of the last row of the tongue-and-groove base modules four corner joints with external tongues of four three-coordinate corner posts of the roof module, respectively, and in the openings between the horizontal bars of four three-coordinate corner posts of the roof module, sections of the coordinate inter-module-step expander are installed, the number of which is equal to the number of inter-module-step expanders on the corresponding side of the base module; - the assembly of the roof module is carried out, which consists in installing three-coordinate corner posts of the roof module and sections of coordinate inter-module-step expanders with internal tongues of the inner sheet pile panels on the external horizontal sheet piles until the roof module is completely filled; - Rigid fixation of the sheet pile base modules between each other through an external intermodular tongue, fixation of the sheet pile base modules with a three-coordinate corner post and fixation of the sheet pile base modules with a coordinate intermodule-step expander, which consists in a threaded connection by means of dielectric studs and / or dielectric bolts and / or cold welding. 2. The method according to claim 1, which consists in masking the antenna shelter by performing a planar pattern by applying radio-transparent paint to the outer surfaces of the tongue-and-groove base modules, to the outer surfaces of the bars of the three-coordinate corner posts and to the outer surfaces of the sections of the coordinate inter-module-step expanders. 3. The method according to claim 1, which consists in masking the antenna shelter by performing a three-dimensional pattern by mechanical processing or by installing cold welding of dielectric panels on the outer surfaces of the tongue-and-groove base modules, on the outer surfaces of the bars of the three-coordinate corner posts and on the outer surfaces of the sections of the coordinate intermodule-stepping expanders, and the color of the dielectric panels can match the natural color of the dielectric or with subsequent application of radio-transparent paint. 4. The method according to claim 1, which consists in connecting half-tongue panels of a door or hatch with inner-tongue panels, and / or with three-coordinate corner posts, and / or with sections of coordinate intermodule-step expanders using dielectric loops, which are fixed using dielectric bolts and /or cold welding. 5. The method according to claim 1, which consists in forming a complete closure of the floor module of the antenna shelter by installing inner sheet pile panels in the opening of the floor module contour, while external intermodular sheet piles are installed in the connection area of the end walls of adjacent inner sheet pile panels. 6. The method according to claim 1, which consists in strengthening the rigidity of the connection on the inside of the antenna shelter of the end walls of adjacent inner sheet piling panels of the side walls, the inner sheet piling panels of the floor module modules and the inner sheet piling panels of the roof module by installing dielectric intermodular stiffeners, which consist of a rectangular base plate and located on it, perpendicularly along the longitudinal axis, the plate of the stiffener, while the width of the base plate is equal to the width of the external intermodular tongue, and the length of the base plate and the length of the plate of the stiffener are equal to or less than the length of the external intermodular tongue, and the base plate of the intermodular stiffener is attached to the studs rigid fixation of sheet pile panels. 7. The method according to claim 1, which consists in strengthening the rigidity of the connection, on the inside of the antenna shelter, of the inner sheet pile panels of the field module with the inner sheet pile panels of the side walls through the coordinate intermodule-step expander and the inner sheet pile panels of the side walls with the inner sheet pile panels of the roof module through the coordinate intermodule-step expander by installing dielectric intermodular corner reinforcements, one face of which is installed on the connection area of the end walls of adjacent inner sheet pile panels of the side walls, and the other side is installed on the connection area of the end walls of adjacent inner sheet pile panels of the floor module and the roof module, respectively, with one and the other edges of the intermodular corner amplifiers fastened to rigid fixation studs of the floor module inner sheet piling panels, side wall inner sheet piling panels and roof module inner sheet piling panels, respectively. 8. The method according to claim 7, which consists in making intermodular corner amplifiers in the form of a carrier plate-like shape, which is one face of the intermodular corner amplifier, in the center of the vertical beam of which a stop post is perpendicularly installed, which is the other face of the intermodular corner amplifier, made in the form of a rectangular plate, in this case, the length of the horizontal beam of the bearing plate-shaped form is equal to the length of the side of the tongue-and-groove panel, and the height of the vertical beam and the length of the thrust post are equal to half the length of the tongue-and-groove panel, and the vertical beam of the L-shaped carrier plate is installed on the connection area of the sheet pile panels of the side walls with the coordinate intermodule-step expander. 9. The method according to claim 7, which consists in the implementation of intermodular corner amplifiers in the form of a right dihedral angle, one and the other faces of which are made in the form of rectangular plates, while on the edge of the intermodular corner amplifiers from the side of the inner right angle, a plate of the corner amplifier is installed perpendicularly in the center L-shaped, the length of the horizontal and vertical rays of which is equal to the length of the face of the right dihedral angle on which it is installed, and the length of the plate of one and the other faces is less than or equal to half the length of the external intermodular tongue, and the width of the plate of one and the other faces is equal to the width of the external intermodular sheet piling, while one and the other faces of the intermodular corner reinforcements are attached to the studs of rigid fixation of the inner tongue and groove panels of the floor module, the inner tongue panels of the side walls and the inner tongue panels of the roof module, respectively. 10. The method according to claim 1, which consists in strengthening the rigidity of the vertical corner joint on the inside of the antenna shelter, the inner sheet pile panels of adjacent side walls, connected through a coordinate inter-module-step expander by installing dielectric vertical internal corner stiffeners of the side walls, made in the form of a straight dihedral corner, one and the other faces of which are made in the form of rectangular plates, while the length of the face of the dihedral angle is equal to or less than the length of the external intermodular tongue, and the width is equal to or greater than half the width of the external intermodular tongue, while on the inside of the right dihedral angle of the vertical internal corner reinforcement rigidity, a dielectric, at least one corner strut in the form of a plate, the outer contour of which is made in the form of an isosceles hyperbola, the asymptotes of which are mutually perpendicular, is installed, while one and the other branches of the outer contour of the corner strut are installed on one and the other plates of the inner faces of the vertical inner corner stiffeners, respectively. 11. The method according to claim 6, which consists in strengthening the roof module of the antenna shelter by installing at least one dielectric horizontal carrier beam installed symmetrically between one and the other side walls, the ends of the carrier beam being fixed on the intermodular stiffeners of the inner sheet pile panels of one and the other side walls, while between the horizontal carrier beam and the intermodular stiffeners of the tongue and groove panels of the roof module, dielectric slopes are installed in the form of dielectric plates, forming triangular trusses that form a floating ceiling. 12. The method according to claim 1, which consists in strengthening the antenna shelter by installing guy wires in the corners of the upper row of sheet pile base modules and / or in the lower rows of sheet pile base modules from the outer and / or inner side of the antenna shelter. 13. The method according to p. 1, which consists in creating forced or natural air exchange of the internal volume of the antenna shelter by making through ventilation holes in the sheet pile base modules.

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